Comparative kinetics of phenobarbital after administration of the acid and the propylhexedrine salt (barbexaclone)

Summary The kinetics of phenobarbital (PB) was compared after oral administration of equivalent doses of the drug as the acid or the propylhexedrine salt (barbexaclone) to 7 normal volunteers. The absorption and elimination parameters were very similar. It was concluded that propylhexedrine did not affect the serum kinetics of PB given as barbexaclone.     

Pharmacokinetics and tissue distribution of olanzapine in rats

The single dose pharmacokinetics of olanzapine in rats, following an oral dose and its distribution in the brain and other tissues after repeated oral and intra-peritoneal (i.p.) administration, were studied. Olanzapine in plasma, brain, liver, lung, kidney, spleen and fat was assayed at predose, 0.25, 0.5, 1, 2, 5, 12, 24, 36, 48 h postoral dose of 6 mg/kg and after daily oral and i.p. doses of 0.25, 1, 3, and 6 mg/kg/day of olanzapine for 15 consecutive days by a sensitive and specific HPLC method with electrochemical detection. Olanzapine was readily absorbed and distributed in plasma and tissues as the peak concentrations were reached within approximately 45 min after the oral dose. The terminal half-life of olanzapine in plasma was 2.5 h and in tissues it ranged from 3 to 5.2 h. The area under the concentration-time curve (AUC(last)) was lowest in plasma and largest in liver and lung. The AUC(last) of olanzapine was eight times larger in brain and three to 32 times larger in other tissues than that in plasma. After repeated oral doses, the plasma and tissue concentrations of olanzapine were generally higher than those after repeated i.p. doses. The liver and spleen had the highest concentrations after oral and i.p doses, respectively. In both cases, the tissue concentrations were four- to 46-fold higher than that in plasma and correlated with administered doses. Likewise, plasma concentrations strongly correlated with the simultaneous brain and tissue concentrations (r(2)>0.908, p<0.0001). On average, the brain levels were 6.3-13.1 and 5.4-17.6 times higher than the corresponding plasma level after oral and i.p. doses, respectively. The tissue to plasma level ratio of olanzapine was higher in other tissues. The data indicated that olanzapine is rapidly absorbed and widely distributed in the tissues of rats after oral and i.p. administration. The plasma concentration appears to predict the simultaneous concentration in brain and other tissues. There was no marked localized accumulation of olanzapine in any of the regions of the rat brain.     

Pharmacokinetic characteristics of bornaprolol in healthy volunteers

1. Six young male volunteers received five single doses of bornaprolol, i.v. (20 mg) and orally (120, 240, 480, 960 mg) administered at 2-week intervals. Plasma concentrations of bornaprolol and its conjugated metabolite were determined by gas chromatography. 2. After i.v. administration, plasma bornaprolol levels were detectable over 8 h, and mean values were 60 l/h for total clearance (C1), 207 l for volume of distribution (V beta), 2.6 h for elimination half-life (t1/2 beta). After oral administration, plasma bornaprolol levels were detectable over 24-48 h, and mean values of pharmacokinetics parameters were 60 l/h for C1, 1500 l for V beta, 20 h for t1/2 beta. Maximum plasma concentrations and area under the plasma concentration-time curve increased in a non-dose-dependent manner. 3. The glucuronide conjugate appeared in the blood within 5-10 min and its plasma level greatly exceeded bornaprolol concentrations. The mean value of the ratio of the metabolite AUC/parent product AUC was 14 after i.v. administration and 13-21 following oral administration, depending on dose. The AUC for the metabolite did not increase proportionally with oral doses. 4. Bornaprolol is principally eliminated after metabolism. This process did not increase with increasing oral doses and bioavailability seemed to decrease inversely with oral dose.     

