Comparative pharmacokinetics of single doses of doxylamine succinate following intranasal,oral and intravenous administration in rats

The intranasal route of administration provides a potential useful way of administering a range of systemic drugs. In order to assess the feasibility of this approach for the treatment of nausea and vomiting, doxylamine succinate was studied in rats for the pharmacokinetics (AUC, C(max), t(max)) following intranasal, oral and intravenous administrations. Subjects (six male Sprague-Dawley rats per time interval for each route of administration) received 2-mg doses of doxylamine succinate orally and I-mg doses intranasally and intravenously, respectively. The various formulations were formulated in isotonic saline (0.9% w/v) at 25 +/- 1 degrees C. Doxylamine succinate concentrations in plasma were determined with a high-performance liquid chromatographic assay and a liquid-liquid extraction procedure. Intranasal and oral bioavailabilities were determined from AUC values relative to those after intravenous dosing. Intranasal bioavailability was greater than that of oral doxylamine succinate (70.8 vs 24.7%). The intranasal and oral routes of administration differed significantly from the intravenous route of administration. Peak plasma concentration (C(max)) was 887.6 ng/ml (S.D. 74.4), 281.4 ng/ml (S.D. 24.6) and 1296.4 ng/ml (S.D. 388.9) for the intranasal, oral and intravenous routes, respectively. The time to achieve C(max) for the intranasal route (t(max)=0.5 h) was faster than for the oral route (t(max)=1.5 h), but no statistically significant differences between the C(max) values were found using 95% confidence intervals. The results of this study show that doxylamine succinate is rapidly and effectively absorbed from the nasal mucosa.     

Brain, plasma and tissue pharmacokinetics of risperidone and 9-hydroxyrisperidone after separate oral administration to rats

RATIONALE: Following an oral dose of risperidone (RSP), concentrations of its major metabolite 9-hydroxyrisperidone (9-OHRSP) were high in plasma and tissues but disproportionately lower in the brain compared to RSP, indicating that 9-OHRSP may have different pharmacokinetic properties. OBJECTIVES: To investigate non-compartmental pharmacokinetics of RSP and 9-OHRSP in plasma, brain and other tissues after separate administration of a single oral dose of 6 mg/kg RSP and 9-OHRSP to rats. METHODS: Plasma, brain, liver, lung, kidney and spleen tissues were collected at pre-dose and at 0.5, 1, 2, 5, 6, 12, 24, 36 and 48 h post-dose, homogenized in saline and assayed for RSP and 9-OHRSP using a sensitive and specific liquid chromatography tandem mass spectrometry method. RESULTS: The concentration-time curve of RSP and 9-OHRSP showed that they were readily absorbed and followed a multiphase elimination pattern. The terminal elimination half-life (t(1/2) ) of RSP after the RSP dose was longest in the liver (17.6 h) and shortest in the spleen (1.2 h). The t(1/2)of 9-OHRSP after the RSP dose was shorter in plasma (3.4 h) and other tissues (approximately 8-11 h) than that for RSP but it was longer in the spleen. However, the t(1/2) of 9-OHRSP after the 9-OHRSP dose was shorter in most tissues as compared to the t(1/2) of 9-OHRSP after the RSP dose. The area under the concentration-time curve (AUC) of RSP and 9-OHRSP was 6-67 times higher in the plasma and tissues than in the brain. AUCs of 9-OHRSP in tissues after the RSP dose were 2-5 times higher than those for RSP, except in the brain, where AUCs of RSP and 9-OHRSP were similar. CONCLUSION: Pharmacokinetics of 9-OHRSP in many tissues were different after RSP and 9-OHRSP doses. The reason for disproportionate brain levels of 9-OHRSP is not clear. The overall exposure to active drug in the brain as represented by AUC was similar after the RSP and 9-OHRSP doses and the 9-OHRSP is probably an equal contributor to the pharmacological actions of RSP.     

