Comparative single-dose pharmacokinetics of clonazepam following intravenous, intramuscular and oral administration to healthy volunteers

The objective was to assess the single-dose pharmacokinetics of clonazepam following i.m., p.o. and i.v. administration. In an open-label, three-way crossover study, 12 healthy volunteers were randomized to receive a single dose of 2 mg clonazepam either by the i.m., p.o. or i.v. route. Serial blood samples were collected up to 120 h after drug administration. Plasma concentrations of clonazepam were determined by electron-capture gas-liquid chromatography. The absorption rates of clonazepam after i.m. and p.o. administration of clonazepam were significantly different from each other, as reflected by the respective mean values of maximum plasma concentration (C(max) 11.0 vs. 14.9 ng.ml(-1)) and time to reach maximum concentration (t(max) 3.1 vs. 1.7 h). Secondary plasma peaks of clonazepam were observed in 9 volunteers after i.m. injection (C(max) 9.9 ng.ml(-1); t(max) 10.4 h). A comparison of the area under the plasma concentration-time curves (AUC) shows that the i.m. route is equivalent to the oral route (AUC(0- infinity ) 620 vs. 561 ng.h.ml(-1)). Clonazepam was almost completely absorbed after i.m. and p.o. administration, as shown by the mean absolute bioavailability of 93 and 90%, respectively. No significant differences existed between the elimination half-lives (i.v. 38.0 h; i.m. 43.6 h; p.o. 39.0 h). The average clearance and volume of distribution (V(Z)) were 55 ml.min(-1) and 180 liters, respectively. In conclusion, the observed differences in C(max) and t(max) after i.m. and p.o. administration were consistent with a slower absorption rate of clonazepam after i.m. injection. The systemic exposure to clonazepam was not affected by the route of extravascular administration. Statistical evaluation of these kinetic data showed differences in the absorption rate, so that clonazepam given by the i.m. route is not bioequivalent to the oral route. On the basis of the results of this study, we would recommend the same i.m. and p.o. dose in epileptic patients, but therapeutic response would be expected to be less predictable and to occur later in the case of i.m. administration.

Comparative single- and multiple-dose pharmacokinetics of levodopa and 3-O-methyldopa following a new dual-release and a conventional slow-release formulation of levodopa and benserazide in healthy volunteers

The objective was to assess the single- and multiple-dose pharmacokinetics of levodopa and 3-O-methyldopa following administration of a new dual-release and conventional slow-release formulation of levodopa/benserazide in the dose ratio of 4:1. In an open-label, two-way cross-over study, 20 healthy volunteers were randomized to receive first either Madopar DR or Madopar HBS for 8 days. Then they crossed over to the other formulation. A first dose of 200 mg levodopa and 50 mg benserazide ('250' mg) was given on day 1, '125' mg t.i.d. on the subsequent 6 days (days 2-7), followed by '250' mg on day 8. The two treatment periods of 8 days were separated by a wash-out period of at least 7 days. Blood samples were taken at specific times over a 12-hour period (day 1) or a 36-hour period (day 8). Plasma concentrations of levodopa and 3-O-methyldopa were measured by high-performance liquid chromatography for pharmacokinetic evaluation. The pharmacokinetics of levodopa after a single-dose administration (day 1) of Madopar DR and Madopar HBS were significantly different as reflected by the respective mean values of maximum plasma concentration (C(max) 1.99 vs. 0.82 mg x l-1), time to reach maximum concentration (t(max) 0.7 vs. 2.6 h) and area under the plasma concentration-time curve (AUC(0- infinity ) 4.52 vs. 3.18 mg x h x l-1). The respective values after multiple doses (day 8) were: C(max) 1.98 vs. 0.93 mg x l-1, t(max) 0.7 vs. 2.3 h and AUC(0-infinity ) 4.84 vs. 3.96 mg x h x l-1. The relative bioavailability (Madopar DR vs. Madopar HBS) was 1.73 on day 1 and 1.32 on day 8. Bioequivalence could not be demonstrated for log-transformed data of AUC and C(max) within a predefined range of 80-125 and 70-143%, respectively. In conclusion, the observed differences in C(max), t(max) and AUC are consistent with a faster rate and higher extent of levodopa absorption after administration of Madopar DR. Statistical evaluation of these kinetic data showed that Madopar DR is not bioequivalent to Madopar HBS.

