methylcellulose and hydroxypropylmethylcellulose-acetate-succinate

Hydroxypropyl methylcellulose acetate succinate (HPMCAS) has multi-disciplinary applications spanning across the development of drug delivery systems, in 3D printing, and in tissue engineering, etc. HPMCAS helps in maintaining the drug in a super-saturated condition by inhibiting its precipitation, thereby increasing the rate and extent of dissolution in the aqueous media. HPMCAS has several distinctive characteristics, such as being amphiphilic in nature, having an ionization pH, and a succinyl and acetyl substitution ratio, all of which are beneficial while developing formulations. This review provides insights regarding the various types of formulations being developed using HPMCAS, including amorphous solid dispersion (ASD), amorphous nanoparticles, dry coating, and 3D printing, along with their applicability in drug delivery and biomedical fields. Furthermore, HPMCAS, compared with other carbohydrate polymers, shows several benefits in drug delivery, including proficiency in imparting stable ASD with a high dissolution rate, being easily processable, and enhancing bioavailability. The various commercially available formulations, regulatory considerations, and key patents containing the HPMCAS have been discussed in this review.

Topics: Biological Availability; Drug Delivery Systems; Methylcellulose; Nanoparticles

Amorphous solid dispersions (ASDs) are a proven system for achieving a supersaturated state of drug, in which the concentration of drug is greater than its crystalline solubility. The usage of Hydroxypropyl Methylcellulose Acetate Succinate (HPMCAS) in the development of ASDs has grown significantly, as evidenced by the fact that majority of commercially approved ASD formulations are based on HPMCAS. HPMCAS has been widely utilized as a solubility enhancer and precipitation inhibitor or stabilizer to achieve supersaturation and inhibit crystallization of drugs in the gastrointestinal tract. The characteristics of HPMCAS ASDs such as less hygroscopic, strong drug-polymer hydrophobic interactions, high solubilization efficiency, greater potential to generate, maintain drug supersaturation and crystallization inhibition outperform other polymeric carriers in ASD development. Furthermore, combining HPMCAS with other polymers or surfactants as ternary ASDs could be a viable approach for enhancing oral absorption of poorly soluble drugs. This review discusses the concepts of supersaturation maintenance or precipitation inhibition of HPMCAS in the ASD formulations. In addition, the mechanisms underlying for improved dissolution performance, oral bioavailability and stability of HPMCAS ASDs are explored.

Topics: Drug Compounding; Methylcellulose; Polymers; Solubility

Hypromellose acetate succinate (HPMCAS) is an enteric polymer that has been successfully employed as a carrier in amorphous solid dispersions (ASDs). Deprotonation of succinic acid substituents at intestinal pH levels results in solubilization of the polymer. However, the acidic moieties responsible for favorable pH-dependent solubility can also result in incompatibilities between acid-sensitive drugs and HPMCAS. Solution-state conversion of the carboxylic acid substituents of enteric polymers into carboxylate salts to reduce acid-mediated drug degradation is a demonstrated effective strategy for generating ASDs in enteric polymers. This work aimed to extend the use of a pre-ionized enteric polymer to KinetiSol solvent-free processing to reduce acid- or base-mediated drug degradation during processing. Pre-ionization of HPMCAS was accomplished by reaction with a stoichiometric quantity of sodium carbonate (Na

Topics: Catalysis; Methylcellulose; Polymers; Solubility

Hydroxypropyl methylcellulose acetate succinate (HPMCAS) is a weakly acidic polymer that is widely used in the formulation of amorphous solid dispersions (ASDs). While the pH-dependent solubility of HPMCAS is widely recognized, the role of other solution properties, including buffer capacity, is less well understood in the context of ASD dissolution. The goal of this study was to elucidate the rate-limiting steps for drug and HPMCAS release from ASDs formulated with two poorly water soluble model drugs, indomethacin and indomethacin methyl ester. The surface area normalized release rate of the drug and/or polymer in a variety of media was determined. The HPMCAS gel layer apparent pH was determined by incorporating pH sensitive dyes into the polymer matrix. Water uptake extent and rate into the ASDs were measured gravimetrically. For neat HPMCAS, the rate-limiting step for polymer dissolution was observed to be the polymer solubility at the polymer-solution interface. This, in turn, was impacted by the gel layer pH which was found to be substantially lower than the bulk solution pH, varying with medium buffer capacity. For the ASDs, the HPMCAS release rate was found to control the drug release rate. However, both drugs reduced the polymer release rate with indomethacin methyl ester having a larger impact. In low buffer capacity media, the presence of the drug had less impact on release rates when compared to observations in higher strength buffers, suggesting changes in the rate-limiting steps for HPMCAS dissolution. The observations made in this study can contribute to the fundamental understanding of acidic polymer dissolution in the presence and absence of a molecularly dispersed lipophilic drug and will help aid in the design of more

Topics: Drug Liberation; Esters; Indomethacin; Methylcellulose; Polymers; Solubility; Water

Understanding the dissolution mechanisms of amorphous solid dispersions (ASDs) and being able to link enhanced drug exposure with process parameters are key when formulating poorly soluble compounds. Thus, in this study, ASDs composed by itraconazole (ITZ) and hydroxypropylmethylcellulose acetate succinate (HPMCAS) were formulated with different polymer grades and drug loads (DLs) and processed by spray drying with different atomization ratios and outlet temperatures. Their

Topics: Calorimetry, Differential Scanning; Colloids; Drug Combinations; Drug Compounding; Drug Liberation; Itraconazole; Methylcellulose; Microscopy, Electron, Scanning; Particle Size; X-Ray Diffraction

Nucleation inhibition and maintenance of drug supersaturation over a prolonged period are desirable for improving oral absorption of amorphous solid dispersions. The present study investigates the impact of binary and ternary amorphous solid dispersions on the supersaturation kinetics of nifedipine using the polymers hydroxypropylmethylcellulose acetate succinate (HPMCAS) LG, and HG, Eudragit® RSPO, Eudragit® FS100, Kollidon® VA64 and Plasdone™ K-29/32. The amorphous solubility, nucleation induction time, and particle size analysis of nifedipine in a supersaturated solution were performed with and without the presence of polymers, alone or in combination. The HPMCAS-HG and HPMCAS-HG + LG combinations showed the highest nifedipine amorphous solubility of 169.47, 149.151 µg/mL, respectively and delay in nucleation induction time up to 120 min compared to other polymeric combinations. The solid dispersions prepared via hot melt extrusion showed the transformation of crystalline nifedipine to amorphous form. The in-vitro non-sink dissolution study revealed that although the binary nifedipine/HPMCAS-LG system had shown the greater supersaturation concentration of 66.1 µg/mL but could not maintain a supersaturation level up to 360 min. A synergistic effect emerged for ternary nifedipine/HPMCAS-LG/HPMCAS-HG, and nifedipine/HPMCAS-LG/Eudragit®FS100 systems maintained the supersaturation level with enhanced dissolution performance, demonstrating the potential of polymeric combinations for improved amorphous solid dispersion performance.

Topics: Kinetics; Methylcellulose; Polymers; Solubility

3D printing (3DP) by fused deposition modelling (FDM) is one of the most extensively developed methods in additive manufacturing. Optimizing printability by improving feedability, nozzle extrusion, and layer deposition is crucial for manufacturing solid oral dosage forms with desirable properties. This work aimed to use HPMCAS (Affinisol

Topics: Dosage Forms; Drug Liberation; Excipients; Methylcellulose; Printing, Three-Dimensional; Tablets; Technology, Pharmaceutical

Amorphous solid dispersions (ASDs) utilize the kinetic stability of the amorphous state to stabilize drug molecules within a glassy polymer matrix. Therefore, understanding the glassy-state stability of the polymer excipient is critical to ASD design and performance. Here, we investigated the physical aging of hydroxypropyl methylcellulose acetate succinate (HPMCAS), a commonly used polymer in ASD formulations. We found that HPMCAS exhibited conventional physical aging behavior when annealed near the glass transition temperature (

Topics: Drug Stability; Excipients; Methylcellulose; Polymers; Solubility

Changing the physical state from crystalline to amorphous is an elegant method to increase the bioavailability of poorly soluble new chemical entity (NCE) drug candidates. Subsequently, we report findings from repeat-dose toxicity studies of an NCE formulated as a spray-dried amorphous solid dispersion (SD-ASD) based on hydroxypropyl methylcellulose acetate succinate (HPMC-AS) in rats. At necropsy, agglomerates of SD-ASD were found in the stomach and small intestine, which in reference to literature were termed pharmacobezoars. We interpreted the pH-dependent insolubility of HPMC-AS in the acidic gastric environment to be a precondition for pharmacobezoar formation. Gastric pharmacobezoars were not associated with clinical signs or alterations of clinical pathology parameters. Pharmacobezoar-correlated histopathological findings were limited to the stomach and consisted of atrophy, erosion, ulcer, and inflammation, predominantly of the nonglandular mucosa. Pharmacobezoars in the small intestines induced obstructive ileus with overt clinical signs which required unscheduled euthanasia, prominent alterations of clinical pathology parameters indicative of hypotonic dehydration, degenerative and inflammatory processes in the gastrointestinal tract, and secondary renal findings. The incidence of pharmacobezoars increased with dose and duration of dosing. Besides the relevance of pharmacobezoars to animal welfare, they limit the non-observed adverse effect level in nonclinical testing programs and conclusively their informative value.

Topics: Animals; Gastrointestinal Tract; Methylcellulose; Rats; Research

Polymers play an important role in amorphous solid dispersions (ASDs), enhancing stability in the solid state and maintaining supersaturation in aqueous solutions of intrinsically low-water-soluble drug candidates. Hydroxypropyl methylcellulose acetate succinate (HPMCAS) is widely used in ASDs due to its hydrophobic/hydrophilic balance and ionizability of the substituent functionalities. While colloid formation of HPMCAS in solution due to this hydrophobic/hydrophilic balance has been studied, the impact of the polymer conformation (random coil vs aggregated) on drug supersaturation of ASDs is not well understood. To our knowledge, this is the first report where the critical aggregation concentration for three grades of HPMCAS (HF/MF/LF) has been determined via fluorescence spectroscopy using the environment-sensitive probe pyrene. The specific impact of polymer conformation (random coil vs aggregate) on the model drug celecoxib (CLX) has been elucidated with fluorescence quenching and nuclear magnetic resonance (NMR) spectroscopy. A negative deviation of the Stern-Volmer plot indicated that aggregated HPMCAS effectively blocked the quencher's access to CLX. This is further supported by NMR observations, where NMR spectra indicate a larger change of chemical shift of the -NH group of CLX when HPMCAS is above its aggregated concentration, suggesting strong H-bonding interactions between aggregated HPMCAS and CLX. Finally, the supersaturation-precipitation study shows that all three grades of HPMCAS in the aggregated state significantly enhanced CLX supersaturation compared to the nonaggregated state, indicating that polymer aggregation plays a critical role in maintaining drug supersaturation.

Topics: Celecoxib; Chemical Precipitation; Crystallization; Magnetic Resonance Spectroscopy; Methylcellulose; Solubility; Spectrometry, Fluorescence

Poor solubility of drug candidates is a well-known and thoroughly studied challenge in the development of oral dosage forms. One important approach to tackle this challenge is the formulation as an amorphous solid dispersion (ASD). To reach the desired biopharmaceutical improvement a high supersaturation has to be reached quickly and then be conserved long enough for absorption to take place. In the presented study, various formulations of regorafenib have been produced and characterized in biorelevant in-vitro experiments. Povidone-based formulations, which are equivalent to the marketed product Stivarga®, showed a fast drug release but limited stability and robustness after that. In contrast, HPMCAS-based formulations exhibited excellent stability of the supersaturated solution, but unacceptably slow drug release. The attempt to combine the desired attributes of both formulations by producing a ternary ASD failed. Only co-administration of HPMCAS as an external stabilizer to the rapidly releasing Povidone-based ASDs led to the desired dissolution profile and high robustness. This optimized formulation was tested in a pharmacokinetic animal model using Wistar rats. Despite the promising in-vitro results, the new formulation did not perform better in the animal model. No differences in AUC could be detected when compared to the conventional (marketed) formulation. These data represent to first in-vivo study of the new concept of external stabilization of ASDs. Subsequent in-vitro studies revealed that temporary exposure of the ASD to gastric medium had a significant and long-lasting effect on the dissolution performance and externally administered stabilizer could not prevent this sufficiently. By applying the co-administered HPMCAS as an enteric coating onto Stivarga tablets, a new bi-functional approach was realized. This approach achieved the desired tailoring of the dissolution profile and high robustness against gastric medium as well as against seeding.

Topics: Animals; Biological Products; Dosage Forms; Drug Administration Routes; Drug Compounding; Drug Liberation; Excipients; Methylcellulose; Phenylurea Compounds; Povidone; Pyridines; Rats; Solid Phase Extraction; Solubility; Tablets, Enteric-Coated

The intestinal fluid pH is maintained by the bicarbonate buffer system that shows unique properties regarding drug dissolution. Nevertheless, current compendial dissolution tests use phosphate buffers. The purpose of the present study was to investigate the effect of bicarbonate and phosphate buffers on the dissolution profiles of amorphous solid dispersions (ASD) composed of ionizable polymers.. Hydroxypropylmethylcellulose acetate succinate (HPMCAS), amino methacrylate copolymer (AMC), and hydroxypropylmethylcellulose (HPMC) were employed as acidic, basic, and neutral polymers, respectively. Nifedipine (NIF) was used as a model drug. Dissolution profiles were measured in pH 6.5 bicarbonate and phosphate buffers by a mini-scale paddle dissolution test. The pH of bicarbonate buffers was maintained by the floating lid method.. The pH change of the bicarbonate buffer was suppressed to less than + 0.25 pH for 3 h by the floating lid method. In all cases, the NIF concentration was supersaturated against the solubility of crystalline NIF. The dissolution rates of HPMCAS and AMC ASDs were 1.5 to 2.0-fold slower in the bicarbonate buffer than in the phosphate buffer when compared at the same buffer capacity. The dissolution profile of HPMC ASD was not affected by the buffer species. The higher the buffer capacity and ionic strength, the faster the dissolution rate of HPMCAS ASD.. The dissolution rate of ASDs with ionizable polymers would be overestimated by using unphysiological phosphate buffer solutions. It is important to use a biorelevant bicarbonate buffer solution for dissolution testing.

Topics: Bicarbonates; Buffers; Chemistry, Pharmaceutical; Drug Carriers; Drug Liberation; Hydrogen-Ion Concentration; Methylcellulose; Nifedipine; Phosphates; Polymers; Solubility

We demonstrated a facile approach, by adjusting the solvent ratio of water/acetone binary mixture, to alter the intermolecular interactions between Enzalutamide (ENZ) and hydroxypropyl methylcellulose acetate succinate (HPMC-AS) for spray drying process, which can be readily implemented to produce spray-dried dispersions (SDD) with enhanced stability and bioavailability. The prepared SDD of ENZ/HPMC-AS were examined systematically in terms of particle size, morphology, dissolution, solubility, stability, and bioavailability. Our results show that the introduction of water (up to 30% volume fraction) can effectively reduce the hydrodynamic diameter of HPMC-AS from approximately 220 nm to 160 nm (a reduction of c.a. 20%), which increases the miscibility of the drug and polymer, delaying or inhibiting the crystallization of ENZ during the spray drying process, resulting in a homogeneous amorphous phase. The benefits of using acetone/water binary mixture were subsequently evidenced by an increased specific surface area, improved dissolution profile and relative bioavailability, enhanced stability, and elevated drug release rate. This fundamental finding underpins the great potential of using binary mixture for spray drying process to process active pharmaceutical ingredients (APIs) that are otherwise challenging to handle.

Topics: Acetone; Benzamides; Biological Availability; Drug Stability; Methylcellulose; Nitriles; Pharmaceutical Preparations; Phenylthiohydantoin; Solubility; Solvents; Water

We present a new approach for characterizing drug-polymer interactions in aqueous media, using sedimentation velocity analytical ultracentrifugation (AUC). We investigated the potential interaction of ketoconazole (KTZ), a poorly water-soluble drug, with polyacrylic acid (PAA) and a polyvinyl caprolactam-polyvinyl acetate-polyethylene glycol graft copolymer (Soluplus) in aqueous buffers. The effect of the polymer on the sedimentation coefficient of the drug was the observable metric. The drug alone, when subjected to AUC, exhibited a very narrow sedimentation peak at 0.2 Svedberg (S), in agreement with the expectation for a monomeric drug with a molar mass < 1000 Dalton. Conversely, the neat polymers showed broad profiles with higher sedimentation coefficients, reflecting their larger more heterogeneous size distributions. The sedimentation profiles of the drug-polymer mixtures were expectedly different from the profile of the neat drug. With KTZ-Soluplus, a complete shift to faster sedimentation times (indicative of an interaction) was observed, while with KTZ-PAA, a split peak indicated the existence of the drug in both free and interacting states. The sedimentation profile of carbamazepine, a second model drug, in the presence of hydroxypropyl methyl cellulose acetate succinate (HPMCAS, another polymer) revealed multiple "populations" of drug-polymer species, very similar to the sedimentation profile of neat HPMCAS. The interactions probed by AUC were compared with the results from isothermal titration calorimetry. In vitro dissolution tests performed on amorphous solid dispersions prepared with the same drug-polymer pairs suggested that the interactions may play a role in prolonging drug supersaturation. The results show the possibility of characterizing drug-polymer interactions in aqueous solution with high hydrodynamic resolution, addressing a major challenge frequently encountered in the mechanistic investigations of the dissolution behavior of amorphous solid dispersions.

Topics: Acrylic Resins; Crystallization; Ketoconazole; Methylcellulose; Pharmaceutical Preparations; Polyethylene Glycols; Polymers; Polyvinyls; Solubility; Ultracentrifugation; Water; X-Ray Diffraction

This study investigates the effects of supercritical CO

Topics: Carbon Dioxide; Cellulose; Drug Compounding; Itraconazole; Methylcellulose; Solubility; Succinates

The present study was aimed to develop a novel sustained-release formulation for allopurinol (ALP/SR) with the use of a pH-sensitive polymer, hydroxypropyl methylcellulose acetate succinate, to reduce nephrotoxicity. ALP/SR was evaluated in terms of crystallinity, the dissolution profile, pharmacokinetic behavior, and nephrotoxicity in a rat model of nephropathy. Under acidic conditions (pH1.2), sustained release behavior was seen for ALP/SR, although both crystalline ALP and ALP/SR exhibited rapid dissolution at neutral condition. After multiple oral administrations of ALP samples (10 mg-ALP/kg) for 4 days in a rat model of nephropathy, ALP/SR led to a low and sustained plasma concentration of ALP, as evidenced by half the maximum concentration of ALP and a 2.5-fold increase in the half-life of ALP compared with crystalline ALP, possibly due to suppressed dissolution behavior under acidic conditions. Repeated-dosing of ALP/SR resulted in significant reductions in plasma creatinine and blood urea nitrogen levels by 73% and 69%, respectively, in comparison with crystalline ALP, suggesting the low nephrotoxic risk of ALP/SR. From these findings, a strategic SR formulation approach might be an efficacious dosage option for ALP to avoid severe nephrotoxicity in patients with nephropathy.

Topics: Administration, Oral; Allopurinol; Animals; Antineoplastic Agents; Blood Urea Nitrogen; Cisplatin; Creatinine; Delayed-Action Preparations; Drug Liberation; Gout Suppressants; Half-Life; Kidney; Kidney Diseases; Male; Methylcellulose; Rats, Sprague-Dawley

Among the great number of poorly soluble drugs in pharmaceutical development, most of them are weak bases. Typically, they readily dissolve in an acidic environment but are prone to precipitation at elevated pH. This was aimed to be counteracted by the preparation of amorphous solid dispersions (ASDs) using the pH-dependent soluble polymers methacrylic acid ethylacrylate copolymer (Eudragit L100-55) and hydroxypropylmethylcellulose acetate succinate (HPMCAS) via hot-melt extrusion. The hot-melt extruded ASDs were of amorphous nature and single phased with the presence of specific interactions between drug and polymer as revealed by X-ray powder diffraction (XRPD), differential scanning calorimetry (DSC), and Fourier-transform infrared spectroscopy (FT-IR). The ASDs were milled and classified into six particle size fractions. We investigated the influence of particle size, drug load, and polymer type on the dissolution performance. The best dissolution performance was achieved for the ASD made from Eudragit L100-55 at a drug load of 10%, whereby the dissolution rate was inversely proportional to the particle size. Within a pH-shift dissolution experiment (from pH 1 to pH 6.8), amorphous-amorphous phase separation occurred as a result of exposure to acidic medium which caused markedly reduced dissolution rates at subsequent higher pH values. Phase separation could be prevented by using enteric capsules (Vcaps Enteric®), which provided optimal dissolution profiles for the Eudragit L100-55 ASD at a drug load of 10%.

Topics: Acrylic Resins; Antifungal Agents; Calorimetry, Differential Scanning; Drug Compounding; Drug Liberation; Hydrogen-Ion Concentration; Ketoconazole; Methacrylates; Methylcellulose; Particle Size; Pharmaceutical Preparations; Polymers; Powder Diffraction; Solubility; Spectroscopy, Fourier Transform Infrared

Amorphous solid dispersions (ASDs), which consist of a drug dispersed in a polymeric matrix, are increasingly being applied to improve the

Topics: Crystallization; Drug Compounding; Drug Liberation; Hypromellose Derivatives; Methylcellulose; Nanoparticles; Polymers; Solubility; Water

To evaluate the effects of Hydroxypropyl methylcellulose acetate succinate(HPMCAS MF) on absorption of silybin(SLB) from supersaturable self-nanoemulsifying drug delivery system which was pre-prepared at the early stage experiment. The cell toxicity of self-emulsifying preparation was evaluated by the MTT method, and the in vitro membrane permeability and absorption promoting effect of the self-emulsifying preparation were evaluated by establishing a Caco-2 cell monolayer model. The in vivo and in vitro supersaturation correlation was evaluated via the blood concentration of SLB. The results of MTT showed that the concentration of the preparation below 2 mg·mL~(-1)(C_(SLB) 100 μg·mL~(-1)) was not toxic to Caco-2 cells, and the addition of polymer had no significant effect on Caco-2 cells viability. As compared with the solution group, the transport results showed that the P_(app)(AP→BL) of the self-emulsifying preparation had a very significant increase; the transport rate of silybin can be reduced by polymer in 0-30 min; however, there was no difference in supersaturated transport between supersaturated SLB self-nanoemulsion drug delivery system(SLB-SSNEDDS) and SLB self-nanoemulsion drug delivery system(SLB-SNEDDS) within 2 hours. As compared with SLB suspension, pharmacokinetic parameters showed that the blood concentration of both SLB-SNEDDS and SLB-SSNEDDS groups were significantly increased, and C_(max) was 5.25 times and 9.69 times respectively of that in SLB suspension group, with a relative bioavailability of 578.45% and 1 139.44% respectively. C_(max) and relative bioavailability of SLB-SSNEDDS were 1.85 times and 197% of those of SLB-SNEDDS, respectively. Therefore, on the one hand, SSNEDDS can increase the solubility of SLB in gastrointestinal tract by maintaining stability of SLB supersaturation state; on the other hand, the osmotic transport process of SLB was regulated through the composition of its preparations, and both of them could jointly promote the transport and absorption of SLB to improve the oral bioavailability of SLB.

Topics: Administration, Oral; Biological Availability; Caco-2 Cells; Drug Delivery Systems; Emulsions; Humans; Methylcellulose; Nanoparticles; Particle Size; Silybin; Solubility

Microencapsulation is a potential biotechnological tool, which can overcome antimicrobial peptides (AMP) instabilities and reduce toxic side effects. Thus, this study evaluates the antibacterial activities of the Ctx(Ile

Topics: Acinetobacter baumannii; Alginates; Drug Compounding; Food Additives; Hemolysis; Methylcellulose; Microbial Sensitivity Tests; Particle Size; Pore Forming Cytotoxic Proteins; Pseudomonas aeruginosa; Salmonella; Staphylococcus aureus

HPMCAS-HF, HPMCAS-MF and HPMCAS-LF were used as carriers to prepare the amorphous solid dispersions (ASDs) of quercetin (Que) by co-precipitation. The Que ASD based on PVP K30 was prepared by solvent evaporation method. The ability of polymer to inhibit Que crystallization was evaluated. The study found the order of the ability of polymer to inhibit Que nucleation to be: HF > MF > LF > K30, and that to maintain Que supersaturation to be: HF > K30 > MF > LF. The prepared solid dispersions were characterized by IR, DSC and PXRD. Although HF was the most effective crystallization inhibitor, the release of the Que/HF ASD was poor and assigned to the carrier-controlled dissolution for the strong interactions between Que and HF. The Que/MF ASD exhibited better dissolution behavior compared to the Que/K30 ASD. The dissolution behavior of the Que ASD depended on the polymer-Que interactions and the ability of crystallization inhibition of the polymer.

Topics: Methylcellulose; Povidone; Quercetin; Solubility

Lutein has been used as a dietary supplement for the treatment of eye diseases, especially age-related macular degeneration. For oral formulations, we investigated lutein stability in artificial set-ups mimicking different physiological conditions and found that lutein was degraded over time under acidic conditions. To enhance the stability of lutein upon oral intake, we developed enteric-coated lutein solid dispersions (SD) by applying a polymer, hydroxypropyl methylcellulose acetate succinate (HPMCAS-LF), through a solvent-controlled precipitation method. The SD were characterized in crystallinity, morphology, and drug entrapment. In the dissolution profile of lutein SD, a F80 formulation showed resistance toward the acidic environment under simulated gastric conditions while exhibiting a bursting drug release under simulated intestinal conditions. Our results highlight the potential use of HPMCAS-LF as an effective matrix to enhance lutein bioavailability during oral delivery and to provide novel insights into the eye-care supplement industry, with direct benefits for the health of patients.

Topics: Biological Availability; Chromatography, High Pressure Liquid; Drug Liberation; Drug Stability; Humans; Lutein; Methylcellulose; Polymers; Solubility; Solvents; X-Ray Diffraction

Candesartan cilexetil (CC) is a poorly soluble antihypertensive drug with

Topics: Animals; Antihypertensive Agents; Benzimidazoles; Biological Availability; Biphenyl Compounds; Chemistry, Pharmaceutical; Drug Carriers; Drug Delivery Systems; Male; Methylcellulose; Polymers; Rats; Rats, Wistar; Solubility; Tetrazoles

Mesoporous silica has emerged as an enabling formulation for poorly soluble active pharmaceutical ingredients (APIs). Unlike other formulations, mesoporous silica typically does not inhibit precipitation of supersaturated API therefore, a suitable precipitation inhibitor (PI) should be added to increase absorption from the gastrointestinal (GI) tract. However, there is limited research about optimal processes for combining PIs with silica formulations. Typically, the PI is added by simply blending the API-loaded silica mechanically with the selected PI. This has the drawback of an additional blending step and may also not be optimal with regard to release of drug and PI. By contrast, loading PI simultaneously with the API onto mesoporous silica, i.e. co-incorporation, is attractive from both a performance and practical perspective. The aim of this study was to demonstrate the utility of a co-incorporation approach for combining PIs with silica formulations, and to develop a mechanistic rationale for improvement of the performance of silica formulations using the co-incorporation approach. The results indicate that co-incorporating HPMCAS with glibenclamide onto silica significantly improved the extent and duration of drug supersaturation in single-medium and transfer dissolution experiments. Extensive spectroscopic characterization of the formulation revealed that the improved performance was related to the formation of drug-polymer interactions already in the solid state; the immobilization of API-loaded silica on HPMCAS plates, which prevents premature release and precipitation of API; and drug-polymer proximity on disintegration of the formulation, allowing for rapid onset of precipitation inhibition. The data suggests that co-incorporating the PI with the API is appealing for silica formulations from both a practical and formulation performance perspective.

Topics: Chemical Precipitation; Drug Carriers; Drug Liberation; Glyburide; Hypoglycemic Agents; Methylcellulose; Porosity; Silicon Dioxide

Formulation of amorphous solid dispersions (ASD) is one possibility to improve poor aqueous drug solubility by creating supersaturation. In case of weakly basic drugs like ketoconazole (KTZ), supersaturation can also be generated during the gastrointestinal (GI) transfer from the stomach to the intestine due to pH-dependent solubility. In both cases, the supersaturation during dissolution can be stabilized by polymeric precipitation inhibitors. A small-scale GI transfer model was used to compare the dissolution performance of ASD versus crystalline KTZ with the polymeric precipitation inhibitor HPMCAS. Similar in vitro AUCs were found for the transfer from SGF pH2 into FaSSIF. Moreover, the impact of variability in gastric pH on drug dissolution was assessed. Here, the ASD performed significantly better at a simulated hypochlorhydric gastric pHof 4. Last, the importance of drug-polymer interactions for precipitation inhibition was evaluated. HPMCAS HF and LF grades with and without the basic polymer Eudragit EPO were used. However, EPO caused a faster precipitation probably due to competition for the interaction sites between KTZ and HPMCAS. Thus, the results are suited to assess the benefits of amorphous formulations vs. precipitation inhibitors under different gastrointestinal conditions to optimize the design of such drug delivery systems.

Topics: Chemical Precipitation; Chemistry, Pharmaceutical; Drug Liberation; Gastrointestinal Tract; Hydrogen-Ion Concentration; Ketoconazole; Methylcellulose; Pharmaceutical Preparations; Polymers; Polymethacrylic Acids; Solubility

Hydroxypropylmethylcellulose (HPMC) acetyl succinate (HPMC-AS) is a key polymer used for the enablement of amorphous solid dispersions (ASDs) in oral solid dosage forms. Choice of the appropriate grade within the material is often made empirically by the manufacturer of small-scale formulations, followed by extensive real time stability. A key factor in understanding and predicting the performance of an ASD is related to the presence of hydrogen (or other) bonds between the polymer and active pharmaceutical ingredient (API), which will increase stability over the parameters captured by miscibility and predicted by the Gordon-Taylor equation. Solid state nuclear magnetic resonance (NMR) is particularly well equipped to probe spatial proximities, for example, between polymer and API; however, in the case of HPMC-AS, these interactions have been sometimes difficult to identity as the carbon-13 NMR spectra assignment is yet to be firmly established. Using feedstock, selectively substituted HPMC polymers, and NMR editing experiments, we propose here a comprehensive understanding of the chemical structure of HPMC-AS and a definitive spectral assignment of the

Topics: Carbohydrate Conformation; Carbon Isotopes; Chemistry, Pharmaceutical; Magnetic Resonance Spectroscopy; Methylcellulose; Polymers

In the pharmaceutical industry, polymers are used as excipients for formulating poorly water-soluble active pharmaceutical ingredients (APIs) in so-called "amorphous solid dispersions" (ASDs). ASDs can be produced via solvent-based processes, where API and polymer are both dissolved in a solvent, followed by a solvent evaporation step (e.g. spray drying). Aiming at a homogeneous API/polymer formulation, phase separation of the components (API, polymer, solvent) during solvent evaporation must be avoided. The latter is often determined by the phase behavior of polymer/solvent mixtures used for ASD processing. Therefore, this work investigates the polymer-solvent interactions in these mixtures. Suitable polymer/solvent combinations investigated in this work comprise the pharmaceutically relevant polymers poly(vinylpyrrolidone) (PVP), poly(vinylpyrrolidone-co-vinyl acetate) (PVPVA64), and hydroxyppropyl methylcellulose acetate succinate 126G (HPMCAS) as well as the solvents acetone, dichloromethane (DCM), ethanol, ethyl acetate, methanol, and water. Based on vapor-sorption experiments demixing of solvents and polymers were predicted using the Perturbed-Chain Statistical Associating Fluid Theory (PC-SAFT). These were found to be correct for all investigated solvent/polymer mixtures. Acetone, DCM, ethanol, methanol, and water were found to be completely miscible with PVPVA64. DCM, ethanol, methanol, and water were found to be completely miscible with PVP K90, while none of the investigated solvents was appropriate for avoiding immiscibility with HPMCAS. In addition, the impact of temperature, polymer molecular weight, and solvent-mixture composition on miscibility was successfully predicted using PC-SAFT. Thus, the proposed methodology allows identifying suitable solvents or solvent mixtures relevant for solvent-based preparations of pharmaceutical ASD formulations with low experimental effort.

Topics: Chemistry, Pharmaceutical; Excipients; Methylcellulose; Molecular Weight; Phase Transition; Polymers; Povidone; Pyrrolidines; Solvents; Temperature; Vinyl Compounds

In this study, the impact of drug and hydroxypropyl methylcellulose acetate succinate (HPMCAS) grades physicochemical properties on extrusion process, dissolution and stability of the hot melt extruded amorphous solid dispersions (ASDs) of nifedipine and efavirenz was investigated. Incorporation of drugs affected the extrusion temperature required for solid dispersion preparation. Differential scanning calorimetry and powder X-ray diffraction studies confirmed the amorphous conversion of the drugs in the prepared formulations. The amorphous nature of ASDs was unchanged after 3 months of stability testing at 40 °C and 75% relative humidity. The dissolution efficiency of the ASDs was dependent on the log P of the drug. The inhibitory effect of HPMCAS on drug precipitation was dependent on the hydrophobic interactions between drug and polymer, polymer grade, and dose of the drug. The dissolution efficiency and dissolution rate of the ASDs were dependent on the log P of the drug and solubility and hydrophilicity of the polymer grade respectively. The inhibitory effect of HPMCAS on drug precipitation was dependent on the hydrophobic interactions between drug and polymer, polymer grade, and the dissolution dose of the drug.

Topics: Acetates; Alkynes; Benzoxazines; Cyclopropanes; Drug Compounding; Drug Liberation; Drug Stability; Excipients; Hot Melt Extrusion Technology; Hot Temperature; Hypromellose Derivatives; Methylcellulose; Nifedipine; Solubility; Succinates

Despite the wide utilization of amorphous solid dispersions (ASDs) for formulating poorly water-soluble drugs, fundamental understanding of the structural basis behind their stability and dissolution behavior is limited. This is largely due to the lack of high-resolution structural tools for investigating multicomponent and amorphous systems in the solid state. In this study, we present what is likely the first publication quantifying the molecular interaction between the drug and polymer in ASDs at an angstrom level by utilizing

Topics: Hydrogen Bonding; Magnetic Resonance Spectroscopy; Methylcellulose; Models, Molecular; Molecular Structure; Polymers; Triazoles

Understanding and prevention of unwanted changes of a pharmaceutical formulation during the production process is part of the critical requirements for the successful approval of a new drug product. Polymer-based formulations, so-called amorphous solid dispersions (ASDs), are often produced via solvent-based processes. In such processes, active pharmaceutical ingredients (APIs) and polymers are first dissolved in a solvent or solvent mixture, then the solvent is evaporated, for example, via spray drying or rotary evaporation. During the drying step, unwanted liquid-liquid phase separation may occur, leading to polymer-rich and API-rich regions with crystallization potential, and thus, heterogeneities and a two-phasic system in the final ASD. Phase separation in ASDs may impact their bioperformance because of the locally higher degree of API supersaturation. Although it is known that the choice of the solvent plays an important role in the formation of heterogeneities, solvent-impact on ASD drying and eventual product quality is often neglected in the process design. This study aims to investigate for the first time the phase behavior and drying process of API/polymer/solvents systems from a thermodynamic perspective. Unwanted phase changes during the drying process of the ASD containing hydroxypropyl methylcellulose acetate succinate and naproxen prepared from acetone/water or ethanol/water solvent mixtures were predicted using the thermodynamic model PC-SAFT. The predicted phase behavior and drying curves were successfully validated by confocal Raman spectroscopy.

Topics: Acetone; Chemistry, Pharmaceutical; Crystallization; Desiccation; Drug Compounding; Ethanol; Methylcellulose; Models, Chemical; Naproxen; Phase Transition; Polymers; Solubility; Solvents; Spectrum Analysis, Raman; Thermodynamics; Water

This study demonstrated that an enteric polymer can mitigate the effects of gastric pH on the oral absorption of a poorly water-soluble weak acid drug, dantrolene (DNT). An amorphous solid dispersion (ASD) of DNT with hydroxypropyl methylcellulose (HPMC) acetate succinate (ASD-HPMCAS) was prepared as the enteric released ASD (ER-SF). ASD with HPMC (ASD-HPMC) and DNT sodium salt were also used as immediate-release supersaturable formulations (IR-SFs) with and without water-soluble polymer, respectively. In vivo study with rats and in vitro study with a dissolution/permeation (D/P) system were performed to evaluate oral DNT absorption from each formulation under normal and high gastric pH conditions in rats and humans, respectively. The oral absorption of DNT from both IR-SFs in rats with a high gastric pH was significantly higher than that in rats with a normal gastric pH. In contrast, ASD-HPMCAS attenuated the difference in oral absorption between normal and high gastric pH conditions with significant improvement of DNT absorption. In vivo results implied that an enteric polymer delayed the onset of dissolution until after gastric emptying. ASD-HPMCAS generated supersaturation in the small intestine irrespective of gastric conditions, which was supported bythe in vitrostudy using the D/P system. This study suggested that an enteric polymer is useful to mitigate the inter- and intra-individual differences in oral absorption of poorly water-soluble weak acid drugs.

Topics: Administration, Oral; Animals; Caco-2 Cells; Dantrolene; Drug Compounding; Gastric Acid; Humans; Hydrogen-Ion Concentration; Hypromellose Derivatives; Intestinal Absorption; Male; Methylcellulose; Muscle Relaxants, Central; Polymers; Rats; Rats, Sprague-Dawley; Solubility

Using fixed dose combinations of drugs instead of administering drugs separately can be beneficial for both patients and the health care system, but the current understanding of how multidrug formulations work at the molecular level is still in its infancy. Here, we explore dissolution, solubility, and supersaturation of various drug combinations in amorphous formulations. The effect of chemical structural similarity on combination behavior was investigated by using structurally related compounds of both drugs. The effect of polymer type on solution behavior was also evaluated using chemically diverse polymers. Indapamide (IPM) concentration decreased when combined with felodipine (FDN) or its analogues, which occurred even when the IPM solution was undersaturated. The extent of solubility decrease of FDN was less than that of IPM from the dissolution of an equimolar formulation of the drugs. No significant solubility decrease was observed for FDN at low contents of IPM which was also observed for other dihydropyridines, whereas FDN decreases at high contents of IPM. This was explained by the complex nature of the colloidal precipitates of the combinations which impacts the chemical potential of the drugs in solution at different levels. The maximum achievable concentration of FDN and IPM during dissolution of the polyvinylpyrrolidone-based amorphous solid dispersion was higher than the value measured with the hydroxypropyl methylcellulose acetate succinate-based formulation. This emphasizes the significance of molecular properties and chemical diversity of drugs and polymers on solution chemistry and solubility profiles. These findings may apply to drugs administered as a single dosage form or in separate dosage forms and hence need to be well controlled to assure effective treatments and patient safety.

