phenanthrenes and Hyperlipidemias

Danshen, the dried root of Salvia miltiorrhiza, has been widely used in China and, to a lesser extent, in Japan, the United States, and other European countries for the treatment of cardiovascular and cerebrovascular diseases. In China, the specific clinical use is angina pectoris, hyperlipidemia, and acute ischemic stroke. The current review covers its traditional uses, chemical constituents, pharmacological activities, pharmacokinetics, clinical applications, and potential herb-drug interactions based on information obtained in both the English and Chinese literature. Although numerous clinical trials have demonstrated that certain Danshen products in China are effective and safe for the treatment of cardiovascular diseases, most of these lack sufficient quality. Therefore, large randomized clinical trials and further scientific research to determine its mechanism of actions will be necessary to ensure the safety, effectiveness, and better understanding of its action.

Topics: Abietanes; Angina Pectoris; Animals; Benzofurans; Drugs, Chinese Herbal; Fibrinolytic Agents; Herb-Drug Interactions; Humans; Hyperlipidemias; Lactates; Phenanthrenes; Phenanthrolines; Plant Extracts; Randomized Controlled Trials as Topic; Salvia miltiorrhiza; Stroke

Experimental hyperlipidemia has shown to decrease cytochrome P450 3A4 and 2C11 expression and to increase liver concentrations and the plasma protein binding of halofantrine (HF) enantiomers. The present study examined the effect of hyperlipidemic (HL) serum on the metabolism of HF enantiomers by primary rat hepatocytes. Hepatocytes from normolipidemic (NL) and HL (poloxamer 407 treated) rats were incubated with rac-HF in cell media with or without additional rat serum (5%). In those incubations with rat serum, the hepatocytes were preincubated or coincubated with serum from NL or HL rats. Rat serum-free hepatocyte incubations served as controls. Stereospecific assays were used to measure HF and desbutylhalofantrine (its major metabolite) enantiomer concentrations in whole well contents (cells + media). Concentrations of desbutylhalofantrine were not measurable. The disappearance (apparent metabolism) of (-)-HF exceeded that of antipode, but HF metabolism did not differ between hepatocytes from NL and HL rats. Coincubation of HL rat serum with NL hepatocytes caused a significant decrease in the disappearance of (-)-HF, whereas in HL hepatocytes, a substantially decreased apparent metabolism was noted for both enantiomers. Compared with NL serum, (-)-HF disappearance was significantly lowered upon preincubation of NL hepatocytes with HL serum. A combination of factors including diminished drug metabolizing or lipoprotein receptor expression, and increased plasma protein binding in the wells, may have contributed to a decrease in apparent metabolism of the HF enantiomers in the presence of lipoproteins from HL rat serum.

Topics: Animals; Antimalarials; Hepatocytes; Hyperlipidemias; Lipoproteins; Phenanthrenes; Rats; Rats, Sprague-Dawley; Stereoisomerism

Halofantrine can cause a prolongation of the cardiac QT interval, leading to serious ventricular arrhythmias. Hyperlipidaemia elevates plasma concentration of halofantrine and may influence its tissue uptake. The present study examined the effect of experimental hyperlipidaemia on QT interval prolongation induced by halofantrine in rats.. Normolipidaemic and hyperlipidaemic rats (induced with poloxamer 407) were given 4 doses of halofantrine (i.v., 4-40 mg·kg(-1)·d(-1)) or vehicle every 12 h. Under brief anaesthesia, ECGs were recorded before administration of the vehicle or drug and 12 h after the first and last doses. Blood samples were taken at the same time after the first and last dose of halofantrine. Hearts were also collected 12 h after the last dose. Plasma and heart samples were assayed for drug and desbutylhalofantrine using a stereospecific method.. In the vehicle group, hyperlipidaemia by itself did not affect the ECG. Compared to baseline, QT intervals were significantly higher in both normolipidaemic and hyperlipidaemic rats after halofantrine. In hyperlipidaemic rats, plasma but not heart concentrations of the halofantrine enantiomers were significantly higher compared to those in normolipidaemic rats. Despite the lack of difference in the concentrations of halofantrine in heart, QT intervals were significantly higher in hyperlipidaemic compared to those in normolipidaemic rats.. The unbound fraction of halofantrine appeared to be the controlling factor for drug uptake by the heart. Our data suggested a greater vulnerability to halofantrine-induced QT interval prolongation in the hyperlipidaemic state.