Comparative pharmacokinetics of a marker compound,baicalin in KOB extract after oral administration to normal and allergic-induced rats

Abstract

KOB extracts are a polyherbal medicine had been prescribed for the treatment of hyperhydrosis and allergic diseases such as allergic asthma and rhinitis in oriental clinics. Therefore, the pharmacokinetic studies of the KOB extract administered orally to normal rats and rhinitis-induced rats to understand the correlation of the efficacy and plasma concentration of KOB in patients of allergic rhinitis in future were performed. The study was conducted according to administration for pure baicalin in normal rats, baicalin in KOB extract in normal rats and rhinitis-induced rats. Baicalin in rat plasma was analyzed and validated by HPLC analysis. The interday precision based on the standard deviation of replicates of quality control samples ranged from 3.6% to 7.9% with accuracy ranging from 92.9% to 101.2% for baicalin. Based on validated analysis, pharmacokinetic study was carried out. Pure baicalin in normal rats and baicalin in KOB extract in normal rats showed bimodal curves due to direct absorption and glucuronidation. The T_max, C_max and AUC of pure baicalin in normal rats or baicalin in KOB extract in normal rats were 12?h, 0.68?µg/ml and 9.85?µg?h/ml, respectively, or 12?h, 0.46?µg/ml and 6.36?µg?h/ml, respectively. The analytical method showed excellent sensitivity, precision and accuracy, being successfully employed in a pharmacokinetic study of polyherbal medicine, KOB extract. Allergic-induced condition did not affect the pharmacokinetics of KOB extracts, suggesting KOB extracts did not require dosage adjustment in subjects with allergic-induced diseases.     

Comparative pharmacokinetics of midazolam and loprazolam in healthy subjects after oral administration

The pharmacokinetics of oral midazolam (Dormicum, 15 mg) and loprazolam (Dormonoct, 1 mg) were studied in eight healthy young volunteers in a cross-over design. Plasma concentrations of midazolam were measured with a gas chromatographic method and loprazolam concentrations were determined by a radio-receptor technique. Absorption of midazolam proceeded very rapidly (median tmax = 0.4 h) and a rapid onset of sedative action was observed. Loprazolam absorption was relatively slow (median tmax = 3 h) and its absorption profile was often irregular. Most subjects fell asleep before peak concentrations were reached. Median peak concentrations were 94 ng ml-1 and 3.1 ng ml-1 for midazolam and loprozolam, respectively. The median elimination half-life of midazolam was 1.8 h and that of loprazolam 15 h. It is possible that the elimination half-life of loprazolam as determined by radioreceptor assay is determined by active metabolites rather than by loprazolam itself. Midazolam elimination half-life was the same when determined by radioreceptor assay or by GLC. There was no significant correlation between the half-lives of the two drugs.     

Cocaine pharmacodynamics after intravenous and oral administration in rats: relation to pharmacokinetics

  Rationale: To design optimal dose regimes for oral cocaine, it is essential to characterize pharmacokinetics (PK) of cocaine after IV and PO administration. Objectives: To investigate the absolute bioavailability of oral cocaine, its effectiveness and the relation between PK and PD in a within-subject design. Methods: We used the effects of IV and PO cocaine on a contingency-controlled timing behavior, the differential reinforcement of low rate schedule (DRL 45-s) in 3-h sessions, as the PD measures [i.e., the shorter-response rate (srr) and the reinforcement rate (rr)]. Cocaine PK parameters were determined by simultaneous modeling of the concentration-time profiles (CTPs) after IV 2 mg/kg and PO 20 mg/kg cocaine administration. The absolute oral cocaine bioavailability was determined pharmacokinetically (F) and pharmacodynamically (F_srr and F_rr). Results: IV and PO cocaine increased the shorter response rate and decreased the reinforcement rate in a dose- and time-related fashion, which mirrored the respective prototypical serum cocaine CTPs. After the absorption phase, the serum cocaine CTP of PO cocaine paralleled that of IV cocaine. The duration of action for PO cocaine was longer than that for IV cocaine owing to its larger mean residence time. The active metabolite, norcocaine, was not detected after IV but after PO cocaine administration. The value of F was 4.66% which was significantly lower than the values of F_srr (13.67%) and F_rr (32.63%). Furthermore, the concentration-effect relations for the reinforcement rate revealed that PO cocaine was more potent than IV cocaine. Conclusions: Oral cocaine is more effective behaviorally than from predictions made in terms of its PK. The differences in active metabolite profiles as well as the rate and extent of acute tolerance for IV versus PO cocaine may account for the greater potency observed for oral cocaine. Received: 23 July 1998 / Final version: 2 February 1999     

Comparative pharmacokinetics of cefuroxime lysine after single intravenous,intraperitoneal, and intramuscular administration to rats

Aim:

To compare the pharmacokinetic parameters of cefuroxime lysine, a new second-generation of cephalosporin antibiotics, after intravenous (IV), intraperitoneal (IP), or intramuscular (IM) administration.