Topics: Antihypertensive Agents; Chemistry, Pharmaceutical; Crystallization; Drug Combinations; Drug Compounding; Drug Interactions; Drug Liberation; Felodipine; Humans; Hypertension; Indapamide; Methylcellulose; Patient Safety; Povidone; Solubility; Solutions

The objective was to characterize hydroxypropyl methylcellulose acetate succinate (HMPCAS) grades L, M, and H to enhance itraconazole (ITZ) release and permeation from spray dried dispersions (SDDs), and to investigate underpinning molecular ITZ-HPMCAS interactions that differentiated grade performance.. ITZ or its SDDs were subjected to solution stabilization assessment, one-dimensional proton nuclear magnetic resonance (NMR) spectroscopy, saturation transfer difference NMR studies, small volume dissolution, solid state transformation studies, and in vitro dissolution/permeation flux studies.. HPMCAS-L was the best performing grade overall and exhibited greatest ITZ supersaturation concentration, small volume dissolution, and in vitro dissolution/permeation flux. Meanwhile, H grade retarded ITZ precipitation to the greatest extent in solution stabilization studies and exhibited greater hydrophobic interaction with ITZ in NMR studies. However, this apparent advantage of H grade through hydrophobic interactions between drug-polymer appeared to limit overall dissolution/permeation performance of SDD.. In vitro SDD studies and drug-polymer interaction studies provided insight into the performance of HPMCAS grades, as well as the relative contributions of various mechanisms that polymer can promote ITZ absorption from SDD.

Topics: Chemistry, Pharmaceutical; Fiber Optic Technology; Itraconazole; Kinetics; Magnetic Resonance Spectroscopy; Methylcellulose; Solubility

Amorphous solid dispersions (ASDs) of class II and IV biopharmaceutics classification system drugs in water-miscible polymers are a well-recognized means of enhancing dissolution, while such dispersions in hydrophobic polymers form the basis of micro- and nanoparticulate technologies. However, drug recrystallization presents significant problems for product development, and the mechanisms and pathways involved are poorly understood. Here, we outline the use of combined differential scanning calorimetry (DSC)-synchrotron X-ray diffraction to monitor the sequential appearance of polymorphs of olanzapine (OLZ) when dispersed in a range of polymers. In a recent study (

Topics: Calorimetry, Differential Scanning; Chemistry, Pharmaceutical; Crystallization; Drug Compounding; Drug Liberation; Hot Temperature; Hydrophobic and Hydrophilic Interactions; Methylcellulose; Olanzapine; Polyesters; Polyglactin 910; Solubility; X-Ray Diffraction

Hydroxypropyl methylcellulose acetate succinate (HPMCAS) has gained popularity as a carrier for amorphous solid dispersion because of its ability to maintain drugs in supersaturated state after dissolution in aqueous media. In part I and II of this series of articles, we have demonstrated that amorphous solid dispersions containing HPMCAS may be prepared using surfactants as plasticizers to reduce processing temperature (Solanki et al., J Pharm Sci. 2019; 108:1453-65), where surfactants also increase dissolution rate and degree of supersaturation (Solanki et al., J Pharm Sci. 2019; 108: 3063-73). The present investigation was undertaken to develop melt extrudates of itraconazole-HPMCAS and itraconazole-surfactant-HPMCAS mixtures into tablets having tensile strength ≥2 MPa, where poloxamer 407 and d-α-tocopherol polyethylene glycol 1000 succinate were used as surfactants. Milled filaments were sieved to collect <212-μm particles, which were then compressed into tablets with different excipients (silicified microcrystalline cellulose [MCC], Avicel PH-102, dicalcium phosphate, lactose, and Starch 1500). Initial screening of various diluents showed that only silicified MCC and Avicel PH-102 could provide the target tensile strength of ≥2 MPa. Tabletability (tensile strength vs. compaction pressure), compressibility (porosity vs. compaction pressure), and compactibility (tensile strength vs. porosity) were then studied for tablet formulations. The desired tensile strength could be obtained at the diluent level of 50%-70%, where silicified MCC provided better hardness than Avicel PH-102. Tablets disintegrated in <2 min, and drug release from tablets was comparable to that of milled filaments.

Topics: Cellulose; Chemistry, Pharmaceutical; Drug Compounding; Drug Liberation; Excipients; Hardness; Hot Melt Extrusion Technology; Itraconazole; Lactose; Methylcellulose; Polyethylene Glycols; Solubility; Surface-Active Agents; Tablets; Temperature; Tensile Strength

To enhance in vitro dissolution of Cur by preparing Cur solid dispersions. The ability of HPMCAS-HF,HPMCAS-MF,HPMCAS-LF and PVPK30 to maintain supersaturated solution was investigated by supersaturation test. Amorphous solid dispersions were prepared by the solvent-evaporation method. The prepared samples were characterized using infrared spectroscopy( IR) and differential scanning calorimetry( DSC),and in vitro dissolution was investigated. DSC and IR results showed that in 1 ∶3 and 1 ∶9 solid dispersions,Cur was amorphously dispersed in the carrier,and the interaction existed between drug and carrier. The supersaturation test showed that the order of the ability of polymer to inhibit crystallization of Cur was MF>HF>LF>K30. The dissolution results showed that Cur-K30 amorphous solid dispersion had the highest drug release rate; Cur-K30 and Cur-LF amorphous solid dispersions had a quicker but not stable dissolution rate,and the drug concentration decrease after 4 h; Cur-MF and Cur-HF solid dispersions had a low dissolution,which however increased steadily,attributing to the strong ability of the polymers to inhibit the crystallization of Cur. HPMCAS could inhibit the degradation of Cur better than K30,especially MF and HF. The amorphous solid dispersions of cur significantly enhanced the dissolution of Cur and improved the chemical stability of Cur. This study can provide a basis for the rational selection of the polymer used for Cur solid dispersion.

Topics: Chemistry, Pharmaceutical; Curcumin; Drug Stability; Methylcellulose; Polymers; Solubility

Fungal biofilms are invariably recalcitrant to antifungal drugs and thus can cause recurrent serious infections. The aim of this work was to prepare highly effective form of the antifungal drug griseofulvin using the chloroform solvate embedded into different polymeric matrices. Based on their solid solubility, solvated (chloroform) and non-solvated (methanol and acetone) solid dispersions were prepared using different materials: silica, microcrystalline cellulose, polyvinylpyrrolidone and hydroxypropyl methylcellulose acetate succinate (HPMCAS) by which HPMCAS dispersions showed the highest solubility of about 200 μg/mL compared with ∼30 μg/mL for pure griseofulvin. The anti fungal potential of griseofulvin was assessed against the dermatophytes T. rubrum. Metabolic and protease activity of T. rubrum NCPF 935 with and without the presence of GF:HPMCAS chloroform solvates showed significant reduction compared to the untreated control after 24 h period. Confocal laser scanning microscopy showed thin hyphae compared to Control and GF:HPMCAS (non solvated). Dynamic vapour sorption data showed that HPMCAS formed most stable solvate structure preventing recrystallization and solvate expulsion, which could explain the disruptive effect of the biofilms. This could be explained by the formed hydrogen bonds as revealed by the solid and liquid state NMR data, which was further confirmed via thermal and FTIR analyses.

Topics: Antifungal Agents; Biofilms; Griseofulvin; Methylcellulose; Microbial Sensitivity Tests; Particle Size; Solubility; Surface Properties; Trichophyton

The overall goal of this study was to investigate the dissolution performance and crystallization kinetics of amorphous solid dispersions (ASDs) of a weakly basic compound, posaconazole, dispersed in a pH-sensitive polymeric matrix consisting of hydroxypropyl methylcellulose acetate succinate (HPMC-AS), using fasted-state simulated media.. ASDs with three different drug loadings, 10, 25 and 50 wt.%, and the commercially available tablets were exposed to acidic media (pH 1.6), followed by transfer to, and dissolution in, intestinal media (pH 6.5). Parallel single stage dissolution experiments in only simulated intestinal media were also performed to better understand the impact of the gastric stage. Different analytical methods, including nanoparticle tracking analysis, powder x-ray diffraction, second harmonic generation and two-photon excitation ultraviolet fluorescence microscopy, were used to characterize the phase behavior of these systems at different stages of dissolution.. Results revealed that all ASDs exhibited some degree of drug release upon suspension in acidic media, and were also vulnerable to matrix crystallization. Upon transfer to intestinal media conditions, supersaturation was observed. This was short-lived for some dispersions due to the release of the crystals formed in the acid immersion stage which acted as seeds for crystal growth. Lower drug loading ASDs also exhibited transient formation of amorphous nanodroplets prior to crystallization.. This work emphasizes the significance of assessing the impact of pH change on dissolution and provides a fundamental basis of understanding the phase behavior kinetics of ASDs of weakly basic drugs when formulated with pH sensitive polymers.

Topics: Crystallization; Drug Carriers; Drug Compounding; Drug Liberation; Hydrogen-Ion Concentration; Kinetics; Methylcellulose; Nanoparticles; Particle Size; Phase Transition; Solubility; Temperature; Triazoles

Because spray-dried dispersion (SDD) performance depends on polymer selection and drug load, time- and resource-sparing methods to screen drug/polymer combinations before spray drying are desirable. The primary objective was to assess the utility of films to anticipate the effects of drug load and polymer grade on dissolution performance of tablets containing SDDs of itraconazole (ITZ). A secondary objective was to characterize the solid-state attributes of films and SDDs to explain drug load and polymer effects on dissolution performance. SDDs employed three different grades of hypromellose acetate succinate (i.e., either HPMCAS-L, HPMCAS-M, or HPMCAS-H). Solid-state characterization employed differential scanning calorimetry (DSC), powder X-ray diffraction (PXRD), and solid-state nuclear magnetic resonance (ssNMR) spectroscopy. Results indicate that films correctly anticipated the effects of drug load and polymer on dissolution performance. The best dissolution profiles were observed under the following conditions: 20% drug loading performed better than 30% for both films and SDDs, and the polymer grade rank order was HPMCAS-L > HPMCAS-M > HPMCAS-H for both films and SDDs. No dissolution was detected from films or SDDs containing HPMCAS-H. Solid-state characterization revealed percent crystallinity and phase miscibility as contributing factors to dissolution, but were not the sole factors. Amorphous content in films varied with drug load (10% > 20% > 30%) and polymer grades (HPMCAS-L > HPMCAS-M > HPMCAS-H), in agreement with dissolution. In conclusion, films anticipated the rank-order effects of drug load and polymer grade on dissolution performance from SDDs of ITZ, in part through percent crystallinity and phase miscibility influences.

Topics: Antifungal Agents; Calorimetry, Differential Scanning; Desiccation; Drug Carriers; Itraconazole; Methylcellulose; Polymers; Solubility; Tablets; X-Ray Diffraction

Traditional methods for estimating drug-polymer solubility either require fast dissolution in the polymeric matrix, rapid re-crystallization kinetics from supersaturated states or derive from regular solution theories. In this work, we present a new method for determining drug solubility, purely based on thermodynamic considerations, that uses only experimental data from DSC for calculations.. The new thermodynamic model presented combines DSC analysis and application of Hess's law to determine free energies of conversion of binary mixtures to amorphous solid dispersions, free energies of mixing as well as solubility as a function of temperature. The model drug indomethacin and polymers HPMCAS LF, PVP K29/32 and Eudragit EPO were used in these studies.. Free energies were calculated as a function of temperature, for different drug-polymer compositions and the results show that HPMCAS LF solid dispersion with high drug content are less thermodynamically favorable compared to other polymer systems. Solubility of indomethacin in HPMCAS LF, PVP K29/32 and Eudragit EPO was 24, 55 and 56% w/w, respectively, at 25°C.. The thermodynamic model presented has great advantages over traditional methods. It does not require estimation of any interaction parameters, it is almost assumption-free and uses only thermal data for calculations.

Topics: Crystallization; Drug Compounding; Drug Stability; Indomethacin; Kinetics; Methylcellulose; Models, Molecular; Polymers; Polymethacrylic Acids; Povidone; Solubility; Thermodynamics; Transition Temperature

Amorphous solid dispersion (ASD) is one of the most promising strategies for improving the solubility of active pharmaceutical ingredients (APIs) with low aqueous solubility. Solvent-based techniques such as electrospinning (ES), spray-drying (SD) and rotary evaporation (RE), have all previously been shown to be effective techniques for formulating ASDs. To date however, the effect of these processing techniques on the physicochemical properties and ASD homogeneity or "quality of ASD" produced remains largely unexplored. This work uses ibuprofen (IBU) as a model BCS class II API with two cellulosic excipients, HPMCAS and HPMCP-HP55 to produce ASDs by employing ES, SD and RE processing techniques. The physicochemical, morphological and dissolution properties of each sample were evaluated and the ASD forming strengths of each of the polymers were assessed using Differential Scanning Calorimetry (DSC). Principal |Component Analysis (PCA) of Raman spectra of crystalline and amorphous IBU was employed for qualitative analysis of ASD homogeneity and subsequent ASD stability during long-term storage. Results show that while ASD formation is predominantly dependent on API:excipient ratio, the ASD homogeneity is highly dependent on processing technique. Dissolution studies show that electrospun samples had the highest API release rate due to their fibrous morphology and higher specific surface area. However, these samples were the least homogenous of all ASDs produced thereby potentially influencing sample stability during long term storage. In addition, the higher melting point depression, higher T

Topics: Anti-Inflammatory Agents, Non-Steroidal; Calorimetry, Differential Scanning; Chemistry, Pharmaceutical; Drug Compounding; Drug Liberation; Drug Stability; Drug Storage; Excipients; Hydrogen Bonding; Ibuprofen; Methylcellulose; Polymers; Solubility; Solvents

Low-order high-energy nifedipine (NIF) solid dispersions (SDs) were generated by melt solvent amorphization with polyethylene glycol (PEG) 1450 and hypromellose acetate succinate (HPMCAS-HF) to increase NIF solubility while achieving acceptable physical stability. HPMCAS-HF was used as a crystallization inhibitor. Individual formulation components, their physical mixtures (PMs), and SDs were characterized by differential scanning calorimetry, powder X-ray diffraction, and Fourier transform infrared spectroscopy (FTIR). NIF solubility and percent crystallinity (PC) were determined at the initial time and after 5 days stored at 25 °C and 60% RH. FTIR indicated that hydrogen bonding was involved with the amorphization process. FTIR showed that NIF:HPMCAS-HF intermolecular interactions were weaker than NIF:PEG 1450 interactions. NIF:PEG 1450 SD solubilities were significantly higher than their PM counterparts (p < 0.0001). The solubilities of NIF:PEG 1450:HPMCAS-HF SDs were significantly higher than their corresponding NIF:PEG 1450 SDs (p < 0.0001-0.043). All the SD solubilities showed a statistically significant decrease (p < 0.0001) after storage for 5 days. SDs PC were statistically lower than their comparable PMs (p < 0.0001). The PCs of SDs with HPMCAS-HF were significantly lower than SDs not containing only PEG 1450. All SDs exhibited a significant increase in PC (p < 0.0001-0.0089) on storage. Thermogravimetric analysis results showed that HPMCAS-HF bound water at higher temperatures than PEG 1450 (p < 0.0001-0.0039). HPMCAS-HF slowed the crystallization process of SDs, although it did not completely inhibit NIF crystal growth.

Topics: Calcium Channel Blockers; Crystallization; Drug Compounding; Drug Storage; Excipients; Methylcellulose; Nifedipine; Polyethylene Glycols; Powders; Solubility; Spectroscopy, Fourier Transform Infrared; Water; X-Ray Diffraction

Amorphous Solid Dispersion (ASD) based formulations have been frequently used to improve the bioavailability of poorly water soluble drugs, however, common processes to produce ASDs are not feasible for Absorption, Distribution, Metabolism and Excretion (ADME) studies with radio-labeled Active Pharmaceutical Ingredients (API) due to the complications associated with radioactive material handling. Liquid formulations are routinely used to support the ADME studies, though bridging the bioperformance between a liquid formulation to the amorphous dosage form for poorly soluble compounds has not been well studied, and can be challenging due to the potentially rapid in vitro and in vivo recrystallization and precipitation. Here we report the development of a fit for purpose liquid formulation that could accommodate the radioactive API and provide comparable bioavailability relative to the amorphous formulation without the need for dose adjustment. A number of formulation approaches were explored and the prototype formulations were evaluated by dissolution and preclinical pharmacokinetic studies. A PolyEthylene Glycol 400 (PEG 400) based solution formulation impregnated with a polymer, HydroxyPropyl MethylCellulose Acetate Succinate-L (HPMCAS-L), was identified as the lead formulation. It was found that the bioavailability of the formulation can be compromised by the presence of undissolved crystalline seeds, and the inclusion of HPMCAS-L can mitigate this effect, as well as potentially facilitate the nanoparticle formation. During the study, it is also noted that although dissolution test is instrumental in the formulation development, the in vitro study over predicted the extent of in vivo precipitation for PEG 400 formulation containing no crystalline seeds.

Topics: Animals; Biological Availability; Chemistry, Pharmaceutical; Crystallization; Dogs; Drug Carriers; Drug Liberation; Male; Methylcellulose; Pharmaceutical Preparations; Polyethylene Glycols; Polymers; Solubility; Water

Usage of the amorphous phase of compounds has become the method of choice to overcome oral bioavailability problems related to poor solubility. Due to the unstable nature of glasses, it is clear that the method of preparation of the amorphous glass will have an impact on physical/chemical stability and in turn in vivo performance. The method of preparation can also have a profound impact on the mechanical properties of the amorphous phase. We have explored the impact of preparation method on the mechanical properties of an amorphous solid dispersion using a development compound, GDC-0810. Three methods were used to generate amorphous solid dispersions (ASDs) of 50% GDC-0810 with hydroxypropyl methylcellulose acetate succinate: (1) spray drying, (2) coprecipitation using overhead mixing, and (3) coprecipitation using resonant acoustic mixing. All 3 methods were found to generate ASDs with good phase mixing and similar glass transition temperatures. Coprecipitated ASD powders (overhead mixing and resonant acoustic mixing) demonstrated superior tabletability and flow properties when compared to the spray drying powder. Careful choice of manufacturing process can be used to tune material properties of ASDs to make them more amenable for downstream operations like tableting. Acoustic mixing has been demonstrated as a scalable new method to make ASDs through coprecipitation.

Topics: Cinnamates; Crystallization; Drug Compounding; Equipment Design; Excipients; Indazoles; Methylcellulose; Phase Transition; Solubility; Transition Temperature

Topics: Adrenergic beta-Antagonists; Carvedilol; Drug Carriers; Drug Liberation; Glycerides; Hot Melt Extrusion Technology; Methylcellulose; Polymers; Povidone; Solubility

Spray-dried dispersions (SDDs) are an important technology for enhancing the oral bioavailability of poorly water-soluble drugs. To design an effective oral SDD formulation, the key rate-determining step(s) for oral drug absorption must be understood. This work combined in vivo and in vitro tests with in silico modeling to identify the rate-determining steps for oral absorption of belinostat SDDs made with 3 different polymers (PVP K30, PVP VA64, and HPMCAS-M). The goal was developing a belinostat SDD formulation that maximizes oral bioavailability (ideally matching the performance of a belinostat oral solution) and defining critical performance attributes for formulation optimization. The in vivo pharmacokinetic study with beagle dogs demonstrated that 1 of the 3 SDDs (PVP K30 SDD) matched the performance of the oral solution. In vitro data coupled with in silico modeling elucidated differences among the SDDs and supported the hypothesis that absorption of belinostat in the small intestine from the other 2 SDDs (PVP VA64 and HPMCAS-M) may be limited by dissolution rate or reduced drug activity (maximum concentration) in the presence of polymer. It was concluded that drug concentration in the stomach before emptying into the proximal intestine is a key factor for maximizing in vivo performance.

Topics: Administration, Oral; Animals; Biological Availability; Computer Simulation; Dogs; Drug Compounding; Excipients; Humans; Hydroxamic Acids; Methylcellulose; Models, Biological; Oral Mucosal Absorption; Povidone; Solubility; Sulfonamides

The present study details the development of a small-scale spray-drying approach for the routine screening of amorphous solid dispersions (ASDs). This strategy aims to overcome the limitations of standard screening methodologies like solvent casting and quench cooling to predict drug-polymer miscibility of spray-dried solid dispersions (SDSDs) and therefore to guarantee appropriate carrier and drug-loading (DL) selection. A DoE approach was conducted to optimize process conditions of ProCept 4M8-TriX spray-drying to maximize the yield from a 100 mg batch of Itraconazole/HPMCAS-LF and Itraconazole/Soluplus 40:60 (w/w). Optimized process parameters include: inlet temperature, pump speed, drying and atomizing airflows. Identified process conditions derived from the DoE analysis were further (i) tested with Itraconazole, Naproxen and seven polymers, (ii) adapted for small cyclone use, (iii) downscaled to 20 mg batch production. Drug-polymer miscibility was systematically characterized using modulated differential scanning calorimetry (mDSC). Spray-drying was identified as a well-suited screening approach: mean yield of 10.1 to 40.6% and 51.1 to 81.0% were obtained for 20 and 100 mg ASD productions, respectively. Additionally, this work demonstrates the interest to move beyond conventional screening approaches and integrate spray-drying during screening phases so that a greater prediction accuracy in terms of SDSDs miscibility and performance can be obtained.

Topics: Anti-Inflammatory Agents, Non-Steroidal; Antifungal Agents; Calorimetry, Differential Scanning; Crystallization; Desiccation; Drug Development; Itraconazole; Methylcellulose; Naproxen; Phase Transition; Polyethylene Glycols; Polymers; Polyvinyls; Solubility; Solvents

Hydroxypropyl methylcellulose acetate succinate (HPMCAS) has been widely investigated as a carrier for amorphous solid dispersion (ASD) of poorly water-soluble drugs. However, its use has mostly been limited to ASDs prepared by spray drying using organic solvents, and the solvent-free method, hot-melt extrusion (HME), has only limited use because it requires high processing temperature where the polymer and drug may degrade. In this investigation, surfactants were used as plasticizers to reduce the processing temperature. Their effects on drug release were also determined. To determine suitability of using surfactants, the miscibility of HPMCAS with 3 surfactants (poloxamer 188, poloxamer 407, and d-alpha tocopheryl polyethylene glycol 1000 succinate) and a model drug, itraconazole (ITZ), was studied by film casting. HPMCAS was miscible with ITZ (>30%) and each surfactant (>20%), and in ternary HPMCAS-ITZ-surfactant (60:20:20) system. ASDs prepared by HME of HPMCAS-ITZ-surfactant mixtures (70:20:10 and 65:20:15) at 160°C were physically stable after exposure to 40°C and 75% relative humidity for 1 month. The presence of 15% w/w surfactant provided up to 50% drug release at pH 1 as compared to only 8% from ASDs with HPMCAS alone. On changing the pH of the dissolution medium from 1 to 6.8 in a step-dissolution process, complete drug release (90%-100%) and extremely high apparent supersaturation (∼75,000 times) of ITZ were observed when the solutions were filtered through 0.45 μm filters. The apparently supersaturated solutions consisted of colloidal particles of ∼300 nm size. The present study demonstrates that stable ASDs with improved processability and drug release may be prepared by HME.

Topics: Drug Carriers; Drug Compounding; Drug Liberation; Hot Melt Extrusion Technology; Hydrogen-Ion Concentration; Itraconazole; Methylcellulose; Solubility; Surface-Active Agents

Topics: Androstadienes; Cellulose; Chromatography, High Pressure Liquid; Crystallization; Magnetic Resonance Spectroscopy; Methylcellulose; Polymers; Spectrophotometry, Infrared; Thermodynamics

Two pharmaceutical polymers with high glass transition temperatures (T

Topics: Antifungal Agents; Chemistry, Pharmaceutical; Crystallization; Drug Carriers; Drug Stability; Drug Storage; Excipients; Humidity; Hydrophobic and Hydrophilic Interactions; Itraconazole; Methylcellulose; Polymers; Pyrrolidines; Thermodynamics; Transition Temperature; Vinyl Compounds

In spite of the large research efforts in the past two decades, it is still difficult, if possible at all, to predict what manufacturing technology will lead to the best amorphous solid dispersions (ASDs) in terms of drug to polymer ratio ("drug loading") and physical stability. In general, ASDs can be prepared by solvent based methods, heat based methods and mechanochemical activation. In the current study, one manufacturing technique per category was selected: spray drying, hot melt extrusion and cryo-milling, respectively. These processes were compared for their capability to formulate high drug loaded ASDs. High drug loadings may allow decreasing the pill burden and/or reducing dosage size, which both increase the therapeutic compliance. A fast crystallizer, naproxen, in combination with PVP K25, PVP-VA64, HPMC and HPMC-AS was used as a model system. Clear differences in the physical structure of the ASDs were observed. Our data indicate that not only the drug loading is dependent on the manufacturing process, but also the carrier that is able to incorporate the highest drug loading. This suggests that a carrier should be selected not only as function of the API, but also as function of the manufacturing process. Overall, hot melt extrusion showed to be most suited to reach high drug loadings for these naproxen-polymer combinations. This was in agreement with our finding that heat is an important energy input for mixing.

Topics: Chemistry, Pharmaceutical; Crystallization; Drug Carriers; Drug Compounding; Hot Temperature; Hypromellose Derivatives; Methylcellulose; Naproxen; Polymers; Povidone; Pyrrolidines; Technology, Pharmaceutical; Vinyl Compounds

The purpose of this study was to research a novel combination of Plasdone-S630 and HPMCAS-HF as hot-melt carrier used in ziprasidone hydrochloride for enhanced oral bioavailability and dismissed food effect. Ziprasidone hydrochloride solid dispersion (ZH-SD) was prepared by hot-melt extrusion technique, and its optimized formulation was selected by the central composite design (CCD), which was characterized for powder X-ray diffraction (PXRD), fourier transform infrared spectroscopy (FTIR), in vitro dissolution study, and stability study. Finally, the in vivo study in fasted/fed state was carried out in beagle dogs. Based on PXRD analysis, HME technique successfully dispersed ziprasidone with a low crystallinity hydrochloride form in the polymers. According to the analysis of FTIR, hydrogen bonds were formed between drug and polymers during the process of HME. Without any noticeable bulk, crystalline could be found from the micrograph of ZH-SD when analyzed the result of scanning electron microscope (SEM). Pharmacokinetics studies indicated that the bioavailability of ZH-SD formulation had no significant difference in fasted and fed state, and the C

Topics: Administration, Oral; Animals; Biological Availability; Dogs; Drug Combinations; Fasting; Methylcellulose; Pharmaceutic Aids; Piperazines; Povidone; Solubility; Spectroscopy, Fourier Transform Infrared; Thiazoles; X-Ray Diffraction

Molecular interactions between drug and polymeric carriers are believed to be the key for high drug loading and better physical stability of micro-particles. However, molecular interactions between drug and polymer are still difficult to investigate using only experimental tools. In this study, high-loaded glipizide (GLP)/hydroxypropyl methylcellulose acetate succinate (HPMCAS) (1/1 w/w) micro-particles were prepared using an in situ pH-dependent solubility method. Molecular interactions within the micro-particles were investigated by integrated experimental and modeling techniques. The dissolution rate of GLP/HPMCAS micro-particles was significantly better than those of solid dispersions and physical mixtures. Scanning electron microscopy images showed that the polymer inhibited GLP recrystallization. Experimental (FTIR spectroscopy, differential scanning calorimetry, powder X-ray diffraction and nuclear magnetic resonance spectroscopy) and molecular dynamics simulation revealed that hydrogen-bonding was the key to the properties of the micro-particles. Our research developed high drug-loading GLP/HPMCAS micro-particles and investigated the interactions between drug and polymer at the molecular level. This integrated approach could be practical methodology for future formulation design.

Topics: Crystallization; Drug Liberation; Glipizide; Hydrogen Bonding; Hypoglycemic Agents; Methylcellulose; Molecular Dynamics Simulation; Solubility

The omega-3-fatty acid, docosahexaenoic acid (DHA) 22:6 n-3, is an important food component for the visual and brain development of infants. In this study two approaches have been explored for the encapsulation of DHA in the pH dependant polymer hydroxyl-propyl-methyl-cellulose-acetate-succinate (HPMCAS). In the first approach Direct Spray Drying (DSD) was implemented for the microencapsulation of DHA/HPMCAS organic solutions, whilst in the second approach solid lipid nanoparticle (SLN) dispersions of DHA, were first produced by high-pressure homogenization, prior to being spray dried in HPMCAS aqueous solutions. The DSD approach resulted in significantly higher quantities of DHA being encapsulated, at 2.09 g/100 g compared to 0.60 g/100 g in the spray-dried SLNs. The DHA stability increased with the direct spray-drying approach. Release studies of DHA in the direct sprayed dried samples revealed a lag time for 2 h in acidic media followed by rapid release in phosphate buffer (pH 6.8).

Topics: Calorimetry, Differential Scanning; Desiccation; Docosahexaenoic Acids; Drug Compounding; Hydrogen-Ion Concentration; Methylcellulose; Nanoparticles; Particle Size; Polymers; Pressure; Spectroscopy, Fourier Transform Infrared; Thermogravimetry

Drug-polymer interactions have a substantial impact on stability and performance of amorphous solid dispersions (ASD) but are difficult to analyze. Whereas there are many screening methods described for polymer selection based for example on glass forming ability, drug-polymer miscibility, supersaturation, or inhibition of recrystallization, the distinct detection of physico-chemical interactions mostly lacks miniaturized techniques. This work presents an interaction screening assessing the relative viscosity increase between highly concentrated polymer solutions with and without the model drug ketoconazole (KTZ). The fluorescent molecular rotor 9-(2-carboxy-2-cyanovinyl)julolidine was added to the solutions in a miniaturized setup in μL-scale. Due to its environment-sensitive emission behavior, the integrated fluorescence intensity can be used as a viscosity dye within this screening approach (FluViSc). Differences in relative viscosity increases through addition of KTZ were proposed to rank polymers regarding KTZ-polymer interactions. Absolute viscosities were measured with a cone-plate rheometer as a complimentary method and supported the results acquired by the FluViSc. Solid-state nuclear magnetic resonance (ss-NMR) relaxation time measurements and Raman spectroscopy were utilized to investigate drug-polymer interactions at a molecular level. Whereas Raman spectroscopy was not suited to reveal KTZ-polymer interactions, ss-NMR relaxation time measurements differentiated between the selected polymeric carriers hydroxypropylmethylcellulose acetate succinate (HPMCAS) and polyvinylpyrrolidone vinyl acetate 60:40 (PVP-VA64). Interactions were detected for HPMCAS/KTZ ASD while there was no hint for interactions between KTZ and PVP-VA64. These results were in correlation with the FluViSc. The findings were correlated with the dissolution performance of ASD and found to be predictive for supersaturation and inhibition of precipitation during dissolution.

Topics: Biological Availability; Calorimetry, Differential Scanning; Crystallization; Drug Carriers; Drug Compounding; Drug Liberation; Drug Stability; Hydrogen Bonding; Ketoconazole; Magnetic Resonance Spectroscopy; Methylcellulose; Polymers; Pyrrolidines; Solubility; Spectrum Analysis, Raman; Vinyl Compounds; Viscosity; X-Ray Diffraction

To address the problem of precipitation of a poorly soluble drug during dissolution of highly soluble cocrystals by preparing granules intimately mixed with a water-soluble polymer.. Effectiveness of polymers as precipitation inhibitors during the dissolution of carbamazepine-nicotinamide (CBZ-NCT) cocrystal was assessed based on induction time of crystallization from a supersaturated solution in presence of different polymers at two concentrations. Dissolution was evaluated by both intrinsic dissolution rate (IDR) and USP dissolution method. Powder manufacturability was assessed using a shear cell and compaction simulator to assess flowability and tabletability, respectively.. Hydroxypropyl methylcellulose acetate succinate (HPMCAS) was the most effective polymer against precipitation of CBZ and the IDR of a 1:1 (w/w) CBZ-NCT/HPMCAS mixture was the highest. The final formulation of 1:1 CBZ-NCT/HPMCAS granule exhibited excellent flowability, good tabletability, and significantly improved drug release rate than cocrystal formulations without HPMCAS or the CBZ formulation.. The particle engineering strategy of modifying the diffusion layer on the surface of highly soluble cocrystal with a polymer is effective for inhibiting premature precipitation of CBZ. Assisted with predictive tools for characterizing powder flowability and tabletability, the design of high quality tablet product with improved drug release rate and manufacturability can be achieved in an efficient manner.

Topics: Carbamazepine; Crystallization; Diffusion; Drug Compounding; Drug Liberation; Methylcellulose; Nanoparticles; Niacinamide; Powders; Silicon Dioxide; Solubility; Surface Properties; Tablets

The majority of NCEs are weakly basic drugs. Consequently, their solubility is highly pH-dependent, with higher solubility in the acidic stomach and poor solubility in the neutral intestinal environment. The gastric emptying of dissolved drug can lead to the intestinal precipitation of the drug. One option of reducing this process is to formulate the drug together with a precipitation inhibitor (PI). The aim of this study was to investigate the effects of different PIs on the intestinal concentrations of ketoconazole and five orally administered kinase inhibitors (i.e. pazopanib, gefitinib, lapatinib, vemurafenib, and a Merck KGaA research compound, MSC-A) with the aid of a predictive small-scale in vitro transfer model. This screening revealed that HPMCAS and Soluplus® were the most effective PIs. Whereas all other drugs precipitated within several minutes, gefitinib expressed highly variable amorphous precipitation which was confirmed by PXRD. During the transfer model experiments, this intermediate supersaturated state was stabilized using HPMCAS and Soluplus®. The PI screening protocol described herein allows to study the effect of PIs for solubility and potential bioavailability improvement of poorly soluble drugs to support formulation development already in early stages.

Topics: Biological Availability; Chemical Precipitation; Drug Liberation; Hydrogen-Ion Concentration; Intestines; Ketoconazole; Methylcellulose; Models, Biological; Polyethylene Glycols; Polyvinyls; Protein Kinase Inhibitors; Solubility

Although hydroxypropyl methylcellulose acetate succinate (HPMCAS) has been widely used as a carrier for amorphous solid dispersion of poorly water-soluble drugs, its application has mostly been limited to spray drying, and the solvent-free method of hot melt extrusion has rarely been used. This is on account of the high temperature (≥170°C) required for extrusion where the polymer and even a drug may degrade. In part 1 of this series of papers, we demonstrated that HPMCAS is miscible with surfactants such as, poloxamer 188, poloxamer 407 and d-alpha tocopheryl polyethylene glycol 1000 succinate, which may also serve as plasticizers (Solanki et al., J Pharm Sci. 2019; 108 (4):1453-1465). The present investigation was undertaken to determine plasticization effects of the surfactants and a model drug, itraconazole, in reducing melt extrusion temperatures of HPMCAS. The determination of complex viscosity as functions of temperature and also as functions of angular frequency at certain fixed temperatures showed that the surfactants and the drug greatly reduce viscosity of HPMCAS by their plasticization effects. Surfactants and drug also had synergistic effects in reducing viscosity. The torque analysis during melt extrusion demonstrated that these additives greatly enhanced extrudability of HPMCAS. Surfactant-drug-polymer mixtures were successfully extruded as stable amorphous solid dispersions at 130°C, which is much lower than the minimum extrusion temperature of 170°C for neat HPMCAS.

Topics: Calorimetry, Differential Scanning; Drug Carriers; Drug Compounding; Hot Melt Extrusion Technology; Hot Temperature; Hydrogen-Ion Concentration; Itraconazole; Methylcellulose; Rheology; Surface-Active Agents; Viscosity

The impact of surfactants on supersaturation of clotrimazole solutions was systematically evaluated. Four clinically relevant surfactants, sodium dodecyl sulfate, vitamin E TPGS, Tween 80, and docusate sodium were studied. The induction time for nucleation and rate of desupersaturation were determined at a supersaturation ratio of 90% amorphous solubility. Measurement was also performed in the presence of predissolved hydroxypropyl methylcellulose acetate succinate to study the effect of surfactant-polymer interaction on desupersaturation. The 4 surfactants showed varied effects on desupersaturation. From supersaturation maintenance perspective, in the presence of hydroxypropyl methylcellulose acetate succinate, the rank order for the 4 surfactants was found to be: docusate sodium > vitamin E TPGS > sodium dodecyl sulfate > Tween 80. Given the importance of maintaining supersaturation and varied effect of surfactants on nucleation kinetics and desupersaturation rate, a careful examination of active pharmaceutical ingredient, polymer and surfactant interaction on an individual basis is recommended for selecting an appropriate surfactant for use in amorphous solid dispersion formulation.

Topics: Clotrimazole; Methylcellulose; Polymers; Solubility; Surface-Active Agents

Much work has been devoted to analysing thermodynamic models for solid dispersions with a view to identifying regions in the phase diagram where amorphous phase separation or drug recrystallization can occur. However, detailed partial differential equation non-equilibrium models that track the evolution of solid dispersions in time and space are lacking. Hence theoretical predictions for the timescale over which phase separation occurs in a solid dispersion are not available. In this paper, we address some of these deficiencies by (i) constructing a general multicomponent diffusion model for a dissolving solid dispersion; (ii) specializing the model to a binary drug/polymer system in storage; (iii) deriving an effective concentration dependent drug diffusion coefficient for the binary system, thereby obtaining a theoretical prediction for the timescale over which phase separation occurs; (iv) calculating the phase diagram for the Felodipine/HPMCAS system; and (iv) presenting a detailed numerical investigation of the Felodipine/HPMCAS system assuming a Flory-Huggins activity coefficient. The numerical simulations exhibit numerous interesting phenomena, such as the formation of polymer droplets and strings, Ostwald ripening/coarsening, phase inversion, and droplet-to-string transitions. A numerical simulation of the fabrication process for a solid dispersion in a hot melt extruder was also presented. STATEMENT OF SIGNIFICANCE: Solid dispersions are products that contain mixtures of drug and other materials e.g. polymer. These are liable to separate-out over time - a phenomenon known as phase separation. This means that it is possible the product differs both compositionally and structurally between the time of manufacture and the time it is taken by the patient, leading to poor bioavailability and so ultimately the shelf-life of the product has to be reduced. Theoretical predictions for the timescale over which phase separation occurs are not currently available. Also lacking are detailed partial differential equation non-equilibrium models that track the evolution of solid dispersions in time and space. This study addresses these issues, before presenting a detailed investigation of a particular drug-polymer system.

Topics: Felodipine; Methylcellulose; Models, Chemical; Phase Transition

Cocrystallization is a novel approach for tackling the lower solubility concerns when they can yield solution concentration a lot better than their corresponding parent drug in crystalline form. To get the actual solubility and dissolution gains offered by the cocrystals, phase changes in solution (dissolution) has to be interrupted. In current study, we selected commonly used polymers in order to study their effects on the super saturation of carbamezepine-succinic acid (CBZ-SUC) cocrystal during dissolution studies. To observe solid phase changes during dissolution in situ Raman spectroscopy was used. At the completion of each test the solid phase was analyzed by Fourier-transform infrared spectroscopy (FTIR) and powder X-Ray diffractometry. In polymers absence, no dissolution improvement was achieved by the cocrystal owing to its quick transformation to the stable carbamazepine dihydrate (CBZDH). Pre-dissolved PVP at 2% w/v concentration did not inhibit CBZ crystallization as a dihydrate, whereas at 0.025% w/v pre-dissolved hydroxypropyl methyl cellulose acetate succinate (HPMCAS) did stabilize the cocrystal in buffer solution (pH 6.8) for the course of time studied. This cocrystal stabilization resulted in enhanced CBZ solubility ( ̴ 4fold) caused by cocrystal super saturation state. Seeding of this stable supersaturated state with 1% w/v CBZDH resulted in CBZ crystallization as dihydrate with ultimate loss of solubility advantage.

