Thymoquinone (THQ), the active constituent of Nigella sativa seeds, has demonstrated some potential pharmacological activities. The present study was designed to investigate the pharmacokinetic behavior of THQ following intravenous (IV) and oral (PO) administration using an animal model. THQ was given vascularly (5 mg/kg IV) and extravascularly (20 mg/kg PO) to Vole rabbits, and blood samples were collected at predetermined time points. The concentrations of THQ in plasma were measured by a high-performance liquid chromatography, and the pharmacokinetic parameters were determined using both compartmental and non-compartmental analyses. The calculated clearance (CL) following IV administration was 7.19 ± 0.83 ml/kg/min, and the estimated volume of distribution at steady state (V ss) was 700.90 ± 55.01 ml/kg. Whereas with PO dosing, apparent CL/F value was 12.30 ± 0.30 ml/min/kg and V ss/F was 5,109.46 ± 196.08 ml/kg. These parameters were associated with an elimination half-life (T 1/2) of 63.43 ± 10.69 and 274.61 ± 8.48 min with IV and PO dosing, respectively. The calculated absorption T 1/2 was about 217 min. Compartmental analysis revealed T 1/2α of ~8.9 min and T 1/2β of ~86.6 min. The calculated absolute bioavailability of THQ was ~58 % with a lag time of ~23 min. The estimated THQ protein binding was >99 %. Therefore, THQ represents a compound with rapid elimination and relatively slower absorption following PO administration.
Glibenclamide and thymoquinone plasma concentrations were analysed using a sensitive RP-HPLC method, and non-compartmental model pharmacokinetic parameters were calculated. The maximum reduction in blood glucose level was observed 3 hours following glibenclamide administration, which reached 47.4% of baseline, whereas it was reduced by 53.0% to 56.2% when co-administrated with thymoquinone. Plasma concentration of glibenclamide was increased by 13.4% and 21.8% by the co-administration of thymoquinone as single and multiple doses, respectively (P<0.05). The AUC and T1/2 of glibenclamide were also increased respectively by 32.0% and 17.4% with a thymoquinone single dose, and by 52.5% and 92.8% after chronic treatment. Furthermore, diabetic rats treated with thymoquinone demonstrated a marked decrease in hepatic protein expressions of CYP3A2 and CYP2C11 enzymes that are responsible for the metabolism of glibenclamide. The current data suggest that thymoquinone exhibits a synergistic effect with glibenclamide on glucose level, which could be explained by reducing CYP450 activity at the protein level.
The endothelium, a highly active structure, regulates vascular homeostasis through the release of numerous vasoactive factors that control vascular tone and vascular smooth cell proliferation. A larger number of medicinal plants and their isolated chemical constituents have been shown to beneficially affect the endothelium. For example, flavonoids in black tea, green tea, and concord grape cause a vasodilation possibly through their antioxidant properties. Allicin, a by-product of the enzyme alliinase, has been proposed to be the main active metabolite and responsible for most of the biological activities of garlic, including a dose-dependent dilation on the isolated coronaries. Thymoquinone, the principal phytochemical compound found in the volatile oil of the black seed, and the hawthorn extract have also been shown to improve aging-related impairment of endothelium-dependent relaxations in animal models. In this review, the effect of some of the natural products, including Camellia sinensis (black tea and green tea), Vitis labrusca (concord grape), Allium sativum (garlic), and Nigella sativa (black seed) and Crataegus ssp (hawthorn extract), is explored. The molecular mechanisms behind these potential therapeutic effects are also discussed.
The present work was designed to evaluate the effect of some commonly used herbs viz. garden cress (Lepidium sativum), black seed (Nigella sativa) and fenugreek (Trigonella foenum-graceum) on the disposition of phenytoin after oral administration in a dog model. Phenytoin was given orally at a dose of 50 mg, and blood samples were obtained for the determination of drug's pharmacokinetic parameters. After a suitable washout period, animals were commenced on a specific herb treatment for one week. Garden cress treatment caused a modest increase in maximum observed concentration (Cmax ) and terminal half-life (T1/2λ ) of phenytoin with a reduction in clearance by 33%. The effect of black seed therapy was more drastic on drug elimination and to a lesser extent on its volume of distribution at steady state (Vss ) with a consequent reduction in systemic exposure measured by area under the curve (AUC0-∞ ) by about 87%. The effect of fenugreek therapy resembled, albeit to a lesser extent, that of black seed with a significant reduction in AUC0-∞ by ~72%. In addition, there was a 73% increase in Vss . Our findings suggest that the phenytoin disposition can be significantly altered by the concurrent consumption of tested herbal products.
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