Topics: Animals; Dose-Response Relationship, Drug; Drug Administration Schedule; Electrocardiography; Hyperlipidemias; Long QT Syndrome; Male; Phenanthrenes; Rats; Rats, Sprague-Dawley

The effect of hyperlipidemia on the biodistribution of (+/-)-halofantrine (HF) was studied in rats. Plasma, adipose, and highly perfused tissues heart, lung, liver, kidney, spleen and brain were harvested for up to 48 h after dosing animals with 2 mg/kg (+/-)-HF intravenously by tail vein. Stereospecific HPLC was used to measure HF and desbutyl-HF (DHF) enantiomer concentrations. Plasma concentrations of both HF enantiomers in hyperlipidemic (HL) exceeded those in normolipidemic (NL) rats by 11- to 15-fold. Significant increases in AUC of both HF enantiomers were noted in HL spleen tissue whereas decreases were seen in HL lung and fat. In rest of the tissues either decreases or no changes were noted in HL. The concentrations of DHF were very low in NL and HL plasma but were much higher in all highly perfused tissues. Both HF and DHF enantiomers shifted from lipoprotein deficient fraction to triglyceride-rich fractions in HL plasma following in vitro incubation of the respective racemic compounds. Compared to NL, no significant differences were noted in HF metabolism to DHF in HL liver microsomes. It would appear that both reduced plasma unbound fraction and lipoprotein associated directed uptake of lipoprotein-bound drug by tissues play roles in enantiomer biodistribution.

Topics: Animals; Antimalarials; Hyperlipidemias; Lipoproteins; Male; Microsomes, Liver; Phenanthrenes; Protein Binding; Rats; Rats, Sprague-Dawley; Stereoisomerism

To investigate the synergistic effect of salvianolic acids (Sals) and tanshinones (Tans), to compare the pharmacodynamic effect of Danshen co-microemulsion, salvianolic acids microemulsion, tanshinones microemulsion, tanshinones suspension and blank microemulsion on hemorheology in rats with hyperlipidemia.. Fat milk was administered to SD rats in the morning for 23 days, and drugs were given in the afternoon since the 13th day. On the 14th day, the blood viscosity, haematocrit and platelet aggregation were determined.. Both Tans and Sals could inhibit the platelet aggregation, and decrease the blood viscosity. The effect of Sals on the decrease of blood viscosity was much more significant than that of other groups. And Tans could significantly inhibit the platelet aggregation than others. Compared to Tans or Sals used separately, co-administration of Tans and Sals at the same time could decrease the blood viscosity and inhibit the platelet aggregation significantly.. As a new drug carrier, the microemulsion system can increase tanshinone solubility dramatically and improve its bioavailability. And co-mecroemulsion of Tans and Sals can produce the synergy of Tans and Sals preferably and are much more efficient than either Tans microemulsion or Sals microemulsion used alone.

Topics: Abietanes; Animals; Blood Viscosity; Caffeic Acids; Cholesterol; Drug Carriers; Drug Synergism; Drugs, Chinese Herbal; Emulsions; Hyperlipidemias; Lactates; Male; Phenanthrenes; Platelet Aggregation; Random Allocation; Rats; Rats, Sprague-Dawley; Salvia miltiorrhiza; Triglycerides

