水飞蓟宾在大鼠小肠中的吸收特性

目的考察水飞蓟宾在大鼠各肠段的吸收。方法以一定浓度的水飞蓟宾溶液作为灌流液，以0.1 mL·min^-1进行大鼠不同肠段的单向灌流,于不同时间收集肠灌流液并肝门静脉取血，分别用HPLC测定灌流液和血中药物浓度。结果实验结果表明190 μg·mL^-1水飞蓟宾在不同肠段的吸收速率常数(k_a)和有效透过系数(P_eff)是十二指肠>空肠>回肠>结肠。质量浓度为80 μg·mL^-1的水飞蓟宾灌流液在十二指肠的吸收与190和300 μg·mL^-1的吸收情况均有显著性差异(P<0.05)，但质量浓度为190 μg·mL^-1与300 μg·mL^-1的吸收之间无显著性差异(P>0.05)。肝门静脉血中药物分析也显示十二指肠>空肠>回肠>结肠。结论水飞蓟宾在小肠全肠道均有吸收且有高浓度饱和现象。     

家犬单剂量和多剂量口服阿昔莫司缓释制剂的药代动力学和生物等效性研究

目的研究阿昔莫司缓释片在家犬体内单剂量和多剂量的药代动力学和生物等效性。方法测定6只家犬单剂量和多剂量口服缓释片和普通胶囊后的血药浓度。结果阿昔莫司的药-时曲线符合非隔室模型。单剂量给药后，缓释片和普通胶囊的AUC分别为(158±30)和(147±37) μg·h·mL^-1；T_max分别为(4.3±0.8)和(2.6±1.3) h；C_max分别为(29±6)和(42±10) μg·mL^-1；T_1/2分别为(2.3±0.7)和(1.60±0.10) h；MRT分别为(6.0±0.8)和(3.9±0.7) h；F_r为(108±16)%。多剂量给药后，缓释片和普通胶囊的AUC分别为(209±23)和(195±26) μg·h·mL^-1；T_max分别为(6.3±0.8)和(3.4±1.5) h；C_max分别为(27±4)和(36±5) μg·mL^-1；Cmin分别为(2.2±1.0)和(0.20±0.20) μg·mL^-1；C_av分别为(8.7±1.0)和(8.1±1.1) μg·mL^-1；FI分别为(293±73)%和(448±91)%；F_r为(114±19)%。结论单剂量实验的双单侧检验结果表明：缓释片和普通胶囊生物等效；缓释片具有良好的缓释效果。多剂量实验结果表明：缓释片和普通胶囊生物等效；缓释片的波动系数优于普通胶囊。     

番茄红素脂质体的体外释放及大鼠体内药代动力学和抗氧化功能

利用旋转薄膜-超声法制备了番茄红素脂质体并研究其体外释放，大鼠体内药代动力学和对机体抗氧化能力的影响。用液相色谱法测定大鼠体内的番茄红素含量，所得数据进行3P97程序处理，得到各主要药代动力学参数；配制人工胃液和肠液，比较番茄红素油和番茄红素脂质体的体外释放效果；番茄红素油和番茄红素脂质体灌胃后，用试剂盒测定大鼠血清和肝组织匀浆中的超氧化物歧化酶活性、丙二醛、总抗氧化能力、过氧化氢酶及谷胱甘肽过氧化酶的含量。结果显示，脂质体体外释放呈肠溶性；番茄红素油及番茄红素脂质体的T_max分别为4.45和7.45 h；C_max为0.473和0.654 μg·mL^-1；AUC分别为12.38和21.67 μg·h·mL^-1。抗氧化指标测定结果表明：番茄红素脂质体比番茄红素油显著地提高机体内抗氧化酶的活力，抑制脂质过氧化。     

番茄红素微囊的体内外药剂学行为

目的考察番茄红素微囊的体外释放、番茄红素原料及番茄红素微囊在家犬体内的药代动力学、体外释放和体内吸收的相关性。方法用分光光度法测定释放介质中番茄红素的含量。用HPLC法测定家犬体内的番茄红素含量，数据用3P87程序处理，得到各主要药代动力学参数。体内吸收与体外释放进行点点相关。结果微囊体外释放呈肠溶性，原料及番茄红素微囊的T_1/2α分别为7.30和15.06 h；T_1/2β分别为28.10和46.76 h；T_max分别为22.32和41.03 h；AUC_0-∞分别为1.67和2.08 μg·h·L^-1。体内外相关性良好。结论微囊较原料药呈现缓释特征，体内外相关性结果表明可以根据体外释放情况预测体内的吸收。     