Topics: Carbamazepine; Crystallization; Methylcellulose; Polymers; Powders; Solubility; Spectrophotometry, Ultraviolet; Spectroscopy, Fourier Transform Infrared; Spectrum Analysis, Raman; Succinic Acid; X-Ray Diffraction

Amorphous solid dispersions (ASDs) represent an important formulation technique to achieve supersaturation in gastrointestinal fluids and to enhance absorption of poorly water-soluble drugs. Drug release from such systems is complex due to emergence of different colloidal structures and potential drug precipitation, which can occur in parallel to absorption. The latter drug uptake from the intestinal lumen can be simulated by an organic layer in a biphasic in vitro test, which was employed in this work to mechanistically study the release of ketoconazole from ASDs produced by hot melt extrusion using different HPMCAS grades. A particular aim was to introduce diffusing wave spectroscopy (DWS) to biopharmaceutical testing of solid dispersions. Results indicated that amorphous formulations prevented crystallization of the weakly basic drug upon transfer into the intestinal medium. Microrheological differences among polymer grades and plasticizers were revealed in the aqueous phase, which affected drug release and subsequently uptake into the organic layer. The results indicate that DWS can be employed as a new non-invasive tool to better understand drug release from solid dispersions. This novel light scattering technique is highly promising for future biopharmaceutical research on supersaturating systems such as solid dispersions.

Topics: Drug Liberation; Ketoconazole; Methylcellulose; Rheology; Spectrum Analysis; Suspensions

The characterization of intestinal dissolution of poorly soluble drugs represents a key task during the development of both new drug candidates and drug products. The bicarbonate buffer is considered as the most biorelevant buffer for simulating intestinal conditions. However, because of its complex nature, being the volatility of CO

Topics: Administration, Oral; Animals; Bicarbonates; Buffers; Chemical Precipitation; Drug Delivery Systems; Drug Liberation; Female; Gastrointestinal Absorption; Gastrointestinal Tract; Hydrogen-Ion Concentration; Indazoles; Ketoconazole; Lapatinib; Methylcellulose; Models, Biological; Phosphates; Pyrimidines; Rats; Rats, Wistar; Solubility; Sulfonamides

The objective of the current study was to develop an amorphous solid dispersion for a high melting point compound, griseofulvin (GRF), with an enhanced solubility and a controlled release pattern utilizing hot melt extrusion (HME) technology. Hypromellose acetate succinate (HPMCAS, Shin-Etsu AQOAT®, medium particle size) was explored as the polymeric carrier, while hypromellose (HPMC, Metolose® SR) was chosen as the release rate control agent. GRF presented an HPMCAS grade-dependent solubility: AS-HMP > AS-MMP > AS-LMP. At 10 wt.% loading, the release of GRF was prolonged to 6 h with the incorporation of 10% HPMC 90SH-100SR, while its solubility was enhanced up to sevenfold. Fourier transform infrared spectroscopy (FT-IR) identified the H-bonding between drug and polymers. Element analysis utilizing X-ray photoelectron spectroscopy (XPS) discovered that less GRF aggregated on the surface of binary powders compared with ternary powders containing HPMC, indicating the relatively poor wettability of the latter one. The morphology of extrudates was observed by scanning electron microscopy (SEM) and atomic force microscopy (AFM), illustrating a much smoother and uniform surface of binary extrudates. Immediate release tablets including 10% super-disintegrant L-HPC were able to achieve identical dissolution profile as the powders of extrudates.

Topics: Antifungal Agents; Chemistry, Pharmaceutical; Delayed-Action Preparations; Drug Carriers; Drug Delivery Systems; Excipients; Griseofulvin; Hydrogen Bonding; Hypromellose Derivatives; Methylcellulose; Particle Size; Solubility; Spectroscopy, Fourier Transform Infrared; Tablets

The primary aim of this study was to identify pharmaceutically acceptable amorphous polymers for producing 3D printed tablets of a model drug, haloperidol, for rapid release by fused deposition modeling. Filaments for 3D printing were prepared by hot melt extrusion at 150°C with 10% and 20% w/w of haloperidol using Kollidon

Topics: Chemistry, Pharmaceutical; Drug Liberation; Excipients; Haloperidol; Hydrogen-Ion Concentration; Methylcellulose; Polymers; Povidone; Printing; Printing, Three-Dimensional; Solubility; Tablets; Technology, Pharmaceutical

Topics: Animals; Cellulose; Dosage Forms; Excipients; Gastrointestinal Tract; Male; Methylcellulose; Particle Size; Pharmaceutical Preparations; Pilot Projects; Polymers; Polyvinyls; Positron Emission Tomography Computed Tomography; Printing, Three-Dimensional; Rats; Rats, Sprague-Dawley; Rodentia; Technology, Pharmaceutical

Much contemporary research of poorly water-soluble drugs focuses on amorphous solid dispersions (SDs) for oral drug delivery. Recently, a multifractal formalism has been introduced to describe the distribution of an inorganic carrier in SDs. The present work attempts to directly image model drugs by means of scanning electron microscopy and energy dispersive X-ray spectroscopy. The compounds amlodipine, felodipine, glyburide, and indomethacine, which include halogens to enable sufficient scattering in energy dispersive X-ray spectroscopy, were employed to prepare SDs with hydroxypropyl methylcellulose acetate succinate (HPMCAS) by using a microwave method. Following chemical imaging, it was demonstrated that drug distribution was best described by multifractals, which was clearly superior to a monofractal assumption. The obtained fractal dimensions were influenced by drug loading and it was possible to detect microstructural changes upon addition of the plasticizer urea. Accordingly, the multifractal approach bears much potential to better explore the analytical results of chemical formulation imaging. Insights can be gained from the microstructural organization of SDs, which is interesting to further study formulation and process factors as well as physical stability.

Topics: Amlodipine; Crystallography, X-Ray; Dosage Forms; Drug Carriers; Drug Compounding; Felodipine; Fractals; Glyburide; Indomethacin; Methylcellulose; Microscopy, Electron, Scanning; Pharmaceutical Preparations; Powder Diffraction; Solubility; Spectrometry, X-Ray Emission; Technology, Pharmaceutical

The oral route is widely accepted as the most physiological path for exogenous administration of insulin, as it closely mimic the endogenous insulin pathway. Thus, in this work it is proposed an innovative lipid-polymeric nanocarrier to delivery insulin orally. Areas covered: Nanoparticles were produced through a modified solvent emulsification-evaporation method, using ethyl palmitate and hydroxypropylmethylcellulose acetate succinate as matrix. Lipid-polymeric nanoparticles were around 300 nm in size, negatively charged (-20 mV) and associated insulin with efficiency higher than 80%. Differential scanning calorimetry suggested thermal stability of nanoparticles. In vitro release assays under simulated gastrointestinal conditions resulted in 9% and 14% of insulin released at pH 1.2 during 2 h and at pH 6.8 for 6 h, respectively, demonstrating the ability of those nanoparticles to protect insulin against premature degradation. Importantly, nanoparticles were observed to be safe at potential therapeutic concentrations as did not originate cytotoxicity to intestinal epithelial cells. Lastly, the permeability of nanoencapsulated insulin through Caco-2 monolayers and a triple Caco-2/HT29-MTX/Raji B cell model correlated well with slow release kinetics, and fosters the effectiveness of nanoparticles to promote intestinal absorption of peptidic drugs. Expert opinion: Lipid-polymeric nanoparticles were developed to encapsulate and carry insulin through intestine. Overall, nanoparticles provide insulin stability and intestinal permeability.

Topics: Administration, Oral; Animals; Caco-2 Cells; Calorimetry, Differential Scanning; Chromatography, High Pressure Liquid; Drug Delivery Systems; Humans; Hydrogen-Ion Concentration; Hypoglycemic Agents; Insulin; Intestinal Absorption; Methylcellulose; Microscopy, Electron, Scanning; Nanoparticles; Palmitic Acids; Permeability; X-Ray Diffraction

The preparation of amorphous solid dispersions (ASDs) is a well-established strategy for formulating active pharmaceutical ingredients by embedding them in excipients, usually amorphous polymers. Different polymers can be combined for designing ASDs with desired properties like an optimized dissolution behavior. One important criterion for the development of ASD compositions is the physical stability. In this work, the physical stability of API/polymer-blend ASDs was investigated by thermodynamic modeling and stability studies. Amorphous naproxen (NAP) and acetaminophen (APAP) were embedded in blends of hydroxypropyl methylcellulose acetate succinate (HPMCAS) and either poly(vinylpyrrolidone) (PVP) or poly(vinylpyrrolidone-co-vinyl acetate) (PVPVA64). Parameters for modeling the API solubility in the blends and the glass-transition temperature curves of the water-free systems with Perturbed-Chain Statistical Associating Fluid Theory and Kwei equation, respectively, were correlated to experimental data. The phase behavior for standardized storage conditions (0%, 60% and 75% relative humidity (RH)) was predicted and compared to six months-long stability studies. According to modeling and experimental results, the physical stability was reduced with increasing HPMCAS content and increasing RH. This trend was observed for all investigated systems, with both APIs (NAP and APAP) and both polymer blends (PVP/HPMCAS and PVPVA64/HPMCAS). PC-SAFT and the Kwei equation turned out to be suitable tools for modeling and predicting the physical stability of the investigated API/polymer-blends ASDs.

Topics: Acetaminophen; Dosage Forms; Drug Compounding; Drug Stability; Drug Storage; Excipients; Humidity; Methylcellulose; Models, Chemical; Models, Statistical; Naproxen; Phase Transition; Polymers; Povidone; Pyrrolidines; Technology, Pharmaceutical; Thermodynamics; Time Factors; Transition Temperature; Vinyl Compounds

The efficacy of rifapentine, an oral antibiotic used to treat tuberculosis, may be reduced due to degradation at gastric pH and low solubility at intestinal pH. We hypothesized that delivery properties would be improved in vitro by incorporating rifapentine into pH-responsive amorphous solid dispersions (ASDs) with cellulose derivatives including: hydroxypropylmethylcellulose acetate succinate (HPMCAS), cellulose acetate suberate (CASub), and 5-carboxypentyl hydroxypropyl cellulose (CHC). ASDs generally reduced rifapentine release at gastric pH, with CASub affording >31-fold decrease in area under the curve (AUC) compared to rifapentine alone. Critically, reduced gastric dissolution was accompanied by reduced degradation to 3-formylrifamycin. Certain ASDs also enhanced apparent solubility and stabilization of supersaturated solutions at intestinal pH, with HPMCAS providing nearly 4-fold increase in total AUC vs. rifapentine alone. These results suggest that rifapentine delivery via ASD with these cellulosic polymers may improve bioavailability in vivo.

Topics: Antibiotics, Antitubercular; Cellulose; Drug Carriers; Drug Delivery Systems; Humans; Hydrogen-Ion Concentration; Methylcellulose; Molecular Conformation; Rifampin; Solubility

The aim of this paper was to compare the in vitro dissolution and in vivo bioavailability of three solubility enhancement technologies for β-lapachone (LPC), a poorly water soluble compound with extremely high crystallization propensity. LPC cocrystal was prepared by co-grinding LPC with resorcinol. LPC crystalline and amorphous solid dispersions (CSD and ASD) were obtained by spray drying with Poloxamer 188 and HPMC-AS, respectively. The cocrystal structure was solved by single crystal x-ray diffraction. All formulations were characterized by WAXRD, DSC, POM and SEM. USP II and intrinsic dissolution studies were used to compare the in vitro dissolution of these formulations, and a crossover dog pharmacokinetic study was used to compare their in vivo bioavailability. An 1:1 LPC-resorcinol cocrystal with higher solubility and faster dissolution rate was obtained, yet it converted to LPC crystal rapidly in solution. LPC/HPMC-AS ASD was confirmed to be amorphous and uniform, while the crystal and crystallite sizes of LPC in CSD were found to be ∼1-3 μm and around 40 nm, respectively. These formulations performed similarly during USP II dissolution, while demonstrated dramatically different oral bioavailability of ∼32%, ∼5%, and ∼1% in dogs, for CSD, co-crystal, and ASD, respectively. CSD showed the fastest intrinsic dissolution rate among the three. The three formulations showed poor IVIVC which could be due to rapid and unpredictable crystallization kinetics. Considering all the reasons, we conclude that for molecules with extremely high crystallization tendency that cannot be inhibited by any pharmaceutical excipients, size-reduction technologies such as CSD could be advantageous for oral bioavailability enhancement in vivo than technologies only generating transient but not sustained supersaturation.

Topics: Administration, Oral; Animals; Biological Availability; Cross-Over Studies; Crystallization; Crystallography, X-Ray; Dogs; Dosage Forms; Drug Compounding; Drug Liberation; Methylcellulose; Naphthoquinones; Particle Size; Poloxamer; Resorcinols; Solubility; Technology, Pharmaceutical

Among the strategies to improve the biopharmaceutic properties of poorly soluble drugs, Supersaturating Drug Delivery Systems like polymer-based amorphous solid dispersions (SD) have been successfully applied. The screening of appropriate polymeric carriers to compose SD is a crucial point on their development. In this study, hydroxypropylmethylcellulose (HPMC), hydroxypropylmethylcellulose acetate succinate (HPMCAS) types L, M and H and polyvinyl caprolactam-polyvinyl acetate-polyethylene glycol graft copolymer (SOL) were evaluated by in vitro supersaturation studies regarding their anti-precipitant ability on the poorly soluble drug candesartan cilexetil (CC) under two different media, including biorelevant conditions. According to the results, HPMCAS M was considered the best carrier to develop SD containing CC among all the polymers tested, due to its good anti-precipitant performance in both media. In addition, the medium used in the in vitro supersaturation studies played an important role on the results, and its selection should be carefully done.

Topics: Benzimidazoles; Biphenyl Compounds; Drug Carriers; Drug Delivery Systems; Methylcellulose; Polymers; Solubility; Tetrazoles

Three- dimensional (3D) printing has received significant attention as a manufacturing process for pharmaceutical dosage forms. In this study, we used Fusion Deposition Modelling (FDM) in order to print "candy - like" formulations by imitating Starmix® sweets to prepare paediatric medicines with enhanced palatability.. Hot melt extrusion processing (HME) was coupled with FDM to prepare extruded filaments of indomethacin (IND), hypromellose acetate succinate (HPMCAS) and polyethylene glycol (PEG) formulations and subsequently feed them in the 3D printer. The shapes of the Starmix® objects were printed in the form of a heart, ring, bottle, ring, bear and lion. Differential scanning calorimetry (DSC), X-ray powder diffraction (XRPD), Fourier Transform Infra-red Spectroscopy (FT-IR) and confocal Raman analysis were used to assess the drug - excipient interactions and the content uniformity.. Physicochemical analysis showed the presence of molecularly dispersed IND in the printed tablets. In vivo taste masking evaluation demonstrated excellent masking of the drug bitterness. The printed forms were evaluated for drug dissolution and showed immediate IND release independently of the printed shape, within 60 min.. 3D printing was used successfully to process drug loaded filaments for the development of paediatric printed tablets in the form of Starmix® designs.

Topics: Administration, Oral; Anti-Inflammatory Agents, Non-Steroidal; Child; Drug Compounding; Drug Liberation; Excipients; Feasibility Studies; Humans; Indomethacin; Methylcellulose; Polyethylene Glycols; Printing, Three-Dimensional; Tablets; Taste; Taste Perception

Drug-polymer miscibility has been proposed to play a critical role in physical stability of amorphous solid dispersions (ASDs). The purpose of the current work was to investigate the role of drug-polymer miscibility on molecular mobility, measured as enthalpy relaxation (ER) of amorphous irbesartan (IBS) in ASDs.. Two polymers, i.e. polyvinylpyrrolidone K30 (PVP K30) and hydroxypropyl methylcellulose acetate succinate (HPMCAS), were used to generate ASDs with 10% w/w of the polymer. Drug-polymer miscibility was determined using melting point depression (MPD) method. Molecular mobility was assessed from ER studies at a common degree of undercooling (DOU) (T. IBS exhibited higher miscibility in PVP K30 as compared to HPMCAS at temperature > 140°C. However, extrapolation of miscibility data to storage temperature (62°C) using Flory-Huggins (F-H) theory revealed a reversal of the trend. Miscibility of IBS was found to be higher in HPMCAS (2.6%) than PVP K30 (1.3%) at 62°C. Stretched relaxation time (τ. Miscibility of drug-polymer at storage temperature explained the behavior of the molecular mobility, while miscibility near the melting point provided a reverse trend. Results suggest that drug-polymer miscibility determined at temperatures higher than the storage temperature should be viewed cautiously.

Topics: Biological Availability; Chemistry, Pharmaceutical; Drug Compounding; Drug Stability; Drug Storage; Excipients; Irbesartan; Methylcellulose; Povidone; Solubility; Temperature

The purpose of this study was to use statistical design of experiments to develop a stable aqueous enteric coating formulation containing stabilizing excipients, such as polyethylene glycol that can minimize hydroxypropyl methylcellulose acetate succinate aggregation and minimize spray-nozzle clogging at elevated processing temperatures. The mechanisms of stabilization (i.e. charge stabilization and molecular interactions) were studied by performing zeta potential and FTIR studies. Electrostatic stabilization by sodium lauryl sulfate and hydrogen bonding by polyethylene glycol provided dispersion stability and yielded a stable aqueous coating formulation that prevented spray-nozzle clogging. An enteric coated tablet with better gastric resistance was obtained by incorporating fumed silica (Aerosil® R972) as the anti-tacking agent instead of talc. Dissolution testing on the riboflavin enteric coated tablets showed a good enteric release profile without releasing riboflavin in 0.1 N HCl, and completely disintegrating within 10 min in phosphate buffer (pH 6.8).

Topics: Chemistry, Pharmaceutical; Drug Liberation; Drug Stability; Hydrochloric Acid; Methylcellulose; Plasticizers; Polyethylene Glycols; Riboflavin; Silicon Dioxide; Sodium Dodecyl Sulfate; Tablets, Enteric-Coated; Talc; Vitamin B 12

Hot-melt extrusion (HME) has gained increasing attention in the pharmaceutical industry; however, its potential in the preparation of solid self-emulsifying drug delivery systems (S-SMEDDS) is still unexplored. This study sought to prepare enteric S-SMEDDS by HME and evaluate the effects of the process and formulation variables on S-SMEDDS properties via Box-Behnken design. Liquid SMEDDS were developed, and carvedilol was used as a class II model drug. Mean size, polydispersity index (PdI) and zeta potential of the resulting microemulsions were determined. The extrudates were then obtained by blending the lipid mixture and HPMCAS using a twin-screw hot-melt extruder. SEM, optical microscopy and PXRD were used to characterize the extrudates. In vitro microemulsion reconstitution and drug release were also studied. L-SMEDDS gave rise to microemulsions with low mean size, PdI and zeta potential (140.04 ± 7.22 nm, 0.219 ± 0.011 and -9.77 ± 0.86 mV). S-SMEDDS were successfully prepared by HME, and an HMPCAS matrix was able to avoid microemulsion reconstitution and retain drug release in pH 1.2 (12.97%-25.54%). Conversely, microemulsion reconstitution and drug release were gradual in pH 6.8 and complete for some formulations. Extrudates prepared at the lowest drug concentration and highest temperature and recirculation time promoted a complete and rapid drug release in pH 6.8 giving rise to small and uniform microemulsion droplets.

Topics: Carbazoles; Carvedilol; Chemistry, Pharmaceutical; Drug Delivery Systems; Drug Liberation; Emulsions; Hot Temperature; Hydrogen-Ion Concentration; Lipids; Methylcellulose; Particle Size; Propanolamines; Solubility

Hydroxypropyl methylcellulose acetate succinate (HPMCAS) has been widely used in amorphous solid dispersions and as an enteric coating polymer. Under aqueous coating conditions and at elevated coating temperatures, HPMCAS particles tend to aggregate and clog the spray-nozzle, hence interrupting the coating process. This research focused on how plasticizers and surfactants, excipients used for aqueous coating, affect the properties and stability of HPMCAS. This information would be useful in identifying suitable excipients for developing a stable HPMCAS aqueous enteric coating formulation. Triethyl citrate was found to be the most compatible plasticizer with HPMCAS, and displayed suitable thermal and mechanical properties. PEG 4000, the co-plasticizer, provided dispersion stability by yielding a dispersible sediment without aggregation at the elevated processing temperatures. Zeta potential measurements indicated sodium lauryl sulfate (SLS) could be used as a potential stabilizing agent at concentrations above its critical micelle concentration (CMC). This study facilitated the understanding of the HPMCAS aggregation mechanism, in addition to identifying suitable stabilizing agents. These stabilizing excipients could potentially be used to develop a stable aqueous coating formulation that does not exhibit polymer aggregation and nozzle clogging during the coating process.

Topics: Citrates; Drug Compounding; Excipients; Kinetics; Mechanical Phenomena; Methylcellulose; Plasticizers; Polyethylene Glycols; Sodium Dodecyl Sulfate; Surface-Active Agents; Tablets; Temperature

The accuracy of amorphous solubility advantage calculation was evaluated by experimental solubility measurement. Ten structurally diverse compounds were studied to test the generlity of the theoretical calculation. Three reported methods of calculating Gibbs free energy difference between amorphous and crystalline solids were evaluated. Experimental solubility advantage was measured by direct dissolution of amorphous solid in buffer. When necessary, hydroxypropyl methylcellulose acetate succinate (HPMCAS) was predissolved in buffer to inhibit desupersaturation. By direct dissolution, the effect of different preparation methods on amorphous solubility was also studied. Finally, solubility measurement was performed in fasted state simulated intestinal fluid (FaSSIF) to assess the effect of bile salt on the concentration-based amorphous solubility advantage. The results showed that the assumption of constant heat capacity differences between crystal and supercooled liquid or amorphous solid is sufficient for accurate theoretical calculation, which is attributed to the fact that the heat capacity of crystal is nearly parallel to that of supercooled liquid or amorphous solid. Different preparation methods do not have significant impact on amorphous solubility advantage. Experimental measurement agrees with the theoretical calculation within a factor of 0.7 to 1.8. The concentration-based amorphous solubility advantage in FaSSIF agrees well with theoretical calculation. This work demonstrates that theoretical calculation of amorphous solubility advantage is robust and can be applied in early drug development for assessing the utility of the amorphous phase.

Topics: Buffers; Crystallization; Methylcellulose; Pharmaceutical Preparations; Solubility

Amorphous solid dispersions (ASDs) are inherently unstable because of high internal energy. Evaluating physical and chemical stability during the process and storage is essential. Numerous researches have demonstrated how polymers influence the drug precipitation and physical stability of ASDs, while the influence of polymers on the chemical stability of ASDs is often overlooked. Therefore, this study aimed to investigate the effect of polymers on the physical and chemical stability of spray-dried ASDs using dipyridamole (DP) as a model drug. Proper polymers were selected by assessing their abilities to inhibit drug recrystallization in supersaturated solutions. HPMC E5, Soluplus®, HPMCP-55, and HPMCAS-LP were shown to be effective stabilizers. The optimized formulations were further stored at a high temperature (60 °C) and high humidity (40 °C, 75% RH) for 2 months, and their physical and chemical stability was evaluated using polarizing optical microscopy, FTIR, HPLC, and mass spectrometry (MS). In general, crystallization was observed in all samples, which indicated the physical instability under stressed storage conditions. Also, it was noted that the polymers in ASDs rather than physical mixtures, induced a dramatic drug degradation after being exposed to a high temperature (HPMCP-55 > 80% and HPMCAS-LP > 50%) and high humidity (HPMCP-55 > 40% and HPMCAS-LP > 10%). The MS analysis further confirmed the degradation products, which might be generated from the reaction between dipyridamole and phthalic anhydride decomposed from HPMCP-55 and HPMCAS-LP. Overall, the exposure of ASDs to stressed conditions resulted in recrystallization and even the chemical degradation induced by polymers.

Topics: Crystallization; Dipyridamole; Drug Compounding; Drug Stability; Humidity; Methylcellulose; Phosphodiesterase Inhibitors; Polyethylene Glycols; Polymers; Polyvinyls; Solubility

The interest in using electrospraying as a manufacturing method for amorphous solid dispersions has grown remarkably. However, the impact of formulation and process parameters needs further clarification. In this study, amorphous solid dispersions of darunavir and hydroxypropyl methylcellulose (HPMC), hydroxypropyl methylcellulose acetate succinate (HPMC AS) and polyvinylpyrrolidone K-30 (PVP) were prepared with electrospraying and spray drying, in order to compare both solvent based manufacturing techniques. Our results revealed that electrospraying was as successful as spray drying. The formulations prepared with the two methods were amorphous and had similar characteristics concerning the residual solvent and drug release. Although differences in the morphology and the particle size distributions were observed, this was not reflected in the pharmaceutical performance of the formulations. Electrosprayed amorphous solid dispersions made up of darunavir and PVP were studied in more detail by means of a full factorial experimental design. The impact of two process and two formulation parameters on the properties of the amorphous solid dispersions was determined. The feed flow rate had a significant effect on the diameter and morphology of the particles whereas the tip-to-collector distance had no significant impact within the tested range. The drug loading influenced the homogeneity and the residual solvent, and the total solids concentration had an impact on the homogeneity and the morphology.

Topics: Chemistry, Pharmaceutical; Darunavir; Drug Compounding; Drug Liberation; HIV Protease Inhibitors; Hypromellose Derivatives; Methylcellulose; Particle Size; Polymers; Povidone; Solvents; Technology, Pharmaceutical

Hydroxypropyl methylcellulose acetate succinate (HPMC-AS) is one of the most widely used polymers used in amorphous solid dispersions (ASD) for solubility and bioavailability enhancement of poorly water-soluble drugs. Once released from ASDs, HPMC-AS was often found to be highly effective in maintaining drug supersaturation, and this capability is dependent on the concentration and substitution types of this pH-dependent polymer. Therefore, accurate quantification of different grades of HPMC-AS allows us to better understand the release and supersaturation mechanisms of HPMC-AS based ASDs. Since previously reported analytical methods were unable to quantify HPMC-AS in a complex medium with enough sensitivity, we hereby developed a high-sensitivity HPLC-ELSD (evaporative light scattering detector) method with satisfactory specificity, linearity, accuracy and precision, to quantify HPMC-AS down to 20 μg/mL in dissolution media, with the presence of various commonly used pharmaceutical excipients. With the assistance of this method, we compared the intrinsic dissolution rates (IDR) of both the drug and the polymer of posaconazole ASDs based on different types of HPMC-AS. We observed that: 1) For ASDs that were spray dried and uniformly mixed, drug and polymer released simultaneously into the medium with practically identical IDRs slower than the IDR of pure HPMC-AS; 2) For ASDs that were heterogeneously mixed, IDRs of the drug and polymer were significantly slower or faster than the IDRs of the drug and polymer of the uniform ASDs, respectively. In summary, the high sensitivity HPLC-ELSD method established here can be readily applied to quantify HPMC-AS in various dissolution media, thus helps to reveal the release kinetics and mechanisms of different HPMC-AS based ASDs.

Topics: Chromatography, High Pressure Liquid; Desiccation; Drug Liberation; Kinetics; Methylcellulose

Hydroxypropyl methylcellulose acetate succinate (HPMC-AS) is one of the commonly selected polymers used in amorphous solid dispersions (ASD) with excellent capabilities to maintain aqueous supersaturation of poorly water-soluble drugs and inhibit their crystallization, but the underlying mechanisms remain elusive. In this study, posaconazole was chosen as the model drug to study the supersaturation maintaining and crystallization inhibition capabilities of different types of HPMC-AS under pH 5.5-7.5. We analyzed the HPMC-AS aggregation status in solution using combination of static and dynamic light scattering and observed higher polymer aggregation number when higher grade HPMC-AS or lower pH was used, which correlates well with prolonged drug supersaturation or crystallization inhibition. The amount of HPMC-AS coprecipitated with PSZ, a direct indicator of drug/HPMC-AS affinity, also showed positive correlation with the drug supersaturation and crystallization inhibition in the dissolution process. Therefore, we conclude that the aggregation behavior of HPMC-AS and the drug/HPMC-AS affinity are the key mechanisms that lead to posaconazole supersaturation and crystallization inhibition when HPMC-AS was applied.

Topics: Crystallization; Hydrogen-Ion Concentration; Light; Methylcellulose

Hydroxypropyl methylcellulose acetate succinate (HPMCAS) is an excellent polymeric carrier for melt extrusion amorphous solid dispersion. However, its pH-dependent solubility limits its application, especially for narrow absorption window drugs. The current study proposed a novel dual approach of foam extrusion and microenvironmental pH modulation to overcome this limitation. Sodium bicarbonate was used as a blowing agent and the remaining sodium carbonate acted as an internal pH modifier. Compared with conventional extrusion, foam extrusion dramatically lowered the extrudate physical strength (breaking force and hardness decreased by 20-fold; breaking energy and deformation energy decreased by >30-fold). Milling efficiency of foam extrudate was largely improved compared with that of conventional extrudates, demonstrating smaller particle size, larger specific surface area, and ability to pass through a smaller milling screen. The foam extrudate could generate a supersaturation concentration up to 8-fold higher than the solubility of the pure drug. It also significantly enhanced drug dissolution in a two-step biorelevant medium (p < 0.05). This novel approach improved both manufacturing processability and dissolution of HPMCAS-based solid dispersions.

Topics: Chemistry, Pharmaceutical; Drug Compounding; Hydrogen-Ion Concentration; Methylcellulose

In current study, a novel nimodipine solid dispersion (NM-SD) was prepared by hot-melt extrusion (HME) with Hypromellose methylcellulose acetate succinate (H type and fine grades, HPMCAS-HF) for its excellent recrystallization inhibition effects. NM was confirmed to exist as an amorphous state in NM-SD by differential scanning calorimetry (DSC), powder X-ray diffraction (PXRD), hot stage microscopy (HSM) and scanning electron micrographs (SEM). FT-IR analysis illustrated hydrogen bond interaction between drugs and excipients in NM-SD. The release behavior of NM-SD tablets was investigated in the dissolution medium of pH 6.8 for the in vitro study, which showed that the release of nimodipine could be realized in vitro without recrystallization within two hours. The in vivo pharmacokinetic profiles study in Sprague-Dawley rats was also determined. It was obvious that the C

Topics: Animals; Calorimetry, Differential Scanning; Crystallization; Drug Compounding; Methylcellulose; Nimodipine; Particle Size; Rats, Sprague-Dawley; Spectroscopy, Fourier Transform Infrared; Tablets; Temperature; Thermogravimetry; X-Ray Diffraction

The purpose of the present study was to investigate the precipitation of a drug on the particle surface of its salt in biorelevant media. Pioglitazone (PIO, weak base, pK

Topics: Bile; Chemical Precipitation; Crystallization; Glass; Hypromellose Derivatives; Methylcellulose; Micelles; Pioglitazone; Salts; Spectrum Analysis, Raman; X-Ray Diffraction

Ciprofloxacin (CIP) is a poorly soluble drug that also displays poor permeability. Attempts to improve the solubility of this drug to date have largely focused on the formation of crystalline salts and metal complexes. The aim of this study was to prepare amorphous solid dispersions (ASDs) by ball milling CIP with various polymers. Following examination of their solid state characteristics and physical stability, the solubility advantage of these ASDs was studied, and their permeability was investigated via parallel artificial membrane permeability assay (PAMPA). Finally, the minimum inhibitory concentration (MIC) and minimum bactericidal concentration (MBC) of the ASDs were compared to those of CIP. It was discovered that acidic polymers, such as Eudragit L100, Eudragit L100-55, Carbopol, and HPMCAS, were necessary for the amorphization of CIP. In each case, the positively charged secondary amine of CIP was found to interact with carboxylate groups in the polymers, forming amorphous polymeric drug salts. Although the ASDs began to crystallize within days under accelerated stability conditions, they remained fully X-ray amorphous following exposure to 90% RH at 25 °C, and demonstrated higher than predicted glass transition temperatures. The solubility of CIP in water and simulated intestinal fluid was also increased by all of the ASDs studied. Unlike a number of other solubility enhancing formulations, the ASDs did not decrease the permeability of the drug. Similarly, no decrease in antibiotic efficacy was observed, and significant improvements in the MIC and MBC of CIP were obtained with ASDs containing HPMCAS-LG and HPMCAS-MG. Therefore, ASDs may be a viable alternative for formulating CIP with improved solubility, bioavailability, and antimicrobial activity.

Topics: Acrylic Resins; Ciprofloxacin; Methylcellulose; Microbial Sensitivity Tests; Polymers; Polymethacrylic Acids; Solubility

Improving the oral absorption of compounds with low aqueous solubility is a common challenge that often requires an enabling technology. Frequently, oral absorption can be improved by formulating the compound as an amorphous solid dispersion (ASD). Upon dissolution, an ASD can reach a higher concentration of unbound drug than the crystalline form, and often generates a large number of sub-micrometer, rapidly dissolving drug-rich colloids. These drug-rich colloids have the potential to decrease the diffusional resistance across the unstirred water layer of the intestinal tract (UWL) by acting as rapidly diffusing shuttles for unbound drug. In a prior study utilizing a membrane flux assay, we demonstrated that, for itraconazole, increasing the concentration of drug-rich colloids increased membrane flux in vitro. In this study, we evaluate spray-dried amorphous solid dispersions (SDDs) of itraconazole with hydroxypropyl methylcellulose acetate succinate (HPMCAS) to study the impact of varying concentrations of drug-rich colloids on the oral absorption of itraconazole in rats, and to quantify their impact on in vitro flux as a function of bile salt concentration. When Sporanox and itraconazole/AFFINISOL High Productivity HPMCAS SDDs were dosed in rats, the maximum absorption rate for each formulation rank-ordered with membrane flux in vitro. The relative maximum absorption rate in vivo correlated well with the in vitro flux measured in 2% SIF (26.8 mM bile acid concentration), a representative bile acid concentration for rats. In vitro it was found that as the bile salt concentration increases, the importance of colloids for improving UWL permeability is diminished. We demonstrate that drug-containing micelles and colloids both contribute to aqueous boundary layer diffusion in proportion to their diffusion coefficient and drug loading. These data suggest that, for compounds with very low aqueous solubility and high epithelial permeability, designing amorphous formulations that produce colloids on dissolution may be a viable approach to improve oral bioavailability.

Topics: Animals; Calorimetry, Differential Scanning; Colloids; Itraconazole; Male; Methylcellulose; Micelles; Rats; Rats, Sprague-Dawley

Mesoporous silicas (SLC) have demonstrated considerable potential to improve bioavailability of poorly soluble drugs by facilitating rapid dissolution and generating supersaturation. The addition of certain polymers can further enhance the dissolution of these formulations by preventing drug precipitation. This study uses fenofibrate as a model drug to investigate the performance of an SLC-based formulation, delivered with hydroxypropyl methylcellulose acetate succinate (HPMCAS) as a precipitation inhibitor, in pigs. The ability of biorelevant dissolution testing to predict the in vivo performance was also assessed.. Fenofibrate-loaded mesoporous silica (FF-SLC), together with HPMCAS, displayed significant improvements in biorelevant dissolution tests relative to a reference formulation consisting of a physical mixture of crystalline fenofibrate with HPMCAS. In vivo assessment in fasted pigs demonstrated bioavailabilities of 86.69 ± 35.37% with combination of FF-SLC and HPMCAS in capsule form and 75.47 ± 14.58% as a suspension, compared to 19.92 ± 9.89% with the reference formulation. A positive correlation was identified between bioavailability and dissolution efficiency.. The substantial improvements in bioavailability of fenofibrate from the SLC-based formulations confirm the ability of this formulation strategy to overcome the dissolution and solubility limitations, further raising the prospects of a future commercially available SLC-based formulation.

Topics: Administration, Oral; Animals; Biological Availability; Dosage Forms; Fenofibrate; Hypolipidemic Agents; Male; Methylcellulose; Porosity; Silicon Dioxide; Solubility; Swine

An advanced oral drug delivery system that can effectively deliver drugs with poor oral bioavailability is strongly desirable. Herein, a multifunctional nano-in-micro structured composite is developed by encapsulation of the mucoadhesive poly(methyl vinyl ether-co-maleic acid) modified halloysite nanotubes (HNTs) with the pH-responsive hydroxypropyl methylcellulose acetate succinate by the microfluidics to control the drug release, increase cell-particle interaction, and improve drug absorption. The microparticles show spherical shape, homogeneous particle size distribution (58 ± 1 µm), and pH-responsive dissolution behavior at pH > 6, and they prevent the premature release of curcumin in simulated pH conditions of the stomach and immediately release the curcumin in simulated pH conditions of the small intestine. The surface modification of HNT with mucoadhesive poly(methyl vinyl ether-co-maleic acid) significantly enhances its interactions with the intestinal Caco-2/HT29-MTX cells and the mouse small intestines, and increases the permeability of curcumin across the co-cultured Caco-2/HT29-MTX cell monolayers by about 13 times compared to the free curcumin. Therefore, the developed multifunctional nanotube-mucoadhesive poly(methyl vinyl ether-co-maleic acid)@hydroxypropyl methylcellulose acetate succinate composite is a promising oral drug delivery system for drugs with poor oral bioavailability.

Topics: Administration, Oral; Animals; Caco-2 Cells; Cell Proliferation; Cell Survival; Curcumin; Drug Carriers; Drug Liberation; HT29 Cells; Humans; Hydrogen-Ion Concentration; Intestine, Small; Maleates; Methyl Ethers; Methylcellulose; Mice; Nanotubes; Particle Size; Permeability; Polyvinyls

We recently developed coarse-grained (CG) force fields for hydroxypropyl methylcellulose acetate succinate (HPMCAS) polymers and the model drug molecule phenytoin, and a continuum transport model to study the polymer-drug nanostructures presented during a dissolution test after solvation of solid dispersion particles. We model the polymer-drug interactions that contribute to suppression of drug aggregation, release, and crystal growth during the dissolution process, and we take these as indicators of polymer effectiveness. We find that the size and the intermolecular interaction strength of the functional group and the drug loading concentration are the major factors that impact the effectiveness of the polymeric excipient. The hydroxypropyl acetyl group is the most effective functional group, followed by the acetyl group, while the deprotonated succinyl group is the least effective functional group, except that the deprotonated succinyl group at the 6-position is very effective in slowing down the phenytoin crystal growth. Our simulation results thus suggest HPMCAS with higher acetyl and lower succinyl content is more effective in promoting phenytoin solubility in dissolution media, and polymers become less effective when drug loading becomes high (i.e., 50% of the mass of the polymer/drug solid dispersion), agreeing with previous experimental studies. In addition, our transport model indicates that the drug release time from a solid dispersion particle of 2 μm diameter is less than 10 min, correlating well with the experimental time scale for a typical dissolution profile to reach maximum peak concentration. Our modeling effort, therefore, provides new avenues to understand the dissolution behavior of complex HPMCAS-phenytoin solid dispersions and offers a new design tool to optimize the formulation. Moreover, the systematic and robust approach used in our computational models can be extended to other polymeric excipients and drug candidates.