Pharmacokinetic studies with a dual-release formulation of levodopa, a novel principle in the treatment of Parkinson's disease

The objectives of the two studies reported here were the investigation of the influence of tablet breaking and food on the pharmacokinetics of levodopa and 3-O-methyldopa (3-OMD) after administration of a new levodopa/benserazide formulation with a biphasic drug delivery profile (Madopar DR). Both studies had an open-label, randomised, two-way crossover design and were conducted in 12 healthy young subjects. The pharmacokinetics of levodopa and 3-OMD after one intact or two halved tablets were very similar with average Cmax and tmax 1.9 mg x l(-1) and 1.2 h, respectively. Administration of the formulation after a standard breakfast did not influence the extent of levodopa absorption but increased the absorption rate. Cmax and tmax were on average 2.1 mg x l(-1) and 1.3 h, respectively, in the fed condition and 1.5 mg x l(-1) and 2.5 h in the fasted condition. The presence of food did not markedly affect the plateau in levodopa levels between about 1 and 3 h after intake. In conclusion, the release characteristics in healthy subjects of the new levodopa/benserazide formulation are influenced only to a minor extent by concomitant intake of food or by tablet breaking.

COMT inhibition by tolcapone further improves levodopa pharmacokinetics when combined with a dual-release formulation of levodopa/benserazide. A novel principle in the treatment of Parkinson's disease

The objective of the study reported here was the investigation of the effect of catechol-O-methyl transferase (COMT) inhibition by tolcapone on the pharmacokinetics of levodopa and 3-O-methyldopa (3-OMD) after administration of a new dual-release formulation (dual-RF) of levodopa/benserazide (200/50). The study had a double-blind, placebo-controlled, randomized, crossover design and was conducted in 18 healthy young subjects. On the 2 treatment days, separated by a washout period of 7 days, the dual-RF was administered in combination (blinded) with tolcapone (200 mg) or placebo. Both treatment combinations were well tolerated. Tolcapone increased the bioavailability (AUC 0-infinity) and apparent elimination half-life (t(1/2)) of levodopa by 80 and 40%, respectively, compared to placebo. The maximal plasma concentration (Cmax) was slightly elevated by tolcapone. In the presence of tolcapone, formation of 3-OMD was substantially reduced. In conclusion, the effect of tolcapone on levodopa pharmacokinetics after administration of the dual-RF is similar to the one observed after immediate- and slow-RFs and leads to a marked improvement in levodopa pharmacokinetics and subsequently to an optimization of levodopa therapy.

Lack of bioequivalence of a generic mefloquine tablet with the standard product

OBJECTIVE

To assess the bioequivalence between a generic tablet of mefloquine (Mephaquin = M1) with the reference tablet (Lariam = M2) in healthy volunteers.

METHODS

This open label, randomized two-way crossover study was performed in a single centre. Following an overnight fast, eighteen healthy volunteers received a single oral dose of 750 mg mefloquine either in the form of three M1 lactabs or three M2 tablets. Serial blood samples were collected up to 8 weeks after drug administration. Plasma samples were analysed for mefloquine and its carboxylic acid metabolite using liquid chromatography and subsequent tandem mass spectrometry (LC-MS/MS). The pharmacokinetic parameters of mefloquine and its metabolite were estimated by non-compartmental methods.

RESULTS

The pharmacokinetics of mefloquine after administration of M1 and M2 tablets were significantly different as reflected by the respective mean values of maximum plasma concentration (Cmax 656 vs 1018 ng x ml(-1)), time to reach maximum concentration (tmax 46 vs 13 h) and area under the plasma concentration-time curve (AUC0-->infinity 338 vs 432 microg x h x ml(-1)). No significant differences existed between the elimination half-lives of the two formulations (394 vs 396 h). The relative bioavailability (M1 vs M2) was 0.78 and ranged from 0.38 to 1.37. Bioequivalence could not be demonstrated for log-transformed data of AUC0-->infinity or AUC0-->last within a predefined range of 80-125% and for Cmax within a range of 70-143%.

CONCLUSIONS

The observed differences in Cmax, tmax and AUC are consistent with a slower rate and lower extent of mefloquine absorption after administration of M1. Statistical evaluation of these kinetic data showed that the M1 tablet is not bioequivalent to the M2 tablet. Clinical consequences of this finding cannot be excluded.

Comparative single- and multiple-dose pharmacokinetics of levodopa and 3-O-methyldopa following a new dual-release and a conventional slow-release formulation of levodopa and benserazide in healthy subjects

A multiple-dose study was performed to assess the pharmacokinetic profile of a new levodopa/benserazide dual-release formulation (DRF) in comparison with a conventional slow-release formulation (SRF). The study was of an open label, randomized, two-way cross-over design and was conducted in 18 subjects. Assessment of the two formulations was at day 1 (single-dose) and at day 7 after a 5-day t. i.d. pre-treatment (100 mg levodopa and 25 mg benserazide) in fasting state. The pharmacokinetic parameters reflecting bioavailability, accumulation and metabolism of levodopa were determined. The levodopa pharmacokinetics of the new DRF showed rapid absorption (tmax=1.1 h), followed by sustained levodopa plasma concentrations, similar to the SRF. Following multi-dose administration, the peak plasma concentration of the new DRF was 90% higher compared to the SFR (Cmax=2.1 and 1.1 microg/ml, respectively). The bioavailability was significantly increased by 40% (AUC0-infinity=6.1 and 4.3 microg x h/ml, respectively). The new DFR was well tolerated as shown by the low incidence of mild side effects. In conclusion, the results of this study confirmed the levodopa dual-release properties of this new levodopa/benserazide formulation.

