The absorption, distribution, metabolism and excretion of rofecoxib, a potent and selective cyclooxygenase-2 inhibitor, in rats and dogs.

Absorption, distribution, metabolism, and excretion studies were conducted in rats and dogs with rofecoxib (VIOXX, MK-0966), a potent and highly selective inhibitor of cyclooxygenase-2 (COX-2). In rats, the nonexponential decay during the terminal phase (4- to 10-h time interval) of rofecoxib plasma concentration versus time curves after i.v. or oral administration of [(14)C]rofecoxib precluded accurate determinations of half-life, AUC(0-infinity) (area under the plasma concentration versus time curve extrapolated to infinity), and hence, bioavailability. After i.v. administration of [(14)C]rofecoxib to dogs, plasma clearance, volume of distribution at steady state, and elimination half-life values of rofecoxib were 3.6 ml/min/kg, 1.0 l/kg, and 2.6 h, respectively. Oral absorption (5 mg/kg) was rapid in both species with C(max) occurring by 0.5 h (rats) and 1.5 h (dogs). Bioavailability in dogs was 26%. Systemic exposure increased with increasing dosage in rats and dogs after i.v. (1, 2, and 4 mg/kg), or oral (2, 5, and 10 mg/kg) administration, except in rats where no additional increase was observed between the 5 and 10 mg/kg doses. Radioactivity distributed rapidly to tissues, with the highest concentrations of the i.v. dose observed in most tissues by 5 min and by 30 min in liver, skin, fat, prostate, and bladder. Excretion occurred primarily by the biliary route in rats and dogs, except after i.v. administration of [(14)C]rofecoxib to dogs, where excretion was divided between biliary and renal routes. Metabolism of rofecoxib was extensive. 5-Hydroxyrofecoxib-O-beta-D-glucuronide was the major metabolite excreted by rats in urine and bile. 5-Hydroxyrofecoxib, rofecoxib-3',4'-dihydrodiol, and 4'-hydroxyrofecoxib sulfate were less abundant, whereas cis- and trans-3,4-dihydro-rofecoxib were minor. Major metabolites in dog were 5-hydroxyrofecoxib-O-beta-D-glucuronide (urine), trans-3, 4-dihydro-rofecoxib (urine), and 5-hydroxyrofecoxib (bile).     

Pharmacokinetics, tissue distribution and excretion of gambogic acid in rats.

The plasma pharmacokinetics, excretion, and tissue distribution of gambogic acid (GA), a novel anti-tumor drug, were investigated after intravenous (i.v.) bolus administration in rats. Plasma profiles were obtained after i.v. administration of GA at the doses of 1, 2 and 4 mg/kg. The elimination half-life (tl/2) values for GA were estimated to be 14.9, 15.7 and 16.1 min, while the mean area under concentration-time curve (AUC(t)) values were 54.2, 96.1 and 182.4 microg min/ml, respectively. GA was mainly excreted into the bile (36.5% over 16 h). The cumulative sum of fecal excretion within 48 h was 1.26% of the i.v. administered dose. No GA was detected in the urine after i.v. administration. GA had a limited tissue distribution, with the highest concentrations being found in the liver. GA reached its maximal concentration in all tissues at 5 min post-dose. In conclusion, the present observations indicated that GA was rapidly eliminated from the blood and transferred to the tissues. Moreover, the majority of GA appeared to be excreted into the bile within 16 h of i.v. administration.     