高效液相色谱法测定人血清和尿中盐酸青藤碱浓度及药代动力学研究

用RP-HPLC法,以三唑仑为内标,反相C₁₈为分析柱,乙腈—0.01mol·L^-1磷酸二氢钠—四甲基乙二胺(46∶54∶0.22v/v)为流动相,磷酸调至pH6.9,检测波长263nm,测定血清和尿中盐酸青藤碱浓度,线性范围分别为6～480ng·mL^-1和0.06～3μg·mL^-1,平均回收率75.88%和91.35%,日内日间误差小于5%,最低检测浓度血清4ng·mL^-1,尿40ng·mL^-1。8名健康男性志愿者单次口服盐酸青藤碱片80mg,测定血清及尿浓度,该药符合二室开放模型,体内消除符合一级动力学消除过程,主要药代动力学参数:T_1/2α0.791±0.491h,T_1/2β9.397±2.425h,T_{max 1.040±0.274h,Cmax246.604±71.165ng·mL^-1,AUC 2651.158±1039.050ng·h·mL^-1,CL 0.033±0.01ng·mL^-1。}     

诺氟沙星注射剂和胶囊剂的人体药代动力学

目的：考察自制的肌注诺氟沙星注射剂在体内的动态行为,并与诺氟沙星胶囊剂进行比较。方法：用HPLC法测定这两种制剂在人体的血药浓度,并用非线性最小二乘法迭代程序进行数据处理。结果：注射剂在体内的过程可用开放型二室模型描述,其主要体内参数为：AUC=5.84 h.μg.mL^-1,T_max=0.35 h,C_max=1.14 μg.mL^-1,MRT=7.32 h;而胶囊剂则符合一室模型,主要体内参数为：AUC=4.29 h.μg.mL^-1,T_max=1.28 h,C_max=0.72 μg.mL^-1,MRT=6.16 h。结论：注射剂较胶囊剂生物利用度高,起效快,峰浓度高,作用持久。     

间硝苯地平在Beagle犬体内的药代动力学

目的用反相高效液相色谱法研究间硝苯地平(m-nifedipine，m-Nif)在Beagle犬体内的药代动力学特征。方法正交设计优化色谱分离条件，Beagle犬分别iv给予m-Nif 0.288 mg·kg^-1和ig m-Nif 1.152，3.456，10.370 mg·kg^-1。用反相高效液相色谱法分析血浆中原型药物浓度，血浆药物浓度-时间数据用3P97药代动力学软件分析。结果Beagle犬iv m-Nif，其体内过程符合二室模型，T_1/2β为116.8 min；ig给予m-Nif 后在Beagle犬体内的代谢符合一室模型，其中低剂量(1.152 mg·kg^-1)组C_max为20 μg·L^-1， T_1/2(k_e)为147 min；中剂量(3.456 mg·kg^-1)组C_max为36 μg·L^-1，T_1/2(k_e) 为122 min；高剂量(10.37 mg·kg^-1)组C_max为69 μg·L^-1，T_1/2(k_e)为144 min。结论Beagle犬ig和iv m-Nif 后，血浆中药物消除迅速，口服绝对生物利用度较低。     