Pharmacokinetics and distribution of clioquinol in golden hamsters

Clioquinol (5-chloro-7-iodo-8-quinolinol) is a zinc and copper chelator that can dissolve amyloid deposits and may be beneficial in Alzheimer's disease. Prion diseases are also degenerative CNS disorders characterised by amyloid deposits. The pharmacokinetics and tissue distribution of drugs active against prions may clarify their targets of action. We describe the pharmacokinetics of clioquinol in hamster plasma, spleen and brain after single and repeated oral or intraperitoneal administration (50 mg kg(-1)), as well as after administration with the diet. A single intraperitoneal administration led to peak plasma clioquinol concentrations after 15 min (Tmax), followed by a decay with an apparent half-life of 2.20 +/- 1.1 h. After oral administration, Tmax was reached after 30 min and was followed by a similar process of decay; the AUC(0-last) was 16% that recorded after intraperitoneal administration. The Cmax and AUC values in spleen after a single administration were about 65% (i.p.) and 25% (p.o.) those observed in blood; those in liver were 35% (p.o.) those observed in blood and those in brain were 20% (i.p.) and 10% (p.o.) those observed in plasma. After repeated oral doses, the plasma, brain and spleen concentrations were similar to those observed at the same times after a single dose. One hour after intraperitoneal dosing, clioquinol was also found in the ventricular CSF. Clioquinol was also given with the diet; its morning and afternoon concentrations were similar, and matched those after oral administration. No toxicity was found after chronic administration. Our results indicate that clioquinol, after oral administration with the diet, reaches concentrations in brain and peripheral tissues (particularly spleen) that can be considered effective in preventing prion accumulation, but are at least ten times lower than those likely to cause toxicity.     

Toxicokinetics of lambda-cyhalothrin in rats

The toxicokinetics of lambda-cyhalothrin after single 20 mg kg(-1) oral and 3 mg kg(-1) intravenous doses were studied in rats. Serial blood samples were obtained after oral and intravenous administration. Liver, brain, spinal cord, sciatic nerve, vas deferens, anococcygeus and myenteric plexus tissue samples were also collected. Plasma, liver, hypothalamus, cerebellum, medulla oblongata, frontal cortex, striatum, hippocampus, midbrain, spinal cord, vas deferens, anococcygeus, myenteric plexus and sciatic nerve concentrations of lambda-cyhalothrin were determined by HPLC. The plasma and tissue concentration-time data for lambda-cyhalothrin were found to fit a two-compartment open model. For lambda-cyhalothrin, the elimination half-life (T1/2beta) and the mean residence time from plasma were 7.55 and 8.55 h after i.v. and 10.27 and 14.43 h after oral administration. The total plasma clearance was not influenced by dose concentration or route and reached a value of 0.060l h(-1)kg(-1). After i.v. administration, the apparent volume of distribution and at steady state were 0.68 and 0.53l kg(-1), suggesting a diffusion of the pyrethroid into tissue. After oral administration, lambda-cyhalothrin was extensively but slowly absorbed (Tmax, 2.69 h). The oral bioavailability was found to be 67.37%. Significant differences in the kinetic parameters between nervous tissues and plasma was observed. The maximum concentrations in hypothalamus (Cmax, 24.12 microg g(-1)) and myenteric plexus (Cmax, 25.12 microg g(-1)) were about 1.5 times higher than in plasma (Cmax, 15.65 microg ml(-1)) and 1.3 times higher than in liver (Cmax, 18.42 microg ml(-1)). Nervous tissue accumulation of lambda-cyhalothrin was also reflected by the area under the concentration curve ratios of tissue/plasma (liver). The T1/2beta for lambda-cyhalothrin was significantly greater for the nerve tissues, including neuromuscular fibres, (range 12-26 and 15-34 h, after i.v. and oral doses) than for plasma (7.55 and 10.27 h, respectively).     

Pharmacokinetics and clinical effect of phenobarbital in children with severe falciparum malaria and convulsions