LC-MS法测定Beagle犬血浆中埃博霉素B及其药动学研究

目的建立液相色谱串联质谱（LC—MS）法测定Beagle犬血浆中埃博霉素B含量,分析埃博霉素B在Beagle犬体内的药动学参数。方法采用LC—MS方法测定Beagle犬接受O．05,O．10和0．15mg／kg埃博霉素B静脉给药后不同时问点的血浆浓度,药物浓度一时间数据通过DAS2．0版软件进行分析。结果血浆中埃博霉素B在O．1～18ng／mL浓度范围内线性关系良好（r=O．9999）,血浆中样品提取回收率大于70％,日内和日间的精密度（RSD）均小于15％。药动学参数t1/2β分别为（76．20±7．24）、（71．41±10．62）和（64．62±9．76）h,AUCo。分别为（43．89±7．95）、（95．16±20．82）和（127．43±31．41）μg／（L·h）。结论LC—MS测定方法操作简便,专属性强,灵敏度高,适用于Beagle犬体内埃博霉素B的浓度测定和药动学研究。Beagle犬静脉注射3个剂量埃博霉索B后的药物浓度一时问数据符合二室模型特征,且埃博霉素B在犬体内半衰期较长。     

Absorption, distribution, metabolism and excretion of the cholecystokinin-1 antagonist dexloxiglumide in the dog.

Single oral doses of 14C-dexloxiglumide were rapidly and extensively absorbed in dogs and also eliminated rapidly with a short half-life. Following single intravenous doses, dexloxiglumide was characterised as a drug having a high clearance (30.7 and 27.0 ml/min/kg in males and females respectively), a low volume of distribution (Vss, 0.34 and 0.27 L/kg in males and females respectively) and a moderate systemic availability (about 33%). It was extensively bound to plasma proteins (89%). Dexloxiglumide is mainly cleared by the liver. Its renal clearance was minor. In only the kidney, liver and gastrointestinal tract, were concentrations of 14C generally greater than those in plasma. 14C concentrations generally peaked at 0.25h and declined rapidly during 24h being present only in a few tissues (such as the kidney, liver and gastrointestinal tract) at 24h. Single intravenous or oral doses were mainly excreted in the faeces (77-89%), mostly during 24h. Urine contained up to 7.5% dose. Mean recoveries during 7 days ranged between 93-97%. Biliary excretion of 14C was prominent (64% dose during 24h) in the disposition of 14C which was probably also subjected to some limited enterohepatic circulation. Unchanged dexloxiglumide was the major component in plasma. Urine and faeces contained several 14C-components amongst which unchanged dexloxiglumide was the most important (eg. about 55% dose in faeces). LC-MS/MS of urine and bile extracts showed that dexloxiglumide was metabolised mainly by O-demethylation and by conjugation with glucuronic acid.     

Bioavailability of ginkgolides and bilobalide from extracts of ginkgo biloba using GC/MS

The bioavailability of ginkgolides A, B and bilobalide was studied in rats after single oral administration of 30, 55 and 100 mg/kg Ginkgo extract EGb 761. The plasma levels of the terpene lactones were measured by a specific GC/MS method. The pharmacokinetics of the mentioned substances were found to be dose-linear. For the lowest dose maximum concentrations were 68, 40 and 159 ng/ml and half-lives 1.7, 2.0 and 2.2 h for ginkgolide A, B and bilobalide, respectively. Clearance values ranged from 24.2 to 37.6 ml/min/kg.     

Rapid determination of isocorydine in rat plasma and tissues using liquid chromatography--tandem mass spectrometry and its applications to pharmacokinetics and tissue distribution

A rapid and sensitive method for the determination of isocorydine in rat plasma and tissues was developed using liquid chromatography-tandem mass spectrometry (LC-MS/MS). The biological samples were processed by extracting with diethyl ether-dichloromethane (3:2, v/v) and tetrahydropulmatine was used as the internal standard (IS). Detection of the analytes was achieved using positive ion mode electrospray ionization in the multiple reaction monitoring mode. The MS/MS ion transitions monitored were m/z 342.0→279.0 and 356.0→191.9 for isocorydine and IS, respectively. The maximum plasma concentration (C(max) 2496.8 ± 374.4 μg/L) was achieved at 0.278 ± 0.113 h (T(max)) and the half-life (t(1/2)) of isocorydine was 0.906 ± 0.222 h after a 20 mg/kg oral administration. As for a 2 mg/kg intravenous (i.v.) administration, the C(max) and clearance (CL) were 1843.3 ± 338.3 μg/L and 2.381 ± 0.356 L/h/kg, respectively. Based on the AUC(0-∞) obtained from oral and i.v. administration, the absolute bioavailability (F) was estimated as 33.4%. Tissue distribution results indicated that isocorydine underwent a rapid and wide distribution into tissues and it could effectively cross the blood-brain barrier.     