丙戊酸钠和丙戊酸镁在大鼠体内的药动学研究

目的 研究丙戊酸钠和丙戊酸镁在大鼠体内的药动学特征,评价其优势丙戊酸盐,为临床合理用药提供参考。方法 SD大鼠随机分为2组,分别灌胃给予丙戊酸钠片和丙戊酸镁片。于不同时间点眼眶取血。采用HPLC测定血清中丙戊酸的血药浓度,计算2种丙戊酸盐在大鼠体内的药动学参数,并比较2种丙戊酸盐之间的差异。结果 HPLC测定丙戊酸血药浓度方法专属性好,血清丙戊酸浓度在10.00~110.00 μg·mL^-1内线性关系良好。精密度、稳定性和回收率均符合要求。丙戊酸钠和丙戊酸镁在大鼠体内的主要药动学参数：T_1/2分别为（14.02±3.86） h和（12.11±1.95） h;T_max分别为（3.67±0.58） h和（2.67±0.26） h;C_max分别为（67.10±10.87）μg·mL^-1和（75.67±12.94）μg·mL^-1;AUC_（0-t）分别为（969.86±72.08）μg·mL^-1·h和（1 093.56±48.69）μg·mL^-1·h;AUC_（0-∞）分别为（1 178.10±185.29）μg·mL^-1·h和（1 279.35±109.18）μg·mL^-1·h;MRT_0-t分别为（10.73±2.05） h和（13.06±3.24） h。V_d分别为（16.31±2.18） L和（23.47±2.19） L;CL分别为（0.056 3±0.009） L·h^-1和（0.051 1±0.004） L·h^-1。结论 与丙戊酸钠相比,丙戊酸镁在大鼠体内的药动学参数具有一定的优势,可能是一种更具有治疗优势的丙戊酸盐。     

普罗布考包合物胶囊在家犬体内的药代动力学与相对生物利用度

目的研究普罗布考包合物胶囊在家犬体内的药代动力学与相对生物利用度。方法用高效液相色谱法测定6条健康犬po 250 mg普罗布考片(制剂A)或普罗布考包合物胶囊(制剂B)后不同时间血浆中活性药物的浓度,绘制药-时曲线,计算药代动力学参数及相对生物利用度。结果制剂A和制剂B的药-时曲线符合二室模型,其T_max均为(9.3±2.1) h,C_max分别为(1.5±1.0) μg·mL^-1和(2.3±0.9) μg·mL^-1,AUC_0～240分别为(85±56) μg·h·mL^-1和(134±55) μg·h·mL^-1。以制剂A为参比,制剂B中普罗布考的相对生物利用度为(198±90)%,两种制剂的AUC_0～240有显著性差异(P<0.05)。结论初步分析认为,改善普罗布考的水溶性是提高普罗布考生物利用度的关键因素之一。     

十名志愿者口服维拉帕米缓释片药代动力学和心电图研究

对10名男性受试者单剂量po240mgVer缓释片药代动力学及心电图变化进行研究。血药浓度—时间数据用零级吸收过程的一室模型拟合,其药代动力学参数:T_max5.9±1.6h;C_max118.9±37.2μg·L^-1;T₁ 5.4±1.5h;k₀30.5±17.5μg·L^-1·h^-1;T_1/210.8±4.9h。PR间期延长有显著意义,血药浓度与PR间期变化满足S 型模型,其药效学参数:EC₅₀ 64.6±16.9μg·L^-1; E_max54±11ms;s 1.68±0.66。     

The preparation of silybin-phospholipid complex and the study on its pharmacokinetics in rats

The aim of the present study was to find a way of prepare silybin-phospholipid complex to make oral bioavailability of silybin increase and to study its physicochemical properties and to compare the pharmacokinetic characteristics and bioavailability after oral administration of silybin-phospholipid complex and silybin-N-methylglucamine in rats. Using ethanol as a reaction medium, silybin and phospholipids were resolved into the medium, after the organic solvent was removed under vacuum condition, silybin-phospholipid complex was formed. The new complex's physicochemical properties including scanning electron microscopy (SEM), transmission electron microscopy (TEM), differential scanning calorimetry (DSC), solubility, dissolution, etc., were tested. The concentrations of silybin after oral administration of silybin-phospholipid complex and silybin-N-methylglucamine at different time in rats were determined by RP-HPLC. The pharmacokinetic parameters were computed by software program 3p97. Our data showed that silybin and phospholipids in the silybin-phospholipid complex were combined by non-covalent-bond, not forming a new compound and the solubility of silybin-phospholipid complex in water and in n-octanol was effectively enhanced. We found that mean plasma concentration-time curve of silybin after oral administration of silybin-phospholipid complex and silybin-N-methylglucamine in rats was both in accordance with open single-compartment model with first-order absorption. Pharmacokinetic parameters of silybin in rats were Tmax 10 and 5 min; Cmax 126.72 and 104.29 ng ml(-1); AUC(0-infinity) 1020.33 and 235.81 ng ml(-1)h, respectively. The bioavailability of silybin in rats was increased remarkably after oral administration of silybin-phospholipid complex comparing to silybin-N-methylglucamine. This was mainly due to an impressive improvement of the lipophilic property of silybin-phospholipid complex and improvement of the biological effect of silybin.     