AIMS: Phenobarbital is commonly used to treat status epilepticus in resource-poor countries. Although a dose of 20 mg kg(-1) is recommended, this dose, administered intramuscularly (i.m.) for prophylaxis, is associated with an increase in mortality in children with cerebral malaria. We evaluated a 15-mg kg(-1) intravenous (i.v.) dose of phenobarbital to determine its pharmacokinetics and clinical effects in children with severe falciparum malaria and status epilepticus. METHODS: Twelve children (M/F: 11/1), aged 7-62 months, received a loading dose of phenobarbital (15 mg kg(-1)) as an i.v. infusion over 20 min and maintenance dose of 5 mg kg(-1) at 24 and 48 h later. The duration of convulsions and their recurrence were recorded. Vital signs were monitored. Plasma and cerebrospinal fluid (CSF) phenobarbital concentrations were measured with an Abbott TDx FLx fluorescence polarisation immunoassay analyser (Abbott Laboratories, Diagnostic Division, Abbott Park, IL, USA). Simulations were performed to predict the optimum dosage regimen that would maintain plasma phenobarbital concentrations between 15 and 20 mg l(-1) for 72 h. RESULTS: All the children achieved plasma concentrations above 15 mg l(-1) by the end of the infusion. Mean (95% confidence interval or median and range for Cmax) pharmacokinetic parameters were: area under curve [AUC (0, infinity)]: 4259 (3169, 5448) mg l(-1).h, t(1/2): 82.9 (62, 103) h, CL: 5.8 (4.4, 7.3) ml kg(-1) h(-1), Vss: 0.8 (0.7, 0.9) l kg (-1), CSF: plasma phenobarbital concentration ratio: 0.7 (0.5, 0.8; n= 6) and Cmax: 19.9 (17.9-27.9) mg l(-1). Eight of the children had their convulsions controlled and none of them had recurrence of convulsions. Simulations suggested that a loading dose of 15 mg kg(-1) followed by two maintenance doses of 2.5 mg kg(-1) at 24 h and 48 h would maintain plasma phenobarbital concentrations between 16.4 and 20 mg l(-1) for 72 h. CONCLUSIONS: Phenobarbital, given as an i.v. loading dose, 15 mg kg(-1), achieves maximum plasma concentrations of greater than 15 mg l(-1) with good clinical effect and no significant adverse events in children with severe falciparum malaria. A maintenance dose of 2.5 mg kg(-1) at 24 h and 48 h was predicted to be sufficient to maintain concentrations of 15-20 mg l(-1) for 72 h, and may be a suitable regimen for treatment of convulsions in these children.     

A review of the clinical pharmacokinetics and metabolism of the alpha 1-adrenoceptor antagonist indoramin

1. The alpha 1-adrenoceptor antagonist indoramin is rapidly and extensively absorbed after oral administration, but with only low to moderate bioavailability (8-24% median) from the tablet (Baratol). Although plasma protein binding is high (72-86%), the drug is widely distributed into tissues (with median Vz 6.3-7.7 l/kg after i.v. dosage). 2. Elimination of indoramin is rapid in most healthy volunteers, with median plasma clearances of 18-26 ml/min per kg, after i.v. dosage. Elimination occurs principally by metabolism, the major route being indole 6-hydroxylation, followed by sulphate conjugation of 6-hydroxyindoramin. The faecal route of excretion predominates (45-50% of dose), with a further 35-40% in the urine. 3. Extensive variation in single-dose oral pharmacokinetics of indoramin is due largely to the existence of a poor metabolizer phenotype which co-segregates with that of debrisoquine. 4. On repeated administration (37.5 mg twice daily) to healthy volunteers, plasma concentrations of indoramin accumulate 3-4-fold above those anticipated from single-dose kinetics. However, steady state is achieved within the first week of dosing. 5. The pharmacokinetics of indoramin are substantially altered in the elderly. The oral AUC for a 50 mg dose is increased approx. 5-fold and the t1/2 2.5-fold. 6. Cirrhotic liver disease enhances bioavailability and decreases clearance, approx. 2-fold in each case for single oral and i.v. doses of 50 mg and 0.15 mg/kg respectively. 7. After oral indoramin Cmax and AUC are both raised (58% and 25%, respectively, for a 50 mg dose) by co-ingested ethanol (0.5 g/kg). After i.v. indoramin, kinetics are unaffected by alcohol, but indoramin (0.175 mg/kg) slightly increases (26%) blood ethanol concentrations during the first hour after dosing. 8. The pharmacodynamics of indoramin appear to be related to the combined pharmacokinetics of the drug and its 6-hydroxylated metabolite, which contributes to the antihypertensive effect.     

Absorption and Disposition of a Selective Aldosterone Receptor Antagonist,Eplerenone, in the Dog