Contrasting systemic stabilities of the acyl and phenolic glucuronides of diflunisal in the rat

1. Diflunisal (DF) is metabolized in humans and rats primarily to its acyl glucuronide, phenolic glucuronide and sulphate conjugates. 2. After i.v. administration of DF acyl glucuronide to pentobarbitone-anaesthetized rats, DF and its phenolic glucuronide and sulphate conjugates appeared rapidly in plasma, indicating ready systemic hydrolysis of the acyl glucuronide and subsequent biotransformation of liberated DF. 3. Approximately 72% of the acyl glucuronide dose was recovered in bile and urine over 6 h: 52% as acyl glucuronide, 6% as phenolic glucuronide, 5% as sulphate, and 8% as isomers of the acyl glucuronide arising from intramolecular acyl migration. 4. Blockage of excretion routes by ligation of the ureters, bile duct, and both ureters and bile duct, decreased plasma clearance of the acyl glucuronide from 7.8 ml/min per kg to 6.0, 3.2 and 2.2 ml/min per kg respectively, and increased the apparent terminal plasma half-life of DF from 2.1 h to 2.6, 3.4 and 6.3 h, respectively. 5. By contrast, DF phenolic glucuronide was quite stable after i.v. administration at the same dose. 6. This study shows that systemic cycling between DF and its acyl glucuronide exists in the rat in vivo, with portions of each cycle of unstable acyl glucuronide through DF yielding stable phenolic glucuronide and (presumptively stable) sulphate conjugate.     

Pharmacokinetics and excretion of phenol red in the channel catfish.

1. Disposition of phenol red was examined in channel catfish (Ictalurus punctatus) after oral or intravascular (i.v.) dosing at 10 mg/kg body weight. 2. Phenol red was not detectable in plasma, urine, or bile after oral administration. 3. After i.v. dosing, plasma concentrations of phenol red were best described by a two-compartment pharmacokinetic model with distribution and elimination half-lives of 2.3 and 21 min, respectively. The apparent volume of distribution at steady state (Vss) was 225 ml/kg and total body clearance (Clb) was 658 ml/h per kg. Plasma protein binding was 19%. 4. Biliary excretion was the primary route of elimination of phenol red; in 24 h, 55% of the i.v. dose was excreted in bile compared with 24% in urine. No metabolites were detected in these fluids. 5. The use of anaesthesia during dosing had no effect on the quantitative excretion of phenol red by renal or biliary routes.     

The disposition of radioactivity after administration of the anthelminthic methyl-14C-5-cyclopropylcarbonyl-2-benzimidazole carbamate (ciclobendazole) to rats and dogs