水飞蓟宾口服亚微乳剂的制备及大鼠体内药动学研究

目的:制备水飞蓟宾口服亚微乳并研究其在大鼠体内的药动学。方法:采用薄膜分散-探头超声法制备水飞蓟宾亚微乳。大鼠分别灌服水林佳(市售水飞蓟宾磷脂复合物胶囊)和水飞蓟宾亚微乳,于不同时间点取血,HPLC法测定血药浓度,采用DAS(Date Acquisition System)软件求算药动学参数。结果:水飞蓟宾亚微乳制剂的平均粒径为(155.9±2.2)nm,Zeta电位为-(29.62±0.03)mV,体外释放动力学符合Weibull方程;大鼠灌服水林佳和水飞蓟宾亚微乳后MRT分别为(1.73±0.03)h和(3.44±0.08)h,AUC0-∞分别为(1.83±0.38)mg·h·L-1和(4.72±0.48)mg·h·L-1。水飞蓟宾亚微乳的相对生物利用度为257.9%。结论:水飞蓟宾制成亚微乳制剂后延长了药物在体内的滞留时间,提高了药物的口服生物利用度。     

水飞蓟素前体脂质体的制备和大鼠药代动力学的研究水飞蓟素前体脂质体的制备和大鼠药代动力学的研究

目的为了提高水飞蓟素的口服生物利用度，研制水飞蓟素前体脂质体并对其理化性质进行考察；研究水飞蓟素前体脂质体的大鼠体内生物利用度。方法采用薄膜载体沉积法制备水飞蓟素前体脂质体，通过研究水合后脂质体的包封率、粒径、稳定性来考察其理化性质；将水飞蓟素前体脂质体在体外进行水合，再给予大鼠灌胃，用RP-HPLC法测定不同时间血浆中总的和游离的水飞蓟素的浓度，通过3P97程序计算药代动力学参数。结果用该法制得的前体脂质体包封率可达90%以上，平均粒径为238.8 nm，稳定性较好；药代动力学研究表明水飞蓟素脂质体在体内吸收较快，生物利用度较高。结论采用薄膜载体沉积法制备水飞蓟素前体脂质体，制备工艺简单，易于工业化生产；将水飞蓟素制备成前体脂质体提高了水飞蓟素的生物利用度。     

Pharmacokinetic studies on IdB 1016, a silybin- phosphatidylcholine complex, in healthy human subjects

IdB 1016 is a complex of silybin (the main active component of silymarin) and phosphatidylcholine, which in animal models shows greater oral bioavailability and therefore greater pharmacological activity compared with pure silybin and silymarin. In order to assess its pharmacokinetic profile in man, plasma silybin levels were determined after administration of single oral doses of IdB 1016 and silymarin (equivalent to 360 mg silybin) to 9 healthy volunteers. Although absorption was rapid with both preparations, the bioavailability of IdB 1016 was much greater than that of silymarin, as indicated by higher plasma silybin levels at all sampling times after intake of the complex. Regardless of the preparation used, the terminal half-life was relatively short (generally less than 4 h). In a subsequent study, 9 healthy volunteers received IdB 1016 (120 mg b.i.d., expressed as silybin equivalents) for 8 consecutive days. The plasma silybin level profiles and kinetic parameters on day 1 were similar to those determined on day 8. Most of the silybin present in the systemic circulation was in conjugated form. Less than 3% of the administered dose was accounted for by urinary recovery of free plus conjugated silybin, a significant proportion of the dose probably being excreted in the bile. It is concluded that complexation with phosphatidylcholine in IdB 1016 greatly increases the oral bioavailability of silybin, probably by facilitating its passage across the gastrointestinal mucosa.     

Comparative bioavailability of Silipide, a new flavanolignan complex, in rats.

