HPLC/MS法研究左旋黄皮酰胺及其代谢物在Beagle犬血浆中的药代动力学HPLC/MS法研究左旋黄皮酰胺及其代谢物在Beagle犬血浆中的药代动力学

目的用HPLC/MS法研究左旋黄皮酰胺［(-)-clau］及其代谢物6-羟基-黄皮酰胺(6-OH-clau)在Beagle犬血浆中的药代动力学过程。方法Beagle犬灌胃左旋黄皮酰胺30 mg·kg^-1，采集静脉血样，血浆经乙酸乙酯萃取分离后，用HPLC/MS选择性正离子检测内标(格列吡嗪，［M+H］⁺，m/z 446)法测定左旋黄皮酰胺(［M+H］⁺，m/z 298)及6-羟基-黄皮酰胺(［M+H-H₂O］⁺，m/z 296)的浓度，以甲醇-水-冰醋酸(60∶40∶0.8)为流动相，流速1.0 mL·min^-1。用3P97软件计算药代动力学参数。结果左旋黄皮酰胺和6-羟基-黄皮酰胺分别在1.0～200 ng·mL^-1和0.2～40.0 ng·mL^-1线性关系良好(r>0.999)，萃取回收率均大于85%。原药及其代谢物的体内过程均符合二室模型；左旋黄皮酰胺及6-羟基-黄皮酰胺的C_max分别为(21±10) ng·mL^-1和(3.9±2.2) ng·mL^-1；T_max分别为(0.8±0.5) h和(1.3±0.5) h；T_1/2α分别为(0.9±0.6) h和(1.4±0.6) h；T_1/2β分别为(19±23) h和(13±12) h；AUC_{0-24 h}分别为(69±14) h·ng·mL^-1和(12±7) h·ng·mL^-1。结论Beagle犬灌胃左旋黄皮酰胺后迅速吸收，血药浓度一相消除很快，但末端消除较慢；其代谢物6-羟基-黄皮酰胺血药浓度经时过程与左旋黄皮酰胺相似，但血药浓度相对较小。

Pharmacokinetics of (-)-clausenamide and its major metabolite 6-hydroxyl-clausenamide in Beagle dogs by HPLC/MS

To establish a sensitive and accurate method to study the pharmacokinetics of (-)-clausenamide (-)-clau] and its major metabolite 6-hydroxyl-clausenamide (6-OH-clau) in the plasma of the Beagle dog. METHODS: (-)-Clau was orally administered to six Beagle dogs at the dose of 30 mg x kg(-1), venous blood from front leg was sampled and plasma was separated for analysis. After extraction with ethyl acetate, the plasma samples were analyzed by HPLC/MS and the mobile phase was a mixture of methanol-water-acetic acid (60: 40: 0. 8) at the flow rate of 1.0 mL x min(-1). The API-ES positive ion SIM detection was carried out for the detection of both (-)-clau (M + H] (+), m/z 298 ) and 6-OH-clau (M + H - H2 O](+), m/z 296) with glipzide (glip) (M + H](+), m/z 446) as internal standard. The pharmacokinetic parameters were calculated by 3P97 software. RESULTS: There was good linear relationship ( r > 0. 999) between the SIM responses and the concentrations for (-)-clau and 6-OH-clau at the range from 1.0 to 200 ng x mL(-1) and 0.2 to 40.0 ng x mL(-1), respectively. The absolute recovery was greater than 85%. The plasma concentration-time curves of (-)-clau and 6-OH-clau were both best fitted to a two-compartment model. The C(max) of (-)-clau and 6-OH-clau were (21 +/- 10) ng x mL(-1) and (3.9 +/- 2.2) ng x mL(-1), T(max) were (0.8 +/- 0.5) h and (1.3 +/- 0.5) h, T 1/2 alpha were (0.9 +/- 0.6) hand (1.4 +/- 0.6) h, T 1/2 beta were (19 +/- 23) hand (13 +/- 12) h, AUC(0-24 h) were (69 +/- 14) h x ng x mL(-1) and (12 +/- 7) h x ng x mL(-1) respectively. CONCLUSION: The established HPLC/MS method was sensitive and specific for the determination of (-)-clau. It was shown that the absorption and first phase elimination of (-)-clau were very quick in Beagle dogs, but the terminal elimination was very slow. The plasma concentration profile of its major metabolite 6-OH-clau was similar to (-)-clau and the AUC was relatively small in comparison with (-)-clau.