1. The disposition of radioactivity has been studied in rats and dogs after administration of a new anthelminthic agent, 14C-labelled methyl-5-cyclopropylcarbonyl-2-benzimidazole carbamate (14C-ciclobendazole). 2. An oral dose of 14C-ciclobendazole (4 mg/kg) to rats was rapidly absorbed and about 70% and 20% of the dose was excreted in the faeces and urine, respectively, during 2 days. Bile duct cannulated rats excreted about 80% of the dose in 48-h bile, about 2% in the faeces and about 10% in the urine showing that an oral dose was well-absorbed and that some enterohepatic circulation probably occurred. The excretion of radioactivity in the bile was less after i.v. administration. 3. An oral dose of 14C-ciclobendazole (4 mg/kg) to dogs was mainly eliminated during 2 days with about 80% of the dose in the faeces and only about 10% in the urine. Anaesthetised bile duct-cannulated dogs, excreted between 26% and 35% of an oral dose in the bile during 24 h and up to 58% of an oral dose was absorbed at this time. 4. The tissue distribution of radioactivity in rats and dogs after single or multiple oral doses of 14C-ciclobendazole (4 mg/kg) showed that there was no unusual accumulation or localisation of radioactivity in the measured tissues. Highest concentrations were present in the intestinal tract, liver and kidneys, organs associated with biotransformation and excretion and also in the lungs and adrenals. 5. After oral administration of 14C-ciclobendazole to rate at three different dose levels (4, 40 and 400 mg/kg), peak plasma levels occurred at 15-30 min and declined with similar half-lives (about 20 h). A comparison of peak concentrations and areas under the plasma concentration-time relationships showed that the absorption of ciclobendazole was probably dose-dependent, a lower proportion probably being absorbed at higher doses. After repeated daily oral dosing with 14C-ciclobendazole (4 mg/kg), there were no significant changes in either the daily plasma concentrations or the biological half-life measured after the last dose, indicating that ciclobendazole probably did not induce or inhibit its own metabolism when dosed repeatedly at 4 mg/kg. 6. A comparison of the areas under the plasma concentration-time relationships after oral, i.p. and i.v. administration of 14C-ciclobendazole to rates indicated that there was no signigicant uptake by the liver during first pass and that an oral dose was well absorbed by rats. 7. The peak plasma concentration in the dog, after an oral dose of 14C-ciclobendazole (4 mg/kg) was reached at about 30 min and declined with a half-life of about 3 h. 8. Ciclobendazole was probably well-absorbed by rats and dogs and excreted more rapidly by the latter species than by the former Relatively higher plasma concentrations of drug and/or metabolites were thus achieved in rats than in dogs.     

Pharmacokinetics of valerenic acid in rats after intravenous and oral administrations

Valerenic acid (VA), a sesquiterpenoid, is one of the major secondary bioactive metabolites of VALERIANA OFFICINALIS L. Until now IN VIVO studies on the absorption, bioavailability, disposition, and metabolism of VA are limited. We established and validated an LC-MS/MS assay for the determination of VA in rat plasma and successfully used this method for pharmacokinetic studies in rats after intravenous (i. v.) and oral administrations. The plasma concentration-time data was analyzed by both non-compartmental and compartmental approaches using WinNonlin software. Following i. v. administration, the disposition of VA in rat plasma was biphasic, subdivided into a fast distribution and a slow elimination phase. The half-life of the distribution phase was 6-12 min, and that of the terminal elimination phase 6-46 h, indicating a possible large tissue binding. Disposition PK of valerenic acid after oral treatment was also described by a two-compartment model with a clearance (CL/F) of 2-5 L · h (-1) · kg (-1) and volume of distribution of (V (d)) 17-20 L · kg (-1). The extent of absorption (F) after oral administration was estimated to be 33.70 % with a half-life of 2.7-5 h. Dose proportionality was observed in terms of dose and AUCs, suggesting linear pharmacokinetics at the dose levels studied in rats.     

Bioavailability and pharmacokinetics of S-propargyl-L-cysteine, a novel cardioprotective agent, after single and multiple doses in Beagle dogs

As a novel hydrogen sulfide-modulated agent, S-propargyl-L-cysteine (SPRC) is proven to be a potent cardioprotective candidate. Bioavailability and pharmacokinetics of SPRC (20?mg/kg) in beagle dogs after oral and intravenous administrations were investigated in this study. Plasma concentrations of SPRC were measured by a LC-MS/MS method. Intravenous administration of SPRC (single dose) to beagle dogs gave a mean plasma half-life of 14.7?h, mean clearance of 0.4?ml min?1 kg?1 and mean apparent volume of distribution of 0.56?L/kg. Single oral administration was completely, fast absorbed (T(max)= 0.33?±?0.20?h) with a mean absolute availability of 112% and mean plasma half-life of 16.5?h. Multiple oral administration (once daily for 10 consecutive days) of SPRC to dogs resulted in steady state plasma drug concentration being reached after seven doses and didn't cause obvious accumulation. No significant difference was found between the single and multiple pharmacokinetic parameters.     