Methods:

Twelve male and 12 virgin female Sprague-Dawley rats, weighing from 200 to 250 g, were divided into three groups (n=4 for each gender in each group). The rats were administered a single dose (67.5 mg/kg) of cefuroxime lysine via IV bolus or IP or IM injection. Blood samples were collected and analyzed with a validated UFLC-MS/MS method. The concentration-time data were then calculated by compartmental and non-compartmental pharmacokinetic methods using DAS software.

Results:

After IV, IP or IM administration, the plasma cefuroxime lysine disposition was best described by a tri-compartmental, bi-compartmental or mono-compartmental open model, respectively, with first-order elimination. The plasma concentration profiles were similar through the 3 administration routes. The distribution process was rapid after IV administration [t_1/2(d), 0.10±0.11 h vs 1.36±0.65 and 1.25±1.01 h]. The AUMC_0–∞ is markedly larger, and mean residence time (MRT) is greatly longer after IP administration than that in IV, or IM routes (AUMC_0–∞: 55.33±20.34 vs 16.84±4.85 and 36.17±13.24 mg·h²/L; MRT: 0.93±0.10 h vs 0.37±0.07 h and 0.65±0.05 h). The C_max after IM injection was significantly higher than that in IP injection (73.51±12.46 vs 49.09±7.06 mg/L). The AUC_0–∞ in male rats were significantly higher than that in female rats after IM administration (66.38±16.5 vs 44.23±6.37 mg·h/L). There was no significantly sex-related difference in other pharmacokinetic parameters of cefuroxime lysine between male and female rats.

Conclusion:

Cefuroxime lysine shows quick absorption after IV injection, a long retension after IP injection, and a high C_max after IM injection. After IM administration the AUC_0–∞ in male rats was significantly larger than that in female rats.     

Comparative pharmacokinetics of sulphasalazine and sulphapyridine after rectal and oral administration to patients with ulcerative colitis

Summary Rectal administration of sulphasalazine to patients with ulcerative colitis has recently been shown to have similar therapeutic activity but fewer side effects than oral treatment. The present study is a comparison of the pharmacokinetics of sulphasalazine (SASP) and its metabolite sulphapyridine (SP) after rectal and oral administration of SASP to 6 patients with ulcerative colitis. The areas under the concentration-time curves (AUC) and the maximum concentrations (C_max) of SASP and SP were significantly lower after rectal than oral administration of SASP (p<0.05). These findings support the view that the lower frequency of side effects after rectal administration of SASP may result from the lower plasma levels of SASP and SP.     

Amiodarone pharmacokinetics. II. Disposition kinetics following subchronic administration in rats

A 30 mg kg-1 intravenous bolus of 14C-amiodarone (19 microCi kg-1) was given to male Sprague-Dawley rats pretreated with 0 (vehicle), 25 or 100 mg kg-1 day-1 of amiodarone HCl orally for 37-42 days to determine the effects of dose and duration of administration on the disposition kinetics of amiodarone. Serial blood samples and total urine were collected over 48 hours and assayed for 14C-amiodarone by liquid scintillation counting following separation by HPLC. In all three groups, the blood 14C-amiodarone concentration-time curves declined bioexponentially with terminal half-lives (t1/2 beta) ranging from 14-22 hours. No differences in beta, t1/2 beta, or central compartment volume (Vc) were observed between the three groups of rats. In the rats pretreated with 100 mg kg-1 day-1 of amiodarone HCl for 5-6 weeks, amiodarone clearance (CL) and steady state volume of distribution (Vss) were reduced 52 per cent (12.2 to 5.9 ml min-1 kg-1) and 41 per cent (11.73 to 6.97 l kg-1), respectively. At the lower amiodarone daily dose, no changes in CL or Vss were observed. Negligible levels of radioactivity were detected in the urine. Amiodarone accounted for approximately 30-40 per cent of the total radioactivity in each blood specimen. This study demonstrated that CL and Vss were dose-dependent, and that beta, t1/2 beta and Vc were dose-independent. The results further suggested that the disposition kinetics of amiodarone were independent of the duration of drug administration.     