Topics: Chemistry, Pharmaceutical; Crystallization; Drug Carriers; Drug Liberation; Drug Stability; Excipients; Hydrogen Bonding; Methylcellulose; Models, Chemical; Models, Molecular; Molecular Dynamics Simulation; Nanostructures; Phenytoin; Solubility

Various techniques have been used to detect crystallization in amorphous solid dispersions (ASD). However, most of these techniques do not enable the detection of very low levels of crystallinity (<1%). The aim of the current study was to compare the sensitivity of second harmonic generation (SHG) microscopy with powder X-ray diffraction (XRPD) in detecting the presence of crystals in low drug loading amorphous solid dispersions. Amorphous solid dispersions of the poorly water soluble compounds, flutamide (FTM, 15wt.% drug loading) and ezetimibe (EZT, 30wt.% drug loading) with hydroxypropyl methylcellulose acetate succinate (HPMCAS) were prepared by spray drying. To induce crystallization, samples were subsequently stored at 75% or 82% relative humidity (RH) and 40°C. Crystallization was monitored by XRPD and by SHG microscopy. Solid state nuclear magnetic resonance spectroscopy (ssNMR) was used to further investigate crystallinity in selected samples. For flutamide, crystals were detected by SHG microscopy after 8days of storage at 40°C/82% RH, whereas no evidence of crystallinity could be observed by XRPD until 26days. Correspondingly, for FTM samples stored at 40°C/75% RH, crystals were detected after 11days by SHG microscopy and after 53days by XRPD. The evolution of crystals, that is an increase in the number and size of crystalline regions, with time could be readily monitored from the SHG images, and revealed the formation of needle-shaped crystals. Further investigation with scanning electron microscopy indicated an unexpected mechanism of crystallization, whereby flutamide crystals grew as needle-shaped projections from the surface of the spray dried particles. Similarly, EZT crystals could be detected at earlier time points (15days) with SHG microscopy relative to with XRPD (60days). Thus, SHG microscopy was found to be a highly sensitive method for detecting and monitoring the evolution of crystals formed from spray dried particles, providing much earlier detection of crystallinity than XRPD under comparable run times.

Topics: Crystallization; Desiccation; Ezetimibe; Flutamide; Humidity; Methylcellulose; Powders; Second Harmonic Generation Microscopy; Solubility; X-Ray Diffraction

The aim of this research was to study the interplay of solid and solution state phase transformations during the dissolution of ritonavir (RTV) amorphous solid dispersions (ASDs).. RTV ASDs with polyvinylpyrrolidone (PVP), polyvinylpyrrolidone vinyl acetate (PVPVA) and hydroxypropyl methylcellulose acetate succinate (HPMCAS) were prepared at 10-50% drug loading by solvent evaporation. The miscibility of RTV ASDs was studied before and after exposure to 97% relative humidity (RH). Non-sink dissolution studies were performed on fresh and moisture-exposed ASDs. RTV and polymer release were monitored using ultraviolet-visible spectroscopy. Techniques including fluorescence spectroscopy, confocal imaging, scanning electron microscopy (SEM), atomic force microscopy (AFM), differential scanning calorimetry (DSC) and nanoparticle tracking analysis (NTA) were utilized to monitor solid and the solution state phase transformations.. All RTV-PVP and RTV-PVPVA ASDs underwent moisture-induced amorphous-amorphous phase separation (AAPS) on high RH storage whereas RTV-HPMCAS ASDs remained miscible. Non-sink dissolution of PVP- and PVPVA-based ASDs at low drug loadings led to rapid RTV and polymer release resulting in concentrations in excess of amorphous solubility, liquid-liquid phase separation (LLPS) and amorphous nanodroplet formation. High drug loading PVP- and PVPVA-based ASDs did not exhibit LLPS upon dissolution as a consequence of extensive AAPS in the hydrated ASD matrix. All RTV-HPMCAS ASDs led to LLPS upon dissolution.. RTV ASD dissolution is governed by a competition between the dissolution rate and the rate of phase separation in the hydrated ASD matrix. LLPS was observed for ASDs where the drug release was polymer controlled and only ASDs that remained miscible during the initial phase of dissolution led to LLPS. Techniques such as fluorescence spectroscopy, confocal imaging and SEM were useful in understanding the phase behavior of ASDs upon hydration and dissolution and were helpful in elucidating the mechanism of generation of amorphous nanodroplets.

Topics: Crystallization; Cytochrome P-450 CYP3A Inhibitors; Delayed-Action Preparations; Drug Liberation; Excipients; HIV Protease Inhibitors; Humidity; Methylcellulose; Phase Transition; Povidone; Ritonavir; Solubility; Vinyl Compounds

The purpose of this work is to compare the long-term physical stability of amorphous solid dispersion (ASD) formulations based on three different commercially used excipients, namely, poly(vinylpyrrolidone) K25 (PVP), poly(vinylpyrrolidone-co-vinyl acetate) (PVPVA64), and hydroxypropyl methylcellulose acetate succinate 126G (HPMCAS), at standardized ICH storage conditions, 25 °C/0% relative humidity (RH), 25 °C/60% RH, and 40 °C/75% RH. Acetaminophen (APAP) and naproxen (NAP) were used as active pharmaceutical ingredients (APIs). 18 month long stability studies of these formulations were analyzed and compared with the API/polymer phase diagrams, which were modeled and predicted by applying the Perturbed-Chain Statistical Associating Fluid Theory (PC-SAFT) and the Gordon-Taylor or Kwei equation. The study showed that, at dry storage, the solubility of the APIs in the polymers and the kinetic stabilizing ability of the polymers increase in the following order: HPMCAS < PVPVA64 < PVP. RH significantly reduces the kinetic stabilization as well as NAP solubility in the polymers, while the impact on APAP solubility is small. The impact of RH on the stability increases with increasing hydrophilicity of the pure polymers (HPMCAS < PVPVA64 < PVP). The experimental stability results were in very good agreement with predictions confirming that PC-SAFT and the Kwei equation are suitable predictive tools for determining appropriate ASD compositions and storage conditions to ensure long-term physical stability.

Topics: Acetaminophen; Chemistry, Pharmaceutical; Crystallization; Drug Carriers; Drug Compounding; Drug Stability; Excipients; Humidity; Kinetics; Methylcellulose; Models, Chemical; Naproxen; Povidone; Pyrrolidines; Solubility; Thermodynamics; Vinyl Compounds

Currently cocrystals are considered as an established approach for making crystalline solids with overall improved physico-chemical properties. However, some otherwise well behaving cocrystals undergo rapid dissociation during dissolution, with ultimate conversion to parent drug and thus apparent loss of improved solubility. The polymeric carriers are long known to manipulate this conversion during dissolution to parent crystalline drug, which may hinder or accelerate the dissolution process if used in a dosage form. The goal of this study was to deliver in vivo a more soluble carbamazepine-succinic acid (CBZ-SUC) cocrystal in suspension formulation utilizing Hydroxypropyl methyl cellulose (HPMC-AS) as a crystallization inhibitor and Polyvinyl carpolactam-polyvinyl acetate-polyethylene glycol graft copolymer ® as solubilizer. The concentration of these polymers were systemically varied during in vitro dissolution studies, while selected formulations from dissolution studies were tested in vivo. Pharmacokinetic studies (PK) in rabbits demonstrated that formulation F7-X (1% cocrystal, 1% HPMC-AS and 2% Polyvinyl carpolactam-polyvinyl acetatepolyethylene glycol graft co-polymer®) caused almost 6fold improvement in AUC0-72 (***P k 0.05) as well as much higher C

Topics: Administration, Oral; Animals; Biological Availability; Carbamazepine; Crystallization; Drug Compounding; Methylcellulose; Polyethylene Glycols; Polyvinyls; Rabbits; Solubility; Succinates; Tablets; Technology, Pharmaceutical

To investigate the effect of compression on the crystallization behavior in amorphous tablets using sum frequency generation (SFG) microscopy imaging and more established analytical methods.. Tablets containing neat amorphous griseofulvin with/without excipients (silica, hydroxypropyl methylcellulose acetate succinate (HPMCAS), microcrystalline cellulose (MCC) and polyethylene glycol (PEG)) were prepared. They were analyzed upon preparation and storage using attenuated total reflectance Fourier transform infrared (ATR-FTIR) spectroscopy, scanning electron microscopy (SEM) and SFG microscopy.. Compression-induced crystallization occurred predominantly on the surface of the neat amorphous griseofulvin tablets, with minimal crystallinity being detected in the core of the tablets. The presence of various types of excipients was not able to mitigate the compression-induced surface crystallization of the amorphous griseofulvin tablets. However, the excipients affected the crystallization rate of amorphous griseofulvin in the core of the tablet upon compression and storage.. SFG microscopy can be used in combination with ATR-FTIR spectroscopy and SEM to understand the crystallization behaviour of amorphous tablets upon compression and storage. When selecting excipients for amorphous formulations, it is important to consider the effect of the excipients on the physical stability of the amorphous formulations.

Topics: Cellulose; Chemistry, Pharmaceutical; Crystallization; Excipients; Griseofulvin; Methylcellulose; Microscopy, Electron, Scanning; Polyethylene Glycols; Pressure; Silicon Dioxide; Spectroscopy, Fourier Transform Infrared; Tablets

The purpose of this study was to determine the drug-polymer miscibility of GENE-A, a Genentech molecule, and hydroxypropyl methylcellulose-acetate succinate (HPMC-AS), a polymer, using computational and experimental approaches. The Flory-Huggins interaction parameter,χ, was obtained by calculating the solubility parameters for GENE-A and HPMC-AS over the temperature range of 25-100°C to obtain the free energy of mixing at different drug loadings (0-100%) using the Materials Studio modeling and simulation platform (thermodynamic approach). Solid-state nuclear magnetic spectroscopy (ssNMR) was used to measure the proton relaxation times for both drug and polymer at different drug loadings (up to 60%) at RT (kinetic approach). Thermodynamically, the drug and polymer were predicted to show favorable mixing as indicated by a negative Gibbs free energy of mixing from 25 to 100°C. ssNMR showed near identical relaxation times for both drug and polymer in the solid dispersion at RT and 40°C for a period up to 6 months showing phase mixing between the API and polymer on <10nm scale. Orthogonal computational and experimental approaches indicate phase mixing of the system components.

Topics: Chemistry, Pharmaceutical; Drug Stability; Methylcellulose; Pharmaceutical Preparations; Polymers; Solubility; Technology, Pharmaceutical; Thermodynamics

A generalized screening approach, applying isothermal calorimetry at 37 °C 100% RH, to formulations of spray dried dispersions (SDDs) for two active pharmaceutical ingredients (APIs) (BMS-903452 and BMS-986034) is demonstrated. APIs 452 and 034, with similar chemotypes, were synthesized and promoted during development for oral dosing. Both APIs were formulated as SDDs for animal exposure studies using the polymer hydroxypropylmethlycellulose acetyl succinate M grade (HPMCAS-M). 452 formulated at 30% (wt/wt %) was an extremely robust SDD that was able to withstand 40 °C 75% RH open storage conditions for 6 months with no physical evidence of crystallization or loss of dissolution performance. Though 034 was a chemical analogue with similar physical chemical properties to 452, a physically stable SDD of 034 could not be formulated in HPMCAS-M at any of the drug loads attempted. This study was used to develop experience with specific physical characterization laboratory techniques to evaluate the physical stability of SDDs and to characterize the propensity of SDDs to phase separate and possibly crystallize. The screening strategy adopted was to stress the formulated SDDs with a temperature humidity screen, within the calorimeter, and to apply orthogonal analytical techniques to gain a more informed understanding of why these SDDs formulated with HPMCAS-M demonstrated such different physical stability. Isothermal calorimetry (thermal activity monitor, TAM) was employed as a primary stress screen wherein the SDD formulations were monitored for 3 days at 37 °C 100% RH for signs of phase separation and possible crystallization of API. Powder X-ray diffraction (pXRD), modulated differential scanning calorimetry (mDSC), Fourier transform infrared spectroscopy (FTIR), and solid state nuclear magnetic resonance (ssNMR) were all used to examine formulated SDDs and neat amorphous drug. 452 SDDs formulated at 30% (wt/wt %) or less did not show phase separation behavior upon exposure to 37 °C 100% RH for 3 days. 034 SDD formulations from 10 through 50% (wt/wt %) all demonstrated thermal traces consistent with exothermic phase separation events over 3 days at 37 °C 100% RH in the TAM. However, only the 15, 30, and 50% containing 034 samples showed pXRD patterns consistent with crystalline material in post-TAM samples. Isothermal calorimetry is a useful screening tool to probe robust SDD physical performance and help investigate the level of drug polymer miscibility unde

Topics: Animals; Calorimetry; Calorimetry, Differential Scanning; Chemistry, Pharmaceutical; Crystallization; Drug Stability; Humidity; Methylcellulose; Polymers; Powders; Pyridones; Solubility; Spectroscopy, Fourier Transform Infrared; Sulfones; Temperature; X-Ray Diffraction

We present coarse-grained (CG) force fields for hydroxypropyl-methylcellulose acetate succinate (HPMCAS) polymers and the drug molecule phenytoin using a bead/stiff spring model, with each bead representing a HPMCAS monomer or monomer side group (hydroxypropyl acetyl, acetyl, or succinyl) or a single phenytoin ring. We obtain the bonded and nonbonded interaction parameters in our CG model using the RDFs from atomistic simulations of short HPMCAS model oligomers (20-mer) and atomistic simulations of phenytoin molecules. The nonbonded interactions are modeled using a LJ 12-6 potential, with separate parameters for each monomer substitution type, which allows heterogeneous polymer chains to be modeled. The cross interaction terms between the polymer and phenytoin CG beads are obtained explicitly from atomistic level polymer-phenytoin simulations, rather than from mixing rules. We study the solvation behavior of 50-mer and 100-mer polymer chains and find chain-length-dependent aggregation. We also compare the phenytoin CG force field developed in this work with that in Mandal et al. (Soft Matter, 2016, 12, 8246-8255) and conclude both are suitable for studying the interaction between polymer and drug in solvated solid dispersion formulation, in the absence of drug crystallization. Finally, we present simulations of heterogeneous HPMCAS model polymer chains and phenytoin molecules. Polymer and drug form a complex in a short period of simulation time due to strong intermolecular interactions. Moreover, the protonated polymer chains are more effective than deprotonated ones in inhibiting the drug aggregation in the polymer-drug complex.

Topics: Chemistry, Pharmaceutical; Computer Simulation; Crystallization; Drug Stability; Methylcellulose; Phenytoin; Polymers

Novel, high-yield alternating current electrospinning (ACES) and direct current electrospinning methods were investigated to prepare high-quality hydroxypropylmethylcellulose acetate succinate (HPMCAS) fibers for the dissolution enhancement of poorly soluble spironolactone. Although HPMCAS is of great pharmaceutical importance as a carrier of marketed solid dispersion-based products, it was found to be unprocessable using electrospinning. Addition of small amounts of polyethylene oxide as aid polymer provided smooth fibers with direct current electrospinning but strongly beaded products with ACES. Solution characteristics were thus modified by introducing further excipients. In the presence of sodium dodecyl sulfate, high-quality, HPMCAS-based fibers were obtained even at higher throughput rates of ACES owing to the change in conductivity (rather than surface tension). Replacement of sodium dodecyl sulfate with non-surface-active salts (calcium chloride and ammonium acetate) maintained the fine quality of nanofibers, confirming the importance of conductivity in ACES process. The HPMCAS-based fibers contained spironolactone in an amorphous form according to differential scanning calorimetry and X-ray powder diffraction. In vitro dissolution tests revealed fast drug release rates depending on the salt used to adjust conductivity. The presented results signify that ACES can be a prospective process for high-scale production of fibrous solid dispersions in which conductivity of solution has a fundamental role.

Topics: Drug Carriers; Drug Liberation; Excipients; Methylcellulose; Nanofibers; Polyethylene Glycols; Sodium Dodecyl Sulfate; Solubility; Spironolactone

Blends of hydroxypropyl methylcellulose acetate succinate (HPMCAS) and dodecyl (C

Topics: Acrylamides; Acrylic Resins; Excipients; Hydrophobic and Hydrophilic Interactions; Methylcellulose; Micelles; Phenytoin; Polymers

Mesoporous silica-based dosage forms offer the potential for improving the absorption of poorly soluble drugs after oral administration. In this investigation, fenofibrate was used as a model drug to study the ability of monomodal ('PSP A') and bimodal ('PSP B') porous silica to improve release by a 'spring' effect in in vitro biorelevant dissolution tests. Also investigated was the addition of various polymers to provide a 'parachute' effect, that is, to keep the drug in solution after its release.. Loading fenofibrate onto PSP A or PSP B porous silica substantially improved the dissolution profile of fenofibrate under fasted state conditions compared with both pure drug and the marketed product, TriCor® 145 mg. Adding a polymer such as hydroxypropyl methylcellulose acetate succinate, polyvinylpyrrolidone or copovidon (HPMCAS, PVP or PVPVA) sustains the higher release of fenofibrate from the PSP A silica, resulting in a combination 'spring and parachute' effect - loading the drug onto the silica causes a 'spring' effect while the polymer enhances the spring effect (HPMCAS, PVP) and adds a sustaining 'parachute'. Interestingly, a silica to polymer ratio of 4:1 w/w appears to have an optimal effect for fenofibrate (HPMCAS, PVP). Dissolution results under conditions simulating the fasted state in the small intestine with the PSP A or the PSP B silica with HPMCAS added in a 4:1 w/w ratio show very substantial improvement over the marketed, nanosized product (TriCor® 145 mg).. Further experiments to determine whether the highly positive effects on fenofibrate release observed with the silica prototypes investigated to date can be translated to further poorly soluble drugs and to what extent they translate into improved in-vivo performance are warranted.

Topics: Delayed-Action Preparations; Drug Compounding; Fasting; Fenofibrate; Gastric Juice; Hypolipidemic Agents; Hypromellose Derivatives; Intestinal Secretions; Kinetics; Methylcellulose; Models, Chemical; Nanoparticles; Particle Size; Porosity; Povidone; Pyrrolidines; Silicon Dioxide; Solubility; Technology, Pharmaceutical; Vinyl Compounds

The use of soluble cocrystal for delivering drugs with low solubility, although a potentially effective approach, often suffers the problem of rapid disproportionation during dissolution, which negates the solubility advantages offered by the cocrystal. This necessitates their robust stabilization in order for successful use in a tablet dosage form. The cocrystal between carbamezepine and succinic acid (CBZ-SUC) exhibits a higher aqueous solubility than its dihydrate, which is the stable form of CBZ in water. Using this model system, we demonstrate an efficient and material-sparing tablet formulation screening approach enabled by intrinsic dissolution rate measurements. Three tablet formulations capable of stabilizing the cocrystal both under accelerated condition of 40 °C and 75% RH and during dissolution were developed using three different polymers, Soluplus® (F1), Kollidon VA/64 (F2) and Hydroxypropyl methyl cellulose acetate succinate (F3). When compared to a marketed product, Epitol® 200 mg tablets (F0), drug release after 60 min from formulations F1 (∼82%), F2 (∼95%) and F3 (∼95%) was all higher than that from Epitol® (79%) in a modified simulated intestinal fluid. Studies in albino rabbits show correspondingly better bioavailability of F1-F3 than Epitol.

Topics: Animals; Carbamazepine; Chemistry, Pharmaceutical; Crystallization; Methylcellulose; Polyethylene Glycols; Polymers; Polyvinyls; Pyrrolidines; Rabbits; Solubility; Succinic Acid; Tablets; Vinyl Compounds

The aims of this study were twofold. First, to evaluate the effectiveness of selected polymers in inhibiting solution crystallization of celecoxib. Second, to compare the release rate and crystallization tendency of celecoxib amorphous solid dispersions (ASDs) formulated with a single polymer, or binary polymer combinations.. The effectiveness of polymers, polyvinylpyrrolidone (PVP), hydroxypropylmethyl cellulose (HPMC) or HPMC acetate succinate (HPMCAS), in maintaining supersaturation of celecoxib solutions was evaluated by performing nucleation induction time measurements. Crystallization kinetics of ASD suspensions were monitored using Raman spectroscopy. Dissolution experiments were carried out under non-sink conditions.. Pure amorphous celecoxib crystallized rapidly through both matrix and solution pathways. Matrix and solution crystallization was inhibited when celecoxib was molecularly mixed with a polymer, resulting in release of the drug to form supersaturated solutions. Cellulosic polymers were more effective than PVP in maintaining supersaturation. Combining a cellulosic polymer and PVP enabled improved drug release and stability to crystallization.. Inclusion of an effective solution crystallization inhibitor as a minor component in ternary dispersions resulted in prolonged supersaturation following dissolution. This study shows the feasibility of formulation strategies for ASDs where a major polymer component is used to achieve one key property e.g. release, while a minor polymer component is added to prevent crystallization.

Topics: Celecoxib; Chemistry, Pharmaceutical; Crystallization; Drug Stability; Kinetics; Methylcellulose; Polymers; Povidone; Solubility; Solutions; Spectrum Analysis, Raman

The aim of this study was to formulate probiotics-encapsulated pellets with hydroxypropyl methylcellulose acetate succinate (HPMCAS) using a dry powder coating technique to improve the storage stability, acid resistance, and intestinal adherence of viable bacteria (Lactobacillus acidophilus and Bifidobacteria animalis ssp. Lactis). Dry coated pellet (DCP) loaded with probiotics was optimized with respect to the quantity of the HPMCAS, an enteric coating polymer (108 mg), and the kinds and amounts of plasticizer (triethyl citrate, 15.7 mg; acetylated monoglyceride, 6.8 mg), by evaluating the survival rate of the bacteria during preparation process and in an acidic medium. Dry coating process allows the whole survivals of living bacteria during preparation process. The DCP formulation exhibited markedly higher acid tolerability and storage stability compared to uncoated viable bacteria. In an in vivo mucosal adherence study in rats, a profound colonization of viable bacteria in the small and large intestine was observed in rats receiving DCP system (p<0.05) compared to rats receiving uncoated probiotics. Moreover, we found that the repeated DCP administration noticeably inhibited intestinal penetration of endotoxin, a potent inflammatory stimulant, from intestinal mucus. The novel DCP system may be an alternative approach for improving bacterial viability in the preparation process and in an acidic medium, and to promote mucosal colonization of probiotic bacteria in the human gut.

Topics: Animals; Bifidobacterium; Intestinal Mucosa; Lactobacillus acidophilus; Male; Methylcellulose; Probiotics; Rats; Rats, Sprague-Dawley

Amorphous solid dispersions (ASDs) are of great interest as enabling formulations because of their ability to increase the bioavailability of poorly soluble drugs. However, the dissolution of these formulations under nonsink dissolution conditions results in highly supersaturated drug solutions that can undergo different types of phase transitions. The purpose of this study was to characterize the phase behavior of solutions resulting from the dissolution of model ASDs as well as the degree of supersaturation attained. Danazol was chosen as a poorly water-soluble model drug, and three polymers were used to form the dispersions: polyvinylpyrrolidone (PVP), hydroxypropylmethyl cellulose (HPMC), and hydroxypropylmethyl cellulose acetate succinate (HPMCAS). Dissolution studies were carried out under nonsink conditions, and solution phase behavior was characterized using several orthogonal techniques. It was found that liquid-liquid phase separation (LLPS) occurred following dissolution and prior to crystallization for most of the dispersions. Using flux measurements, it was further observed that the maximum attainable supersaturation following dissolution was equivalent to the amorphous solubility. The dissolution of the ASDs led to sustained supersaturation, the duration of which varied depending on the drug loading and the type of polymer used in the formulation. The overall supersaturation profile observed thus depended on a complex interplay between dissolution rate, polymer type, drug loading, and the kinetics of crystallization.

Topics: Crystallization; Danazol; Hypromellose Derivatives; Methylcellulose; Polymers; Povidone

The aim of the study was to investigate the effect of novel polymer/lipid formulations on the dissolution rates of the water insoluble indomethacin (INM), co-processed by hot melt extrusion (HME). Formulations consisted of the hydrophilic hydroxypropyl methyl cellulose polymer (HPMCAS) and stearoyl macrogol-32 glycerides-Gelucire 50/13 (GLC) were processed with a twin screw extruder to produce solid dispersions. The extrudates characterized by X-ray powder diffraction (XRPD), differential scanning calorimetry (DSC) and hot stage microscopy (HSM) indicated the presence of amorphous INM within the polymer/lipid matrices. In-line monitoring via near-infrared (NIR) spectroscopy revealed significant peak shifts indicating possible interactions and H-bonding formation between the drug and the polymer/lipid carriers. Furthermore, in vitro dissolution studies showed a synergistic effect of the polymer/lipid carrier with 2-h lag time in acidic media followed by enhanced INM dissolution rates at pH > 5.5.

Topics: Calorimetry, Differential Scanning; Chemistry, Pharmaceutical; Delayed-Action Preparations; Drug Carriers; Drug Compounding; Fats; Glycerides; Hot Temperature; Hydrogen-Ion Concentration; Hydrophobic and Hydrophilic Interactions; Indomethacin; Lipids; Methylcellulose; Oils; Polyethylene Glycols; Polymers; Solubility; X-Ray Diffraction

The objective of the study was to identify the extragranular component requirements (level and type of excipients) to develop an immediate release tablet of solid dispersions prepared by hot melt extrusion (HME) process using commonly used HME polymers. Solid dispersions of compound X were prepared using polyvinyl pyrrolidone co-vinyl acetate 64 (PVP VA64), Soluplus, and hypromellose acetate succinate (HPMCAS-LF) polymers in 1:2 ratio by HME through 18 mm extruder. A mixture design was employed to study effect of type of polymer, filler (microcrystalline cellulose (MCC), lactose, and dicalcium phosphate anhydrous (DCPA)), and disintegrant (Crospovidone, croscarmellose sodium, and sodium starch glycolate (SSG)) as well as level of extrudates, filler, and disintegrant on tablet properties such as disintegration time (DT), tensile strength (TS), compactibility, and dissolution. Higher extrudate level resulted in longer DT and lower TS so 60-70% was the maximum amount of acceptable extrudate level in tablets. Fast disintegration was achieved with HPMCAS-containing tablets, whereas Soluplus- and PVP VA64-containing tablets had higher TS. Crospovidone and croscarmellose sodium were more suitable disintegrant than SSG to achieve short DT, and MCC was a suitable filler to prepare tablets with acceptable TS for each studied HME polymer. The influence of extragranular components on dissolution from tablets should be carefully evaluated while finalizing tablet composition, as it varies for each HME polymer. The developed statistical models identified suitable level of fillers and disintegrants for each studied HME polymer to achieve tablets with rapid DT (<15 min) and acceptable TS (≥1 MPa at 10-15% tablet porosity), and their predictivity was confirmed by conducting internal and external validation studies.

Topics: Carboxymethylcellulose Sodium; Cellulose; Chemistry, Pharmaceutical; Drug Compounding; Excipients; Lactose; Methylcellulose; Phthalic Acids; Polyethylene Glycols; Polymers; Polyvinyls; Povidone; Pyrrolidines; Solubility; Starch; Tablets; Tensile Strength; Vinyl Compounds

Amorphous solid dispersions (ASDs) have been extensively exploited as a strategy for improving the dissolution performance of poorly water-soluble drugs. However, factors underpinning the observed dissolution profiles are not clearly understood, and the choice of polymeric carriers is largely empirical. In the current study, the dissolution performance of a high drug loading ASD containing the poorly water-soluble, anti-inflammatory agent, celecoxib, was optimized by using binary polymers combinations. Polyacrylic acid (PAA), a highly water-soluble polymer, was used to substantially increase the dissolution rate of the drug, while hydroxypropyl methyl cellulose (HPMC) or HPMC acetate succinate (HPMCAS) were added to stabilize the solid amorphous matrix against crystallization upon hydration, as well as to maintain supersaturation. Quantitative measurements of the impact of the polymers on the solution nucleation and growth rates of celecoxib revealed that, while the cellulose derivatives are effective nucleation inhibitors, it is more difficult to completely prevent crystal growth in solutions containing seed crystals, in particular at high supersaturations. Therefore, it is critical to prevent the formation of crystals in the dissolving matrix during dissolution. By using certain ratios of HPMC and PAA, both rapid release as well as crystallization inhibition could be achieved, even at high drug loadings. Utilizing combinations of polymers may therefore be useful to tailor release profiles while providing optimized crystallization inhibition.

Topics: Acrylic Resins; Celecoxib; Chemistry, Pharmaceutical; Drug Carriers; Drug Compounding; Drug Stability; Hypromellose Derivatives; Methylcellulose; Polymers; Solubility

Excipients are essential for solubility enhancing formulations. Hence it is important to understand how additives impact key solution properties, particularly when supersaturated solutions are generated by dissolution of the solubility enhancing formulation. Herein, the impact of different concentrations of dissolved polymers on the thermodynamic and kinetic properties of supersaturated solutions of danazol were investigated.. A variety of experimental techniques was used, including nanoparticle tracking analysis, fluorescence and ultraviolet spectroscopy and flux measurements to characterize the solution phase behavior.. Neither the crystalline nor amorphous solubility of danazol was impacted by common amorphous solid dispersion polymers, polyvinylpyrrolidone, hydroxypropylmethyl cellulose (HPMC) or HPMC-acetate succinate. Consequently, the maximum membrane transport rate was limited only by the amorphous solubility, and not by the presence of the polymers. The polymers were able to inhibit crystallization to some extent at concentrations as low as 1 μg/mL, with the maximum effectiveness being reached at 10 μg/mL. Aqueous danazol solutions formed a drug-rich phase with a mean size of 250 nm when the concentration exceeded the amorphous solubility, and the polymers modified the surface properties of this drug-rich phase.. The phase behavior of supersaturated solutions is complex and the kinetics of phase transformations can be substantially modified by polymeric additives present at low concentrations. However, fortunately, these additives do not appear to impact the bulk thermodynamic properties of the solution, thus enabling supersaturated solutions, which provide enhanced membrane transport relative to saturated solutions to be generated.

Topics: Crystallization; Danazol; Estrogen Antagonists; Excipients; Hypromellose Derivatives; Kinetics; Methylcellulose; Particle Size; Phase Transition; Povidone; Solubility; Solutions

Solubility parameters of HPMCAS have not yet been investigated intensively. On this account, total and three-dimensional solubility parameters of HPMCAS were determined by using different experimental as well as computational methods. In addition, solubility properties of HPMCAS in a huge number of solvents were tested and a Teas plot for HPMCAS was created. The total solubility parameter of about 24 MPa(0.5) was confirmed by various procedures and compared with values of plasticizers. Twenty common pharmaceutical plasticizers were evaluated in terms of their suitability for supporting film formation of HPMCAS under dry coating conditions. Therefore, glass transition temperatures of mixtures of polymer and plasticizers were inspected and film formation of potential ones was further investigated in dry coating of pellets. Contact angles of plasticizers on HPMCAS were determined in order to give a hint of achievable coating efficiencies in dry coating, but none was found to spread on HPMCAS. A few common substances, e.g. dimethyl phthalate, glycerol monocaprylate, and polyethylene glycol 400, enabled plasticization of HPMCAS; however, only triethyl citrate and triacetin were found to be suitable for use in dry coating. Addition of acetylated monoglycerides to triacetin increased coating efficiency, which was likewise previously demonstrated for triethyl citrate.

Topics: Drug Stability; Excipients; Methylcellulose; Monoglycerides; Plasticizers; Polyethylene Glycols; Polymers; Solubility; Transition Temperature; Triacetin

Amorphous solid dispersion formulations have been widely used to enhance bioavailability of poorly soluble drugs. In these formulations, polymer is included to physically stabilize the amorphous drug by dispersing it in the polymeric carrier and thus forming a solid solution. The polymer can also maintain supersaturation and promote speciation during dissolution, thus enabling better absorption as compared to crystalline drug substance. In this paper, we report the use of hot melt extrusion (HME) to develop amorphous formulations of a poorly soluble compound (FaSSIF solubility=1μg/mL). The poor solubility of the compound and high dose (300mg) necessitated the use of amorphous formulation to achieve adequate bioperformance. The effect of using three different polymers (HPMCAS-HF, HPMCAS-LF and copovidone), on the dissolution, physical stability, and bioperformance of the formulations was demonstrated. In this particular case, HPMCAS-HF containing HME provided the highest bioavailability and also had better physical stability as compared to extrudates using HPMCAS-LF and copovidone. The data demonstrated that the polymer type can have significant impact on the formulation bioperformance and physical stability. Thus a thorough understanding of the polymer choice is imperative when designing an amorphous solid dispersion formulation, such that the formulation provides robust bioperformance and has adequate shelf life.

Topics: Animals; Biological Availability; Chemistry, Pharmaceutical; Dogs; Drug Carriers; Drug Compounding; Drug Stability; Male; Methylcellulose; Pharmaceutical Preparations; Polymers; Pyrrolidines; Solubility; Vinyl Compounds; Water

Amorphous solid dispersions (ASDs) formulated with acid-insoluble (enteric) polymers form suspensions in acidic media where the polymer is largely insoluble. However, a small amount of drug can dissolve and a supersaturated solution may be generated. The goal of this study was to gain insight into the leaching mechanisms of both drug and polymer from the suspended particles, studying the impact of solution additives such as surfactants.. ASDs were prepared by spray drying lopinavir (LPV) with an enteric polymer, either hydroxypropylmethylcellulose acetate succinate (HPMCAS) or hydroxypropylmethylcellulose phthalate (HPMCP). Four surfactants and a suspending agent were added to the liquid media to evaluate the effect of these excipients on leaching. pH 3 and pH 5 buffers were used to investigate the effect of pH.. The extent of drug leaching from the amorphous formulation was proportional to the crystalline solubility of the drug in the same medium. All surfactants promoted solubilization of LPV with the exception of poloxamer and sodium dodecyl sulfate-HPMCP combinations. A small amount of polymer ionization significantly enhanced LPV leaching in solutions containing an ionic surfactant.. The mechanism of enhanced leaching appeared to be solubilization, with the apparent supersaturation remaining the same for systems containing the same polymer.

Topics: Chemistry, Pharmaceutical; Crystallization; Excipients; Hydrogen-Ion Concentration; Lopinavir; Methylcellulose; Polymers; Sodium Dodecyl Sulfate; Solubility; Solutions; Surface-Active Agents

Previously, we introduced a one-step nano-extrusion (NANEX) process for transferring aqueous nano-suspensions into solid formulations directly in the liquid phase. Nano-suspensions were fed into molten polymers via a side-feeding device and excess water was eliminated via devolatilization. However, the drug content in nano-suspensions is restricted to 30 % (w/w), and obtaining sufficiently high drug loadings in the final formulation requires the processing of high water amounts and thus a fundamental process understanding. To this end, we investigated four polymers with different physicochemical characteristics (Kollidon(®) VA64, Eudragit(®) E PO, HPMCAS and PEG 20000) in terms of their maximum water uptake/removal capacity. Process parameters as throughput and screw speed were adapted and their effect on the mean residence time and filling degree was studied. Additionally, one-dimensional discretization modeling was performed to examine the complex interactions between the screw geometry and the process parameters during water addition/removal. It was established that polymers with a certain water miscibility/solubility can be manufactured via NANEX. Long residence times of the molten polymer in the extruder and low filling degrees in the degassing zone favored the addition/removal of significant amounts of water. The residual moisture content in the final extrudates was comparable to that of extrudates manufactured without water.

Topics: Chemistry, Pharmaceutical; Drug Compounding; Methylcellulose; Methylmethacrylates; Nanoparticles; Polyethylene Glycols; Polymers; Pyrrolidines; Suspensions; Vinyl Compounds; Water

Glucagon-like peptide-1 (GLP-1), an incretin hormone, is used for type 2 diabetes mellitus (T2DM) treatment because of its ability to stimulate insulin secretion and release in a glucose-dependent manner. Despite of its potent insulinotropic effect, oral GLP-1 delivery is greatly limited by its instability in the gastrointestinal tract, poor absorption efficiency and rapid degradation by dipeptidylpeptidase-4 (DPP4) enzyme leading to a short half-life (~2min). Thus, a multistage dual-drug delivery nanosystem was developed to deliver GLP-1 and DPP4 inhibitor simultaneously. The system comprised of chitosan-modified porous silicon (CSUn) nanoparticles, which were coated by an enteric polymer, hydroxypropylmethylcellulose acetate succinate MF, using aerosol flow reactor technology. A non-obese T2DM rat model induced by co-administration of nicotinamide and streptozotocin was used to evaluate the in vivo efficacy of the nanosystem. The oral administration of H-CSUn nanoparticles resulted in 32% reduction in blood glucose levels and ~6.0-fold enhancement in pancreatic insulin content, as compared to the GLP-1+DPP4 inhibitor solution. Overall, these results present a promising system for oral co-delivery of GLP-1 and DPP4 inhibitor that could be further evaluated in a chronic diabetic study.

Topics: Administration, Oral; Animals; Blood Glucose; Chitosan; Diabetes Mellitus, Experimental; Diabetes Mellitus, Type 2; Dipeptidyl-Peptidase IV Inhibitors; Drug Therapy, Combination; Glucagon-Like Peptide 1; Intestine, Small; Methylcellulose; Nanocomposites; Nanoparticles; Rats, Wistar; Silicon

This study investigates 3 amorphous technologies to improve the dissolution rate and oral bioavailability of flubendazole (FLU). The selected approaches are (1) a standard spray-dried dispersion with hydroxypropylmethylcellulose (HPMC) E5 or polyvinylpyrrolidone-vinyl acetate 64, both with Vitamin E d-α-tocopheryl polyethylene glycol succinate; (2) a modified process spray-dried dispersion (MPSDD) with either HPMC E3 or hydroxypropylmethylcellulose acetate succinate (HPMCAS-M); and (3) confining FLU in ordered mesoporous silica (OMS). The physicochemical stability and in vitro release of optimized formulations were evaluated following 2 weeks of open conditions at 25°C/60% relative humidity (RH) and 40°C/75% RH. All formulations remained amorphous at 25°C/60% RH. Only the MPSDD formulation containing HPMCAS-M and 3/7 (wt./wt.) FLU/OMS did not crystallize following 40°C/75% RH exposure. The OMS and MPSDD formulations contained the lowest and highest amount of hydrolyzed degradant, respectively. All formulations were dosed to rats at 20 mg/kg in suspension. One FLU/OMS formulation was also dosed as a capsule blend. Plasma concentration profiles were determined following a single dose. In vivo findings show that the OMS capsule and suspension resulted in the overall highest area under the curve and Cmax values, respectively. These results cross-evaluate various amorphous formulations and provide a link to enhanced biopharmaceutical performance.