Pharmacokinetic characteristics and hepatic distribution of IH-901, a novel intestinal metabolite of ginseng saponin, in rats

We investigated the pharmacokinetic characteristics of 20- O-(beta-D-glucopyranosyl)-20(S)-protopanaxadiol (IH-901), a metabolite that is formed by intestinal bacteria, after its intravenous (i.v.) or oral administration in rats. We developed an LC/MS/MS-based method to analyze IH-901 levels in plasma, bile, urine and tissue homogenates and validated its use in a pharmacokinetic study. After i.v. administration of 3 - 30 mg/kg IH-901, it disappeared rapidly from the plasma at alpha phase followed by slow disappearance at beta phase (t(1/2,)(alpha) of 0.042 - 0.055 h and t (1/2,)(beta) of 6.98 - 10.6 h, respectively). The oral route slightly prolongs IH-901 plasma levels (terminal phase t(1/2) of 26.1 h) yet leads to a bioavailability of only 4.54 %. Of the various organs tested, the liver contained the majority of the i.v. bolus or orally administered IH-901, and liver IH-901 levels shortly after i.v. administration were 6-fold higher than the initial plasma concentration. The R(h) (hepatic recovery ratio) was calculated to be 0.417, and the uptake clearance (CL(uptake)) for i.v. administered IH-901 was 0.401 mL.min(-1).g liver(-1). Additionally, IH-901 is mostly excreted into the bile, since 40.5 % of the i.v.-administered dose (30 mg/kg) was recovered in the bile within 6 h, and only 15 % was found in the urine. Moreover, at steady state after i. v. infusion of IH-901, C(ss,liver) was about 11.3-fold higher than C(ss,plasma), whereas C(ss,bile) was about (1/2)-fold lower than C(ss,liver). These results indicated that the liver is largely responsible for removing IH-901 from the circulation. Oral administration of IH-901 leads to a low bioavailability; thus, the parenteral route may be the suitable way to deliver IH-901 for clinical applications.     

Pharmacokinetics and disposition of the novel dopamine agonist Z-7760 in rat after intravenous and oral administration

1. Z-7760 (S(-)-N-[N-2-phenylethyl)-6-hexylamino]-N-propyl-5,6-dihydroxy-1,2,3,4-tetrahydro-2-naphthylamine dihydrobromide) is a potent dopamine D-1 and D-2 agonist synthesized during a search for agents to treat heart failure. Reported is the fate of the drug in rat. 2. 3H-Z-7760 was administered p.o. and i.v. to male Sprague-Dawley rats (0.4 mg and 400 microCi/kg in 0.1% ascorbic acid) and venous blood samples collected at intervals up to 48 h. Comparison of the AUC for total 3H showed that 37% of an oral dose of Z-7760 was absorbed. The percentage plasma 3H present as the parent compound fell from 82% 30 min after i.v. dosing to 12% after 24 h. After oral dosing, the fraction of plasma 3H present as unchanged Z-7760 was < 5% and this was essentially unaltered throughout the study. The long terminal elimination phase evident from 6 h was notable after both routes of administration. 3. The bile duct-cannulated rat was given 3H-Z-7760 p.o. (0.4 mg and 40 microCi/kg) and bile was collected for up to 22 h. Biliary excretion accounted for 30% of the dose. No parent compound was detected in the bile. 4. In further studies, other rats were dosed p.o. or i.v. with 3H-Z-7760 (0.4 mg and 400 microCi/kg) and urine and faeces were collected daily for 3 days. The major route of excretion was the faeces with 94-97% 3H recovered after oral and 70-73% after i.v. dosing. A further 4-7% was recovered in the urine after oral and 12-13% after i.v. dosing. 5. After oral administration of Z-7760 (100 mg/kg, 40 microCi/kg) to rats, the major metabolites in the urine were identified as the 5-O-methyl and glucuronic acid conjugates of Z-7760 by LC and MS. The glucuronide was only seen in urine after oral administration but 5-O-methyl-Z-7760 was present in urine and faeces after both routes of administration. 6. The low bioavailability of Z-7760 is the consequence of its poor absorption from the gastrointestinal tract as well as extensive first-pass metabolism that further reduces systemic blood concentrations after oral administration.     