Safety evaluation of longan seed extract: Acute and repeated oral administration

Longan seed extract (LSE) contains high levels of beneficial polyphenolic compounds. The present study evaluated acute and repeated dose (4 and 13 weeks) toxicological effects of aqueous extract of longan seed to ensure the safety of utilization of this extract. Our study revealed that all treated animals survived through the whole experimental periods without adverse effects observed in either sex of animals after acute and repeated dose (4 and 13 weeks) oral administration of LSE. Likewise, growth pattern (body weights, food consumption, and relative organ weights), hematology analysis, and clinical biochemistry analysis in all LSE-treated animals were in normal physiological ranges. Moreover, histopathological finding of LSE-treated animals in repeated dose studies demonstrated no obvious alterations. Although the significant increment in food consumption of female rats (100 mg/kg, Week 4) and % eosinophil of male rats (400 mg/kg), and decrement in food consumption of male rats (250 mg/kg, Week 3 and 9) were observed, these alterations were not dose- and time-response relationships. Therefore, we concluded that acute and repeated dose (4 and 13 weeks) oral administration of LSE has no significant toxicological effects;hence it may be safe to use with caution pending its chronic toxicity study and/or clinical trial.     

Pharmacokinetics of tolbutamide after oral administration to rabbits with folate-lnduced renal failure

The pharmacokinetic of tolbutamide was studied after the oral administration to normal rabbits or rabbits with mild to medium folate-induced renal failure. The plasma concentrations of tolbutamide were significantly elevated (p<0.05) during 9 to 24 h in rabbits with mild or medium folate-induced renal failure. Consequently, the area under the plasma concentration-time curves (AUC) was significantly higher in mild (p<0.05) and medium (p<0.01) folate-induced renal failure rabbits (i.e., 2906 microg/mL x h for mild renal failure and 4074 microg/mL x h for moderate renal failure) than that in normal rabbits (i.e., 2295 microg/mL x h). The cumulative urinary excretion of tolbutamide was significantly depressed (p<0.05) in medium folate-induced renal failure rabbits (i.e., 3.3 mg) compared with that in normal rabbits (i.e., 5.9 mg). The elimination rate constant (Kel) of tolbutamide was significantly decreased in medium renal failure rabbits (i.e., 0.027 h(-1)) than that in normal rabbits (i.e., 0.044 h(-1)); As a result, the terminal half-life of tolbutamide in medium folate-induced renal failure rabbits (i.e., 25.5 h) was significantly longer (p<0.01) than that in normal rabbits (i.e., 15.7 h). The change in pharmacokinetic parameters is consistent with the hypothesis that the alteration is mediated by the depressed metabolic elimination of the drug by the induction of renal failure. Therefore, these observations indicated that the dosage adjustment may be necessary for tolbutamide in patients with renal insufficiency.     

Hydroquinine pharmacokinetics after oral administration in adult patients with muscle cramps