The objective of this study was to determine the effect of lipids on the pharmacokinetics of halofantrine enantiomers. Rats were given (+/-)-halofantrine HCl 2 mg/kg i.v., or 7 mg/kg orally. Some rats were rendered hyperlipidemic by intraperitoneal administration of poloxamer 407 1 g/kg, followed by (+/-)-halofantrine HCl intravenously. In other normolipidemic rats, (+/-)-halofantrine was administered under fasted conditions, or after peanut oil given orally. Halofantrine enantiomer plasma concentrations were considerably (>10-fold) increased in hyperlipidemia. Decreases were noted in the clearance, volume of distribution and the unbound fraction in plasma of the hyperlipidemic rats. Peanut oil caused a significant 28% reduction in clearance of the (-), but not the (+) enantiomer (mean clearance reduced 11%) of halofantrine. After oral halofantrine, peanut oil resulted in a two- to threefold increase in the plasma area under the curves of halofantrine enantiomers. Halofantrine enantiomer pharmacokinetics are highly dependent upon plasma lipid concentrations. Oral lipids may result in a stereoselective interaction at the level of clearance. Because lipids may affect clearance of drugs that bind to lipoproteins, in determining bioavailability of such drugs in food-effect studies, reference intravenous groups should be included to separate true increase in bioavailability from the effects of decreased clearance.

Topics: Administration, Oral; Animals; Antimalarials; Area Under Curve; Biological Availability; Blood Proteins; Cholesterol; Chromatography, High Pressure Liquid; Dietary Fats; Food-Drug Interactions; Hyperlipidemias; Injections, Intravenous; Lipid Metabolism; Lipids; Lipoproteins; Male; Peanut Oil; Phenanthrenes; Plant Oils; Poloxamer; Protein Binding; Rats; Rats, Sprague-Dawley; Stereoisomerism; Triglycerides

The purpose of these studies was to determine the distribution of a lipophilic antimalarial agent, halofantrine hydrochloride (Hf), in fasted plasma from hypo-, normo-, and hyperlipidemic patients that displayed differences in lipoprotein concentration and lipid transfer protein I (LTP I) activity. To assess the influence of modified lipoprotein concentrations and LTP I activity on the plasma distribution of Hf, Hf at a concentration of 1000 ng/mL was incubated in either hypo-, normo-, or hyperlipidemic human plasma for 1 h at 37 degreesC. Following incubation, the plasma samples were separated into their lipoprotein and lipoprotein-deficient plasma (LPDP) fractions by density gradient ultracentrifugation and assayed for Hf by high-pressure liquid chromatography. The activity of LTP I in the dyslipidemic plasma samples was determined in terms of its ability to transfer cholesteryl ester from low-density lipoproteins (LDL) to high-density lipoproteins (HDL). Total plasma and lipoprotein cholesterol (esterified and unesterified), triglyceride, and protein levels in the dyslipidemic plasma samples were determined by enzymatic assays. When Hf was incubated in normolipidemic plasma for 1 h at 37 degreesC, the majority of drug was found in the LPDP fraction. When Hf was incubated in human plasma of varying total lipid, lipoprotein lipid, and protein concentrations and LTP I activity, the following relationships were observed. As the triglyceride-rich lipoprotein (TRL) lipid and protein concentration increased from hypolipidemia through to hyperlipidemia, the proportion of Hf associated with TRL increased (r > 0.90). As the HDL lipid and protein concentration increased, the proportion of Hf associated with HDL decreased (r > 0.70). As the total and lipoprotein lipid levels increased, the LTP I activity of the plasma also proportionally increased (r > 0.85). Furthermore, with the increase in LTP I activity, the proportion of Hf associated with the TRL fraction increased (r > 0.70) and the proportion of Hf associated with the HDL fraction decreased (r > 0.80). In addition, a positive correlation between the proportion of apolar lipid and Hf recovered within each lipoprotein fraction was observed within hypo- (r > 0.80), normo- (r = 0.70), and hyperlipidemic (r > 0.90) plasmas. These findings suggest that changes in the HDL and TRL lipid and protein concentrations, LTP I activity, and the proportion of apolar lipid within each lipoprotein fraction may influence the

Topics: Antimalarials; Carrier Proteins; Cholesterol Ester Transfer Proteins; Chromatography, High Pressure Liquid; Glycoproteins; Humans; Hyperlipidemias; In Vitro Techniques; Lipids; Lipoproteins; Lipoproteins, HDL; Lipoproteins, LDL; Phenanthrenes; Triglycerides