Purpose. The present study was conducted to characterize the pharmacokinetics of eplerenone (EP), a selective aldosterone receptor antagonist, and its open lactone ring form in the dog. Methods. Pharmacokinetic studies of EP were conducted in dogs following i.v., oral, and rectal dosing (15 mg/kg) and following intragastric, intraduodenal, intrajejunal, and intracolonic dosing (7.5 mg/kg). Results. After oral administration, the systemic availability of EP was 79.2%. Systemic availabilities following administration via other routes were similar to that following oral administration. The half-life and plasma clearance of EP were 2.21 hr and 0.329 l/kg/hr, respectively. Plasma concentrations of the open lactone ring form were lower than EP concentrations regardless of the route of administration. The C-14 AUC in red blood cells was approximately 64% and 68% of the plasma AUC for i.v. and oral doses. Percentages of the dose excreted as total radioactivity in urine and feces were 54.2% and 40.6%, respectively, after i.v. administration, and 40.7% and 52.3%, respectively, after oral administration. The percentages of the dose excreted in urine and feces as EP were 13.7% and 2.5%, respectively, after i.v. administration, and 2.1% and 4.6% after oral administration, respectively. Approximately 11% and 15% of the doses were excreted as the open form following i.v. and oral doses. Conclusions. EP was rapidly and efficiently absorbed throughout the gastrointestinal tract, resulting in a good systemic availability. The drug did not preferentially accumulate in red blood cells. EP was extensively metabolized; however, first-pass metabolism after oral and rectal administration was minimal. EP and its metabolites appear to be highly excreted in the bile.     

Pharmacokinetics of nilvadipine, a new dihydropyridine calcium antagonist, in mice, rats, rabbits and dogs

1. The pharmacokinetics of nilvadipine in male and female rats, and in male mice, rabbits and dogs were studied after i.v. and oral dosing. 2. After i.v. dosing (0.1 mg/kg), the plasma concentrations of nilvadipine declined two- or three-exponential with terminal half-lives of 0.73 h in mice, 1.2 h in male and female rats, 3.7 h in rabbits and 5.0 h in dogs. Sex difference in pharmacokinetics after i.v. dosing in rats was not found. The systemic plasma clearance was in the order of mice greater than rats greater than rabbits greater than dogs, and nearly equalled the hepatic blood flow in each species. The volume of distribution at steady-state was high (greater than 4 L/kg) in all species. 3. After oral dosing, plasma concentrations of nilvadipine peaked within 1 h in all species except for middle and higher doses (4 and 16 mg/kg) in dogs. The area under the plasma concentration-time curves in male rats (3.2-100 mg/kg) and dogs (1-16 mg/kg) increased in proportion to the dose. Bioavailability was low in male rats (3-4%) and rabbits (2%), but in other species was 29-44%. The oral clearance in male rats was about 8 times higher than in female rats. 4. The free fraction of nilvadipine in plasma was 1.94% in mice, 1.89% in rabbits and 0.85% in dogs, with no dependence on plasma concentration over a range of 10-100 ng/ml.     

Pharmacokinetics and brain uptake of diazepam after intravenous and intranasal administration in rats and rabbits

The purpose of this study was to investigate the plasma pharmacokinetics and brain uptake of a lipophilic benzodiazepine anticonvulsant, diazepam in New Zealand white rabbits and Sprague-Dawley rats to evaluate the possible absorption pathways after intravenous and intranasal administration. The intranasal formulation was prepared by dissolving DZ and 1% sodium glycocholate into microemulsion system composed of 15% ethyl laurate, 25% Labrasol, 37.5% Transcutol P, 12.5% ethanol, and 10% water. Diazepam was administered intravenously (1 mg/kg) or intranasally (2 mg/kg) to rats and rabbits. Drug concentrations in the plasma and six different regions of the brain tissues, i.e., olfactory bulb, olfactory tract, anterior, middle, and posterior segments of cerebrum and cerebellum were analyzed by LC/MS method after solid phase extraction. After i.n. administration, DZ was rapidly absorbed into the systemic circulation, and readily and homogeneously distributed into the different regions of brain tissues with a t(max) of 5 and 10 min in rats and rabbits, respectively. The bioavailability of DZ in rat plasma (68.4%) and brain (67.7%) were 32-47% higher than those observed in rabbit plasma (51.6%) and brain (45.9%). The AUC(brain)/AUC(plasma) ratios in rabbits after i.n. administration (3.77+/-0.17) were slightly lower than from i.v. administration (4.23+/-0.08). However, in rats the AUC(brain)/AUC(plasma) ratios after i.v. (3.03+/-0.07) and i.n. (3.00+/-0.32) administration were nearly identical. The plasma pharmacokinetic and distribution studies in the two animal models clearly showed that lipophilic DZ molecules reached the brain predominantly from the blood by crossing the blood-brain barrier after i.n. administration with no significant direct nose-to-brain transport via olfactory epithelium.     