Objective: This study was conducted to determine the pharmacokinetic properties of hydroquinine after oral administration in adult patients with muscle cramps. The main reason for this study was the poor availability of pharmacokinetic data, hindering the design of studies to explore the possible relationship between hydroquinine concentrations and effects. Methods: Sixteen adult patients with a clinical history of muscle cramps were given once-daily oral doses of 300 mg hydroquinine hydrobromide for 4 days. Serum and saliva samples were taken following a predefined schedule until 24 h after the last dose. Urine was collected during the study period. Hydroquinine concentrations were measured, and calculations were made of pharmacokinetic parameters using non-linear curve fitting. Results: Pharmacokinetics of hydroquinine could be best described using a one-compartment open model. After oral administration, hydroquinine was rapidly absorbed (mean ± SD: maximum concentration 2.43 ± 0.68 mg/l; time to maximum concentration 1.4 ± 1.2 h; lag time 0.54 ± 0.50 h). With an elimination half-life of 10.9 ± 6.1 h, steady-state was reached in several days. The distribution volume was 1.24 ± 0.29 l/kg, total clearance was 6.7 ± 3.2 l/h. The measured unbound hydroquinine fraction was 8.6 ± 3.0%. No correlation was found between saliva and serum concentrations. Cumulative urinary excretion of unchanged hydroquinine 24 h after the first dose was 35.5 ± 9.2 mg. Conclusion: Pharmacokinetic properties of hydroquinine are roughly similar to those of quinine. The unchanged fraction of hydroquinine excreted in urine is higher than that reported for quinine. Saliva hydroquinine concentrations could not be related to serum values. Steady-state trough or other fixed-time serum concentrations may prove useful for further optimisation of hydroquinine dosage. Received: 19 November 1999 / Accepted: 9 March 2000     

Plasma levels of ethaverine after oral administration to humans

Fourteen healthy human subjects received a 200 mg oral dose of ethaverine hydrochloride as an elixir. Blood samples were obtained for 12 h after dosing. Plasma ethaverine concentrations were determined using a paired-ion, reversed-phase high performance liquid chromatographic method. Individual plasma concentration-time profiles were fitted to a two-compartment model with first-order absorption. The ethaverine was rapidly absorbed, based on a time of maximum plasma concentration of 0.75 h, a time-lag of 8.4 min, and an apparent first-order absorption half-life of 8.6 min. The mean terminal elimination half-life was 3.3 h.     

Pharmacokinetic changes of acebutolol after orall administration in rabbits with diabetes mellitus induced by Alloxan

Because physiological changes that potentially alter pharmacokinetics occurs in diabetes mellitus patients, pharamacokinetics of drugs used in the treatment of hypertension was studied using acebutolol as a model anti-hypertensive drug. Thus, the pharmacokinetics of acebutolol was investigated after oral administration of acebutolol (15 mg/kg) to control rabbits and rabbits with acute or chronic diabetes mellitus induced by alloxan. Kidney and liver functions were documented for acute and chronic diabetes mellitus groups based on plasma chemistry data. After oral administration of acebutolol to acute and chronic groups, the plasma concentrations appeared higher; As a result, area under the plasma concentration-time curve from time zero to time infinity10575 and 8668 microg x h/mL for acute and chronic group, respectively. In comparison, the area was apparently smaller in the control group (i.e., 7132 microg x h/mL). The half-life in acute groups was significantly prolonged 8.45 h compared with the half-life in the control group (i.e., 6.30 h). Alteration in acebutolol pharmacokinetics was more pronounced in the acute group as evidenced by the significantly higher values the area under the plasma concentration time curve, absorption rate constant and maximum plasma concentration compared with chronic or control group. Therefore, these observations indicate that acebutolol pharmacokinetics may be affected in patients with diabetes mellitus, especially in the early stage of the disease.     

Simultaneous determination and pharmacokinetics of five bufadienolides in rat plasma after oral administration of Chansu extract by SPE-HPLC method

A sensitive and rapid solid-phase extraction-high performance liquid chromatography (SPE-HPLC) method has been developed for the determination of five bufadienolides, arenobufagin, teliocinobufagin, cinobufotalin, cinobufagin and resibufogenin in rat plasma and applied to a pharmacokinetic study in rats after oral administration of Chansu extract (Venenum Bufonis). Plasma samples were pretreated with solid-phase extraction using Extract-Clean cartridges, and the extracts were analyzed by a reversed-phase C(18) column on a HPLC system with photodiode array detection (DAD). The calibration curves were linear over the range of 0.10-1.66 microg/ml for arenobufagin, 0.03-1.20 microg/ml for telocinobufagin, 0.01-0.62 microg/ml for cinobufotalin, 0.03-0.70 microg/ml for cinobufagin and 0.02-2.57 microg/ml for resibufogenin, respectively. The limit of quantification was 1.1 ng/ml for arenobufagin, 0.3 ng/ml for telocinobufagin, 9.7 ng/ml for cinobufotalin, 8.8 ng/ml for cinobufagin, 7.7 ng/ml for resibufogenin, respectively. The established method could be easily applied to the determination and pharmacokinetic studies of five bufadienolides in rat plasma after oral administration of Chansu extract.     