Topics: Animals; Antinematodal Agents; Desiccation; Drug Compounding; Drug Delivery Systems; Humidity; Male; Mebendazole; Methylcellulose; Mouth Mucosa; Povidone; Rats; Rats, Sprague-Dawley; Suspensions; Vitamin E

Isothermal microcalorimetry was utilized to monitor the crystallization process of amorphous ritonavir (RTV) and its hydroxypropylmethylcellulose acetate succinate-based amorphous solid dispersion under various stressed conditions. An empirical model was developed: ln(τ)=ln(A)+EaRT-b⋅wc, where τ is the crystallization induction period, A is a pre-exponential factor, Ea is the apparent activation energy, b is the moisture sensitivity parameter, and wc is water content. To minimize the propagation of errors associated with the estimates, a nonlinear approach was used to calculate mean estimates and confidence intervals. The physical stability of neat amorphous RTV and RTV in hydroxypropylmethylcellulose acetate succinate solid dispersions was found to be mainly governed by the nucleation kinetic process. The impact of polymers and moisture on the crystallization process can be quantitatively described by Ea and b in this Arrhenius-type model. The good agreement between the measured values under some less stressful test conditions and those predicted, reflected by the slope and R(2) of the correlation plot of these 2 sets of data on a natural logarithm scale, indicates its predictability of long-term physical stability of amorphous RTV in solid dispersions. To further improve the model, more understanding of the impact of temperature and moisture on the amorphous physical stability and fundamentals regarding nucleation and crystallization is needed.

Topics: Algorithms; Anti-HIV Agents; Calorimetry; Chemistry, Pharmaceutical; Crystallization; Drug Compounding; Drug Stability; Humidity; Kinetics; Methylcellulose; Models, Theoretical; Predictive Value of Tests; Ritonavir; Temperature

Dielectric spectroscopy was used to characterize the structural relaxation in pharmaceutical dispersions containing nifedipine (NIF) and either poly(vinyl) pyrrolidone (PVP) or hydroxypropyl methylcellulose acetate succinate (HPMCAS). The shape of the dielectric response (permittivity versus log time) curve was observed to be independent of temperature. Thus, for the pure NIF as well as the dispersions, the validity of the time-temperature superposition principle was established. Furthermore, though the shape of the full dielectric response varied with polymer concentration, the regime related to the α- or structural relaxation was found to superimpose for the dispersions, though not with the response of the NIF itself. Hence, there is a limited time-temperature-concentration superposition for these systems as well. Therefore, in this polymer concentration range, calculation of long relaxation times in these glass-forming systems becomes possible. We found that strong drug-polymer hydrogen bonding interactions improved the physical stability (i.e., delayed crystallization) by reducing the molecular mobility. The strength of hydrogen bonding, structural relaxation time, and crystallization followed the order: NIF-PV P>NIF-HPMCAS>NIF. With an increase in polymer concentration, the relaxation times were longer indicating a decrease in molecular mobility. The temperature dependence of relaxation time, in other words fragility, was independent of polymer concentration. This is the first application of the superposition principle to characterize structural relaxation in glassy pharmaceutical dispersions.

Topics: Crystallization; Drug Stability; Glass; Hydrogen Bonding; Methylcellulose; Nifedipine; Polymers; Povidone; Temperature

The aim of this study was to identify an adequate formulation for a poorly soluble lead molecule (BI-A) that would achieve sufficiently high plasma concentrations after oral administration in dogs to enable a robust cardiovascular safety pharmacology assessment in telemetry-instrumented conscious dogs during lead optimization in drug discovery. A spray-dried dispersion of BI-A (BI-A-SDD) containing a 1:2 ratio of BI-A and hydroxypropyl methylcellulose acetate succinate-LF was prepared using a Büchi spray dryer B-90 (B-90). Physical form characterization, an in vitro dissolution test and a preliminary pharmacokinetic (PK) study following oral administration of BI-A-SDD were performed. Thereafter, effects on cardiovascular parameters in conscious, chronically-instrumented dogs were investigated for 24h after a single oral dose (5, 10, and 50mg/kg) using a modified Latin square cross-over study design. The BI-A-SDD powder was confirmed to be amorphous and was stable as an aqueous suspension for at least 4h. The BI-A-SDD suspension provided a greater rate and extent of dissolution than the crystalline BI-A suspension and the supersaturation was maintained for at least 4h. In PK studies the Cmax of the BI-A-SDD formulation (25.4μM; 77-fold the projected efficacious Cmax of 0.33μM) was 7.5-fold higher than the Cmax observed using oral administration of a 10% hydroxypropyl-β-cyclodextrin formulation at 100mg/kg in dogs (3.4μM). In conscious, chronically-instrumented dogs, the doses tested and plasma concentrations achieved were sufficient to enable a robust safety pharmacology evaluation. Multiple off-target hemodynamic effects were detected including acute elevations in aortic blood pressure (up to 22% elevation in systolic and diastolic blood pressure) and tachycardia (68% elevation in heart rate), results that were confirmed in other in vivo models. These results led to a deprioritization of BI-A. The study demonstrated that a spray-dried dispersion, prepared using the B-90 in drug discovery, enhanced the oral exposure of a poorly water-soluble molecule, BI-A, and thereby enabled its evaluation in safety pharmacology studies that ultimately resulted in deprioritization of BI-A from a pool of lead compounds.

Topics: Administration, Oral; Animals; Dogs; Dose-Response Relationship, Drug; Drug Compounding; Drug Evaluation, Preclinical; Drug Liberation; Female; Hemodynamics; Male; Methylcellulose; Models, Animal; Particle Size; Powders; Remote Sensing Technology; Solubility; Suspensions

Stabilization of amorphous formulations via mesoporous silica has gained considerable attention for oral delivery of poorly soluble drugs. The release of the drug from the silica is expected to generate supersaturation which is often associated with subsequent precipitation. The aim of the study was hence to develop a novel supersaturable amorphous formulation through the co-loading of a BCS class II drug Celecoxib (CXB) with a precipitation inhibitor hydroxypropyl methylcellulose acetate succinate (HPMCAS) onto the silica. The addition of HPMCAS did not hamper the adsorption but on the contrary promoted the complete solid state conversion of the drug as proved by DSC analysis. In an in vitro pH shift assay, the CXB-HPMCAS co-loaded silica achieved a 5-fold solubility increase over the crystalline CXB and over the CXB-loaded silica blended with HPMCAS which did not show any enhancement. The drug co-loaded silica was then suspended in an aqueous vehicle facilitating the dosing to animals. The CXB-HPMCAS co-loaded silica suspension achieved 15-fold solubility increase in vitro over the crystalline counterpart which translated in 1.35-fold Cmax increase in vivo after oral dosing in rats. This approach represents a novel formulation strategy to maximize in vivo exposure of poorly soluble drugs critical for discovery studies.

Topics: Administration, Oral; Animals; Biological Availability; Celecoxib; Drug Compounding; Drug Liberation; Male; Methylcellulose; Rats; Silicon Dioxide; Solubility

Drug absorption into the body is known to be greatly affected by the solubility of the drug itself. The active pharmaceutical ingredient efonidipine hydrochloride ethanolate (NZ-105) is a novel 1,4-dihydropyridine calcium antagonist that has a very low solubility in water. It is classified as a poorly soluble drug, and improvements in its solubility and higher bioavailability with oral administration are needed. In this study, employing microwave technology as a new means to improve solubility, we established a method for preparing solid dispersions using hydroxypropyl methylcellulose acetate succinate as a polymeric carrier and urea as a third component. This effective method has a treatment time of several minutes (simple) and does not require the use of organic solvents (low environmental impact). The third component, urea, acts to lower the melting point of NZ-105, which promotes amorphization. This greatly improves the solubility compared with the microwave-treated product of NZ-105/HPMC-AS binary system. The solid dispersion prepared with this method, in addition to evaluation in vitro, was tested in vivo using beagle dogs and shown to be effective from the eightfold improvement in absorption compared with NZ-105 alone based on the area under the curve.

Topics: Animals; Area Under Curve; Calorimetry, Differential Scanning; Dihydropyridines; Dogs; Drug Carriers; Hot Temperature; Magnetic Resonance Spectroscopy; Male; Methylcellulose; Microwaves; Nitrophenols; Organic Chemicals; Organophosphorus Compounds; Solubility; Solvents; Urea; X-Ray Diffraction

The purpose of this study was to investigate the feasibility of using a fluorescence-based technique to evaluate drug-polymer miscibility and to probe the correlation between miscibility and physical stability of amorphous solid dispersions (ASDs). Indomethacin-hydroxypropyl methylcellulose (IDM-HPMC), indomethacin-hydroxypropyl methylcellulose acetate succinate, and indomethacin-polyvinylpyrrolidone (IDM-PVP) were used as model systems. The miscibility of the IDM-polymer systems was evaluated by fluorescence spectroscopy, fluorescence imaging, differential scanning calorimetry (DSC), and infrared (IR) spectroscopy. The physical stability of IDM-polymer ASDs stored at 40 °C was evaluated using fluorescence imaging and X-ray diffraction (XRD). The experimentally determined miscibility limit of IDM with the polymers was 50-60%, 20-30%, and 70-80% drug loading for HPMC, HPMCAS, and PVP, respectively. The X-ray results showed that for IDM-HPMC ASDs, samples with a drug loading of less than 50% were maintained in amorphous form during the study period, while samples with drug loadings higher than 50% crystallized within 15 days. For IDM-HPMCAS ASDs, samples with drug loading less than 30% remained amorphous, while samples with drug loadings higher than 30% crystallized within 10 days. IDM-PVP ASDs were found to be resistant to crystallization for all compositions. Thus, a good correlation was observed between phase separation and reduced physical stability, suggesting that miscibility is indeed an important ASDs characteristic. In addition, fluorescence-based techniques show promise in the evaluation of drug-polymer miscibility.

Topics: Calorimetry, Differential Scanning; Fluorescence; Hypromellose Derivatives; Indomethacin; Methylcellulose; Microscopy, Fluorescence; Polymers; Povidone; Spectrophotometry, Infrared; X-Ray Diffraction

We investigated the influence of drug-polymer hydrogen bonding interactions on molecular mobility and the physical stability in solid dispersions of nifedipine with each of the polymers polyvinylpyrrolidone (PVP), hydroxypropylmethyl cellulose (HPMCAS), and poly(acrylic acid) (PAA). The drug-polymer interactions were monitored by FT-IR spectroscopy, the molecular mobility was characterized using broadband dielectric spectroscopy, and the crystallization kinetics was evaluated by powder X-ray diffractometry. The strength of drug-polymer hydrogen bonding, the structural relaxation time, and the crystallization kinetics were rank ordered as PVP > HPMCAS > PAA. At a fixed polymer concentration, the fraction of the drug bonded to the polymer was the highest with PVP. Addition of 20% w/w polymer resulted in ∼65-fold increase in the relaxation time in the PVP dispersion and only ∼5-fold increase in HPMCAS dispersion. In the PAA dispersions, there was no evidence of drug-polymer interactions and the polymer addition did not influence the relaxation time. Thus, the strongest drug-polymer hydrogen bonding interactions in PVP solid dispersions translated to the longest structural relaxation times and the highest resistance to drug crystallization.

Topics: Acrylic Resins; Crystallization; Hydrogen; Hydrogen Bonding; Kinetics; Methylcellulose; Nifedipine; Polymers; Solvents; Spectroscopy, Fourier Transform Infrared; Temperature; X-Ray Diffraction

The Pharmaceutical industry is increasingly utilizing amorphous technologies to overcome solubility challenges. A common approach is the use of drug in polymer dispersions to prevent recrystallization of the amorphous drug. Understanding the factors affecting chemical and physical degradation of the drug within these complex systems, e.g., temperature and relative humidity, is an important step in the selection of a lead formulation, and development of appropriate packaging/storage control strategies. The Arrhenius equation has been used as the basis of a number of models to predict the chemical stability of formulated product. In this work, we investigate the increase in chemical degradation seen for one particular spray dried dispersion formulation using hydroxypropyl methylcellulose acetate succinate (HPMC-AS). Samples, prepared using polymers with different substitution levels, were placed on storage for 6 months under a range of different temperature and relative humidity conditions and the degradant level monitored using high-performance liquid chromatography (HPLC). While the data clearly illustrates the impact of temperature and relative humidity on the degradant levels detected, it also highlighted that these terms do not account for all the variability in the data. An extension of the Arrhenius equation to include a term for the polymer chemistry, specifically the degree of succinoyl substitution on the polymer backbone, was shown to improve the fit of the model to the data.

Topics: Algorithms; Desiccation; Drug Compounding; Drug Stability; Excipients; Humidity; Methylcellulose; Models, Theoretical; Oxadiazoles; Succinic Acid; Sulfonamides; Temperature

The aim of this study was to evaluate a novel combination of Soluplus® and hypromellose acetate succinate (HPMCAS-HF) polymers for solubility enhancement as well as enhanced physicochemical stability of the produced amorphous solid dispersions. This was accomplished by converting the poorly water-soluble crystalline form of carbamazepine into a more soluble amorphous form within the polymeric blends. Carbamazepine (CBZ), a Biopharmaceutics Classification System class II active pharmaceutical ingredient (API) with multiple polymorphs, was utilized as a model drug. Hot-melt extrusion (HME) processing was used to prepare solid dispersions utilizing blends of polymers. Drug loading showed a significant effect on the dissolution rate of CBZ in all of the tested ratios of Soluplus® and HPMCAS-HF. CBZ was completely miscible in the polymeric blends of Soluplus® and HPMCAS-HF up to 40% drug loading. The extrudates were characterized by differential scanning calorimetry (DSC), X-ray diffraction (XRD), Fourier transform infrared (FTIR) spectroscopy and dissolution studies. DSC and XRD data confirmed the formation of amorphous solid dispersions of CBZ in the polymeric blends of Soluplus® and HPMCAS-HF. Drug loading and release of CBZ was increased with Soluplus® (when used as the primary matrix polymer) when formulations contained Soluplus® with 7-21% (w/w) HPMCAS-HF. In addition, this blend of polymers was found to be physically and chemically stable at 40°C, 75% RH over 12 months without any dissolution rate changes.

Topics: Calorimetry, Differential Scanning; Carbamazepine; Chromatography, High Pressure Liquid; Hot Temperature; Methylcellulose; Polyethylene Glycols; Polyvinyls; Solubility; Spectroscopy, Fourier Transform Infrared; Thermogravimetry; X-Ray Diffraction

This study investigated the presence of specific drug-excipient interactions in amorphous solid dispersions of lapatinib (LB) and four commonly used pharmaceutical polymers, including Soluplus, polyvinylpyrrolidone vinyl acetate (PVPVA), hydroxypropylmethylcellulose acetate succinate (HPMCAS), and hydroxypropylmethylcellulose phthalate (HPMCP). Based on predicted pKa differences, LB was hypothesized to exhibit a specific ionic interaction with HPMCP, and possibly with HPMCAS, while Soluplus and PVPVA were studied as controls without ionizable functionality. Thermal studies showed a single glass transition (Tg) for each dispersion, in close agreement with predicted values for Soluplus, PVPVA, and HPMCAS systems. However, the Tg values of LB-HPMCP solid dispersions were markedly higher than predicted values, indicating a strong intermolecular interaction between LB and HPMCP. (15)N solid-state NMR provided direct spectroscopic evidence for protonation of LB (i.e., salt formation) within the HPMCP solid dispersions. (1)H T1 and (1)H T1ρ relaxation studies of the dispersions supported the ionic interaction hypothesis, and indicated multiple phases in the cases of excess drug or polymer. In addition, the dissolution and stability behavior of each system was examined. Both acidic polymers, HPMCAS and HPMCP, effectively inhibited the crystallization of LB on accelerated stability, likely owing to beneficial strong intermolecular hydrogen and/or specific ionic bonds with the acidic polymers. Soluplus and PVPVA showed poor physical properties on stability and subsequently poor crystallization inhibition.

Topics: Biological Availability; Biopharmaceutics; Crystallization; Drug Carriers; Drug Stability; Excipients; Humans; Hydrogen Bonding; Lapatinib; Magnetic Resonance Spectroscopy; Methylcellulose; Polyethylene Glycols; Polyvinyls; Povidone; Quinazolines; Solubility

Using phase diagrams derived from Flory-Huggins theory, we defined the thermodynamic state of amorphous felodipine within three different polymeric carriers. Variation in the solubility and miscibility of felodipine within different polymeric materials (using F-H theory) has been identified and used to select the most suitable polymeric carriers for the production of amorphous drug-polymer solid dispersions. With this information, amorphous felodipine solid dispersions were manufactured using three different polymeric materials (HPMCAS-HF, Soluplus, and PVPK15) at predefined drug loadings, and the crystal growth rates of felodipine from these solid dispersions were investigated. Crystallization of amorphous felodipine was studied using Raman spectral imaging and polarized light microscopy. Using this data, we examined the correlation among several characteristics of solid dispersions to the crystal growth rate of felodipine. An exponential relationship was found to exist between drug loading and crystal growth rate. Moreover, crystal growth within all selected amorphous drug-polymer solid dispersion systems were viscosity dependent (η(-ξ)). The exponent, ξ, was estimated to be 1.36 at a temperature of 80 °C. Values of ξ exceeding 1 may indicate strong viscosity dependent crystal growth in the amorphous drug-polymer solid dispersion systems. We argue that the elevated exponent value (ξ > 1) is a result of drug-polymer mixing which leads to a less fragile amorphous drug-polymer solid dispersion system. All systems investigated displayed an upper critical solution temperature, and the solid-liquid boundary was always higher than the spinodal decomposition curve. Furthermore, for PVP-FD amorphous dispersions at drug loadings exceeding 0.6 volume ratio, the mechanism of phase separation within the metastable zone was found to be driven by nucleation and growth rather than liquid-liquid separation.

Topics: Chemistry, Pharmaceutical; Crystallization; Drug Carriers; Drug Compounding; Drug Delivery Systems; Drug Stability; Felodipine; Glass; Hot Temperature; Methylcellulose; Polyethylene Glycols; Polymers; Polyvinyls; Solubility; Spectrum Analysis, Raman; Thermodynamics; Viscosity

We explored the use of transmission electron microscopy (TEM) to evaluate the crystallinity of griseofulvin (GF)/hydroxypropyl methylcellulose acetate succinate (HPMCAS) solid dispersions. TEM, which provides both real-space images and electron diffraction patterns, was used to unambiguously identify GF crystals in spray dried GF. Using TEM, we were also able to detect GF crystals in a physical mixture of spray dried GF particles and spray dried HPMCAS particles with an overall crystallinity of ∼3 vol %, below the practical lower limit of detection for laboratory-scale wide-angle X-ray scattering (WAXS). Using TEM and WAXS, we did not find crystals in GF/HPMCAS solid dispersions with GF loadings of 5, 10, and 50 wt %. However, we detected GF crystals in annealed 5 wt % GF solid dispersion using TEM, whereas we did not detect crystals using in situ WAXS and modulated differential scanning calorimetry, thereby establishing the superior crystal detection sensitivity of TEM. We also performed TEM analysis of the in situ growth of GF crystals in a TEM sample of 50 wt % GF solid dispersion. Based on this study, TEM has significant potential for characterizing even small degrees of crystallinity in solid dispersions.

Topics: Biopharmaceutics; Calorimetry, Differential Scanning; Crystallization; Drug Compounding; Drug Stability; Excipients; Griseofulvin; Methylcellulose; Microscopy, Electron, Transmission; Scattering, Radiation; Solubility

The maintenance mechanism of the supersaturated state of poorly water-soluble drugs, glibenclamide (GLB) and chlorthalidone (CLT), in hydroxypropyl methylcellulose acetate succinate (HPMC-AS) solution was investigated at a molecular level. HPMC-AS suppressed drug crystallization from supersaturated drug solution and maintained high supersaturated level of drugs with small amount of HPMC-AS for 24 h. However, the dissolution of crystalline GLB into HPMC-AS solution failed to produce supersaturated concentrations, although supersaturated concentrations were achieved by adding amorphous GLB to HPMC-AS solution. HPMC-AS did not improve drug dissolution and/or solubility but efficiently inhibited drug crystallization from supersaturated drug solutions. Such an inhibiting effect led to the long-term maintenance of the amorphous state of GLB in HPMC-AS solution. NMR measurements showed that HPMC-AS suppressed the molecular mobility of CLT depending on their supersaturation level. Highly supersaturated CLT in HPMC-AS solution formed a gel-like structure with HPMC-AS in which the molecular mobility of the CLT was strongly suppressed. The gel-like structure of HPMC-AS could inhibit the reorganization from drug prenuclear aggregates to the crystal nuclei and delay the formation of drug crystals. The prolongation subsequently led to the redissolution of the aggregated drugs in aqueous solution and formed the equilibrium state at the supersaturated drug concentration in HPMC-AS solution. The equilibrium state formation of supersaturated drugs by HPMC-AS should be an essential mechanism underlying the marked drug concentration improvement.

Topics: Chemistry, Pharmaceutical; Chlorthalidone; Chromatography, High Pressure Liquid; Crystallization; Glyburide; Magnetic Resonance Spectroscopy; Methylcellulose; Models, Chemical; Pharmaceutical Preparations; Powders; Solubility; Solutions; Technology, Pharmaceutical; X-Ray Diffraction

To develop a strategy to control benzene, an ICH Q3C Class 1 impurity that may be present in spray solvents at ppm concentration, in amorphous polymer-stabilized spray-dried dispersion (SDD) products.. Risk assessments included determining the probability for benzene concentration in primary spray solvents, the physical properties of volatiles, and the potential enrichment of benzene from solution to solid. Mechanistic understanding of benzene removal was gained through a benzene-spiked fate and tolerance (F&T) study simulating worst-case spray-drying conditions and application of diffusion models for secondary drying.. The mass ratio of spray solution to solid presented the highest risk of benzene enrichment. With slow spray-drying kinetics, benzene was reduced about 700-fold. Under standard secondary-drying conditions to remove residual solvents, residual benzene was further removed. Using diffusion models, the maximum benzene concentration was approximated for SDDs dried to the in-process control (IPC) limit of primary solvents.. Two critical control points were established to eliminate any risk of residual benzene reaching patients: (1) upstream control of benzene in solvents (≤10 ppm) and (2) IPC of residual solvents in polymer-stabilized SDDs.

Topics: Acetone; Benzene; Chromatography, Gas; Desiccation; Diffusion; Drug Compounding; Drug Contamination; Excipients; Methanol; Methylcellulose; Models, Statistical; Reproducibility of Results; Risk Assessment; Solvents

A systematic identification of the degradation products of hydroxypropyl methylcellulose phthalate (HPMCP) during hot melt extrusion (HME) has been performed. A reverse phase HPLC method was developed for the extrudates of both hydroxypropyl methylcellulose acetate succinate (HPMCAS) and HPMCP polymers to quantify their thermal hydrolytic products: acetic acid (AA), succinic acid (SA) for HPMCAS and phthalic acid (PA) for HPMCP, without hydrolysing the polymers in strong alkaline solutions. The polymers were extruded in the temperature range of 160-190 °C at different screw rotation speeds and hydrolytic impurities were analysed. Investigation of extruded HPMCP showed an additional thermal degradation product, who is structural elucidation revealed to be phthalic anhydride (PAH). Moreover, two environmental analytical impurities, dimethyl phthalate and methyl benzoate formed in situ were recorded on GC-MS and their origin was found to be associated with PAH derivatization. Using the experimental data gathered during this study, a degradation mechanism for HPMCP is proposed.

Topics: Acetic Acid; Benzoates; Chromatography, High Pressure Liquid; Drug Compounding; Gas Chromatography-Mass Spectrometry; Hot Temperature; Magnetic Resonance Spectroscopy; Methylcellulose; Phthalic Acids; Phthalic Anhydrides; Spectrophotometry, Infrared; Succinic Acid; Thermogravimetry

The purpose of this study was to develop a novel fluorescence technique employing environment-sensitive fluorescent probes to study phase separation kinetics in hydrated matrices of amorphous solid dispersions (ASDs) following storage at high humidity and during dissolution. The initial miscibility of the ASDs was confirmed using infrared (IR) spectroscopy and differential scanning calorimetry (DSC). Fluorescence spectroscopy, as an independent primary technique, was used together with conventional confirmatory techniques including DSC, X-ray diffraction (XRD), fluorescence microscopy, and IR spectroscopy to study phase separation phenomena. By monitoring the emission characteristics of the environment-sensitive fluorescent probes, it was possible to successfully monitor amorphous-amorphous phase separation (AAPS) as a function of time in probucol-poly(vinylpyrrolidone) (PVP) and ritonavir-PVP ASDs after exposure to water. In contrast, a ritonavir-hydroxypropylmethylcellulose acetate succinate (HPMCAS) ASD, did not show AAPS and was used as a control to demonstrate the capability of the newly developed fluorescence method to differentiate systems that showed no phase separation following exposure to water versus those that did. The results from the fluorescence studies were in good agreement with results obtained using various other complementary techniques. Thus, fluorescence spectroscopy can be utilized as a fast and efficient tool to detect and monitor the kinetics of phase transformations in amorphous solid dispersions during hydration and will help provide mechanistic insight into the stability and dissolution behavior of amorphous solid dispersions.

Topics: Calorimetry, Differential Scanning; Kinetics; Methylcellulose; Probucol; Ritonavir; Water; X-Ray Diffraction

Multifunctional tailorable composite systems, specifically designed for oral dual-delivery of a peptide (glucagon-like peptide-1) and an enzymatic inhibitor (dipeptidyl peptidase 4 (DPP4)), were assembled through the microfluidics technique. Both drugs were coloaded into these systems for a synergistic therapeutic effect. The systems were composed of chitosan and cell-penetrating peptide modified poly(lactide-co-glycolide) and porous silicon nanoparticles as nanomatrices, further encapsulated in an enteric hydroxypropylmethylcellulose acetylsuccinate polymer. The developed multifunctional systems were pH-sensitive, inherited by the enteric polymer, enabling the release of the nanoparticles only in the simulated intestinal conditions. Moreover, the encapsulation into this polymer prevented the degradation of the nanoparticles' modifications. These nanoparticles showed strong and higher interactions with the intestinal cells in comparison with the nonmodified ones. The presence of DPP4 inhibitor enhanced the peptide permeability across intestinal cell monolayers. Overall, this is a promising platform for simultaneously delivering two drugs from a single formulation. Through this approach peptides are expected to increase their bioavailability and efficiency in vivo both by their specific release at the intestinal level and also by the reduced enzymatic activity. The use of this platform, specifically in combination of the two antidiabetic drugs, has clinical potential for the therapy of type 2 diabetes mellitus.

Topics: Caco-2 Cells; Cell Survival; Cell-Penetrating Peptides; Chitosan; Coculture Techniques; Dipeptidyl Peptidase 4; Drug Compounding; Drug Delivery Systems; Drug Liberation; Drug Synergism; Glucagon-Like Peptide 1; HT29 Cells; Humans; Hydrogen-Ion Concentration; Kinetics; Methylcellulose; Microfluidics; Nanoparticles; Permeability; Polyglactin 910; Porosity; Silicon

An increased number of amorphous formulations of poorly water soluble drugs are being introduced into the market due to their higher transient solubility and thus faster absorption and higher bioavailability. While most amorphous drug products contain a single drug substance, there is a growing trend towards co-formulating compounds in the same dosage form to improve patient compliance. The purpose of the present work was to evaluate the dissolution behavior and maximum achievable solution concentrations of amorphous solid dispersions of co-formulated ritonavir and lopinavir, and to compare the results with individual amorphous solid dispersion formulations. Dispersions of ritonavir and lopinavir were prepared in polyvinylpyrrolidone (PVP) or hydroxypropylmethylcellulose acetate succinate (HPMCAS) at a 20% (w/w) total drug loading, both alone and in combination, at three different lopinavir:ritonavir weight ratios. Amorphous films containing both drugs, but no polymer, were also prepared. The dissolution behavior of the dispersions and the amorphous films in non-sink conditions was evaluated, using ultracentrifugation to separate any colloidal material from molecularly dissolved drug. Nanoparticle tracking analysis was used to characterize colloidal material formed during the dissolution process. Results from the dissolution study revealed that, although supersaturated solutions resulted following dissolution, the maximum achievable concentration of each drug, when present in combination, was dramatically lower than when the individual dispersions were dissolved. The maximum achievable solution concentration for systems containing both drugs was found to decrease as the mole fraction of the drug in the amorphous phase decreased. The type of polymer used to formulate the dispersion also appeared to influence the dissolution behavior whereby the HPMCAS dispersions dissolved rapidly, resulting in the generation of a nanodroplets, while the PVP dispersions did not produce as many colloidal species. These results highlight the need to consider potential decreases in achievable supersaturation for formulations containing more than one amorphous compound.

Topics: Chromatography, High Pressure Liquid; Drug Combinations; Drug Liberation; Methylcellulose; Povidone; Solubility; X-Ray Diffraction

Intimate phase mixing between the drug and the polymer is considered a prerequisite to achieve good physical stability for amorphous solid dispersions. In this article, spray dried amorphous dispersions (ASDs) of AMG 517 and HPMC-as were studied by differential scanning calorimetry (DSC), solid-state NMR (SSNMR), and solution calorimetry. DSC analysis showed a weakly asymmetric (ΔTg ≈ 13.5) system with a single glass transition for blends of different compositions indicating phase mixing. The Tg-composition data was modeled using the BKCV equation to accommodate the observed negative deviation from ideality. Proton spin-lattice relaxation times in the laboratory and rotating frames ((1)H T1 and T1ρ), as measured by SSNMR, were consistent with the observation that the components of the dispersion were in intimate contact over a 10-20 nm length scale. Based on the heat of mixing calculated from solution calorimetry and the entropy of mixing calculated from the Flory-Huggins theory, the free energy of mixing was calculated. The free energy of mixing was found to be positive for all ASDs, indicating that the drug and polymer are thermodynamically predisposed to phase separation at 25 °C. This suggests that miscibility measured by DSC and SSNMR is achieved kinetically as the result of intimate mixing between drug and polymer during the spray drying process. This kinetic phase mixing is responsible for the physical stability of the ASD.

Topics: Benzothiazoles; Calorimetry, Differential Scanning; Chemistry, Pharmaceutical; Excipients; Freeze Drying; Magnetic Resonance Spectroscopy; Methylcellulose; Phase Transition; Polymers; Pyrimidines; X-Ray Diffraction

We investigated the effects of the hot-melt extrusion (HME) process on the properties of itraconazole (ITZ) amorphous solid dispersions made by thin film freezing (TFF) technology. The ITZ-HPMCAS L (1:2) TFF composition exhibited limited drug release in acidic media. HME of the ITZ-HPMCAS TFF composition with hydrophilic carriers improved the drug release rate in acidic media. The type and level of hydrophilic carrier in the composition affected the dissolution profiles of the extrudates. A design of experiments (DoE) study was conducted to elucidate those effects. Hot-melt extrusion processing variables such as extrusion temperature and screw configuration also played a critical role on the properties of the extruded compositions. A higher degree of mixing reduced the crystallinity of semicrystalline excipients and favored the drug release in the acidic media; moreover, the drug precipitation rate in the neutral pH media was reduced.

Topics: Antifungal Agents; Calorimetry, Differential Scanning; Chemistry, Pharmaceutical; Chromatography, High Pressure Liquid; Drug Carriers; Excipients; Freezing; Hot Temperature; Hydrogen-Ion Concentration; Itraconazole; Methylcellulose; Microscopy, Electron, Scanning; Solubility; X-Ray Diffraction

We prepared hydroxypropyl methylcellulose (HPMC) esters of substituted succinates and examined their performance for improving the aqueous solubility of crystalline hydrophobic drugs in spray-dried dispersions (SDDs). From one HPMC, we synthesized five HPMC esters using various monosubstituted succinic anhydrides. These HPMC esters along with a commercial HPMC acetate succinate (HPMCAS) were spray-dried from solutions with phenytoin. The SDDs with different matrices at 10 wt % loading had very similar bulk properties with a minimal amount of detectable crystalline phenytoin as revealed by scanning electron microscopy (SEM), powder X-ray diffraction (powder XRD), and differential scanning calorimetry (DSC). In solution, while the SDD with HPMCAS was very effective at achieving high levels of phenytoin supersaturation initially, it was not competent at maintaining such supersaturation due to the rapid crystallization of the dissolved phenytoin. Alternatively, SDDs with several synthesized HPMC esters of substituted succinates not only achieved rather high initial supersaturation but also maintained high concentrations for extended time (i.e., 1.5 h and longer). Such maintenance was largely ascribed to the inhibition of phenytoin nucleation. Structure-property relationships were established, and the most successful systems contained a high degree of substitution and a combination of a thioether with neighboring weak electron-withdrawing groups in the substituted succinic anhydrides. The effective maintenance of supersaturated solutions was only found in SDDs with rather low drug loadings, which indicates the significance of sufficiently high concentrations of polymer additives in the dissolution media.

Topics: Anticonvulsants; Calorimetry, Differential Scanning; Chemical Phenomena; Esters; Excipients; Freeze Drying; Hydrophobic and Hydrophilic Interactions; Methylcellulose; Microscopy, Electron, Scanning; Phenytoin; Solubility; X-Ray Diffraction

To compare the properties of solid dispersions of felodipine for oral bioavailability enhancement using two different polymers, polyvinylpyrrolidone (PVP) and hydroxypropyl methylcellulose acetate succinate (HPMCAS), by hot-melt extrusion (HME) and spray drying.. Felodipine solid dispersions were prepared by HME and spray drying techniques. PVP and HPMCAS were used as polymer matrices at different drug : polymer ratios (1 : 1, 1 : 2 and 1 : 3). Detailed characterization was performed using differential scanning calorimetry, powder X-ray diffractometry, scanning electron microscopy and in-vitro dissolution testing. Dissolution profiles were evaluated in the presence of sodium dodecyl sulphate. Stability of different solid dispersions was studied under accelerated conditions (40°C/75% RH) over 8 weeks.. Spray-dried formulations were found to release felodipine faster than melt extruded formulations for both polymer matrices. Solid dispersions containing HMPCAS exhibited higher drug release rates and better wettability than those produced with a PVP matrix. No significant differences in stability were observed except with HPMCAS at a 1 : 1 ratio, where crystallization was detected in spray-dried formulations.. Solid dispersions of felodipine produced by spray drying exhibited more rapid drug release than corresponding melt extruded formulations, although in some cases improved stability was observed for melt extruded formulations.

Topics: Biological Availability; Chemistry, Pharmaceutical; Desiccation; Drug Carriers; Drug Compounding; Drug Stability; Felodipine; Hot Temperature; Humans; Methylcellulose; Povidone; Solubility; Solutions; Wettability

The inhibitory effect on drug crystallization in aqueous solution was evaluated using various forms of hydroxypropyl methylcellulose acetate succinate (HPMCAS). HPMCAS suppressed crystallization of carbamazepine (CBZ), nifedipine (NIF), mefenamic acid, and dexamethasone. The inhibition of drug crystallization mainly derived from molecular level hydrophobic interactions between the drug and HPMCAS. HPMCAS with a lower succinoyl substituent ratio strongly suppressed drug crystallization. The inhibition of crystallization was affected by pH, with the CBZ crystallization being inhibited at a higher pH due to the hydrophilization of HPMCAS derived from succinoyl ionization. The molecular mobility of CBZ in an HPMCAS solution was evaluated by 1D-(1)H NMR and relaxation time measurements. CBZ mobility was strongly suppressed in the HPMCAS solutions where strong inhibitory effects on CBZ crystallization were observed. The mobility suppression of CBZ in the HPMCAS solution was derived from intermolecular interactions between CBZ and HPMCAS leading to an inhibition of crystallization. The effect of HPMCAS on the drug dissolution rate was evaluated using an NIF/HPMCAS solid dispersion. The dissolution rate of NIF was increased when HPMCAS with a higher succinoyl substituent ratio was used.

Topics: Chemistry, Pharmaceutical; Crystallization; Methylcellulose; Solubility

The objectives of the present work were to use blends of Eudragit L and hydroxypropyl methylcellulose acetate succinate (HPMCAS) as enteric film coatings for lansoprazole (LSP) pellets. The enteric-coated pellets were prepared with a fluid-bed coater. The influence of the blend ratio, type of plasticizer, plasticizer level, coating level, and curing conditions on gastric stability in vitro drug release and drug stability was evaluated. Furthermore, the bioavailability of the blend-coated pellets in beagle dogs was also performed. The blend-coated pellets exhibited significant improvement of gastric stability and drug stability compared to the pure polymer-coated pellets. Moreover, the AUC values of blend-coated pellets were greater than that of the pure polymer-coated pellets. It was concluded that the using blends of Eudragit L and HPMCAS as enteric film coatings for LSP pellets improved the drug stability and oral bioavailability.

Topics: Administration, Oral; Animals; Area Under Curve; Biological Availability; Chemistry, Pharmaceutical; Dogs; Drug Stability; Lansoprazole; Male; Methylcellulose; Plasticizers; Polymethacrylic Acids; Proton Pump Inhibitors; Solubility; Tablets, Enteric-Coated; Technology, Pharmaceutical

We have performed all-atom molecular dynamics simulations of aqueous solutions of model oligomers of hydroxypropyl methylcellulose (HPMC) and hydroxypropyl methylcellulose acetate succinate (HPMCAS) excipients interacting with a representative poorly soluble active pharmaceutical ingredient (API), phenytoin. Simulations reveal formation of excipient-API complexes for some of the oligomers, which results in a reduction of API aggregation. API aggregation and diffusivity decreased with an increase in excipient content. Excipients form a "gel-like" phase spanning the simulation box beyond ∼10 wt %; API diffusivity within this gel phase is much smaller than API diffusivity without excipient, and decreases exponentially, by 5 orders of magnitude, with increased polymer concentration. Substantial differences are observed with variations in methyl, hydroxypropyl, acetate, and succinate substitution levels in the model oligomers and with the deprotonation state of succinate groups, with strongest interactions with hydrophobic phenytoin observed in the case of acetate substitution. These are used to develop quantitative measures of excipient-API interactions and excipient efficiency in the inhibition of API aggregation. We also find that for model oligomers based on Methocel E (manufactured by Dow Pharma & Food Solutions) chemistry, oligomers of length 10 monomers and simulation boxes of size 7 nm give results similar to those for longer oligomers and bigger boxes. The quantitative measures developed in this study are expected to prove useful as computational screening tools in excipient design.

Topics: Excipients; Methylcellulose; Molecular Dynamics Simulation; Polymers

Many upcoming drug candidates are pH-dependent poorly soluble weak bases in the pH range of the gastrointestinal tract. This often leads to a high in vivo variability and bioavailability issues. Aiming to overcome these limitations, the design of solid dispersions for site specific dissolution improvement or maintenance of a potent supersaturation over the entire gastro-intestinal pH-range, is proposed to assure a reliable drug therapy. Solid dispersions containing different ratios of Dipyridamole (DPD) or Griseofulvin (GRI) and the enteric polymer hydroxypropylmethylcellulose-acetate succinate (HPMC-AS) and the water soluble low-viscosity hydroxypropylcellulose (HPC-SSL) were prepared by hot melt extrusion (HME). The solid dispersions were evaluated for their solid state, dissolution characteristics applying a three pH-step dissolution method following an acidic to neutral pH transition and stability. The use of HPMC-AS in binary mixtures with DPD and GRI facilitated increased solubility and supersaturation at pH-controlled release of the preserved amorphous state of the dispersed drug, which even inverted the pH-dependent solubility profile of the weakly basic model drug (Dipyridamole). I.e. a potent site specific delivery system was created. With ternary solid dispersions of API, HPMC-AS and HPC-SSL, tailored release profiles with superior supersaturation over the applied pH-range could be obtained. At the same time, binary and ternary mixtures showed favorable stability properties at a temperature difference between glass transition temperature and the applied storage temperature of down to 16°C.

