coenzyme-q10 and cetyl-palmitate

Solid lipid nanoparticles (SLNs) of coenzyme Q10 (CoQ10) were formulated by a high-pressure homogenization method. The best formulation of SLN dispersion consisted of 13% lipid (cetyl palmitate or stearic acid), 8% surfactant (Tween 80 or Tego Care 450), and water. Stability tests, particle size analysis, differential scanning calorimetry, transmission electron microscopy, and release study were conducted to find the best formulation. A simple cream of CoQ10 and a cream containing CoQ10-loaded SLNs were prepared and compared on volunteers aged 20-30 years. SLNs with particle size between 50 nm and100 nm exhibited the most suitable stability. In vitro release profiles of CoQ10 from simple cream, SLN alone, and CoQ10-loaded SLN cream showed prolonged release for SLNs compared with the simple cream, whereas there was no significant difference between SLN alone and SLN in cream. In vitro release studies also demonstrated that CoQ10-loaded SLN and SLN cream possessed a biphasic release pattern in comparison with simple cream. In vivo skin hydration and elasticity studies on 25 volunteers suggested good dermal penetration and useful activity of Q10 on skin as a hydratant and antiwrinkle cream.

Topics: Calorimetry, Differential Scanning; Drug Stability; Female; Humans; Hydrogen-Ion Concentration; Nanoparticles; Palmitates; Particle Size; Polysorbates; Skin; Statistics, Nonparametric; Stearic Acids; Ubiquinone; Young Adult

In the present study, nanostructured lipid carriers (NLC) composed of cetyl palmitate with various amounts of caprylic/capric triacylglycerols (as liquid lipid) were prepared and Coenzyme Q(10) (Q(10)) has been incorporated in such carriers due to its high lipophilic character. A nanoemulsion composed solely of liquid lipid was prepared for comparison studies. By photon correlation spectroscopy a mean particle size in the range of 180-240nm with a narrow polydispersity index (PI) lower than 0.2 was obtained for all developed formulations. The entrapment efficiency was 100% in all cases. The increase of oil loading did not affect the mean particle size of NLC formulations. NLC and nanoemulsion, stabilized by the same emulsifier, showed zeta potential values in the range -40/-50mV providing a good physical stability of the formulations. Scanning electron microscopy studies revealed NLC of disc-like shape. With respect to lipid polymorphism, a decrease in the ordered structure of NLC was observed with the increase of both oil and Q(10) loadings, allowing therefore high accommodation for Q(10) within the NLC. Using static Franz diffusion cells, the in vitro release studies demonstrated that Q(10)-loaded NLC possessed a biphasic release pattern, in comparison to Q(10)-loaded nanoemulsions comprising similar composition of which a nearly constant release was observed. The NLC release patterns were defined by an initial fast release in comparison to the release of NE followed by a prolonged release, which was dependent on the oil content.

Topics: Administration, Topical; Calorimetry, Differential Scanning; Caprylates; Chemical Phenomena; Chemistry, Physical; Coenzymes; Crystallization; Decanoic Acids; Drug Carriers; Drug Compounding; Electrochemistry; Emulsions; Excipients; Liposomes; Microscopy, Electron, Scanning; Nanoparticles; Oils; Palmitates; Particle Size; Solubility; Ubiquinone; X-Ray Diffraction