HPLC analysis and pharmacokinetic characteristics of 11-hydroxyaclacinomycin X (ID-6105), a novel anthracycline, in rats and beagle dogs

We investigated the pharmacokinetic characteristics of 11-hydroxyaclacinomycin X (ID-6105), a novel anthracycline, after intravenous (i.v.) bolus administration in rats and beagle dogs. We developed an HPLC-based method to analyze ID-6105 levels in plasma, bile, urine, feces, and tissue homogenates and validated the method in a pharmacokinetic study. The plasma concentration of ID-6105 decreased to below the quantifiable limit (0.02 microg/ml) at 4 and 8 h after i.v. administration in rats at doses of 2 and 10 mg/kg, respectively (t(1/2,alpha) and t(1/2,beta) of 0.78 and 17.8 min at a dose of 2 mg/kg, 0.91 and 176 min at a dose of 10 mg/kg, respectively). The AUC increased with nonlinear pharmacokinetics following the dosage increase from 2 to 10 mg/kg in rats, while the pharmacokinetics were not significantly altered in beagle dogs following a dosage increase from 0.5 to 2.5 mg/kg. Of the various tissues tested, ID-6105 was mainly distributed in the lung, spleen, kidney, adrenal gland, and liver after i.v. bolus administration. ID-6105 levels in the lung or kidney 2 h after i.v. bolus administration were comparable to the initial plasma concentration. However, the ID-6105 concentrations in various tissues 48 h after i.v. bolus administration became too small to measure. The cumulative amounts of ID-6105 found in the bile 48 h after the administration of 2 and 10 mg/kg were calculated to be 26.7 and 18.5% of the initial dose, respectively. The corresponding values in the urine 72 h after i.v. administration were 4.33 and 3.07% of the initial dose, suggesting that ID-6105 is mostly excreted in the bile. In conclusion, our observations indicate that ID-6105 was rapidly cleared from the blood and transferred to tissues such as the lung, spleen, kidney, and liver 2 h after i.v. bolus administration. Moreover, the majority of ID-6105 appears to be excreted in the bile by 24 h after i.v. bolus administration.     

Pharmacokinetics of tinidazole in chronic renal failure and in patients on haemodialysis.

The pharmacokinetics of tinidazole after infusion (800 mg in 15 min) were studied in 12 patients with chronic renal failure (RI) and in five patients undergoing regular dialysis treatment (RD). Tinidazole elimination plasma half-life was 15.09 +/- 0.68 h (mean +/- s.e. mean) (RI) and 12.9 +/- 1.0 h after dialysis (RD), but there was a significant decrease in half-life during dialysis (4.25 +/- 0.43 h) P less than 0.001). The apparent volume of distribution (0.64 +/- 0.03 l/kg) was equal to extra and intracellular water volume and tinidazole was little bound to plasma protein (8%). There was a slight sex difference in apparent volume of distribution between male patients (0.70 +/- 0.09 l/kg) and female patients (0.59 +/- 0.10 l/kg) (P = 0.07), but as body clearance decreases in the same order, there was no modification of plasma half-life. In renal failure, pharmacokinetics of tinidazole were not disturbed because no correlation between half-life, body clearance and creatinine clearance occurred; urine elimination was about 7% of administered dose. Plasma clearance during dialysis was 49.9 +/- 3.2 ml/min and about 43% of the available drug was eliminated during the 6 h dialysis procedure. These results suggest that an additional half-dose infusion should be given after the end of dialysis in patients undergoing regular dialysis treatment.     