Topics: Cellulose; Chemistry, Pharmaceutical; Delayed-Action Preparations; Dipyridamole; Drug Carriers; Drug Stability; Griseofulvin; Humans; Hydrogen-Ion Concentration; Kinetics; Methylcellulose; Solubility; Technology, Pharmaceutical; Transition Temperature; Viscosity

Molecular models for HPMCAS polymer have been developed for molecular dynamics (MD) simulation that attempt to mimic the complex substitution patterns in HPMCAS observed experimentally. These molecular models were utilized to create amorphous HPMCAS solids by cooling of the polymeric melts at different water contents to explore the influence of water on molecular mobility, which plays a critical role in stability and drug release from HPMCAS-based solid matrices. The densities found for the simulated amorphous HPMCAS were 1.295, 1.287, and 1.276 g/cm(3) at 0.7, 5.7, and 13.2% w/w water, indicating swelling of the polymer with increasing water content. These densities compare favorably with the experimental density of 1.285 g/cm(3) for commercial HPMCAS-(AQOAT AS-MF) supporting the present HPMCAS models as a realistic representation of amorphous HPMCAS solids. Water molecules were observed to be mostly isolated from each other at a low water content (0.7% w/w), while clusters or strands of water were pervasive and broadly distributed in size at 13.2% w/w water. The average number of first-shell water molecules (n(w)) increased from 0.17 to 3.5, though the latter is still far below that (8.9) expected for the onset of a separate water phase. Increasing water content from 0.7 to 13.2% w/w was found to reduce the T(g) by ~81 K, similar to experimental observations. Plasticization with increasing water content resulted in increasing polymer mobility and water diffusivity. From 0.7 to 13.2% w/w water, the apparent water diffusivity increased from 1.1 × 10(-9) to 7.0 × 10(-8) cm(2)/s, though non-Einsteinian behavior persisted at all water contents explored. This and the water trajectories in the polymers suggest that water diffusion at 0.7% w/w water follows a "hopping" mechanism. At a higher water content (13.2% w/w) water diffusion follows dual diffusive processes: (1) fast water motions within water clusters; and (2) slower diffusion through the more rigid polymer matrix.

Topics: Diffusion; Drug Stability; Hydrogen Bonding; Methylcellulose; Models, Molecular; Molecular Dynamics Simulation; Polymers; Solubility; Water

The effects of drug-crystallization inhibitor in bile acid/lipid micelles solution on drug permeation was evaluated during the drug crystallization process. Hydroxypropyl methylcellulose acetate succinate (HPMC-AS) was used as a drug-crystallization inhibitor, which efficiently suppressed dexamethasone (DEX) crystallization in a gastrointestinal fluid model containing sodium taurocholate (NaTC) and egg-phosphatidylcholine (egg-PC). Changes of molecular state of supersaturated DEX during the DEX crystallization process was monitored in real time using proton nuclear magnetic resonance (1H NMR). It revealed that DEX distribution to bulk water and micellar phases formed by NaTC and egg-PC was not changed during the DEX crystallization process even in the presence of HPMC-AS. DEX permeation during DEX crystallization was evaluated using dissolution/permeability system. The combination of crystallization inhibition by HPMC-AS and micellar encapsulation by NaTC and egg-PC led to considerably higher DEX concentrations and improvement of DEX permeation at the beginning of the DEX crystallization process. Crystallization inhibition by HPMC-AS can efficiently work even in the micellar solution, where NaTC/egg-PC micelles encapsulates some DEX. It was concluded that a crystallization inhibitor contributed to improvement of permeation of a poorly water-soluble drug in gastrointestinal fluid.

Topics: Caco-2 Cells; Crystallization; Dexamethasone; Humans; Intestinal Secretions; Methylcellulose; Permeability; Solutions

The establishment of physiologically relevant in vitro-in vivo correlations (IV-IVCs) is key for any biorelevant dissolution test. Historically, bicarbonate buffers have produced better correlations than compendial phosphate buffered media, though such tests are usually performed at a constant pH experiment, overlooking the notion that the pH of the luminal fluids is variable and fluctuating. In this work, we have devised a dynamic dissolution test method employing a physiological bicarbonate buffer under pH conditions of the proximal gut in order to assess the dissolution behaviour of various enteric polymer-coated (gastro-resistant) prednisolone tablets. The pH of the media is modulated and controlled by an Auto pH System™ which exploits the physiological equilibria between [H2CO3] and [HCO3(-)], to match it to the aboral change in pH with transit of the dosage form through the proximal small intestine (from pH 5.6 up to 6.8). The lag time values for an accelerated release and standard EUDRAGIT(®) L30D-55 coated formulation (25 min and 60 min, respectively) were close to the previously reported initial tablet disintegration time data obtained in-vivo by γ-scintigraphy (28 min and 66 min, respectively). Dissolution of alternative delayed release coated products was also better discriminated in the dynamic buffer system. These data confirm the dynamic dissolution system provides a robust and reliable platform to predict the in vivo fate of oral products in a laboratory setting.

Topics: Cellulose; Chemistry, Pharmaceutical; Delayed-Action Preparations; Drug Liberation; Hydrogen-Ion Concentration; Methylcellulose; Models, Biological; Polymethacrylic Acids; Polyvinyls; Prednisolone; Solubility

BMS-B is a highly lipophilic compound (clog P 7.72) with poor aqueous solubility (<10 ng/mL at pH 1 and 6.5). The compound exhibits low bioavailability in preclinical species when dosed as cosolvent solution formulations, with reduced exposure upon dose escalation. The purpose of this study was to evaluate spray-dried dispersions (SDDs) for enhancing oral exposure and enabling toxicology studies of BMS-B. SDD solids of BMS-B were prepared with 10%-25% drug in hydroxypropyl methylcellulose acetate succinate and showed an enhanced dissolution profile relative to the neat form of the compound. When dosed in rats and monkeys at 5 mg/kg, the SDD exhibited comparable exposure relative to the solution formulation. The SDD was also dosed in rats at 200 and 400 mg/kg and showed dose-proportional exposure compared to the solution formulation. Based on in vitro and in vivo data, the SDD formulation was selected for the toxicology study of BMS-B in rats. In summary, although the SDD approach could be quite challenging for highly lipophilic compounds because of the limitation on wetting and dissolution, the present study demonstrated that SDD can be applied in drug discovery to enhance oral exposure and enable preclinical toxicology studies of highly lipophilic poorly water-soluble compounds.

Topics: Administration, Oral; Animals; Biological Availability; Chemistry, Pharmaceutical; Haplorhini; Macaca fascicularis; Male; Methylcellulose; Purinergic P2Y Receptor Antagonists; Rats; Rats, Sprague-Dawley; Solubility; Solutions; Water

Physical instability of amorphous solid dispersions can be a major impediment to their widespread use. We characterized the molecular mobility in amorphous solid dispersions of itraconazole (ITZ) with each polyvinylpyrrolidone (PVP) and hydroxypropylmethylcellulose acetate succinate (HPMCAS) with the goal of investigating the correlation between molecular mobility and physical stability. Dielectric spectra showed two mobility modes: α-relaxation at temperatures above the glass transition temperature (Tg) and β-relaxation in the sub-Tg range. HPMCAS substantially increased the α-relaxation time, with an attendant increase in crystallization onset time and a decrease in crystallization rate constant, demonstrating the correlation between α-relaxation and stability. The inhibitory effect on α-relaxation as well as stability was temperature dependent and diminished as the temperature was increased above Tg. PVP, on the other hand, affected neither the α-relaxation time nor the crystallization onset time, further establishing the link between α-relaxation and crystallization onset in solid dispersions. However, it inhibited the crystallization rate, an effect attributed to factors other than mobility. Interestingly, both of the polymers acted as plasticizers of β-relaxation, ruling out the latter's involvement in physical stability.

Topics: Crystallization; Drug Stability; Itraconazole; Kinetics; Methylcellulose; Povidone; Synchrotrons; Temperature; X-Ray Diffraction

The purpose of the present study was to formulate polymeric self-emulsifying curcumin nanocapsules with high encapsulation efficiency, good emulsification ability, and optimal globule size for localized targeting in the colon. Formulations were prepared using modified quasiemulsion solvent diffusion method. Concentration of formulation variables, namely, X1 (oil), X2 (polymeric emulsifier), and X3 (adsorbent), was optimized by design of experiments using Box-Behnken design, for its impact on mean globule size (Y1) and encapsulation efficiency (Y2) of the formulation. Polymeric nanocapsules with an average diameter of 100-180 nm and an encapsulation efficiency of 64.85±0.12% were obtained. In vitro studies revealed that formulations released the drug after 5 h lag time corresponding to the time to reach the colonic region. Pronounced localized action was inferred from the plasma concentration profile (C max 200 ng/mL) that depicts limited systemic absorption. Roentgenography study confirms the localized presence of carrier (0-2 h in upper GIT; 2-4 h in small intestine; and 4-24 h in the lower intestine). Optimized formulation showed significantly higher cytotoxicity (IC50 value 20.32 μM) in HT 29 colonic cancer cell line. The present study demonstrates systematic development of polymeric self-emulsifying nanocapsule formulation of curcumin for localized targeting in colon.

Topics: Animals; Calorimetry, Differential Scanning; Cell Survival; Chemistry, Pharmaceutical; Curcumin; Drug Delivery Systems; Emulsifying Agents; Gastrointestinal Tract; Guinea Pigs; HT29 Cells; Humans; Methylcellulose; Nanocapsules; Polymers; Radiography; Regression Analysis; Solubility; X-Ray Diffraction

The role of molecular interactions in ball milled solid dispersions in determining the aqueous solubility of the poorly water-soluble drug, griseofulvin (GF) has been examined. Ball milled solid dispersions of GF and hydroxypropylmethylcellulose acetate succinate (HPMCAS) and GF and polyvinylpyrrolidone (PVP) were prepared and characterized by laser diffraction, scanning electron microscopy and X-ray powder diffraction and the aqueous saturation solubility measured and analyzed using one way ANOVA. The results showed that solid dispersions of GF and HPMCAS possessed an aqueous GF saturation solubility of about ten times higher than the GF solubility achieved from PVP-based solid dispersions. Furthermore, although the aqueous solubility of GF did not vary with the milling conditions used to prepare the solid dispersions with PVP, significant changes in solubility were observed upon changing the milling conditions for preparation of the GF/HPMCAS solid dispersions. Surprisingly, the GF/HPMCAS solid dispersion prepared using spray drying exhibited a significantly lower aqueous solubility than those prepared by bead milling despite their smaller particle size and GF being fully in its amorphous form. It is thought that the higher surface energy of the spray-dried solid dispersions negatively affected the aqueous solubility of GF. In conclusion, the results suggest that the molecular interactions occurring between GF and HPMCAS affect the aqueous solubility of GF and that the molecular interactions appear to remain in the liquid state. In contrast no molecular interactions were evident in the GF/PVP solid dispersions.

Topics: Antifungal Agents; Calorimetry, Differential Scanning; Drug Compounding; Excipients; Griseofulvin; Methylcellulose; Microscopy, Electron, Scanning; Particle Size; Povidone; Powder Diffraction; Solubility; X-Ray Diffraction

Drug polymer-based amorphous solid dispersions (ASD) are widely used in the pharmaceutical industry to improve bioavailability for poorly water-soluble compounds. Spray-drying is the most common process involved in the manufacturing of ASD material. However, spray-drying involves a high investment of material quantity and time. Lower investment manufacturing processes such as fast evaporation and freeze-drying (lyophilization) have been developed to manufacture ASD at the bench level. The general belief is that the overall performance of ASD material is thermodynamically driven and should be independent of the manufacturing process. However, no formal comparison has been made to assess the in vivo performance of material generated by different processes. This study compares the in vitro and in vivo properties of ASD material generated by fast evaporation, lyophilization, and spray-drying methods using griseofulvin as a model compound and hydroxypropyl methylcellulose acetate succinate as the polymer matrix. Our data suggest that despite minor differences in the formulation release properties and stability of the ASD materials, the overall exposure is comparable between the three manufacturing processes under the conditions examined. These results suggest that fast evaporation and lyophilization may be suitable to generate ASD material for oral evaluation. However, caution should be exercised since the general applicability of the present findings will need to be further evaluated.

Topics: Administration, Oral; Animals; Biological Availability; Calorimetry, Differential Scanning; Chemistry, Pharmaceutical; Crystallography, X-Ray; Drug Compounding; Drug Stability; Freeze Drying; Griseofulvin; Magnetic Resonance Spectroscopy; Male; Methylcellulose; Powder Diffraction; Rats; Rats, Sprague-Dawley; Solubility; Technology, Pharmaceutical; Thermogravimetry

Understanding the crystallization kinetics of an amorphous drug is critical for the development of an amorphous solid dispersion (ASD) formulation. This paper examines the phase separation and crystallization of the drug AMG 517 in ASDs of varying drug load at various conditions of temperature and relative humidity using isothermal microcalorimetry. ASDs of AMG 517 in hydroxypropyl methylcellulose acetate succinate (HPMC-AS) were manufactured using a Buchi 290 mini spray dryer system. ASDs were characterized using modulated differential scanning calorimetry (mDSC) and scanning electron microscopy (SEM) prior to isothermal microcalorimetry evaluation, and crystallinity was measured using (19)F solid state nuclear magnetic resonance spectroscopy (SSNMR), before and after crystallization. The crystallization of ASDs of AMG 517 in HPMC-AS was significantly slowed by the presence of HPMC-AS polymer, indicating enhanced physical stability for the ASD formulations. A two-phase crystallization was observed by isothermal microcalorimetry at temperatures near the glass transition temperature (Tg), indicating a drug-rich phase and a miscible ASD phase. (19)F SSNMR showed that only partial crystallization of the drug occurred for the ASDs, suggesting a third phase which did not crystallize, possibly representing a thermodynamically stable, soluble component. Isothermal microcalorimetry provides important kinetic data for monitoring crystallization of the drug in the ASDs and, together with (19)F SSNMR, suggests a three-phase ASD system for AMG 517 in HPMC-AS.

Topics: Benzothiazoles; Calorimetry; Calorimetry, Differential Scanning; Chemistry, Pharmaceutical; Crystallization; Drug Stability; Fluorine; Magnetic Resonance Spectroscopy; Methylcellulose; Microscopy, Electron, Scanning; Phase Transition; Pyrimidines; Transition Temperature

Microprecipitated bulk powder (MBP) is a novel solid dispersion technology to manufacture amorphous formulations of poorly soluble compounds that cannot be processed by spray drying or melt extrusion. An efficient high-throughput screening method has been developed to aid the selection of polymer type, drug loading and antisolvent to solvent ratio for MBP formulation development. With a 96-well platform, the miniaturized coprecipitation screening (MiCoS) includes mixing of drug and polymer in dimethylacetamide, controlled precipitation to generate MBP, filtration/washing, drying and high throughput characterization. The integrated MiCoS approach has been demonstrated with a model compound, glybenclamide. Based on the solid state stability and kinetic solubility of the MBP, hydroxypropylmethylcellulose acetate succinate polymer with 40% or lower drug loading, and antisolvent (0.01 N HCl) to solvent (dimethylacetamide) ratio of 5:1 or higher were selected to make glybenclamide MBP. MiCoS can be applied to both early and late stage formulation processing. In early stage research programs, the system can be used to enable efficacy, pharmacokinetics or mini-toxicology studies for poorly water soluble molecules using minimal amount of drug substance (2-10mg). In late stage development programs, MiCoS can be used to optimize MBP formulation by expanding the experimental design space to include additional formulation variants.

Topics: Acrylic Resins; Chemical Precipitation; Chemistry, Pharmaceutical; Felodipine; Glyburide; Methylcellulose; Miniaturization; Nifedipine; Polymethacrylic Acids; Powders; Solubility

The goal of this study was to demonstrate that MK-0364 solid dispersions can be developed as a means to increase the solubility and bioavailability of a poorly water-soluble drug, MK-0364. The potential solid dispersions would enable an oral solid dosage form as a monotherapy or combination product of MK-0364. Preliminary screening included sample preparation via a solvent casting method, physical characterization, and in vitro dissolution testing. Lead formulations were subsequently manufactured using hot melt extrusion (HME) and spray-drying (SD). All HME (without polyvinyl pyrrolidone) and SD formulations exhibit characteristics of a single phase glass including an amorphous halo when analyzed with X-ray powder diffraction (XRPD), a single glass transition temperature (Tg) measured with differential scanning calorimetry (DSC), and supersaturation when dissolved in dissolution media. The oral absorption of MK-0364 from selected HME and SD formulations in monkeys results in marginally greater exposure with a consistently longer Tmax relative to a liquid filled capsule reference. Based on the processability, physical characterization, in vitro dissolution, and animal pharmacokinetic results, copovidone- and hydroxypropyl methylcellulose acetate succinate (HPMCAS)-based solid dispersion formulations are viable product concepts. The physical stability of both the solid dispersion formulations was also evaluated for 54 weeks under different conditions. The copovidone-based solid dispersion requires protection from moisture.

Topics: Amides; Animals; Cannabinoid Receptor Agonists; Excipients; Hexoses; Macaca mulatta; Methylcellulose; Polyethylene Glycols; Polysorbates; Pyridines; Pyrrolidines; Solubility; Surface-Active Agents; Vinyl Compounds; Vitamin E; Water

The impact of melt extrusion (HME) and spray drying (SD) on mechanical properties of hypromellose acetate succinate (HPMCAS), copovidone, and their formulated blends was studied and compared with that of reference excipients. Tensile strength (TS), compression pressure (CP), elastic modulus (E), and dynamic hardness (Hd ) were determined along with Hiestand indices using compacts prepared at a solid fraction of ∼0.85. HPMCAS and copovidone exhibited lower Hd , lower CP, and lower E than the reference excipients and moderate TS. HPMCAS was found to be highly brittle based on brittle fracture index values. The CP was 24% and 61% higher for HPMCAS after SD and HME, respectively, than for unprocessed material along with a higher Hd . Furthermore, the TS of HPMCAS and copovidone decreased upon HME. Upon blending melt-extruded HPMCAS with plastic materials such as microcrystalline cellulose, the TS increased. These results suggest that SD and HME could impact reworkability by reducing deformation of materials and in case of HME, likely by increasing density due to heating and shear stress in a screw extruder. A somewhat similar effect was observed for the dynamic binding index (BId ) of the excipients and formulated blends. Such data can be used to quantitate the impact of processing on mechanical properties of materials during tablet formulation development.

Topics: Cellulose; Chemistry, Pharmaceutical; Drug Compounding; Excipients; Hardness; Hot Temperature; Methylcellulose; Pyrrolidines; Shear Strength; Tablets; Tensile Strength; Vinyl Compounds

We examined the inhibitory effect of hydroxypropyl methylcellulose acetate succinate (HPMC-AS) on drug recrystallization from a supersaturated solution using carbamazepine (CBZ) and phenytoin (PHT) as model drugs. HPMC-AS HF grade (HF) inhibited the recrystallization of CBZ more strongly than that by HPMC-AS LF grade (LF). 1D-1H NMR measurements showed that the molecular mobility of CBZ was clearly suppressed in the HF solution compared to that in the LF solution. Interaction between CBZ and HF in a supersaturated solution was directly detected using nuclear Overhauser effect spectroscopy (NOESY). The cross-peak intensity obtained using NOESY of HF protons with CBZ aromatic protons was greater than that with the amide proton, which indicated that CBZ had hydrophobic interactions with HF in a supersaturated solution. In contrast, no interaction was observed between CBZ and LF in the LF solution. Saturation transfer difference NMR measurement was used to determine the interaction sites between CBZ and HF. Strong interaction with CBZ was observed with the acetyl substituent of HPMC-AS although the interaction with the succinoyl substituent was quite small. The acetyl groups played an important role in the hydrophobic interaction between HF and CBZ. In addition, HF appeared to be more hydrophobic than LF because of the smaller ratio of the succinoyl substituent. This might be responsible for the strong hydrophobic interaction between HF and CBZ. The intermolecular interactions between CBZ and HPMC-AS shown by using NMR spectroscopy clearly explained the strength of inhibition of HPMC-AS on drug recrystallization.

Topics: Carbamazepine; Chromatography, High Pressure Liquid; Crystallization; Magnetic Resonance Spectroscopy; Methylcellulose; Molecular Structure; Phenytoin

A recent development of coating technology is dry coating, where polymer powder and liquid plasticizer are layered on the cores without using organic solvents or water. Several studies evaluating the process were introduced in literature, however, little information about the critical process parameters (CPPs) is given.. Aim of the study was the investigation and optimization of CPPs with respect to one of the critical quality attributes (CQAs), the coating efficiency of the dry coating process in a rotary fluid bed.. Theophylline pellets were coated with hydroxypropyl methylcellulose acetate succinate as enteric film former and triethyl citrate and acetylated monoglyceride as plasticizer. A 2(5-1) design of experiments (DOEs) was created investigating five independent process parameters namely coating temperature, curing temperature, feeding/spraying rate, air flow and rotor speed. The results were evaluated by multilinear regression using the software Modde(®) 7.. It is shown, that generally, low feeding/spraying rates and low rotor speeds increase coating efficiency. High coating temperatures enhance coating efficiency, whereas medium curing temperatures have been found to be optimum in terms of coating efficiency.. This study provides a scientific base for the design of efficient dry coating processes with respect to coating efficiency.

Topics: Citrates; Dosage Forms; Drug Compounding; Equipment Design; Excipients; Linear Models; Methylcellulose; Monoglycerides; Plasticizers; Technology, Pharmaceutical; Temperature; Theophylline

There has been a growing interest in amorphous solid dispersions for bioavailability enhancement in drug discovery. Spray drying, as shown in this study, is well suited to produce prototype amorphous dispersions in the Candidate Selection stage where drug supply is limited. This investigation mapped the processing window of a micro-spray dryer to achieve desired particle characteristics and optimize throughput/yield. Effects of processing variables on the properties of hypromellose acetate succinate were evaluated by a fractional factorial design of experiments. Parameters studied include solid loading, atomization, nozzle size, and spray rate. Response variables include particle size, morphology and yield. Unlike most other commercial small-scale spray dryers, the ProCepT was capable of producing particles with a relatively wide mean particle size, ca. 2-35 µm, allowing material properties to be tailored to support various applications. In addition, an optimized throughput of 35 g/hour with a yield of 75-95% was achieved, which affords to support studies from Lead-identification/Lead-optimization to early safety studies. A regression model was constructed to quantify the relationship between processing parameters and the response variables. The response surface curves provide a useful tool to design processing conditions, leading to a reduction in development time and drug usage to support drug discovery.

Topics: Biological Availability; Dosage Forms; Drug Compounding; Drug Design; Drug Discovery; Excipients; Methylcellulose; Particle Size; Regression Analysis; Time Factors

In the present work, the possibility of manufacturing by injection molding (IM) a gastro-resistant capsular device based on hydroxypropyl methyl cellulose acetate succinate (HPMCAS) was investigated. By performing as an enteric soluble container, such a device may provide a basis for the development of advantageous alternatives to coated dosage forms. Preliminarily, the processability of the selected thermoplastic polymer was evaluated, and the need for a plasticizer (polyethylene glycol 1500) in order to counterbalance the glassy nature of the molded items was assessed. However, some critical issues related to the physical/mechanical stability (shrinkage and warpage) and opening time of the device after the pH change were highlighted. Accordingly, an in-depth formulation study was carried out taking into account differing release modifiers potentially useful for enhancing the dissolution/disintegration rate of the capsular device at intestinal pH values. Capsule prototypes with thickness of 600 and 900 μm containing Kollicoat(®) IR and/or Explotab(®) CLV could be manufactured, and a promising performance was achieved with appropriate gastric resistance in pH 1.2 medium and break-up in pH 6.8 within 1h. These results would support the design of a dedicated mold for the development of a scalable manufacturing process.

Topics: Capsules; Chemistry, Pharmaceutical; Delayed-Action Preparations; Drug Stability; Hydrogen-Ion Concentration; Methylcellulose; Plasticizers; Polymers; Technology, Pharmaceutical

Amorphous drug-polymer solid dispersions have the potential to enhance the dissolution performance and thus bioavailability of BCS class II drug compounds. The principle drawback of this approach is the limited physical stability of amorphous drug within the dispersion. Accurate determination of the solubility and miscibility of drug in the polymer matrix is the key to the successful design and development of such systems. In this paper, we propose a novel method, based on Flory-Huggins theory, to predict and compare the solubility and miscibility of drug in polymeric systems. The systems chosen for this study are (1) hydroxypropyl methylcellulose acetate succinate HF grade (HPMCAS-HF)-felodipine (FD) and (2) Soluplus (a graft copolymer of polyvinyl caprolactam-polyvinyl acetate-polyethylene glycol)-FD. Samples containing different drug compositions were mixed, ball milled, and then analyzed by differential scanning calorimetry (DSC). The value of the drug-polymer interaction parameter χ was calculated from the crystalline drug melting depression data and extrapolated to lower temperatures. The interaction parameter χ was also calculated at 25 °C for both systems using the van Krevelen solubility parameter method. The rank order of interaction parameters of the two systems obtained at this temperature was comparable. Diagrams of drug-polymer temperature-composition and free energy of mixing (ΔG(mix)) were constructed for both systems. The maximum crystalline drug solubility and amorphous drug miscibility may be predicted based on the phase diagrams. Hyper-DSC was used to assess the validity of constructed phase diagrams by annealing solid dispersions at specific drug loadings. Three different samples for each polymer were selected to represent different regions within the phase diagram.

Topics: Calorimetry, Differential Scanning; Crystallization; Drug Stability; Entropy; Felodipine; Methylcellulose; Polyethylene Glycols; Polymers; Polyvinyls; Solubility; Technology, Pharmaceutical; Temperature; Thermodynamics

The objective of this study was to investigate intermolecular interactions between resveratrol and polymers in amorphous blends and to study the potential correlations between compound-polymer interactions, manufacturability, and stability of the amorphous system to crystallization during storage. Polymers included two grades of poly (vinylpyrrolidone) (PVP), Eudragit E100 (E100), hydroxypropyl methylcellulose (HPMC), hydroxypropyl methylcellulose acetate succinate (HPMCAS), carboxymethyl cellulose acetate butyrate, and poly (acrylic acid) (PAA). Amorphous blends ("solid dispersions") were prepared by dissolving both resveratrol and polymer in a solvent followed by rotary evaporation. Crystallinity was evaluated using X-ray powder diffraction and was studied as a function of time. Mid-infrared (IR) spectroscopy was used to investigate resveratrol-polymer interactions. Polymer influence on the crystallization behavior of resveratrol varied and could be correlated to the polymer structure, whereby polymers with good hydrogen bond acceptor groups performed better as crystallization inhibitors. Resveratrol-polymer hydrogen bonding interactions could be inferred from the IR spectra. Somewhat surprisingly, E100 and resveratrol showed evidence of an acid-base reaction, in addition to intermolecular hydrogen bonding interactions. PVP K29/32 appeared to form stronger hydrogen bond interactions with resveratrol relative to HPMC, HPMCAS, and PAA, consistent with acceptor group chemistry. Long-term stability of the systems against crystallization suggested that stability is linked to the type and strength of intermolecular interactions present. whereby resveratrol blended with E100 and PVP K29/32 showed the greatest stability to crystallization. In conclusion, amorphous resveratrol is unstable and difficult to form, requiring the assistance of a polymeric crystallization inhibitor to facilitate the formation of an amorphous solid dispersion. Polymers effective at inhibiting crystallization were identified, and it is rationalized that their effectiveness is based on the type and strength of their intermolecular interactions with resveratrol.

Topics: Acrylates; Carboxymethylcellulose Sodium; Chemistry, Pharmaceutical; Crystallization; Crystallography, X-Ray; Drug Stability; Drug Storage; Hydrogen Bonding; Hypromellose Derivatives; Methylcellulose; Molecular Structure; Polymers; Povidone; Powder Diffraction; Resveratrol; Solubility; Solvents; Spectroscopy, Fourier Transform Infrared; Stilbenes; Technology, Pharmaceutical; Time Factors

The purposes of this study were to assess the efficiency of different nifedipine amorphous solid dispersions (ASDs) in achieving and maintaining supersaturation and to investigate the solubility-permeability interplay when increasing the apparent solubility via ASD formulations. Spray-dried ASDs of nifedipine in three different hydrophilic polymers, hydroxypropyl methylcellulose acetate succinate (HPMC-AS), copovidone, and polyvinylpyrrolidone (PVP), were prepared and characterized by powder X-ray diffraction and differential scanning calorimetry. The ability of these formulations to achieve and maintain supersaturation over 24 h was assessed. Then, nifedipine's apparent intestinal permeability was investigated as a function of increasing supersaturation in the parallel artificial membrane permeability assay model and in the single-pass rat intestinal perfusion model. The efficiency of the different ASDs to achieve and maintain supersaturation of nifedipine was found to be highly polymer dependent; while a dispersion in HPMC-AS enabled supersaturation 20× that of the crystalline aqueous solubility, a dispersion in copovidone enabled 10×, and PVP allowed supersaturation of only 5× that of the crystalline solubility. Nifedipine flux across the intestine from supersaturated solutions was increased, and the apparent intestinal permeability was constant, irrespective of the degree of supersaturation or the polymer being used. In conclusion, while with other solubility-enabling approaches (e.g., surfactants, cyclodextrins, cosolvents), it is not enough to increase the apparent solubility, but to strike the optimal solubility-permeability balance, which limits the chances for successful drug delivery, the amorphous form emerges as a more advantageous strategy, in which higher apparent solubility (i.e., supersaturation) will be readily translated into higher drug flux and overall absorption.

Topics: Administration, Oral; Animals; Calorimetry, Differential Scanning; Chemistry, Pharmaceutical; Crystallography, X-Ray; Desiccation; Drug Compounding; Hydrophobic and Hydrophilic Interactions; Intestinal Absorption; Jejunum; Male; Membranes, Artificial; Methylcellulose; Nifedipine; Permeability; Povidone; Powder Diffraction; Pyrrolidines; Rats; Rats, Wistar; Solubility; Technology, Pharmaceutical; Time Factors; Vinyl Compounds

Solid dispersions of varying weight ratios compositions of the nonionic drug, griseofulvin and the hydrophilic, anionic polymer, hydroxylpropylmethyl cellulose acetate succinate, have been prepared by ball milling and the resulting samples characterized using a combination of Fourier transform infra-red spectroscopy, X-ray powder diffraction and differential scanning calorimetry. The results suggest that griseofulvin forms hydrogen bonds with the hydroxylpropylmethyl cellulose acetate succinate polymer when prepared in the form of a solid dispersion but not when prepared in a physical mixture of the same composition. As anticipated, the actual measured glass transition temperature of the solid dispersions displayed a linear relationship between that predicted using the Gordon-Taylor and Fox equations assuming ideal mixing, but interestingly only at griseofulvin contents less than 50 wt%. At griseofulvin concentrations greater than this, the measured glass transition temperature of the solid dispersions was almost constant. Furthermore, the crystalline content of the solid dispersions, as determined by differential scanning calorimetry and X-ray powder diffraction followed a similar trend in that the crystalline content significantly decreased at ratios less than 50 wt% of griseofulvin. When the physical mixtures of griseofulvin and the hydroxylpropylmethyl cellulose acetate succinate polymer were analyzed using the Flory-Huggins model, a negative free energy of mixing with an interaction parameter of -0.23 were obtained. Taken together these results suggest that anionic hydrophilic hydroxylpropylmethyl cellulose acetate succinate polymer is a good solvent for crystalline nonionic griseofulvin with the solubility of griseofulvin in the solid dispersion being was estimated to be within the range 40-50 wt%. Below this solubility limit, the amorphous drug exists as amorphous glassy solution while above these values the system is supersaturated and glassy suspension and solution may coexist.

Topics: Calorimetry, Differential Scanning; Crystallization; Drug Compounding; Excipients; Griseofulvin; Hydrogen Bonding; Hydrophobic and Hydrophilic Interactions; Methylcellulose; Molecular Structure; Phase Transition; Solubility; Spectroscopy, Fourier Transform Infrared; X-Ray Diffraction

The feasibility of forming solid molecular dispersions of poorly water-soluble drugs in crosslinked poly(2-hydroethyl methacrylate) (PHEMA) hydrogel has recently been reported by our group. The purpose of the present study is to investigate the extent of enhancement of kinetic solubility of amorphous solid dispersions (ASDs) of indomethacin (IND) in crosslinked PHEMA hydrogels as compared with those based on conventional water-soluble polymer carriers. Our results show that under non-sink conditions, the initial solubility enhancement is higher for ASDs based on polyvinylpyrrolidone (PVP) and hydroxypropylmethylcellulose acetate succinate (HMPCAS), but the ability to maintain this solubility enhancement at longer times is better for ASDs based on PHEMA over a period of 24h with the extent of solubility enhancement of IND ASDs in PHEMA falling between those in PVP and HPMCAS at 10.0% IND loading after 6h and outperforming those in PVP and HPMCAS at 32.9% IND loading after 8h. The observed kinetic solubility profiles reflect the fact that the amorphous IND is released from PHEMA by a different mechanism than those from water-soluble polymer carriers. In this case, the dissolution of IND ASD from water-soluble PVP and HPMCAS is almost instantaneous, resulting in an initial surge of IND concentration followed by a sharp decline due to the nucleation and crystallization events triggered by the rapid build-up of drug supersaturation. On the other hand, the dissolution of IND ASD from insoluble crosslinked PHEMA hydrogel beads is less rapid as it is regulated by a feedback-controlled diffusion mechanism, thus avoiding a sudden surge of supersaturation in the dissolution medium. The absence of an apparent decline in drug concentration during dissolution from IND-PHEMA ASD further reflects the diminished nucleation and crystallization events during IND dissolution from hydrogel-based solid molecular dispersions. Based on the XRD analyses, a threshold IND loading level of about 34% in PHEMA has been identified, above which amorphous to crystalline transition tends to occur. Also, by selecting the appropriate particle sizes, immediate to controlled release of IND from IND-PHEMA ASD can be readily achieved as the release rate increases with decreasing PHEMA bead size. Furthermore, a robust physical stability has been demonstrated in IND-PHEMA ASD with no drug precipitation for up to 8 months at IND loadings below 16.7% under direct open cup exposure to accelerated st

Topics: Cross-Linking Reagents; Crystallization; Delayed-Action Preparations; Drug Carriers; Drug Stability; Drug Storage; Feasibility Studies; Humidity; Hydrogels; Indomethacin; Kinetics; Methylcellulose; Particle Size; Phase Transition; Polyhydroxyethyl Methacrylate; Povidone; Solubility; Time Factors; X-Ray Diffraction

It is well recognized that poor dissolution rate and solubility of drug candidates are key limiting factors for oral bioavailability. While numerous technologies have been developed to enhance solubility of the drug candidates, poor water solubility continuously remains a challenge for drug delivery. Among those technologies, amorphous solid dispersions (SD) have been successfully employed to enhance both dissolution rate and solubility of poorly water-soluble drugs. This research reports a high-throughput screening technology developed by utilizing a 96-well plate system to identify optimal drug load and polymer using a solvent casting approach. A minimal amount of drug was required to evaluate optimal drug load in three different polymers with respect to solubility improvement and solid-state stability of the amorphous drug-polymer system. Validation of this method was demonstrated with three marketed drugs as well as with one internal compound. Scale up of the internal compound SD by spray drying further confirmed the validity of this method, and its quality was comparable to a larger scale process. Here, we demonstrate that our system is highly efficient, cost-effective, and robust to evaluate the feasibility of spray drying technology to produce amorphous solid dispersions.

Topics: Acetaminophen; Celecoxib; Chemistry, Pharmaceutical; Crystallization; Drug Carriers; Drug Stability; Equipment Design; Griseofulvin; High-Throughput Screening Assays; Hypromellose Derivatives; Indomethacin; Kinetics; Methylcellulose; Miniaturization; Pharmaceutical Preparations; Polymers; Povidone; Pyrazoles; Quality Control; Reproducibility of Results; Solubility; Solvents; Sulfonamides; Technology, Pharmaceutical; Vacuum; Water

Recently, we have revealed a trade-off between solubility increase and permeability decrease when solubility-enabling oral formulations are employed. We have shown this trade-off phenomenon to be ubiquitous, and to exist whenever the aqueous solubility is increased via solubilizing excipients, regardless if the mechanism involves decreased free fraction (cyclodextrins complexation, surfactant micellization) or simple cosolvent solubilization. Discovering a way to increase drug solubility without concomitant decreased permeability represents a major advancement in oral delivery of lipophilic drugs and is the goal of this work. For this purpose, we sought to elucidate the solubility-permeability interplay when increased apparent solubility is obtained via supersaturation from an amorphous solid dispersion (ASD) formulation. A spray-dried ASD of the lipophilic drug progesterone was prepared in the hydrophilic polymer hydroxypropyl methylcellulose acetate succinate (HPMC-AS), which enabled supersaturation up to 4× the crystalline drug's aqueous solubility (8 μg/mL). The apparent permeability of progesterone from the ASD in HPMC-AS was then measured as a function of increasing apparent solubility (supersaturation) in the PAMPA and rat intestinal perfusion models. In contrast to previous cases in which apparent solubility increases via cyclodextrins, surfactants, and cosolvents resulted in decreased apparent permeability, supersaturation via ASD resulted in no decrease in apparent permeability with increasing apparent solubility. As a result, overall flux increased markedly with increasing apparent solubility via ASD as compared to the other formulation approaches. This work demonstrates that supersaturation via ASDs has a subtle yet powerful advantage over other solubility-enabling formulation approaches. That is, increased apparent solubility may be achieved without the expense of apparent intestinal membrane permeability. Thus, supersaturation via ASDs presents a markedly increased opportunity to maximize overall oral drug absorption.