Intestinal microbiota-mediated biotransformations alter the pharmacokinetics of the major metabolites of azathioprine in rats after oral administration

Adverse reactions to azathioprine (AZA) vary greatly among individuals, which is associated with the variable levels of its major metabolites 6-thioguanine nucleotides (6-TGN) and 6-methylmercaptopurine (6-MMP). The intestinal microbiota has been proven to contain AZA-metabolizing enzymes, although the explicit role of the intestinal microbiota in AZA metabolism in vivo remains poorly comprehended. In this study, the pharmacokinetic behaviours of 6-TGN and 6-MMP were assessed in the pseudo germ-free (PGF) group and control group following oral administration of AZA. The AUC_0-t and C_max of 6-TGN in the PGF group were significantly decreased by 34.0% and 35.0% (P < 0.05) compared with those in the control group. Additionally, the AUC_0-t and C_max of 6-MMP were reduced by 27.9% and 34.2% in the PGF group, although the differences were not significant. The TPMT and NUDT15 genotypes of rats in the two groups were genetically identical. The expression levels of key AZA-metabolizing enzymes in liver were not different between two groups. Furthermore, the major metabolites of AZA in the incubation system with intestinal microbial enzymes were identified. In summary, shifts in the composition of the intestinal microbiota may regulate the exposure of 6-TGN in vivo by altering the gut microbial metabolism of AZA.     

Dose-independent pharmacokinetics of torasemide after intravenous and oral administration to rats

After intravenous (at doses of 1, 2, 5, and 10 mg/kg) and oral (at doses of 1, 5, and 10 mg/kg) administration of torasemide, the pharmacokinetic parameters were dose-independent. Hence, the extent of absolute oral bioavailability (F) was also independent of oral doses; the values were 95.6, 98.8, and 97.3% for oral doses of 1, 5, and 10 mg/kg, respectively. The high F values indicated that the first-pass (gastric, intestinal, and hepatic) effects of torasemide in rats could be almost negligible. After intravenous administration, the total body clearances of torasemide were extensively slower than the reported cardiac output in rats and hepatic extraction ratio was only 3-4% suggesting almost negligible first-pass effects of torasemide in the heart, lung, and liver in rats. Based on in vitro rat tissue homogenate studies, the tissues studied also showed negligible metabolic activities for torasemide. Equilibrium of torasemide between plasma and blood cells of rat blood reached fast and plasma-to-blood cells concentration ratio was independent of initial blood concentrations of torasemide, 1, 5, and 10 microg/ml; the mean value was 0.279. Protein binding of torasemide to fresh rat plasma was 93.9 +/- 1.53% using an equilibrium dialysis technique.     

The pharmacokinetics of methotrexate after intravenous administration of methotrexate-loaded proliposomes to rats