Bioavailability of silicon and aluminum from Zeolite A in dogs

A study in beagle dogs was carried out to estimate the bioavailability of silicon and aluminum from Zeolite A administered as a capsule, oral suspension, and oral solution relative to an intravenous bolus infusion (i.v.) administered over a 1-1.5 min interval. Twelve dogs received single doses of Zeolite A after a 1 week control period in a randomized five-way crossover design. Plasma samples were drawn at time 0 and for 36 h after dosing. The concentrations of silicon and aluminum were determined by graphite furnace atomic absorption at the University of North Carolina School of Medicine (Bioanalytical Laboratory, UNC). The plasma silicon and aluminum data from i.v. infusion were best described by two-compartment and three-compartment open models, respectively. The mean elimination half-life and clearance of silicon from the i.v. dose were 17.5 h and 0.221 ± 0.0192 ml/min per kg. The mean extent of absorption of silicon from the oral capsule, oral solution and oral suspension was 2.33%, 3.44% and 2.73%, respectively, relative to the intravenous bolus. The mean elimination half-life and clearance of aluminum were 91.2 h and 0.0497 ± 0.0082 ml/min per kg. The extent of absorption of aluminum from the oral dosage forms was less than 0.1%, relative to the intravenous infusion. The plasma aluminum AUC values from the oral capsule and suspension showed no statistical difference from those during the control period, but the aluminum AUC of the oral solution was statistically greater than the AUC of the corresponding control period.     

Propylhexdrine

Propylhexedrine, a sympathomimetic with varied medicinal uses, is one of the compounds to be reviewed by the Expert Committee convened by the World Health Organization (WHO) to determine whether the compound should be scheduled under the Convention on Psychotropic Substances. This paper reviews the pharmacology, medicinal uses, toxicity and abuse-potential of propylhexedrine, with special emphasis on toxicity and abuse potential. The primary medicinal use of propylhexedrine is temporary symptomatic relief of nasal decongestion due to colds, allergies and allergic rhinitis. When used as a nasal inhaler for this indication, propylhexedrine reduces nasal airway resistance without producing rebound congestion. Abuse does not occur by nasal inhalation; however, a small amount of abuse of the propylhexedrine containing nasal inhalers occurs by oral ingestion of the contents of the inhaler or by intravenous injection. Propylhexedrine is a central nervous system (CNS) stimulant of low abuse potential, a stimulant of low preference for stimulant abusers compared with amphetamine, methylphenidate, phenmetrazine.     

Brain pharmacokinetics of a nonpeptidic corticotropin-releasing factor receptor antagonist.

Corticotropin-releasing factor (CRF) is known to play an important role in the body response to stress. Butyl-[2,5-dimethyl-7-(2,4,6-trimethylphenyl)-7H-pyrrolo[2,3-d]pyrimidin-4-yl]-ethylamine (CP-154,526) is a CRF(1) antagonist showing anxiolytic activities in rats in behavioral models, suggesting that CP-154,526 crosses the blood-brain barrier. However, there is no direct evidence for this. This study determined the pharmacokinetic profile of CP-154,526 in rats after i.v. and p.o. application. After i.v. bolus, the concentration declined in a biphasic manner, the first half-life being 0.9 h and the terminal one being 51 h. Systemic clearance was 36 ml/min/kg, and the volume of distribution was 105 l/kg. Oral bioavailability reached 27%. To study brain pharmacokinetics, rats were given a single dose of CP-154,526 p.o. or i.v. and sacrificed after different post-treatment times. Plasma, cortex, striatum, hypothalamus, hippocampus, and cerebellum concentrations were measured. After i.v. bolus, maximal brain concentration was reached after 20 min. The hypothalamus displayed significantly lower concentrations compared with the other brain tissues. In the p.o. study, the maximal plasma concentration was reached after 30 min, whereas the maximal brain concentration was observed after 1 h and remained stable until 2 h post-treatment, without significant differences between the brain tissues. The unidirectional brain extraction ratio was 27 and 9% at vascular concentrations of 0.08 and 16 nmol/ml, respectively. These results demonstrate a large brain penetration of CP-154,526 after i.v. and p.o. applications and a comparable distribution among the brain regions, except for the hypothalamus, which displayed lower concentrations after i.v. bolus.     