Pharmacokinetics of pentachlorophenol in man

Pentachlorophenol (PCP) was given orally to three volunteers at single doses of 3.9, 4.5, 9, and 18.8 mg. Daily urinary excretion of PCP and PCP conjugated to glucuronic acid was monitored using gas chromatography with electron capture detection (GC/ECD). Based on first-order elimination kinetics an elimination half-life of 20 days was derived.To eliminate interference by the uncontrolled absorption of PCP from the environment 0.98 mg ¹³C-PCP was taken by one of the volunteers. PCP levels in urine and plasma were determined using mass spectrometry (GC/ MS) with negative chemical ionization. An elimination half-life of 17 days was found in both urine and blood. The collected data were used to calculate the clearance of PCP: a value of 0.07 ml/min was found. The long elimination half-life of PCP is explained by the low urinary clearance due to the high plasma protein binding (>96%) and the tubular reabsorption. The pH-dependency of the elimination of PCP was investigated, and a distinct increase in the daily excretion was observed following alkalinization by oral administration of sodium bicarbonate.In order to elucidate the role of the enterohepatic circulation as a possible pool for PCP in humans, the bile of cholelithiasis patients with postoperative T-drainage was investigated for PCP and compared with the corresponding urine and plasma levels, but no accumulation of PCP in the enterohepatic circulation could be observed.The daily elimination and plasma levels of PCP in a group of individuals without a specific exposition were found to range from 10 to 48 g/day and 19 to 36 g/l, respectively.     

Electrospray LC-MS/MS quantitation,stability, and preliminary pharmacokinetics of bradykinin antagonist polypeptide B201 (NSC 710295) in the mouse

B201 (NSC 710295), [SUIM-(Darg-Arg-Pro-Hyp-Gly-Igl-Ser-Digl-Oic-Arg)(2)], a third generation of bradykinin (BK) antagonist, has been found to possess high potency. We report the development of a highly sensitive electrospray LC-MS/MS assay method for the analysis of B201 in plasma for the first time, using an ion-trap mass spectrometer. Human or mouse plasma (0.2 ml) was spiked with B201 and the internal standard, substance P. The compounds were extracted with a preconditioned C-18 reversed-phase column and analyzed by LC-MS/MS. The analytes were separated on a 50 x 2 mm (i.d.) BetaBasic C8 column, using a gradient elution. The positive ion selected reaction monitor mode was used monitoring the transitions of ions at m/z 938.9(3+)-->816.0(2+) for B201 and 674.3(2+)-->665.7(2+) for substance P. Assay validation was performed, and the limit of quantitation (LOQ) for B201 was found to be 1 ng/ml for human plasma and 2.5 ng/ml for mouse plasma. The recovery was 78% for B201 and 88% for substance P. The assay was linear from 2.5 to 1500 ng/ml for mouse plasma monitored. Using a 0.2 ml plasma, the within-day CVs were 9.3% at 2.5 ng/ml, 6.5% at 100 ng/ml, and 3.8% at 1000 ng/ml for human plasma (n=6). For mouse plasma, the respective within-day CVs were 17.6, 9.6, and 6.2% (n=6). The between-day CVs for human plasma were 8.2, 10.9, and 2.4%, respectively, (n=3) and the respective values for mouse plasma were 11.9, 8.6 and 6.5% (n=6). Pharmacokinetics of B201 in the mouse was studied following i.v. administration at 5 mg/kg and found to conform to a two-compartment model with an initial half-life of 14 min and a terminal half-life of 44 h. Plasma B201 peak level was detected at microg/ml range and the levels were detectable for a least 24 h. Preliminary oral bioavailability was found to be about 1%. This method demonstrates that an ion trap mass spectrometer can be a powerful tool to quantify large peptides at low nanogram per milliliter with a non-isotopically labeled internal standard.     

Contrasting systemic stabilities of the acyl and phenolic glucuronides of diflunisal in the rat

1. Diflunisal (DF) is metabolized in humans and rats primarily to its acyl glucuronide, phenolic glucuronide and sulphate conjugates.

2. After i.v. administration of DF acyl glucuronide to pentobarbitone-anaesthetized rats, DF and its phenolic glucuronide and sulphate conjugates appeared rapidly in plasma, indicating ready systemic hydrolysis of the acyl glucuronide and subsequent biotransformation of liberated DF.