The pharmacokinetics and tissue distribution of methotrexate (MTX) were investigated after intravenous (i.v.) injection of free MTX (treatment I), MTX-loaded proliposomes (treatment II), and empty proliposomes mixed manually with free MTX (treatment III), 8 mg kg^?1, to rats using an HPLC assay. After i.v. infusion in 1 min, the plasma concentration of MTX (C_p), the area under the plasma concentration-time curve (AUC, 639 versus 913 μg min mL^?1), the terminal half-life (t_1/2, 48.8 versus 397 min), the mean residence time (MRT, 8.40 versus 325 min), and the apparent volume of distribution at steady state (V_ss, 98.1 versus 2800 mL kg^?1) were significantly higher; however, the total body clearance (CL, 12.5 versus 8.76 mL min^?1 kg^?1), renal clearance (CL_R, 4.49 versus 2.78 mL min^?1 kg^?1), non-renal clearance (CL_NR, 7.50 versus 5.99 mL min^?1kg^?1), and the amount of MTX excreted in urine (X_u, 808 versus 685 μg, p < 0.0948) were significantly lower from treatment II than from treatment I. This could be due to the fact that some of the MTX-loaded liposomes (formed immediately after hydration of MTX-loaded proliposomes) are entrapped in tissues and the rest are present in the plasma (higher MRT and V_ss from treatment II), and MTX is slowly released from MTX-loaded liposomes (higher t_1/2 from treatment II). In the present HPLC assay, the concentrations of MTX represent the sum of free MTX and MTX loaded in liposomes (higher C_p and AUC, slower CL from treatment II). After i.v. infusion in 1 min, some pharmacokinetic parameters, such as t_1/2, MRT, and V_ss, were significantly different between treatments I and III; however, the differences seemed to be smaller than those between treatments I and II. After 30 min from i.v. infusion, the tissue to plasma (T/P) ratios of MTX in kidney and stomach from treatment II were significantly lower than those from treatment I. This suggested that the i.v. administration of MTX-loaded proliposomes might have fewer side effects in the organs than that of free MTX. The mean amount of MTX loaded in MTX-loaded proliposomes was 2.54 mg/g proliposomes and the MTX was released slowly from hydrated MTX-loaded proliposomes when incubated with phosphate-buffered saline (PBS), rat plasma, or rat liver homogenate.     

Pharmacokinetics and pharmacodynamics of alprazolam after oral and IV administration

Six fasting male subjects (20–32 years of age) received an oral tablet and an IV 1.0-mg dose of alprazolam in a crossover-design study. Alprazolam plasma concentration in multiple samples during 36 h after dosing was determined by electron-capture gas-liquid chromatography. Psychomotor performance tests, digit-symbol substitution (DSS), and perceptual speed (PS) were administered at 0, 1.25, 2.25, 5.0, and 12.5 h. Sedation was assessed by the subjects and by an observer using the Stanford Sleepiness Scale and a Nurse Rating Sedation Scale (NRSS), respectively. Mean kinetic parameters after IV and oral alprazolam wre as follows: volume of distribution (V _d) 0.72 and 0.84 l/kg; elimination half-life (t _1/2) 11.7 and 11.8 h; clearance (Cl) 0.74 and 0.89 ml/min/kg. There were no significant differences between IV and oral alprazolam in V _d, t _1/2, or area under the curve. The mean fraction absorbed after oral administration was 0.92. Performance on PS and DSS tests was impaired at 1.25 and 2.5 h, but had returned to baseline at 5.0 h for both treatments. Onset of sedation was rapid after IV administration and the average time of peak sedation was 0.48 h. Sedation scores were significantly lower during hour 1 after oral administration than after IV, but were not significantly different at later times. Alprazolam is fully available after oral administration and kinetic parameters are not affected by route of administration. With the exception of rapidity of onset, the pharmacodynamic profiles of IV and oral alprazolam are very similar after a 1.0-mg dose.     

Pharmacokinetics of verproside after intravenous and oral administration in rats

Verproside, a catalpol derivative iridoid glucoside isolated from Pseudolysimachion longifolium, is a candidate for anti-asthmatic drug. The dose-dependency of the pharmacokinetics of verproside was evaluated in rats after intravenous and oral administration. After intravenous administration of verproside (2, 5 and 10 mg/kg doses), the systemic clearance (Cl) was significantly reduced and AUC was significantly increased at 10 mg/kg dose compared to 2 and 5 mg/kg doses. The volume of distribution at steady state (V _ss) remained unchanged as the dose was increased. The extent of urinary excretion was low for both intravenous (3.3–6.2%) and oral (0.01–0.04%) doses. Isovanilloylcatalpol was identified as a metabolite after intravenous administration of verproside and showed the significant decreases in AUC and C _max at 10 mg/kg verproside dose. The reduced systemic clearance of verproside at high doses appears to be due to the saturable metabolism. Upon oral administration of verproside (20, 50 and 100 mg/kg doses), C _max was nonlinearly increased. The extent of verproside recovered from the gastrointestinal tract at 24 h after oral administration was 0.01–0.72% for all three doses studied. The absolute oral bioavailability (F) was 0.3 and 0.5% for 50 and 100 mg/kg doses, respectively. Low F appears to be due to first-pass metabolism.