Kinetic and pharmacological studies on estazolam in mice and man

After i.v. and oral doses of estazolam (5 mg/kg) to mice, the drug was rapidly cleared with a beta half-life (t1/2 beta) of 0.7 h. The active metabolite, 1-oxo-estazolam, was present in traces in mouse plasma and brain. Its elimination t1/2 (beta), determined after i.v. injection of 1-oxo-estazolam (5 mg/kg) to mice, was similar to that of the parent drug in both plasma and brain. After a single oral dose of estazolam (4 mg) to four human volunteers the drug was rapidly absorbed and reached maximum plasma concentrations in one to three hours. Elimination t1/2 of estazolam in humans was 19 h. The metabolite was undetectable in human plasma after either single or multiple doses of estazolam. These results, together with the finding that 1-oxo-estazolam was less effective than estazolam, in terms of ED50 and brain concentrations necessary to antagonize leptazol convulsions and disrupt rota-rod performance in mice, indicate that the metabolite does not contribute significantly to the pharmacological effects of its parent drug.     

Pharmacokinetics of ipratropium bromide after single dose inhalation and oral and intravenous administration

Single doses of ipratropium bromide were administered intravenously, orally and by slow inhalation to ten healthy male volunteers. The plasma level after oral administration followed a low but broad plateau persisting for several hours. After i.v. administration the kinetic parameters were: Vc = 25.9 l, V alpha = 13.1 l, V beta = 3.38 l, t1/2 alpha = 3.85 min, t1/2 beta = 98.4 min, AUC = 15.0 h.ng/ml, kel = 11.8 l/h and total clearance is 2325 ml/min. The bioavailability was 3.3% (range 0.9-6.1%) on comparing the plasma AUCs following i.v. and 20 mg oral administration. The cumulative renal excretion (0-24 h) after i.v. administration was compared with that after oral administration and inhalation. Following oral administration, the apparent systemic availability was around 2%, and after inhalation it was 6.9%. In comparison with oral placebo administration, only after i.v. administration was there a significant change in heart rate (from 63.7 to 90.2 beats/min). The systolic blood pressure rose from 115.1 to 119.6 mm Hg and the diastolic blood pressure from 68.3 to 78.3 mm Hg.     

Pharmacokinetics and metabolism of the antiarrhythmic agent [3H]-diprafenone in the rat

After acute intravenous (i.v.) administration of 3 mg/kg of 3H-labelled 2'[2-hydroxy-3-(1,1-dimethylpropylamino)propoxy]-3-phenylproiop henon hydrochloride ([3H]-diprafenone), plasma radioactivity levels declined biphasically with half-lives of 0.2 h (alpha-phase) and 1.5 h (beta-phase), respectively. After acute oral administration of 9 mg/kg, absorption was prompt but continued, similar to a zero-order process, over many hours resulting in plateau-like plasma levels up to 5-6 h and a subsequent slow decline with a beta-half-life of 6-8 h. Absorption varied between 50 and 80%. Distribution of [3H]-diprafenone was rapid and tissue levels in general paralleled blood levels. After i.v. dosing highest levels of radioactivity were found in the lung; after oral application in the gastrointestinal tract. Radioactivity was distributed into subcellular organelles and the cytosol resulting in an apparent volume of distribution (Varea) of 4-5 l/kg. About 95% of the 3H-activity given was excreted in urine (20%) and faeces (75%) within 48 h after i.v. administration. After oral application, total 3H-recovery was substantially lower. After i.v. dosing most of the 3H-label found in faeces originated from biliary excretion and was almost completed within 4 h after administration. After oral application, biliary excretion varied between about 5 and 35% indicating protracted absorption. 3H-radioactivity was reabsorbed and subject to extensive enterohepatic cycling. After repetitive oral administration, total radioactivity reached a steady state after 4-5 days. The corresponding cumulation factors R ranged between 2 and 3. A decline in elimination rate is likely. [3H]-Diprafenone was metabolized rapidly and quantitatively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Bioavailability of metoprolol in young adults and the elderly,with additional studies on the effects of metoclopramide and probanthine

The plasma concentration curves and urinary excretion of oxmetidine after administration of single i.v. (100 mg) and oral (200 mg) doses have been studied in 11 patients with peptic ulcer disease. The mean bioavailability of the drug was 70% (range 53-91%). After intravenous administration, the mean plasma t 1/2 beta was 3.0 h, the mean apparent volume of distribution 0.7 l/kg, the mean total plasma clearance 12.3 l/h and the mean plasma renal clearance was 0.7 l/h. Following intravenous and oral administration an average of 6% and 3%, respectively, of unchanged drug was found in the urine. The plasma concentration curve after oral administration in most patients exhibited two maxima, with peak concentrations appearing between 45 and 210 min after dosing.     