3. Approximately 72% of the acyl glucuronide dose was recovered in bile and urine over 6 h: 52% as acyl glucuronide, 6% as phenolic glucuronide, 5% as sulphate, and 8% as isomers of the acyl glucuronide arising from intramolecular acyl migration.

4. Blockage of excretion routes by ligation of the ureters, bile duct, and both ureters and bile duct, decreased plasma clearance of the acyl glucuronide from 7.8 ml/min per kg to 6.0, 3.2 and 2.2 ml/min per kg respectively, and increased the apparent terminal plasma half-life of DF from 2.1?h to 2.6, 3.4 and 6.3?h, respectively.

5. By contrast, DF phenolic glucuronide was quite stable after i.v. administration at the same dose.

6. This study shows that systemic cycling between DF and its acyl glucuronide exists in the rat in vivo, with portions of each cycle of unstable acyl glucuronide through DF yielding stable phenolic glucuronide and (presumptively stable) sulphate conjugate.     

Pharmacokinetic study of triptolide, a constituent of immunosuppressive chinese herb medicine, in rats

Triptolide is a potential anti-immune agent, and has shown multi-organic toxicity, however its toxic mechanism remained undiscovered. This paper aimed at characterizing the pharmacokinetic profiles of triptolide in rats to provide the clue to approach the toxic mechanism. The absorption, distribution, metabolism and excretion of triptolide were investigated in male Sprague-Dawley rats after single doses of oral and i.v. administration. After oral administration of 0.6, 1.2 and 2.4 mg/kg, the concentration of triptolide in plasma reached the maximum within 15 min, and declined rapidly with an elimination half-life from 16.81 to 21.70 min. The triptolide kinetics was fitted into one-compartment model after i.v. administration. Oral absolute bioavailability was 72.08% at the dose of 0.6 mg/kg. Triptolide was also rapidly distributed and eliminated in all selected tissues. Less than 1% triptolide of the dose was recovered from the bile, urine or feces as parent drug within 48 h. While triptolide could not be detected in tissues and plasma at 4 h post dose, rats in the group C (oral: 1.2 mg/kg) and D (oral: 2.4 mg/kg) showed obvious toxic response to triptolide and some of rats even died out. It was indicated that triptolide was metabolized extensively, eliminated rapidly, and also showed that the toxicity produced by the triptolide was lag behind the exposure concentration.     

Validation of high-performance liqid chromatography method to determine epirubicin and its pharmacokinetics after intravenous bolus administration in rats

We investigated the pharmacokinetics of epirubicin, an anthracycline derivative antibiotics, after intravenous (i.v.) bolus administration in rats. To analyze epirubicin levels in the plasma, bile, urine and tissue samples, we developed an high-performance liqid chromatography (HPLC)-based method which was validated for a pharmacokinetic study by suitable criteria. The plasma concentration of epirubicin after i.v. bolus administration was rapidly disappeared within 10 min from the blood circulation. The mean plasma half-lives at α phase (t_1/2α) when administered at the dose of 2, 5, 10, 25 and 50 mg/kg were 2.14–2.61 min. The values of t_1/2β at the corresponding doses increased two folds (from 150 to 291 min) with increasing doses. The CL_t values significantly decreased with the increase in dose. In contrast, V_dss values increased about 1.5 times with the increase in dose from 2 to 50 mg/kg. Of the various tissues, epirubicin mainly distributed to the kidney, lung, heart and liver after i.v. bolus administration. The epirubicin concentrations in various tissues at 24 h after i.v. bolus administration were below 1.0 μg/g tissue. Epirubicin was excreted largely in the bile after i.v. bolus administration at the dose of 2, 10 and 50 mg/kg. The cumulative amount of epirubicin in the urine 72 h after dosage represented 20 % of the amount excreted in the bile 12 h after high dosage, indicating that i.v. administered epirubicin was mainly excreted in the bile. In conclusion, epirubicin was rapidly cleared from the blood circulation and transferred to tissues such as the kidney and liver 2 h after i.v. bolus administration. Moreover, the majority of epirubicin appears to be excreted in the bile by 12 h after i.v. bolus administration.