Topics: Administration, Oral; Animals; Cell Membrane Permeability; Chemistry, Pharmaceutical; Cyclodextrins; Excipients; Hydrophobic and Hydrophilic Interactions; Intestinal Absorption; Intestinal Mucosa; Male; Methylcellulose; Pharmaceutical Preparations; Rats; Rats, Wistar; Solubility; Surface-Active Agents

Ovarian cancer is the fifth most leading cause of cancer related deaths in women in the US. Customized immunotherapeutic strategies may serve as an alternative method to control the recurrence or progression of ovarian cancer and to avoid severe adverse effects of chemotherapy. In this study, a microparticulate vaccine using whole cell lysate of a murine ovarian cancer cell line, ID8 was prepared with the use of a spray dryer. These particles were designed for oral delivery using enteric polymers such as methacrylic copolymer, Eudragit(®) FS30D and hydroxyl propyl methyl cellulose acetate succinate. These particles were targeted for uptake via microfold cell (M-cell) in Peyer's patches of small intestine using M-cell targeting ligand, Aleuria aurantia lectin. The interleukins (ILs) such as IL-2 and IL-12 were added to the vaccine formulation to further enhance the immune response. The particles obtained were of 1.58±0.62 μm size with a charge of 12.48±2.32 mV. The vaccine efficacy was evaluated by administering the particles via oral route to C57BL/6 female mice. At the end of vaccination, mice were challenged with live tumor cells. Vaccinated mice showed significant (around six-fold) retardation of tumor volume in comparison to non-vaccinated animals for 3 weeks after the tumor challenge (p<0.001). The serum IgG antibody levels were found to be elevated in case of vaccinated animals in comparison to non-vaccinated group (p<0.05). Analysis of IgG1 titers (indicative of Th2 response) and IgG2a titers (indicative of Th1 response) showed a mixed Th1 and Th2 immune response in case vaccine alone and Th2 response in case of vaccine with interleukins group. Moreover, CD8+ T-cell, CD4+ T-cell and B-cell populations in different lymphatic organs were elevated in case of vaccinated mice. Thus, whole cell lysate vaccine microparticles formulated by spray drying could trigger humoral as well as cellular immune response when administered orally. Such vaccine could potentially be an effective treatment for patients with residual tumor or high tumor-relapse probability.

Topics: Adjuvants, Immunologic; Administration, Oral; Animals; Antibodies, Neoplasm; B-Lymphocytes; Cancer Vaccines; CD4-Positive T-Lymphocytes; CD8-Positive T-Lymphocytes; Chemistry, Pharmaceutical; Drug Carriers; Female; Humans; Interleukins; Methylcellulose; Mice; Mice, Inbred C57BL; Ovarian Neoplasms; Polymethacrylic Acids; Treatment Outcome

The aim of the study was to prepare molecular dispersions of a physically highly unstable amorphous drug, paracetamol (acetaminophen with a T(g) of ca. 25°C) via co-spray drying with a variety of polymers. Solid dispersions at a range of drug loadings (10-90%w/w) using hydroxypropyl methylcellulose/acetate succinate (HPMC/HPMC AS), polyvinylpyrrolidone (PVP) and copovidone were produced and characterised by modulated temperature differential scanning calorimetry (MTDSC), thermogravimetric analysis (TGA), X-ray powder diffraction (XRPD), Fourier transform infrared spectroscopy (FTIR) and scanning electron microscopy (SEM). PVP-based polymers showed a greater tendency than the HPMC-based group to generate temperature-stable dispersions. In particular, copovidone (Plasdone® S-630) was found to be the most effective of the polymers studied and could formulate molecular dispersions at drug loadings up to and including 40%w/w. However, no evidence for direct drug-polymer interactions was found for such systems as a possible stabilising mechanism. The expected relationship of a higher T(g) of the polymer leading to greater stabilisation was not observed, while there was an inverse relationship between viscosity grade and amorphous phase generation. The study has therefore shown that temperature-stable amorphous dispersions of a low T(g) drug may be prepared by co-spray drying, particularly using PVP-based polymers.

Topics: Acetaminophen; Calorimetry, Differential Scanning; Drug Carriers; Drug Stability; Hypromellose Derivatives; Methylcellulose; Microscopy, Electron, Scanning; Polymers; Povidone; Pyrrolidines; Spectroscopy, Fourier Transform Infrared; Temperature; Thermogravimetry; Transition Temperature; Vinyl Compounds; Viscosity; X-Ray Diffraction

A solid dispersion (SPD) of carbamazepine (CBZ) with hydroxypropyl methylcellulose acetate succinate (HPMC-AS) was prepared by the spray drying method. The apparent solubility (37 °C, pH 7.4) of CBZ observed with the SPD was over 3 times higher than the solubility of unprocessed CBZ. The supersaturated solution was stable for 7 days. A higher concentration of CBZ in aqueous medium was also achieved by mixing with Poloxamer 407 (P407), a solubilizing agent. From permeation studies of CBZ using Caco-2 monolayers and dialysis membranes, we observed improved CBZ permeation across the membrane in the supersaturated solution of CBZ/HPMC-AS SPD. On the contrary, the CBZ-solubilized P407 solution exhibited poor permeation by CBZ. The chemical shifts of CBZ on the (1)H NMR spectrum from CBZ/HPMC-AS SPD solution were not altered significantly by coexistence with HPMC-AS. In contrast, an upfield shift of CBZ was observed in the CBZ/P407 solution. The spin-lattice relaxation time (T(1)) over spin-spin relaxation time (T(2)) indicated that the mobility of CBZ in the HPMC-AS solution was much lower than that in water. Meanwhile, the mobility of CBZ in P407 solution was significantly higher than that in water. NMR data indicate that CBZ does not strongly interact with HPMC-AS. CBZ mobility was suppressed due to self-association and microviscosity around CBZ, which do not affect permeation behavior. Most of the CBZ molecules in the CBZ/P407 solution were solubilized in the hydrophobic core of P407, and a few were free to permeate the membrane. The molecular state of CBZ, as evaluated by NMR measurements, directly correlated with permeation behavior.

Topics: Anticonvulsants; Caco-2 Cells; Carbamazepine; Cell Membrane Permeability; Chemical Phenomena; Chromatography, High Pressure Liquid; Dialysis; Dosage Forms; Drug Compounding; Humans; Magnetic Resonance Spectroscopy; Membranes, Artificial; Methylcellulose; Solubility; X-Ray Diffraction

Reducing the absorption difference between fed and fasted states is an important goal in the development of pharmaceutical dosage forms. The goal of this work was to develop and characterize a solid nanocrystalline dispersion (SNCD) to improve the oral absorption of ziprasidone in the fasted state, thereby reducing the food effect observed for the commercial formulation. A solution of ziprasidone hydrochloride and the polymer hydroxypropyl methylcellulose acetate succinate (HPMCAS) was spray-dried to form a solid amorphous spray-dried dispersion (SDD), which was then exposed to a controlled temperature and relative humidity (RH) to yield the ziprasidone SNCD. The SNCD was characterized using powder X-ray diffraction, thermal analysis, microscopy, and in vitro dissolution testing. These tools indicate the SNCD consists of a high-energy crystalline form of ziprasidone in domains approximately 100 nm in diameter but with crystal grain sizes on the order of 20 nm. The SNCD was dosed orally in capsules to beagle dogs. Pharmacokinetic studies showed complete fasted-state absorption of ziprasidone, achieving the desired improvement in the fed/fasted ratio.

Topics: Absorption; Administration, Oral; Animals; Antipsychotic Agents; Biological Availability; Calorimetry, Differential Scanning; Capsules; Crystallization; Dogs; Fasting; Methylcellulose; Piperazines; Solubility; Thiazoles; Tissue Distribution; X-Ray Diffraction

Dry powder coating is a technique to coat substrates without the use of organic solvent or water. The polymer powder is directly applied to the cores to be coated. Liquid additives are often used to lower the glass transition temperature of the polymer and to enhance the adhesion of the powder to the cores. This leads to an increase in coating efficiency of the process. The impact of various liquid additives and their properties like spreading behavior, viscosity and plasticizing activity were investigated with respect to their influence on the coating efficiency of the process. Ethylcellulose and hydroxypropyl methylcellulose acetate succinate were used as coating polymers. Spreading behavior of the liquid additive on the polymer was the most influencing parameter and could be successfully predicted with contact angle measurements on polymer films. Calculations of works of adhesion and spreading coefficients also revealed to be promising predictive techniques for choosing suitable additives to improve process efficiency. Isopropyl myristate showed the best spreading behavior resulting in the highest coating efficiency. Based on these results, a formulation for ethylcellulose containing isopropyl myristate was developed and film formation was examined using dissolution testing and imaging techniques to evaluate the optimum curing conditions.

Topics: Cellulose; Drug Compounding; Excipients; Methylcellulose; Polymers; Powders; Pressure; Solubility; Surface Tension; Transition Temperature; Viscosity

One of the drawbacks with solid solution systems is their thermodynamic instability in solution. Considering the release of these systems from extended-release formulations, in particular swellable matrix tablets, a successful tablet formulation can be regarded as a composition able to maintain the molecular state of the poorly soluble crystalline drug through diffusion in the matrix. This may in turn provide molecular rather than particulate delivery of the substance from the matrix. In this study, the solid state and dissolution behavior of amorphous solid dispersions of a model crystalline substance, butyl paraben in HPMC and HPMCAS, was investigated. In addition, the suitability of HPMCAS as both effective solid solution carrier and as extended-release matrix forming polymer was examined. The release from all systems investigated showed extended-release capacity with a release rate similar to the rate of matrix erosion. However, a detailed study of the factors affecting the release mechanism revealed that upon hydration, the model substance crystallized in the gel layer of the HPMC-based formulation, whereas it remained in amorphous form in the HPMCAS tablets. In the case of HPMCAS formulation, this effect was attributed to (i) the ability of this polymer to keep the model substance in a supersaturated state and (ii) the very slow matrix hydration, resulting in a steep concentration gradient of the drug substance and a short diffusion path through the matrix into the dissolution bulk.

Topics: Calorimetry, Differential Scanning; Crystallization; Crystallography, X-Ray; Hydrogen-Ion Concentration; Hypromellose Derivatives; Methylcellulose; Spectrum Analysis, Raman; Tablets

A method is described for screening compounds that inhibit crystallization in solution to enable more accurate measurement of amorphous drug solubility. Three polymers [polyvinylpyrrolidone, hydroxypropyl methylcellulose, and hydroxypropyl methylcellulose acetate succinate (HPMCAS)] were screened for their ability to inhibit the crystallization of neat amorphous drugs during measurement of solubility of the amorphous form in water. Among the polymers evaluated, HPMCAS was found to be most promising. The use of HPMCAS provided an "apparent solubility" of amorphous drugs that was closer to the theoretically calculated values. With danazol, agreement was essentially quantitative, and for griseofulvin and iopanoic acid, agreement was within a factor of two; these maximum concentrations were sustained for a period of 40-90 min. Dynamic light scattering of filtered samples (0.22 µ) revealed the presence of colloidal drug-polymer assemblies in solution (100-150 nm). The supernatant resulting from this centrifugation gradually decreased in concentration, but remained supersaturated with respect to crystalline drug for several hours. Thus, HPMCAS has been shown to be a useful additive in dissolution media to allow a more accurate determination of the solubility of fast crystallizing neat amorphous drugs, at least for the drugs studied, and it should also serve to retard crystallization in vivo and therefore, facilitate improved bioavailability.

Topics: Chemistry, Pharmaceutical; Colloids; Crystallization; Danazol; Griseofulvin; Hypromellose Derivatives; Iopanoic Acid; Kinetics; Light; Methylcellulose; Pharmaceutical Preparations; Povidone; Scattering, Radiation; Solubility; Technology, Pharmaceutical; Ultracentrifugation

Preparation of amorphous solid dispersions using hot-melt extrusion process for poorly water soluble compounds which degrade on melting remains a challenge due to exposure to high temperatures. The aim of this study was to develop a physically and chemically stable amorphous solid dispersion of a poorly water-soluble compound, NVS981, which is highly thermal sensitive and degrades upon melting at 165 °C. Hydroxypropyl Methyl Cellulose (HPMC) based polymers; HPMC 3cps, HPMC phthalate (HPMCP) and HPMC acetyl succinate (HPMCAS) were selected as carriers to prepare solid dispersions using hot melt extrusion because of their relatively low glass transition temperatures. The solid dispersions were compared for their ease of manufacturing, physical stability such as recrystallization potential, phase separation, molecular mobility and enhancement of drug dissolution. Two different drug loads of 20 and 50% (w/w) were studied in each polymer system. It was interesting to note that solid dispersions with 50% (w/w) drug load were easier to process in the melt extruder compared to 20% (w/w) drug load in all three carriers, which was attributed to the plasticizing behavior of the drug substance. Upon storage at accelerated stability conditions, no phase separation was observed in HPMC 3cps and HPMCAS solid dispersions at the lower and higher drug load, whereas for HPMCP, phase separation was observed at higher drug load after 3 months. The pharmaceutical performance of these solid dispersions was evaluated by studying drug dissolution in pH 6.8 phosphate buffer. Drug release from solid dispersion prepared from polymers used for enteric coating, i.e. HPMCP and HPMCAS was faster compared with the water soluble polymer HPMC 3cps. In conclusion, of the 3 polymers studied for preparing solid dispersions of thermally sensitive compound using hot melt extrusion, HPMCAS was found to be the most promising as it was easily processible and provided stable solid dispersions with enhanced dissolution.

Topics: Crystallization; Drug Carriers; Drug Stability; Drug Storage; Hydrogen-Ion Concentration; Hypromellose Derivatives; Methylcellulose; Solubility; Time Factors; Transition Temperature

It has been previously observed that exposure to high relative humidity (RH) can induce amorphous-amorphous phase separation in solid dispersions composed of certain hydrophobic drugs and poly(vinylpyrrolidone) (PVP). The objective of this study was to investigate if this phenomenon occurred in solid dispersions prepared using less hygroscopic polymers. Drug-polymer miscibility was investigated before and after exposure to high RH using infrared (IR) spectroscopy and differential scanning calorimetry (DSC). PVP, poly(vinylpyrrolidone-co-vinyl acetate) (PVPVA), and hypromellose acetate succinate (HPMCAS) were selected as model polymers, and felodipine, pimozide, indomethacin, and quinidine were selected as model drugs. Drug-polymer mixing at the molecular level was confirmed for all model systems investigated. Moisture-induced drug-polymer demixing was observed in felodipine-PVPVA, quinidine-PVP, quinidine-PVPVA, pimozide-PVPVA, and pimozide-HPMCAS systems, but was absent in the other HPMCAS dispersions and for indomethacin-PVPVA. It is concluded that the balance between the thermodynamic factors (enthalpy and entropy of mixing) in a ternary water-drug-polymer system is the important factor in determining which solid dispersion systems are susceptible to moisture-induced amorphous-amorphous phase separation. Systems with strong drug-polymer interactions and a less hygroscopic polymer will be less susceptible to moisture-induced phase separation, while more hydrophobic drugs will be more susceptible to this phenomenon even at low levels of sorbed moisture.

Topics: Calorimetry, Differential Scanning; Felodipine; Humidity; Indomethacin; Methylcellulose; Models, Theoretical; Molecular Structure; Pimozide; Polymers; Polyvinyls; Povidone; Pyrrolidines; Quinidine; Spectrophotometry, Infrared; Wettability

In this study, the ability of 7 chemically diverse polymers [Eudragit E100 (E100), poly(acrylic acid) (PAA), poly(vinylpyrrolidone) (PVP), poly(vinylpyrrolidone-vinyl acetate) (PVPVA), poly(styrene sulfonic acid) (PSSA), hydroxypropylmethylcellulose (HPMC) and hydroxypropylmethylcellulose acetate succinate (HPMCAS)] to inhibit the crystallization of 8 readily crystallizable model compounds [benzamide (BD), phenacetin (PH), flurbiprofen (FB), flufenamic acid (FFA), chlorpropamide (CP), chlorzoxazone (CZ), bifonazole (BI) and lidocaine (LI)] was investigated. Films of the different drug-polymer combinations were prepared by rapid evaporation from solution, using a spin coating method. A total of 7 different drug/polymer weight ratios [90/10, 75/25, 60/40, 50/50, 40/60, 25/75 and 10/90 (w/w)] were evaluated for each drug-polymer combination. Crystallization behavior of the films was monitored using polarized light microscopy over 7 days of room temperature storage under dry conditions. It was observed that compounds having a higher crystallization tendency for the pure compound tended to be more difficult to stabilize using the polymeric additives; more polymer was required. In addition, the stabilizing ability of the polymers varied considerably for the individual compounds, with the acidic polymers PAA and PSSA showing the most extreme behavior. The acidic polymers were good stabilizers for the drugs with basic and amide functional groups, but extremely poor stabilizers for acidic drugs. A reasonable correlation between crystallization inhibition in spin coated films versus bulk powders (prepared by rotary evaporation) was observed. The small scale screening method is thus a potentially useful technique to evaluate the role of drug-polymer chemistry in the stabilization of amorphous solid dispersions.

Topics: Acrylates; Benzamides; Chlorpropamide; Chlorzoxazone; Chromatography, High Pressure Liquid; Crystallization; Flurbiprofen; Hypromellose Derivatives; Imidazoles; Lidocaine; Methylcellulose; Phenacetin; Polymers; Polyvinyls; Povidone; Pyrrolidines; Solvents

To identify materials and processes which effect supersaturation of the GI milieu for low solubility drugs in order to increase oral bioavailability.. A variety of small and polymeric molecules were screened for their ability to inhibit drug precipitation in supersaturated solutions. The best polymeric materials were utilized to create spray-dried dispersions (SDDs) of drug and polymer, and these were tested for drug form and homogeneity. Dispersions were tested in vitro for their ability to achieve and maintain drug supersaturation, for a variety of drug structures.. Of the 41 materials tested, HPMCAS was the most effective at maintaining drug supersaturation. Drug/HPMCAS SDDs were consistently more effective at achieving and maintaining drug supersaturation in vitro than were SDDs prepared with other polymers. Drug/HPMCAS SDDs were effective in vitro for eight low solubility drugs of widely varying structure. Drug/HPMCAS SDDs were more effective at achieving and maintaining supersaturation than were rotoevaporated Drug/HPMCAS dispersions or physical mixtures of Drug and HPMCAS. The degree of achievable drug supersaturation increased with increasing polymer content in the SDD. The drug in Drug /HPMCAS SDDs was amorphous, and the dispersions were demonstrated to have a single glass transition and were thus homogeneous.. HPMCAS has been identified as a uniquely effective polymer for use in SDDs of low solubility drugs, with broad applicability across a variety of drug structures and properties.

Topics: Chemical Precipitation; Chemistry, Pharmaceutical; Excipients; Gastrointestinal Contents; Humans; Methylcellulose; Particle Size; Pharmaceutical Preparations; Powder Diffraction; Solubility; Transition Temperature; X-Ray Diffraction

This report introduces modified cellulose polymers as new emulsifiers of cubosomes. We prepared novel nanoparticles containing cubic-phase-forming lipids using hydroxypropyl methylcellulose acetate succinate (HPMCAS). Small-angle X-ray scattering showed a much lower incorporation of HPMCAS into the cubic structure of monoolein than did a conventional emulsifier, Pluronic F127, which is known to modify the cubic structure. Cubosomes prepared with HPMCAS showed roughly equal stability as nanoparticles with Pluronic F127. These results suggest that HPMCAS can be a novel emulsifier of cubosomes, which brings about no internal structure modification.

Topics: Cellulose; Chemistry, Physical; Emulsions; Glycerides; Lipids; Methylcellulose; Models, Chemical; Nanoparticles; Nanotechnology; Poloxamer; Polymers; Scattering, Radiation; Surface Properties; X-Rays

The objective of this study was to investigate the effects of polymer type and storage relative humidity (RH) on the crystallization kinetics of felodipine from amorphous solid dispersions.. Crystallization of the model drug felodipine from amorphous solid dispersion samples containing poly(vinyl pyrrolidone) (PVP) and hypromellose acetate succinate (HPMCAS) were evaluated. Samples at three different drug-polymer weight ratios (10, 25, and 50 wt. % polymer) were prepared and stored at six different RHs (0%, 32%, 52% or 66%, 75%, 86%, and 93%). Periodically, the fraction of the drug that had crystallized from the samples was quantified using powder X-ray diffractometry (PXRD).. Felodipine crystallization rates from PVP-containing dispersions were found to be very sensitive to changes in storage RH, while crystallization rates from HPMCAS-containing dispersions were not. PVP and HPMCAS were similar in terms of their ability to inhibit crystallization at low RH, but when the storage RH was increased to 75% or above, felodipine crystallization from PVP-containing solid dispersions proceeded much faster. It is hypothesized that this trend was caused by moisture-induced drug-polymer immiscibility in PVP-felodipine system. For PVP-containing solid dispersion samples stored at 75% RH and above, crystallization of the model drug felodipine seemed to approach a kinetic plateau, whereby a fraction of the drug still remained amorphous even after storage for 500 days or more.. The physical stability of solid dispersions as a function of RH is highly dependent on the polymer used to form the solid dispersion, with PVP-containing dispersions being much less physically stable at high RH than HPMCAS-containing dispersions.

Topics: Crystallization; Drug Carriers; Drug Storage; Felodipine; Humidity; Kinetics; Methylcellulose; Polymers; Povidone; Powders; Wettability

The stability and dissolution properties of griseofulvin binary and ternary solid dispersions were evaluated. Solid dispersions of griseofulvin and hydroxypropyl methylcellulose acetate succinate (HPMCAS) were prepared using the spray drying method. A third polymer, poly[N-(2-hydroxypropyl)methacrylate] (PHPMA), was incorporated to investigate its effect on the interaction of griseofulvin with HPMCAS. In this case, HPMCAS can form H bonds with griseofulvin directly; the addition of PHPMA to the solid dispersion may enhance the stability of the amorphous griseofulvin due to greater interaction with griseofulvin. The X-ray powder diffraction results showed that griseofulvin (binary and ternary solid dispersions) remained amorphous for more than 19 months stored at 85% RH compared with the spray-dried griseofulvin which crystallized totally within 24 h at ambient conditions. The Fourier transform infrared scan showed that griseofulvin carbonyl group formed hydrogen bonds with the hydroxyl group in the HPMCAS, which could explain the extended stability of the drug. Further broadening in the peak could be seen when PHPMA was added to the solid dispersion, which indicates stronger interaction. The glass transition temperatures increased in the ternary solid dispersions regardless of HPMCAS grade. The dissolution rate of the drug in the solid dispersion (both binary and ternary) has significantly increased when compared with the dissolution profile of the spray-dried griseofulvin. These results reveal significant stability of the amorphous form due to the hydrogen bond formation with the polymer. The addition of the third polymer improved the stability but had a minor impact on dissolution.

Topics: Antifungal Agents; Crystallization; Drug Stability; Griseofulvin; Hydrogen Bonding; Methylcellulose; Solubility; Spectroscopy, Fourier Transform Infrared; Temperature

The dry coating process was evaluated in terms of storage stability investigating drug release and agglomeration tendency of the different coated oral dosage forms; hydroxypropyl methylcellulose acetate succinate (HPMCAS) was used with triethylcitrate (TEC) as plasticizer and acetylated monoglyceride (Myvacet) as wetting agent. Talc or colloidal silicon dioxide (Aerosil) was used as anti-tacking agents. In contrast to coating formulations consisting of HPMCAS and Myvacet all formulations containing TEC showed enteric resistance and no agglomeration tendency after preparation. After storage at 10% RH +/- 5% enteric resistance is increased slightly. This increase is more pronounced at 60% RH +/- 5%. The formulations without anti-tacking agents showed higher drug releases after 12 and 24 months due to the damage of the film's integrity during sample preparation caused by the high tackiness of the film. Tackiness is not affected by storing if samples are stored at low relative humidity. At high relative humidity tackiness increases upon storage especially for formulations without anti-tacking agents. The sieving results of the agglomeration measurements after storage can be confirmed by ring shear measurements performed immediately after preparation and approved to be a tool, which is able to predict the agglomeration during storage.

Topics: Adhesiveness; Chemistry, Pharmaceutical; Citrates; Dosage Forms; Drug Compounding; Drug Stability; Humidity; Hydrogen-Ion Concentration; Methylcellulose; Monoglycerides; Powders; Rheology; Silicon Dioxide; Tablets, Enteric-Coated; Talc; Temperature; Theophylline

Amorphous solid dispersions are used as a strategy to improve the bioavailability of poorly water-soluble compounds. When formulating with a polymer, it is important not only for the polymer to stabilize against crystallization in the solid state, but also to improve the dissolution profile through inhibiting crystallization from the supersaturated solution generated by dissolution of the amorphous material. In this study, the dissolution profiles of solid dispersions of felodipine formulated with poly(vinylpyrrolidone) (PVP), hydroxypropyl methylcellulose (HPMC) or hydroxypropyl methylcellulose acetate succinate (HPMCAS) were compared. In addition, concentration versus time profiles were evaluated for the supersaturated solutions of felodipine in the presence and absence of the polymers. HPMCAS was found to maintain the highest level of supersaturation for the greatest length of time for both the dissolution and solution crystallization experiments, whereas PVP was found to be the least effective crystallization inhibitor. All polymers appeared to reduce the crystal growth rates of felodipine at an equivalent supersaturation and this mechanism most likely contributes to the enhanced solution concentration values observed during dissolution of the amorphous solid dispersions.

Topics: Crystallization; Felodipine; Hypromellose Derivatives; Methylcellulose; Polymers; Polyvinyls; Pyrrolidines; Solubility; Thermodynamics

Dry coating is an innovative powder-layering technique that enables the formation of coatings on solid dosage forms with no need for using water or organic solvents. This technique envisages the distribution of polymer powder blends onto substrate cores and the concurrent or alternate nebulization of liquid plasticizers. In this work, a dry coating process based on hydroxypropyl methylcellulose acetate succinate (HPMCAS) was set up in a rotary fluid bed equipment to prepare enteric-coated soft gelatin capsules. Promising results were obtained in terms of process feasibility and product characteristics, thus suggesting the possibility of advantageous applications for the investigated technique when dealing with gelatin capsule substrates.

Topics: Capsules; Excipients; Gelatin; Methylcellulose; Powders; Technology, Pharmaceutical

The aim of the study was in vitro evaluation of piroxicam solid dispersions containing hydroxypropyl methylcellulose acetate succinate (HPMCAS-LF, -HF) as a carrier. Binary (piroxicam-HPMCAS) and ternary (piroxicam-HPMCAS-Carbopol 940) solid dispersions were prepared by spray-drying method. The morphological characteristics were investigated by scanning electron microscopy. X-ray diffraction and differential scanning calorimetry were employed to study physical and chemical properties. In vitro release was studied using a flow-through cell technique. Studies of dissolution rate of piroxicam from solid dispersions were carried out in comparison with corresponding physical mixtures and drug alone. The dissolution profiles depend on the presence of Carbopol 940 in solid dispersions.

Topics: Acrylic Resins; Animals; Anti-Inflammatory Agents, Non-Steroidal; Calorimetry, Differential Scanning; Drug Carriers; Excipients; Eye; Eye Diseases; Humans; Methylcellulose; Microscopy, Electron, Scanning; Ophthalmic Solutions; Particle Size; Piroxicam; Surface Properties; Transition Temperature; X-Ray Diffraction

The stability of hydroxypropyl methylcellulose acetate succinate (HPMC-AS) and its potential incompatibility with active pharmaceutical ingredients (API) carrying hydroxyl group(s) were investigated in this research. HPMC-AS may undergo hydrolysis under harsh processing conditions with the generation of succinic acid and acetic acid, which can form ester bond(s) with the hydroxyl group(s) in API. In this case, the hot-melt extrusion (HME) product prepared from HPMC-AS and our model compound (compound A) was tested after heating at 140 degrees C up to 5 h. The succinate esters of compound A and its epimer were found in the product, suggesting potential drug-excipient incompatibility during formulation development. In addition, dyphylline was also tested with HPMC-AS and the potential incompatibility was further confirmed.

Topics: Chemistry, Pharmaceutical; Chromatography, Liquid; Drug Incompatibility; Dyphylline; Esterification; Excipients; Hydrolysis; Methylcellulose; Tandem Mass Spectrometry

To investigate the ability of various polymers to inhibit the crystallization of amorphous felodipine from amorphous molecular dispersions in the presence of absorbed moisture.. Spin coated films of felodipine with poly(vinylpyrrolidone) (PVP), hydroxypropylmethylcellulose acetate succinate (HPMCAS) and hydroxypropylmethylcellulose (HPMC) were exposed to different storage relative humidities and nucleation rates were measured using polarized light microscopy. Solid dispersions were further characterized using differential scanning calorimetry, infrared spectroscopy and gravimetric measurement of water vapor sorption.. It was found that the polymer additive reduced nucleation rates whereas absorbed water enhanced the nucleation rate as anticipated. When both polymer and water were present, nucleation rates were reduced relative to those of the pure amorphous drug stored at the same relative humidity, despite the fact that the polymer containing systems absorbed more water. Differences between the stabilizing abilities of the various polymers were observed and these were explained by the variations in the moisture contents of the solid dispersions caused by the different hygroscopicities of the component polymers. No correlations could be drawn between nucleation rates and the glass transition temperature (Tg) of the system. PVP containing solid dispersions appeared to undergo molecular level changes on exposure to moisture which may be indicative of phase separation.. In conclusion, it was found that for a given storage relative humidity, although the addition of a polymer increases the moisture content of the system relative to that of the pure amorphous drug, the crystallization tendency was still reduced.

Topics: Absorption; Calorimetry, Differential Scanning; Crystallization; Drug Stability; Felodipine; Humidity; Hypromellose Derivatives; Kinetics; Methylcellulose; Microscopy, Polarization; Polymers; Povidone; Spectroscopy, Fourier Transform Infrared; Technology, Pharmaceutical; Transition Temperature; Water; Wettability

Enteric coatings that deliver drugs to specific regions of the small intestine were examined. Hypromellose acetate succinate (HPMCAS) with different values of succinoyl group contents was used. Decreasing the succinoyl group content resulted in an increase in the pH at which HPMCAS started to dissolve. Drug-containing granules with or without enteric coating were prepared and their in vitro dissolution in a simulated intestinal fluid of pH 6.8 was examined. Granules coated with HPMCAS having the succinoyl group content of 6.2% showed a lag time of about 30 min, although drug release from granules without coating was completed within 20 min. The time lag and dissolution rate were extended and reduced, respectively, as the succinoyl group content was decreased. Rat experiments indicated that enteric-coated granules disintegrated and the bulk of the drugs was immediately released when the granules reached a specific site of the small intestine where the pH corresponded to the pH at which the enteric coating agent started to dissolve. Similar results were observed in monkey experiments. It was suggested that HPMCAS with the succinoyl group content of about 5% was suitable as an enteric coating agent for delivering drugs to the middle-to-lower region of the small intestine.

Topics: Animals; Drug Carriers; Excipients; Hydrogen-Ion Concentration; Intestine, Small; Macaca mulatta; Male; Methylcellulose; Rats; Rats, Wistar; Solubility; Sulfasalazine; Tablets, Enteric-Coated; Theophylline; Tissue Distribution

A highly efficient dry coating process was developed to obtain an enteric film avoiding completely the use of organic solvents and water. Using hydroxypropyl methylcellulose acetate succinate (HPMCAS) an enteric coat should be obtained without adding talc as anti-tacking agent because of problems arising from microbiological contamination. Further on, a method was developed preparing isolated films in order to determine the glass transition temperature (T(g)) and the required process temperature. The process was conducted in the rotary fluid bed with a gravimetric powder feeder achieving an exact dosage in contrast to volumetric powder feeder. A three way nozzle was aligned tangential to the pellet bed movement feeding simultaneously powder and plasticizer into the rotary fluid bed. The determined coating efficiency of the talc-free formulation was high with 94% and storage stability regarding tacking could be achieved using colloidal silicium dioxide as top powder. The T(g) of the enteric coat could be determined analyzing the T(g) of isolated films obtained by coating celluloid spheres instead of pellets using the dry coating process in rotary fluid bed. The dry coating process has been demonstrated to be a serious alternative to conventional solvent or water based coating processes.

Topics: Adhesiveness; Chemistry, Pharmaceutical; Citrates; Drug Stability; Hydrogen-Ion Concentration; Methylcellulose; Particle Size; Plasticizers; Polymers; Powders; Quality Control; Solubility; Tablets, Enteric-Coated; Theophylline

The major aim of the present work was to study the effects of various formulation and processing parameters on the resulting drug release kinetics from theophylline matrix pellets coated with aqueous hydroxypropyl methylcellulose acetate succinate (HPMCAS) dispersions. The plasticizer content, coating level and curing conditions significantly affected the release patterns in 0.1 M HCl, whereas no major effects were observed in phosphate buffer, pH 7.4. Due to the significant size of the HPMCAS particles (being in the micrometer range), their coalescence was particularly crucial and not complete upon coating. Consequently, at low coating levels continuous water-filled channels connected the bead cores with the release medium through which the drug could rapidly diffuse, resulting in high release rates even at low pH. In contrast, at high coating levels such continuous connections did not exist (due to the increased number of polymer particle layers), and drug release was controlled by diffusion through the macromolecular network resulting in much lower release rates in 0.1 M HCl. Importantly, pellet curing at elevated temperature and ambient relative humidity or exposure to elevated relative humidity at room temperature did not significantly alter the microstructure of the coatings, leading to only slightly decreased drug release rates. In contrast, pellet curing at elevated temperature combined with elevated relative humidity induced significant further polymer particle coalescence, resulting in a change of the underlying drug release mechanism and significantly reduced drug release rates.

Topics: Chemistry, Pharmaceutical; Diffusion; Methylcellulose; Solubility; Tablets, Enteric-Coated; Technology, Pharmaceutical; Theophylline

In this research, we have reconsidered the current enteric coating techniques and offered a new solution using both theoretical and practical approaches. This approach is based on the fact that salt formation can solubilize the pH-sensitive polymers in water. However, having applied the polymer solution onto the dosage form's surface, the polymer should be converted to the nonionized form for delayed release action. Ammonium hydrogen carbonate (AHC) is used as a buffering agent with dual actions of salting in and desalting the polymer. Following the application of the coating medium onto the dosage form's surface and drying, AHC dissociate completely to ammonia, carbon dioxide, and water converting the polymer to its nonionized form. FT-IR studies on free film samples further confirmed the proposed mechanism. A range of pH-sensitive polymers and other ingredients in water have been successfully applied at the surface of a model ASA tablets, using pan coating technique. According to the SEM observation, the coating layer is very dense and rigid, despite the fact that, the coated amount of the polymers is quit small. The enteric tablets maintain their shapes in acid medium and passed the USP dissolution test for DR ASA tablets.

Topics: Aspirin; Chemical Phenomena; Chemistry, Pharmaceutical; Chemistry, Physical; Methylcellulose; Microscopy, Electron, Scanning; Polymethacrylic Acids; Solubility; Surface Properties; Tablets, Enteric-Coated; Water

The ability of various polymers to inhibit the crystallization of amorphous felodipine was studied in amorphous molecular dispersions. Spin-coated films of felodipine with poly(vinylpyrrolidone) (PVP), hydroxypropylmethylcellulose acetate succinate (HPMCAS), and hydroxypropylmethylcellulose (HPMC) were prepared and used for measurement of the nucleation rate and to probe drug-polymer intermolecular interactions. Bulk solid dispersions were prepared by a solvent evaporation method and characterized using thermal analysis. It was found that each polymer was able to significantly decrease the nucleation rate of amorphous felodipine even at low concentrations (3-25% w/w). Each polymer was found to affect the nucleation rate to a similar extent at an equivalent weight fraction. For HPMC and HPMCAS, thermal analysis indicated that the glass transition temperature (T(g)) of the solid dispersions were not significantly different from that of felodipine alone, whereas an increase in T(g) was observed for the PVP containing solid dispersions. Infrared spectroscopic studies indicated that hydrogen bonding interactions were formed between felodipine and each of the polymers. These interactions were stronger between felodipine and PVP than for the other polymers. It was speculated that, at the concentrations employed, the polymers reduce the nucleation rate through increasing the kinetic barrier to nucleation.

Topics: Calorimetry, Differential Scanning; Crystallization; Felodipine; Hypromellose Derivatives; Methylcellulose; Polyvinyls; Pyrrolidines; Spectroscopy, Fourier Transform Infrared; Transition Temperature

A newly commercialized high-resolution ultrasonic spectrometer was evaluated for simultaneously measuring concentrations of a model excipient (hypromellose acetate succinate polymer, HPMCAS, CAS No. 71138-97-1) and a model drug (Fenofibrate, CAS No. 49562-28-9) in acetone solution. It was demonstrated that the measurements of both velocity and attenuation had sufficient accuracy and precision. The velocity was found to be directly proportional to concentrations of both HPMCAS polymer and Fenofibrate in solution. The attenuation was found to be directly proportional to concentration of HPMCAS polymer in solution. By establishing linear relationships of measured velocity and attenuation to the concentrations of HPMCAS polymer and the Fenofibrate in a series of standard solutions, it was feasible to simultaneously analyze concentrations of both HPMCAS polymer and Fenofibrate in a test solution. However, it was found that both temperature and moisture had significant influence on the measurement. While the change in velocity was inversely proportional to the change in temperature, the change in velocity was directly proportional to the change in moisture content in solutions.

Topics: Drug Compounding; Excipients; Fenofibrate; Kinetics; Linear Models; Methylcellulose; Pharmaceutical Preparations; Quality Control; Solutions; Spectrum Analysis; Temperature; Ultrasonics; Water

Blends of aqueous dispersions of a water-insoluble and an enteric polymer, namely ethyl cellulose:hydroxypropyl methylcellulose acetate succinate (EC:HPMCAS) and ethyl cellulose:methacrylic acid ethyl acrylate copolymer (EC:Eudragit L), were used as coating materials to control theophylline release from matrix pellets. Varying the polymer blend ratio, broad ranges of drug release patterns were obtained at low as well as at high pH. Interestingly, the resulting release profiles were rather similar for both types of blends in 0.1 M HCl, whereas significant differences were observed in phosphate buffer pH 7.4. Surprisingly, drug release at high pH was much slower for EC:HPMCAS blends compared to EC:Eudragit L blends, although HPMCAS leached out more rapidly (and to a higher extent) from the film coatings than Eudragit L. To explain these phenomena and to better understand the underlying drug release mechanisms, thin polymeric films of identical composition as the pellet coatings were prepared and physicochemically characterized before and upon exposure to the release media. Importantly, the polymer particle size was identified to be a very crucial formulation parameter, determining the resulting film coating structure and properties. The Eudragit L particles are much smaller than the HPMCAS particles (nano- vs. micrometer size range) and, thus, more effectively hinder the formation of a continuous and mechanically stable EC network. Consequently, the EC structures remaining after enteric polymer leaching at high pH are mechanically much weaker in the case of Eudragit L. Upon exposure to phosphate buffer, water-filled cracks are formed, through which the drug rapidly diffuses out. In contrast, the EC structures remaining upon HPMCAS leaching are mechanically stronger and drug release is controlled by diffusion through the polymeric remnants.

Topics: Cellulose; Chemical Phenomena; Chemistry, Physical; Chromatography, High Pressure Liquid; Dosage Forms; Drug Carriers; Drug Stability; Emulsions; Hardness Tests; Kinetics; Methylcellulose; Microscopy, Electron, Scanning; Particle Size; Plasticizers; Polymers; Polymethacrylic Acids; Surface Properties; Theophylline

The utility of hypromellose acetate succinate (HPMCAS), a cellulosic enteric coating agent, as a carrier in a solid dispersion of nifedipine (NP) was evaluated in comparison with other polymers, including hypromellose (HPMC), hypromellose phthalate (HPMCP), methacrylic acid ethyl acrylate copolymer (MAEA), and povidone (PVP). An X-ray diffraction study showed that the minimum amount of HPMCAS required to make the drug completely amorphous was the same as that of other cellulosic polymers, and less than that in dispersions using non-cellulosic polymers. Hypromellose acetate succinate showed the highest drug dissolution level from its solid dispersion in a dissolution study using a buffer of pH 6.8. This characteristic was unchanged after a storage test at high temperature and high humidity. The inhibitory effect of HPMCAS on recrystallization of NP from a supersaturated solution was the greatest among all the polymers examined. Further, the drug release pattern could be modulated by altering the ratio of succinoyl and acetyl moieties in the polymer chain. Our results indicate that HPMCAS is an attractive candidate for use as a carrier in solid dispersions.