Pharmacokinetics of a novel antiangiogenic agent KR-31831 in rats

This study reports the absorption, dose-linearity and pharmacokinetics of a novel antiangiogenic agent KR-31831 in rats after i.v. and oral administration at doses of 5, 10 and 25 mg/kg on both occasions. Concentrations of KR-31831 were determined by a validated LC/MS/MS assay method. After i.v. injection, plasma concentration-time profiles showed multi-compartmental characteristics, and there were no significant differences in Cl (20.8-27.7 ml/min/kg) and dose-normalized AUC (178.1-231 microg x min/ml based on the 5 mg/kg dose) as a function of dose. However, Vss was significantly increased at the 25 mg/kg dose (4931 ml/kg) compared with those (2288-2421 ml/kg) at lower doses. Subsequently, t1/2 was increased from 143-159 min at the lower doses to 304 min at the 25 mg/kg dose. The altered VSS was found to be a result of reduced plasma protein binding at relatively high concentrations. Following oral administration (doses 5-25 mg/kg), the absolute oral bioavailability ranged from 37.8% to 46.3%, and there were no significant alterations in dose-normalized AUC, Tmax, Cmax and t1/2 as a function of dose. The extent of urinary excretion was low for both i.v. (0.35%-0.54%) and oral (0.13%-0.33%) doses. Further discussions on the chemical and microsomal stability were included. In conclusion, dose-independent absorption kinetics were observed at oral doses from 5 to 25 mg/kg in rats. Orally administered KR-31831 could be eliminated mainly by the liver metabolic pathway.     

Pharmacokinetics of the ginkgo B following intravenous administration of ginkgo B emulsion in rats

Ginkgo B (GB) is an extract from the leaves of Ginkgo biloba, used in the treatment of dementia, cerebral insufficiency or related cognitive decline. In this paper, the main features of the pharmacokinetics of GB emulsion in rats were reviewed and the binding rate of GB to rat plasma and human plasma protein were investigated meanwhile. The concentrations of GB in plasma, tissue, and excretion of rats after i.v. administration of GB were measured using HPLC-ESI-MS. The metabolite was qualitated by LC-MS/MS. Intravenously administered GB was eliminated in a biphasic manner with a prominent initial phase (half-life of 0.3 h) followed by a slower terminal phase (half-life of 1.5 h). After i.v. 4, 12 and 36 mg/kg GB emulsion, the pharmacokinetic parameters from a two compartment model analysis of plasma samples were AUC(0-tau) (microg x min/ml): 53.7, 165.5 and 649.7; CL (l/min/kg): 0.07, 0.07 and 0.05; V(C) (l/kg): 2.27, 3.27 and 2.76, respectively. Peak concentrations generally occurred at 10 min except brain and fat. Tissue concentration then declined by several-fold during 6 h although still present in most tissues at 6 h. Single intravenous dose was mainly excreted in the urine (40-50%), feces contained less than 30%. The binding rate to rat plasma was little higher than to human plasma, but the difference was negligible. Some metabolites were found in urine and bile through qualitative analysis on the urine and bile by LC-MS/MS.     

Population pharmacokinetic approach to compare oral and i.v. administration of etoposide

The antitumor effect of etoposide (ETO) may be related to duration of exposure to a relatively low serum level while myelosuppression may be dependent on peak ETO serum levels. With regard to such therapeutic ranges, duration of exposure to predefined plasma ETO concentration ranges and the related AUC (expressed as percent of total AUC, pAUC) were used to compare pharmacokinetic profiles after oral and short time i.v. (1 h infusion) administration of identical ETO doses (100 mg/m2). Patients included in this study received i.v. (18 patients, short-term infusions) or oral (16 patients) ETO on different treatment schedules. Plasma ETO concentrations were determined by HPLC and population pharmacokinetic parameters were calculated (P-Pharm 1.4). Despite an 'apparent bioavailability' of 59%, oral administration of ETO was associated with the same time of exposure to a predefined 'therapeutic range' of 0.5-3 mg/l and a significantly higher pAUC compared to i.v. administration. By contrast, time of exposure to the probably more myelotoxic concentration range above 3 mg/l was significantly shorter and the related pAUC was highly significantly lower after oral than after i.v. administration. These findings demonstrate that oral ETO therapy is at least equivalent to short time i.v. therapy in terms of achieving specific target concentration ranges and avoiding peak concentrations.