The comparative pharmacokinetics of Silipide (IdB 1016, a silybin-phosphatidylcholine complex) and silybin were investigated by measuring unconjugated and total plasma silybin levels as well as total biliary and urinary silybin excretion in rats following administration of a single oral dose (200 mg/kg as silybin). Mean peak levels of unconjugated and total silybin after IdB 1016 were 8.17 and 74.23 micrograms/ml respectively. Mean AUC (0-6 h) values were 9.78 and 232.15 h.micrograms.ml-1 indicating that about 94% of the plasma silybin is present in a conjugated form. After administration of silybin, plasma levels of both unconjugated and total compound were under the analytical detection limit. Cumulative biliary (0-24 h) and urinary (0-72 h) excretion values after administration of IdB 1016 accounted for 3.73% and 3.26% of the administered dose, respectively. After silybin administration, the biliary and urinary excretion accounted for only 0.001% and 0.032% of the dose respectively. Our results indicate a superior bioavailability of silybin administered orally as IdB 1016. This was due mainly to an impressive increase in gastrointestinal absorption.     

Enhancement of oral bioavailability of the poorly water-soluble drug silybin by sodium cholate/ phospholipid-mixed micelles

Aim:

To evaluate a mixed micellar drug delivery system composed of sodium cholate and phospholipid for oral administration of silybin, a promising hepatoprotectants.

Methods:

The optimum formulation of sodium cholate/phospholipid-mixed micelles containing silybin was obtained based on the study of pseudo-ternary phase diagram. The dissolution of silybin-mixed micelles was investigated. The pharmacokinetic characteristics and bioavailability after oral administration of silybin-mixed micelles and silybin-N-methylglucamine were compared in dogs.

Results:

The mean particle size of prepared mixed micelles was 75.9±4.2 nm. The largest solubility of silybin was found to be 10.0±1.1 mg/mL in the optimum formulation of mixed micelles. The silybin-sodium cholate/phospholipid-mixed micelles showed a very slow release of silybin 17.5% (w/w) within 72 h in phosphate buffer (pH 7.4) and 15.6% (w/w) in HCl solution (pH 1.2). After oral administration to dogs, the relative bioavailability of mixed micelles versus silybin-N-methylglucamine in dogs was 252.0%.

Conclusion:

Sodium cholate/phospholipid-mixed micelles are promising carriers in orally delivery of silybin, considering their capability of enhancing bioavailability and large-scale production.     

Comparison of oral bioavailability of genistein and genistin in rats

Genistein (GT) is an isoflavone from Leguminosae and has received much attention as a phytoestrogen. Genistin is a glycoside form of GT (genistein-7-O-beta-D-glucopyranoside, GT-glu) is mainly found in soy-derived foods. In this study, we examined the pharmacokinetic properties and bioavailability of GT in rats and compared with those of GT-glu. In order to characterize and compare the pharmacokinetics of GT and GT-glu, these compounds were administered intravenously and orally. The plasma concentration of GT was determined by HPLC after enzymatic hydrolysis. After oral administration of GT with various doses (4, 20, 40 mg/kg), the bioavailability of GT was 38.58, 24.34 and 30.75%, respectively. The T(max), C(max) and AUC(0-infinity) of GT after oral administration of GT (40 mg/kg), were 2h, 4876.19 ng/ml, 31,269.66 ng h/ml, respectively. When smaller amount of GT was administered, the faster T(max) was observed. Oral administration of GT-glu resulted in longer T(max), lower C(max), and greater bioavailability than that of GT. The pharmacokinetic parameters of GT following oral administration of GT-glu (64 mg/kg as GT-glu, 40 mg/kg as GT) were obtained as follows: 8h (T(max)), 3763.96 ng/ml (C(max)), 51,221.08 ng h/ml (AUC(0-infinity)) and 48.66% (absolute bioavailability), respectively. These results indicate that the oral bioavailability of GT-glu is greater than that of GT.     