Topics: Calcium Channel Blockers; Crystallization; Drug Carriers; Drug Stability; Methylcellulose; Nifedipine; Spectrophotometry, Infrared; Spectroscopy, Fourier Transform Infrared; X-Ray Diffraction

A novel pH-dependent gradient-release delivery system was developed by mixing three kinds of pH-dependent microspheres. Nitrendipine, a dihydropyridine calcium antagonist, was selected as the poorly water-soluble model drug. To obtain gradient-release of the active drug in the stomach, duodenum and lower segment of the small intestine, respectively, three kinds of pH-dependent polymers, i.e. Acrylic resins Eudragit E-100, Hydroxypropylmethylcellulose phthalate and Hydroxypropylmethylcellulose acetate succinate, were formulated to produce the microspheres, which dissolve at an acid condition, the pH of > or = 5.5 and > or = 6.5, respectively. The quasi-emulsion solvent diffusion method was employed in the manufacturing process for the microspheres. All three kinds of microspheres had a highly spherical shape and high incorporation efficiency (>91.0%). The particle sizes were mainly affected by the agitation speed and temperature of the manufacturing process. The results of X-ray diffraction suggested that nitrendipine in the microspheres was molecularly dispersed in an amorphous state. The drug dissolution behavior of the system under the simulated gastrointestinal pH conditions revealed obvious gradient-release characteristics. The dissolution profiles and content of the systems stored at a temperature of 40 degrees C and a relative humidity of 75% were unchanged during a 3-month period of accelerating storage conditions. The results of the bioavailability testing in six healthy dogs suggested that the pH-dependent gradient-release delivery system could improve efficiently the uptake of the poorly water-soluble drug and prolong the Tmax value in vivo.

Topics: Acrylates; Administration, Oral; Animals; Biological Availability; Delayed-Action Preparations; Dogs; Drug Carriers; Drug Stability; Hydrogen-Ion Concentration; Male; Methylcellulose; Microscopy, Electron, Scanning; Microspheres; Nitrendipine; Particle Size; Polymers; X-Ray Diffraction

The molecular weight of hypromellose acetate succinate (HPMCAS), a polymer used for enteric coating, was determined by means of size exclusion chromatography with a multi-angle laser light scattering detector. The weight-average molecular weight (Mw) of several lots and grades ranged approximately from 17000 to 20000, and the number-average molecular weight (Mn) was around 13000. The inter-day precision of measurement, in terms of the coefficient of variation, was less than 5%.

Topics: Chromatography, Gel; Lasers; Light; Methylcellulose; Molecular Weight; Scattering, Radiation

In the present study, gastric juice resistant tablet formulations of lactic acid bacteria (LAB) were developed, using hydroxypropylmethylcellulose acetate succinate (HPMCAS) as well as alginates, apple pectin and Metolose as matrix forming components. To optimize the formulation-using survival rate in acid medium, and disintegration time in intestinal fluid as test parameters-tablets were modified with respect to LAB content, amount of applied excipients per tablet, and compaction forces. A decrease of viable cells of not more than one log unit after 2h of incubation in acid medium was desired, as well as a disintegration time of 1h in phosphate buffer pH 6.8. It was found that the amount of HPMCAS in the tablet correlates with gastric juice resistance. As HPMCAS also leads to a decrease of disintegration time in intestinal fluid, slight amounts of this excipient were preferred. The best protective qualities against artificial gastric juice were observed when tablets were prepared from compaction mixtures of LAB, HPMCAS and sodium alginate.

Topics: Colony Count, Microbial; Compressive Strength; Drug Compounding; Drug Stability; Drug Storage; Excipients; Gastric Juice; Hydrogen-Ion Concentration; Lactic Acid; Lactobacillus acidophilus; Methylcellulose; Probiotics; Solubility; Tablets, Enteric-Coated; Temperature

Weakly basic drugs, such as verapamil hydrochloride, that are poorly soluble in neutral/alkaline medium may have poor oral bioavailability due to reduced solubility in the small intestine and colon. Film coated pellets were prepared using two strategies to enhance drug release at high pH values. Firstly, pellets were coated with Eudragit RS/hydroxypropyl methylcellulose acetate succinate (HMAS) mixtures in proportions of 10:1 and 10:3, respectively. The enteric polymer, HMAS, would dissolve in medium at pH > 6 creating pores through the insoluble Eudragit RS membrane to increase drug release. Secondly, an acidic environment was created within the core by the inclusion of fumaric acid at concentrations of 5 and 10% in order to increase drug solubility. Both strategies enhanced drug release into neutral medium in dissolution studies using the pH change method to simulate GIT transit. Dissolution profiles of samples tested in pH 1.2 for 12 hr were compared with those using the pH change method (pH 1.2 for first 1.5 hr, pH raised to 6.8 for remaining 10.5 hr) using the area under the dissolution curve (AUC), the dissolution half-life (t50%), and the amount of drug released in 3 hr (A3hr) values. Both strategies enhanced drug release into neutral medium although the strategy using HMAS in the film was more effective. The formulation least affected by pH change was a combination of the two strategies, i.e., pellets containing 5% fumaric acid coated with Eudragit RS 12% w/w and HMAS 1.2% w/w.

Topics: Acrylic Resins; Drug Compounding; Drug Implants; Excipients; Fumarates; Hydrogen-Ion Concentration; Kinetics; Methylcellulose; Microscopy, Electron, Scanning; Solubility; Surface Properties; Time Factors; Verapamil

Hoshi et al. [Hoshi et al. J Toxicol Sci 10(Suppl):187-255, 1985a,b,c,d] evaluated the potential for hydroxypropyl methylcellulose acetate succinate (HPMCAS) to produce developmental and reproductive toxicity in a series of studies that included rat and rabbit teratology studies, a rat fertility study, and a rat peri- and postnatal study. The authors concluded that there were no compound-related findings. In the cesarean-section phase of the rat teratology study, however, clubfoot was reported for 0.8, 2.1, 5.5, and 4.1% of fetuses in the control, 625, 1250, and 2500 mg/kg groups, respectively. There were no significant increases in external anomalies, but the apparent dose-related increase in clubfoot was not specifically addressed. In the rabbit teratology study, the number of litters evaluated (12-13 per group) was not consistent with current regulatory guidelines. Therefore, to definitively establish the potential of HPMCAS to produce developmental toxicity, embryo/fetal development studies were carried out in rats and rabbits.. Groups of 20 pregnant Sprague-Dawley rats and New Zealand White rabbits were dosed with 0, 50, 150, 625, or 2500 mg/kg HPMCAS from gestational day (GD) 6-17 or GD 7-19 for rats and rabbits, respectively. Fetuses were collected by cesarean section and examined for external, visceral and skeletal development.. No developmental toxicity was observed as a result of HPMCAS exposure demonstrating that maternal HPMCAS exposure during gestation does not induce developmental anomalies. There were no findings of clubfoot or other limb anomalies in these studies at dose levels equivalent to those that were previously associated with a possible increase in clubfoot.. The conclusion of the earlier study indicating that treatment with HPMCAS at doses up to and including 2500 mg/kg did not produce developmental toxicity was confirmed with these studies. It is likely that the clubfoot noted in the earlier rat teratology study was a misdiagnosis or artifact.

Topics: Animals; Animals, Newborn; Clubfoot; Dose-Response Relationship, Drug; Embryonic and Fetal Development; Female; Methylcellulose; Pregnancy; Rabbits; Rats; Rats, Sprague-Dawley; Reproduction; Teratogens

The purpose of this study was to develop a new method for preparing controlled release (CR) matrix pellets by annealing with water-insoluble polymers, and to elucidate a relationship between the annealing temperature of the matrix pellets and a glass transition temperature (T(g)) or a minimum film-forming temperature (MFT) of the polymer/plasticizer systems that constituted the matrix pellets. The pellets containing theophylline as a model drug were prepared by the extrusion-spheronization method and subsequent annealing. The pellets were characterized mainly by pellet formation, release studies, and thermal evaluations. It was apparent that the annealing temperature for the CR matrix pellets was related to the T(g) and MFT of the polymer/plasticizer systems. For ethylcellulose (EC) containing 22.7% triethylcitrate (TEC), the annealing temperature required for preparing CR pellets was 80 degrees C, which was more than 20 degrees C higher than the T(g) and MFT of this EC/TEC system. In contrast, hydroxypropylmethylcellulose acetate succinate (HPMCAS) containing 22.7% TEC could be used to prepare CR pellets without heating. The T(g) of this HPMCAS/TEC system was about 60 degrees C and the MFT was lower than 20 degrees C, indicating that water can act as a plasticizer for HPMCAS and that HPMCAS/TEC pellets could be annealed at room temperature. These results suggest that MFT is a better indicator than T(g) for estimating annealing temperature. SEM observation showed that the EC/TEC pellets annealed at 80 degrees C had a matrix structure with coalesced particles. On the contrary, unannealed pellets consisted of individually distinguishable particles. The release rate of drug from the matrix CR pellets was dependent on the drug concentration and polymer to plasticizer ratio.

Topics: Cellulose; Drug Compounding; Drug Implants; Drug Stability; Excipients; Hardness; Methylcellulose; Microscopy, Electron, Scanning; Particle Size; Polymers; Solubility; Temperature; Theophylline; Water; X-Ray Diffraction

To develop a new colon targeting formulation, which can suppress drug release completely during 12 h in the stomach and release the drug rapidly after a lag time of 3+/-1 h in the small intestine, the use of press-coated tablets with hydroxypropylmethylcellulose acetate succinate (HPMCAS) in the outer shell was investigated. The release of diltiazem hydrochloride (DIL) as a model drug contained in the core tablets in the 1st fluid (pH 1.2) was suppressed by preparing with higher compression force, but the lag time in the 2nd fluid (pH 6.8) could not exceed 1.5 h. Therefore, to improve the dissolution characteristics, the effects of addition of various hydrophobic additives to HPMCAS were examined. All of the additives examined suppressed the release rate in the 1st fluid, and prolonged the lag time in the 2nd fluid compared to HPMCAS alone. However, although none of the additives examined fulfilled all of the desired criteria, magnesium stearate (MgSt) and calcium stearate (CaSt) showed interesting effects; the former suppressed drug release completely in 1st fluid, while the latter markedly prolonged the lag time in 2nd fluid. To integrate the merits of each additive, press-coated tablets with a powder mixture of HPMCAS, MgSt and CaSt in the outer shell (HMC tablets) were prepared and in vitro tests were performed. The results indicated that HMC tablets with a mixing ratio of 80% HPMCAS, 5-15% MgSt and 15-5% CaSt in the outer shell met the desired criteria and the lag time in 2nd fluid could also be controlled from 2 to 9 h. At a mixing ratio of 80% HPMCAS, 10% MgSt and 10% CaSt, the dissolution profiles of DIL in 1st fluid and 2nd fluid were not remarkably affected by agitation intensity, and addition of bile salts, pretreatment time or anticipated higher pH except for pH 6.0, respectively. These results indicated the usefulness of HMC tablets with the desirable functions for colon-targeting formulations.

Topics: Colon; Diltiazem; Hydrogen-Ion Concentration; Methylcellulose; Pressure; Solubility; Tablets

A new method for preparation of large amounts of empty pressure-controlled colon delivery capsules (PCDCs) by a dipping method has been developed. Empty PCDCs are composed of two polymer membranes. The inner one was a water-insoluble polymer membrane, ethylcellulose (EC). The outer one was an enteric polymer membrane, hydroxypropylmethylcellulose phthalate (HPMCP) or hydroxypropylmethylcellulose acetate succinate (HPMCAS). By consequently dipping into an ethanolic EC solution and an alkalized enteric polymer solution, empty PCDCs were obtained after both the capsule body and cap were adjusted to the size of #2 capsules. With each enteric polymer, two types of empty PCDCs of different thickness were prepared. Fluorescein (FL) was formulated with suppository base, PEG1000, and used as a model drug. FL/PEG1000 suspension was introduced into empty PCDCs which were then sealed with enteric polymer solution. The PCDCs were evaluated by an in vivo experiment using beagle dogs. After oral administration of the test PCDC preparations containing 30 mg of FL, blood samples were obtained from the jugular vein and serum FL levels were measured. The thickness of the EC membrane layer varied in both the capsule body and cap. HPMCAS PCDCs had 62.1+/-5.0 (S.E.) microm (body) and 49.7+/-3.3 microm (cap) with thicker ones and 55.7+/-6.6 microm (body) and 46.8+/-6.2 microm (cap) with thinner ones. HPMCP PCDCs had 28.1+/-3.3 microm (body), 30.9+/-1.0 microm (cap) with thinner ones and 43.1+/-9.8 microm (body), 42.4+/-8.2 microm (cap) with thicker ones. The mean T(i) values, the first appearance time, of FL in the serum of HPMCAS PCDCs were 2.0+/-0.7 h for thicker ones and 3.8+/-0.5 h for thinner ones, while the mean T(i) values of HPMCP PCDCs were 2.0+/-0.0 h for thinner ones and 3.5+/-0.7 h for thicker ones. Since the colon arrival time in beagle dogs was 3.5+/-0.3 h as determined by a sulfasalazine test, thinner HPMCAS PCDCs and thicker HPMCP PCDCs were thought to deliver FL to the colon.

Topics: Animals; Area Under Curve; Capsules; Cellulose; Colon; Contrast Media; Dogs; Drug Delivery Systems; Excipients; Fluorescein; Male; Methylcellulose; Sclerosing Solutions

Effect of magnesium stearate (MgSt) or calcium stearate (CaSt) on the dissolution profiles of diltiazem hydrochloride in the core of press-coated (PC) tablets with an outer shell composed of hydroxypropylmethylcellulose acetate succinate (HPMCAS) was evaluated by porosity and changes in IR spectra of tablets. In JP first fluid (pH 1.2), the lag time increased with decreasing porosity and was greatest by the addition of MgSt to HPMCAS. While, in JP second fluid (pH 6.8), it increased with decreasing porosity by the addition of CaSt, but hardly changed by the addition of MgSt. Thus, using tablets prepared with the same composition as the outer shell, the changes in IR spectra and uptake amount of the dissolution media after immersion in first fluid and second fluid were determined. The results suggested that some physicochemical interaction occur between MgSt and HPMCAS in tablets with HPMCAS and MgSt and the uptake increased markedly in each dissolution medium. These phenomena seem to cause a prolongation of lag time in first fluid but a shortening of it in second fluid in PC tablets with HPMCAS and MgSt. In contrast, CaSt and HPMCAS did not show such interactions and increased the hydrophobic properties of the outer shell. Consequently, the lag time was only slightly prolonged in first fluid, however, markedly prolonged in second fluid due to suppression of second fluid penetration into micro pores in the outer shell and HPMCAS gel formation on the surface in PC tablets with HPMCAS and CaSt.

Topics: Antihypertensive Agents; Chemistry, Pharmaceutical; Diltiazem; Excipients; Methylcellulose; Porosity; Stearic Acids; Tablets

One of the main drawbacks of hydrocolloid matrices as oral controlled drug delivery systems is the often observed decreasing rate of drug release at the end of the release process. This study describes a new pH-controlled hydrocolloid drug delivery system consisting of a neutral cellulose ether as basis polymer and enteric coating materials as additives. The new dosage form is able to accelerate the drug release at a predetermined pH. In a typical example, methylhydroxy ethylcellulose, MHEC 10000 B, was used as the basis polymer and hydroxypropyl methylcellulose acetate succinate, HPMCAS HF, as release modifier. The new delivery system is characterized by its homogeneous structure and easy production by direct compression of the components. The acceleration is well reproducible. Furthermore the new formulation shows high stability against hydrodynamic stress and tolerates ionic strengths up to 0.25 without any significant changes in the release profile. As mechanism of the final burst at pH values >5.7, enforced erosion of the gel layer surrounding the tablet core, could be identified.

Topics: Administration, Oral; Colloids; Delayed-Action Preparations; Drug Delivery Systems; Enzyme Inhibitors; Hydrogen-Ion Concentration; Methylcellulose; Pentoxifylline; Tablets

Dissolution profiles of diltiazem hydrochloride (DIL) contained in core tablets from press-coated (PC) tablets with hydroxypropylmethylcellulose acetate succinate (HPMCAS) and plasticizers-adsorbent in the outer shell were investigated. Although, on the addition of triethyl citrate (TEC), triacetin (TA), and acetyltriethy citrate (ATEC) as plasticizers, DIL release was suppressed completely in first fluid (pH 1.2) for 10 h, it was not suppressed in HPMCAS on the addition of dibutyl sebacate (DBS) and acetylated monoglyceride. On the other hand, DIL in second fluid (pH 6.8) was released rapidly after a lag time in all the PC tablets. Water-soluble plasticizers such as TEC, TA, and ATEC showed greater compatibility to HPMCAS, and the results were consistent with suppression of DIL release in first fluid. Furthermore, as to PC tablets with HPMCAS and TEC-adsorbent, the DIL release in second fluid did not change after pretreatment in first fluid by the paddle-beads methods. To evaluate the resistance of the outer shell against such a mechanical impact, tablets with HPMCAS, HPMCAS and TEC- or DBS-adsorbent (H, HT, or HD tablets, respectively) were prepared. In compressive load-strain curves after immersion in first fluid, wet crushing strength was lower in the order of HT > H > HD tablets. Also, the curves of HT tablets at 3 and 21 h after immersion were quite different from those of other tablets, and it was hard to find crushing points. These results suggested that the resistance of the outer shell was due to plastic deformation properties involving some interaction between HPMCAS and TEC.

Topics: Cardiovascular Agents; Compressive Strength; Diltiazem; Mechanics; Methylcellulose; Plasticizers; Solubility; Tablets, Enteric-Coated

A floating dosage form composed of nicardipine hydrochloride (NH) and hydroxypropylmethylcellulose acetate succinate (enteric polymer) was prepared using a twin-screw extruder. By adjusting the position of the high-pressure screw elements in the immediate vicinity of die outlet, and by controlling the barrel temperature, we were able to prepare a puffed dosage form with very small and uniform pores. It was found that the porosity and pore diameter could be controlled by the varying amount of calcium phosphate dihydrate. In the shaking test, the puffed dosage form was found to have excellent floating ability and mechanical strength in acid solution (JP First Fluid, pH 1.2). The dissolution profile of NH was controlled by the amount of wheat starch. In the dissolution test using JP Second Fluid (pH 6.8), rapid dissolution of NH and loss of buoyancy were observed. It was shown that the puffed dosage form, consisting of enteric polymer prepared using the twin-screw extruder, was very useful as a floating dosage form that was retained for a long period in the stomach.

Topics: Administration, Oral; Calcium Phosphates; Chemistry, Pharmaceutical; Dosage Forms; Kinetics; Methylcellulose; Microscopy, Electron, Scanning; Nicardipine; Vasodilator Agents

Weakly basic drugs or salts thereof demonstrate pH-dependent solubility. The resulting release from conventional matrix tablets decreases with increasing pH-milieu of the gastrointestinal tract. The aim of this study was to overcome this problem and to achieve pH-independent drug release. Two different polymers were used as matrix formers, the water-insoluble and almost unswellable ethylcellulose (EC), and the water-soluble and highly swellable hydroxypropyl methylcellulose (HPMC). Two different approaches to solve the problem of pH-dependent release of weakly basic drugs are demonstrated in this paper. The first one is based on the addition of hydroxypropyl methylcellulose acetate succinate (HPMCAS, an enteric polymer), the second one on the addition of organic acids such as fumaric, succinic or adipic acid to the drug-polymer system. The first approach failed to achieve pH-independent drug release, whereas the addition of organic acids to both matrix formers was found to maintain low pH values within the tablets during drug release in phosphate buffer (pH 6.8 or 7.4). Thus, the micro-environmental conditions for the dissolution and diffusion of the weakly basic drug were almost kept constant. The release of verapamil hydrochloride from tablets composed of ethylcellulose or HPMC and organic acids was found to be pH-independent.

Topics: Calcium Channel Blockers; Delayed-Action Preparations; Excipients; Hydrogen-Ion Concentration; Methylcellulose; Solubility; Tablets; Verapamil; Water

The aim of this study was to develop new multi-layer matrix tablets to achieve bimodal drug release profiles (fast release/slow release/fast release). Hydroxypropyl methylcellulose acetate succinate (HPMCAS, type MF) was chosen as a matrix former, because it is water-insoluble at low, and water-soluble at high pH values. Studies focused on the elucidation of the drug release mechanisms from HPMCAS-MF:drug tablets. In 0.1 N HCl the resulting release kinetics can be described using Fick's second law of diffusion, taking into account axial and radial mass transfer in cylindrical geometry. As the diffusion coefficients are found to be constant and the boundary conditions to be stationary, these systems are purely drug diffusion-controlled. In contrast, the dominating mass transport phenomena in phosphate buffer pH 7.4 are more complex. Due to polymer dissolution the resulting matrix structure is time-variant, leading to increasing drug diffusion coefficients and decreasing tablet dimensions, and thus moving boundary conditions. Drug release is affected by water imbibition, drug diffusion and polymer dissolution and is faster compared to 0.1 N HCl. With knowledge of these underlying release mechanisms, multi-layer matrix tablets were developed to achieve bimodal drug release. HPMCAS-MF:drug mixtures were used as tablet cores. As expected, changing the release medium from 0.1 N HCl to phosphate buffer pH 7. 4 after 2 h, lead to a significant increase in drug release. The abruptness of this rate change could be enhanced by adding two drug-free HPMCAS-MF barrier layers (one on each side) to the system. The addition of a fourth, drug-containing and fast disintegrating initial dose layer yielded the desired bimodal drug release patterns. The process and formulation parameters affecting the resulting release rates were investigated using theophylline and acetaminophen as model drugs.

Topics: Acetaminophen; Biological Transport; Chemistry, Pharmaceutical; Drug Delivery Systems; Methylcellulose; Tablets; Theophylline

A novel enteric coating method was developed. This method involves direct feeding of coating polymer powder and simultaneous spraying of plasticizing agent, without either organic solvent or water, using a centrifugal granulator, fluidized bed, or tablet-coating machine. For film formation, a curing step was then necessary; this involved spraying a small amount (3-8% of core weight) of water or hydroxypropyl methylcellulose solution, followed by heating. Hydroxypropyl methylcellulose acetate succinate was used as the enteric coating polymer, and a combination of triethyl citrate and acetylated monoglyceride was used for plasticization. The coated beads and tablets were evaluated for gastric resistance, intestinal disintegration, and stability, in comparison with beads and tablets from a conventional aqueous coating with the same enteric polymer. The new method required a higher coating amount for gastric resistance compared with the conventional coating, but the processing time was dramatically reduced. The results show that this dry coating method is applicable to the preparation of enteric-coated beads and tablets using commercially available lab-scale apparatus.

Topics: Drug Stability; Methylcellulose; Microscopy, Electron, Scanning; Microspheres; Particle Size; Plasticizers; Powders; Tablets, Enteric-Coated

Duloxetine hydrochloride ((S)-N-methyl-3-(1-naphthalenyloxy)-2-thiophenepropanamine hydrochloride) has been found to react with polymer degradation products or residual free acids present in the enteric polymers hydroxypropyl methylcellulose acetate succinate (HPMCAS) and hydroxypropyl methylcellulose phthalate (HPMCP) in dosage formulations to form succinamide and phthalamide impurities, respectively. The rate of formation of the impurities is accelerated by heat and humidity. The structures were deduced using molecular weights obtained from LC-MS experiments and confirmed by comparison of UV spectra, HPLC retention times, and electrospray mass spectra to independently synthesized material. It is proposed that polymer-bound succinic and phthalic substituents can be cleaved from the polymer, resulting in the formation of either the free acids or the anhydrides. It is postulated that the reaction is enabled by migration of either (1) the free acid or anhydride or (2) the parent drug through the formulation. The formation of these impurities was minimized by increasing the thickness of the physical barrier separating the enteric coating from the drug.

Topics: Adrenergic Uptake Inhibitors; Chromatography, High Pressure Liquid; Drug Contamination; Drug Stability; Duloxetine Hydrochloride; Methylcellulose; Selective Serotonin Reuptake Inhibitors; Spectrophotometry, Ultraviolet; Tablets, Enteric-Coated; Thiophenes

This study was undertaken to develop a sustained-release formulation of tiaramide (TAM), a non-steroidal anti-inflammatory drug with a short half-life, using alginate of different chemical compositions. Alginate gel beads containing TAM were prepared using a gelation of alginate with calcium cations. Bead performance was evaluated in vitro for different dissolution media and beads were also subjected to coating. TAM release was dependent both on its solubility in dissolution medium and the guluronate residue content of the alginate used. The release rate was in the following order: in pH 1.2 > pH 6.8 > water. The fast release rate in pH 1.2 is the result of the high solubility of TAM in acidic medium. Beads based on alginate rich in guluronate residue had the lowest release rate, which can be attributed to the compact structure formed by guluronate residues through cooperative interaction with calcium ions. Alginate beads were administered to beagle dogs, and pharmacokinetic parameters (mean residence time [MRT], tmax, Cmax, and AUC) were calculated. In vivo results were in good agreement with in vitro dissolution characteristics. Beads with high guluronate content gave the best controlled results. In addition, coated beads showed a more satisfactory sustained-release pattern. Calcium alginate appears to be a potential carrier for controlling drug release rate, even for water-soluble drugs such as TAM.

Topics: Administration, Oral; Alginates; Animals; Anti-Inflammatory Agents, Non-Steroidal; Benzothiazoles; Delayed-Action Preparations; Dogs; Glucuronic Acid; Hexuronic Acids; Intestinal Absorption; Male; Methylcellulose; Piperazines

The products that are processed in aqueous form, such as Aqoat MF (suspension), Aquateric (pseudolatex), HP 55 (ammonia-based solution), and Kollicoat MAE 30 D (latex), were compared (in the form of spray dispersions, isolated films prepared from the dispersions, and caffeine-film-coated tablets with 5.5, 8.0, and 11.0 mg film/cm2) with one another and with ethanolic HP 55 S solution. The addition of pigments to all of the liquid preparations, with the exception of the ammoniacal solution of HP 55, led to a slight increase in pH. In each case, the viscosity of both solutions was well above that of the other formulations. The minimum film-forming temperature was decidedly reduced by the addition of pigment. Kollicoat MAE was the undissolved film-former that had the smallest particle size and particle size distribution. The next smallest were those of Aqoat MF. The latex and the suspension were the only products that were sensitive to shear and heat. The isolated films did not display any tack. The strongest films and the films most impermeable to water vapor were obtained from solutions, and this can be ascribed to the fine distribution of the film-former. None of the isolated films showed signs of dissolving at pH 4.5. At pH 5.5, only the HP 55 was dissolved. This was because HP 55 was processed in ammonia-based solution; as a result of which, films that were not very resistant to gastric juice were obtained. The other formulations did not dissolve until the pH reached 6.0. As the pH rose, the rate of dissolution increased for all of the films. The permeability to protons was similar to that of caffeine-film-coated tablets to gastric juice. The resistance increased in the following sequence: HP 55 (ammonia-based) < Aquateric < Aqoat MF < HP 55 S (organic) and Kollicoat MAE. As a result of the temperature treatment and the rate of spraying, the production time on a 5-kg scale was twice as long for 5.5 mg Aqoat MF/cm2 as it was for Kollicoat MAE. This amount of film sufficed for Kollicoat MAE and HP 55 S solution to achieve adequate resistance to gastric juice. Aqoat MF did not attain the same resistance until a thickness of 11 mg film/cm2 was reached. Film tablets with Aquateric and ammonia-based HP 55 solution absorbed more than 20% of gastric juice at this film thickness.

Topics: Aerosols; Caffeine; Cellulose; Excipients; Hardness; Hydrogen-Ion Concentration; Methylcellulose; Particle Size; Permeability; Polymethacrylic Acids; Polysaccharides; Tablets, Enteric-Coated; Viscosity

Serratia marcescens chitinase was immobilized by covalent binding to a polymer (hydroxypropyl methylcellulose acetate succinate, AS-L) showing reversibly soluble-insoluble characteristics with pH change. The immobilized enzyme (CH-AS) was soluble above pH 5.2 and insoluble below 4.5, which offers advantages in that it can carry out hydrolysis of chitin particles in a soluble form yet be recovered after precipitation at low pH. CH-AS has much higher activity than chitinase immobilized to a water-insoluble carrier. The effects of pH and temperature on the activity and stability of CH-AS, and the adsorption of CH-AS to chitin were studied and compared with those of free chitinase. Following repeated pH cycles between 6.6 and 4.5, CH-AS lost 30% of its enzyme activity during the first cycle due to protein release and enzyme denaturation, but substantially less activity was lost in the following cycles, with minimum enzyme denaturation. Chitin hydrolysis with CH-AS could be carried out in a semi-batch mode with intermittent enzyme precipitation and product removal, this can enhance product yield up to 1.4-fold when compared with batch reaction.

Topics: Acetylglucosamine; Adsorption; Chitin; Chitinases; Colloids; Enzymes, Immobilized; Hydrogen-Ion Concentration; Hydrolysis; Methylcellulose; Polymers; Protein Denaturation; Serratia marcescens; Solubility; Temperature

A spray method for the preparation of free films from aqueous polymeric dispersions was investigated. Free films were prepared from aqueous dispersions of methacrylic acid-ethyl methacrylate copolymer (Eudragit L 30D), hydroxypropyl methylcellulose acetate succinate (HPMCAS), cellulose acetate phthalate (CAP), and ethyl cellulose (EC) by a spray method and a cast method, and their mechanical properties and reproducibility were investigated. Uniform films were obtained from the dispersions of Eudragit L 30D, HPMCAS, and EC by the spray method, but films could not be formed by spraying the CAP dispersion. The tensile strength, elongation, and elastic modulus of the sprayed Eudragit L 30D films were similar to the properties of the cast films, and good reproducibility was obtained from both methods. Marked within-run variation in the mechanical properties was observed for the cast HPMCAS and CAP films, which could be due to a settling of the solid particles during the drying step. The variation in the mechanical properties of the sprayed HPMCAS films was lower and the tensile strength significantly higher than that of the cast films. There were also significant differences in tensile strength and elongation of EC films between products of the two methods. The results indicated that the spray method used to prepare the free films from aqueous polymeric dispersions provided uniform films with consistent and reproducible properties.

Topics: Acrylic Resins; Cellulose; Chemistry, Pharmaceutical; Delayed-Action Preparations; Dosage Forms; Gels; Methylcellulose; Polymers; Polymethacrylic Acids; Reproducibility of Results; Surface Properties; Water

A controlled-release table of amoxicillin trihydrate was developed by use of a matrix formulation based on the enteric polymer hydroxypropyl methylcellulose acetate succinate (HPMCAS). Sustained drug release was shown by in vitro dissolution testing; the polymer could suppress drug release in the presence of gastric pH but could enhance drug release in the presence of small intestinal pH, compared with compacts of pure drug. Grinding or physical mixing of the drug with the polymer, an alteration in normal compaction pressure, or a substitution of other enteric polymers did not markedly affect drug release from compacts. Physicochemical testing of samples confirmed that the method of mixing did not alter powder morphology. An ethanolic granulation procedure was used in the production of final tablets (21 x 10 mm) containing amoxicillin (750 mg), HPMCAS, anhydrous directly compressible lactose, and lubricants. These large tablets showed a promising sustained-release effect in vitro when a variable-pH-shift dissolution procedure was used. However, single-dose studies with a panel of fasting subjects showed that the tablets had a relative bioavailability of only 64.4%. Other pharmacokinetic parameters confirmed a lack of therapeutic advantage of these tablets over an equivalent dose of conventional capsules.

Topics: Adult; Amoxicillin; Capsules; Delayed-Action Preparations; Drug Compounding; Excipients; Humans; Hydrogen-Ion Concentration; Male; Methylcellulose; Microscopy, Electron, Scanning; Powders; Solubility; Tablets; X-Ray Diffraction

Hydroxy propyl methyl cellulose acetate succinate high grade (AS-HG) and ethyl cellulose (EC) mixture microcapsules containing cefadroxil or theophylline were prepared by a solvent evaporation method in liquid paraffin dissolved sorbitan tri-stearate as a dispersing agent, and their sustained-release properties were evaluated. The microcapsules prepared with AS-HG:EC (in a 2:5 weight ratio) mixture containing 20% of cefadroxil or theophylline exhibited apparent zero-order releasing pattern in pH 6 to 8, at 50 rpm and 37 degrees C (paddle method). These microcapsules were administered orally to beagle dogs and the plasma concentrations of cefadroxil or theophylline were measured periodically. As a result of in vivo investigation, a satisfactory sustained-release plasma pattern and an apparent zero-order process in the gastrointestinal absorption were confirmed by deconvolution analysis of both drugs.

Topics: Administration, Oral; Animals; Cefadroxil; Cellulose; Delayed-Action Preparations; Dogs; Drug Compounding; Intestinal Absorption; Male; Methylcellulose; Theophylline

Extensive general pharmacological studies of hydroxypropylmethylcellulose acetate succinate (HPMCAS) were carried out in mice, rats, guinea pigs, rabbits, dogs and frogs. HPMCAS appeared to have no significant effect on the central nervous system, autonomic nervous system and cardiovascular system. Various biological analyses of the blood (including hemolysis and coagulation properties) and urine were unaffected, and the compound showed no significant local anesthetic or vascular permeability. At higher doses of HPMCAS, an increase in secretion of saliva in guinea pigs, a decrease in gastric juice secretion in rats and an increase in rectal temperature in rats were observed, but these effects did not show clear dose-dependence.

Topics: Animals; Autonomic Nervous System; Blood Chemical Analysis; Brain; Capillary Permeability; Digestive System; Dogs; Electrolytes; Guinea Pigs; Hemodynamics; Hemolysis; In Vitro Techniques; Male; Methylcellulose; Mice; Rabbits; Rats

The acute toxicity (in rabbits and rats) and the subchronic and chronic toxicities (in rats) of Hydroxypropylmethylcellulose acetate succinate (HPMCAS), a potentially useful pharmaceutical excipient, were investigated. 1) In the acute toxicity study (single oral dose of 2.5 g/kg), no deaths or behavioral abnormalities were observed. Thus, LD50 is higher than 2.5 g/kg. 2) In the subchronic toxicity study (0.63, 1.25 or 2.5 g/kg daily as a single oral dose in the morning, 6 days per week (not Sunday) for 2 months), no significant behavioral abnormality was observed. There was some decrease in body weight gain in rats of both sexes, but the effect was not statistically significant. 3)In the chronic toxicity study (1.25 or 2.5 g/kg daily as a single oral dose in the morning, 6 days per week (not Sunday) for 6 months), no significant behavioral abnormality was observed. There was some decrease in body weight gain in male rats, but it was not statistically significant. 4)Various biochemical and physiological abnormalities in rats were noted in all groups (including the control groups) in the toxicity studies, but there appeared to be no significant dose-related finding attributable to the administration of HPMCAS.

Topics: Administration, Oral; Animals; Body Weight; Eating; Female; Hematologic Tests; Kidney; Lethal Dose 50; Liver; Lung; Male; Methylcellulose; Myocardium; Rabbits; Rats; Spleen; Time Factors

A fertility study was carried out in Slc: SD rats orally administered Hydroxypropylmethylcellulose acetate succinate (HPMCAS), a useful pharmaceutical excipient, at dose levels of 625, 1,250 and 2,500 mg/kg/day. Male rats were treated with HPMCAS from 60 days before pairing until the completion of mating. Female rats received HPMCAS for 22 days, from 14 days prior to mating up to Day 7 of gestation. All pregnant females were sacrificed on Day 21 of gestation and all fetuses were examined for abnormalities. No abnormal signs were seen in mating or fertility in the rat treated with HPMCAS. No external, internal and skeletal anomalies attributable to HPMCAS were observed in the fetuses. It was concluded that HPMCAS had no harmful effect on mating, fertilization, implantation, or embryonic development.

Topics: Administration, Oral; Animals; Body Weight; Bone and Bones; Drinking; Eating; Embryo Implantation; Female; Fertility; Fetus; Male; Methylcellulose; Pregnancy; Rats; Rats, Inbred Strains

A teratogenicity study was carried out in S1c: SD rats orally administered Hydroxypropylmethylcellulose acetate succinate (HPMCAS), a useful pharmaceutical excipient, at dose levels of 625, 1,250 and 2,500 mg/kg/day for a period of 11 days from day 7 to day 17 of gestation. Two-thirds of the pregnant females in each group were sacrificed on Day 21 of gestation and their fetuses were examined. The remaining dams were allowed to litter naturally, and the postnatal development of the offsprings was observed. The incidences of external, internal, and skeletal anomalies were not significantly increased in the fetuses of any treated groups. HPMCAS caused no effects on parturition, lactation, postnatal growth and reproductive ability of the male and female offspring.

Topics: Abnormalities, Drug-Induced; Administration, Oral; Animals; Body Weight; Bone and Bones; Drinking; Eating; Female; Fetus; Hypromellose Derivatives; Male; Methylcellulose; Organ Size; Pregnancy; Rats; Rats, Inbred Strains; Reproduction; Weaning

A teratological study was carried out in New Zealand White rabbits in order to examine the teratogenic potentiality of HPMCAS, a useful pharmaceutical excipient. HPMCAS was orally administered at dose levels of 625, 1,250 and 2,500 mg/kg/day for a period of 13 days from day 6 to day 18 of gestation. All pregnant females were sacrificed on day 29 of gestation and their fetuses were examined. The administration of HPMCAS during a period of organogenesis produced no embryotoxic and teratogenic effects as well as no influence on behavior, appearance and growth of animals.

Topics: Abnormalities, Drug-Induced; Administration, Oral; Animals; Body Weight; Bone and Bones; Drinking; Eating; Female; Fetus; Methylcellulose; Pregnancy; Rabbits

A perinatal and postnatal study was carried out in Slc: SD rats orally administered Hydroxypropylmethylcellulose acetate succinate (HPMCAS), a useful pharmaceutical excipient, at dose levels of 625, 1,250 and 2,500 mg/kg/day for a period from day 17 of gestation to day 21 after delivery. All pregnant rats were allowed to litter naturally, and the postnatal development of the offsprings was observed. In the administered group of 2500 mg/kg, the liver weight was significantly increased in males and showed a tendency to increase in females as compared with control. No significant differences between the control group and the administered groups were found in postnatal growth and differentiation, behavior and reproductive ability of male and female offsprings.

Topics: Administration, Oral; Animals; Animals, Newborn; Body Weight; Bone Development; Drinking; Eating; Female; Fetus; Male; Methylcellulose; Organ Size; Pregnancy; Rats; Rats, Inbred Strains; Reproduction