Pharmacokinetic behaviors and oral bioavailability of oridonin in rat plasma

AIM: To study the intravenous and oral pharmacokinetic behavior of oridonin and its extent of absolute oral bioavailability in rats. METHODS: Oridonin was administered to rats via iv (5, 10 and 15 mg/kg), po (20, 40 and 80 mg/kg) or ip administration (10 mg/kg). The concentrations of oridonin in rat plasma were determined by a high performance liquid chromatography with electrospray ionization mass spectrometric detection (HPLC/ESI-MS) method and the pharmacokinetic parameters were determined by non-compartmental analysis. RESULTS: The plasma concentration of oridonin after intravenous administration decreased polyexponentially, and the pharmacokinetic parameters of oridonin were dose-independent within the examined range. Oridonin was absorbed rapidly after oral gavage with a t(max) of less than 15 min; the extent of absolute bioavailability of oridonin following oral administration was 4.32%, 4.58% and 10.8%. The extent of absolute bioavailability of oridonin following intraperitoneal administration was 12.6%. CONCLUSION: First order rate pharmacokinetics were observed for oridonin within the range of iv doses, while the extent of absolute oral bioavailability was rather low and dose- dependent. The low and dose-dependent extent of oral bioavailability may be due to the saturation of first-pass effects.     

Oral bioavailability in pigs of a miconazole/Hydroxypropyl-γ-cyclodextrin/ L-tataric acid inclusion complex produced by supercritical carbon dioxide processing

The objective of this study was to determine the pharmacokinetic parameters of miconazole after oral administration of a miconazole/hydroxypropyl-gamma-cyclodextrin(HPgammaCD)/L-tartaric acid inclusion complex produced by supercritical carbon dioxide processing. The pharmacokinetics of the miconazole ternary complex (CPLX), of the corresponding physical mixture (PHYS), and of miconazole alone (MICO) were compared after oral administration. Six mixed-breed pigs received each formulation as a single dose (10 mg miconazole/kg) in a crossover design. Miconazole plasma concentrations were determined by a high-performance liquid chromatography method. Preliminary in vitro dissolution data showed that CPLX exhibits a faster and higher dissolution rate than either PHYS or MICO. Following CPLX oral administration, mean area under the plasma concentration curve (AUC(0-infinity)) for miconazole was 95.0 +/- 55.8 microg/min/mL, with the peak plasma concentration (C(max) 0.59 +/- 0.39 microg/mL) at 19.30 minutes. The AUC(0-infinity) and C(max) values were significantly higher than those after oral administration of PHYS (AUC(0-infinity) 38.5 +/- 12.7 microg/min/mL and C(max) 0.24 +/- 0.08 microg/mL; P < .1) and of MICO (AUC(0-infinity) 24.1 +/- 14.0 microg/min/mL and C(max) 0.1 +/- 0.05 microg/mL; P < .1). There were also significant differences between PHYS and MICO (P < .1). The results of the study indicate that CPLX shows improved dissolution properties and a higher relative oral bioavailability compared with PHYS and MICO.     

黄豆苷元磷脂复合物的制备及大鼠体内生物利用度的研究

目的制备黄豆苷元磷脂复合物并测定其在大鼠体内的生物利用度。方法以黄豆苷元与大豆磷脂的复合率为评价指标,采用单因素试验和正交设计优化制备工艺;分别测定黄豆苷元、黄豆苷元-磷脂的物理混合物及黄豆苷元磷脂复合物在水中和正辛醇中的表观溶解度;3组大鼠分别灌胃给予黄豆苷元原料药、黄豆苷元-磷脂的物理混合物及黄豆苷元磷脂复合物后,采用LC-MS/MS测定不同时间血浆中药物浓度,比较相对生物利用度。结果黄豆苷元磷脂复合物优化的制备条件为：反应溶剂为无水乙醇,投料比为1.5∶1（磷脂/药物的摩尔比）,1g·L^-1反应物浓度条件下60℃搅拌2h,结果显示：磷脂复合物在水和正辛醇中表观溶解度比原料药分别提高3.1倍和5.4倍;大鼠灌胃给予黄豆苷元和黄豆苷元磷脂复合物后,Cmax分别为（667±65）,（7509±688）ng·mL^-1,Tmax分别为（3.00±0.82）,（0.42±0.17）h,AUC0–∞分别为（8302±590）,（28870±2411）ng·h·mL^-1。黄豆苷元磷脂复合物口服生物利用度是黄豆苷元原料药的3.48倍。结论将黄豆苷元制成磷脂复合物后在水中的溶解度有所提高,在正辛醇中的溶解度有显著提高,增加了黄豆苷元在胃肠道中的吸收,明显提高黄豆苷元口服生物利用度。