Food increases the bioavailability of mefloquine

OBJECTIVES

To assess the effect of food on the pharmacokinetics of the antimalarial mefloquine and its major plasma metabolite in healthy volunteers.

METHODS

In an open, two-way cross-over study, 20 healthy male volunteers who had fasted overnight were randomised to receive a single oral dose of 750 mg mefloquine in the absence or presence of a standardised, high-fat breakfast, administered 30 min before drug administration. Blood samples were taken at specific times over an 8-week period. Plasma concentrations of mefloquine and its carboxylic acid metabolite were determined by high-performance liquid chromatography for pharmacokinetic evaluation.

RESULTS

The parameters Cmax and AUC of both mefloquine and its metabolite were significantly (P < 0.05) higher under post-prandial conditions than under fasting conditions (mefloquine: mean Cmax 1500 vs 868 micrograms.l-1, mean AUC 645 vs 461 mg l-1.h; metabolite: Cmax 1662 vs 1231 micrograms.l-1, AUC 1740 vs 1310 mg l-1.h). The intersubject variability in Cmax and AUC of mefloquine was less than 30% (coefficient of variation). The time to peak plasma concentration of mefloquine was significantly shorter after food intake (17 vs 36 h). Compared with absorption in volunteers who had fasted, food did not alter t1/2 (mefloquine and its metabolite) and tmax (metabolite).

CONCLUSION

Under the conditions of this study, food increases the rate and the extent of mefloquine absorption. It is reasonable to recommend that mefloquine be administered with food in travellers receiving chemoprophylaxis and in patients on recovery receiving curative treatment. In acutely ill patients, mefloquine should be taken as soon as possible and administration with or shortly after meals should be attempted as soon as feasible.

Stereoselective passage of mefloquine through the blood-brain barrier in the rat

The pharmacokinetics of the enantiomers of mefloquine were studied in the rat after administration of a racemic mixture and of the separate enantiomers (+)-mefloquine and (-)-mefloquine. When 50 mg kg-1 racemic mixture was administered orally for 22 days, plasma concentrations of the (+) enantiomer were 2-3 times higher than those of the (-) enantiomer whereas the opposite was true in every part of the brain (cerebellum, cortex, hippocampus, hypothalamus and striatum). Different concentrations of mefloquine were found in the different regions of the brain; the lowest concentrations of (+/-)-mefloquine (27.0 nmol g-1) were in the cerebellum and the highest (110.0 nmol g-1) in the hippocampus. The main metabolite, carboxymefloquine, was detected in plasma but not in the brain. The results indicate the mefloquine crosses the blood-brain barrier stereoselectively.

Pharmacodynamics of benserazide assessed by its effects on endogenous and exogenous levodopa pharmacokinetics

AIMS

The objectives of the study were to investigate the pharmacodynamics of the peripheral decarboxylase inhibitor benserazide during multiple-dose regimens.

METHODS

Two groups of eight healthy male subjects were consecutively treated for periods of 14 days with benserazide 5, 25, 100 mg three times daily and 12.5, 50, 200 mg three times daily, respectively. Plasma levels of levodopa, 3-O-methyldopa (3-OMD) and 3,4-dihydroxyphenylacetic acid (DOPAC) were determined before benserazide treatment and during all benserazide dosing regimens, as existing endogenously and after administration of 250 mg levodopa.

RESULTS

Endogenous concentrations of levodopa and 3-OMD increased dose-dependently (from 8 up to 52 microg l(-1) and from 0.02 up to 0.50 mg l(-1) , respectively, at doses of 200 mg) with ascending doses of benserazide whereas DOPAC levels remained unchanged. There were no indications of a plateau in the effects of benserazide on the plasma levels of the analytes. The area under the concentration-time curve (AUC) of exogenously administered levodopa increased from 1.2 in the control group to 5.9 mg l(-1) h at benserazide doses of 100-200 mg three times daily. Benserazide caused a dose-dependent increase in the AUC of 3-OMD from 7.4 to 106 mg l(-1) h at doses of 200 mg. Formation of DOPAC was dose-dependently suppressed, with benserazide 5 mg three times daily already halving its AUC.

CONCLUSIONS

The benserazide-dose response data obtained suggest that even at very high doses extracerebral decarboxylase is not yet completely inhibited.

Tolerance of mefloquine by SwissAir trainee pilots

Due to presumed adverse performance impact, a World Health Organization clause currently restricts the use of mefloquine malaria chemoprophylaxis in individuals requiring fine coordination and spatial discrimination. We conducted a double-blind, placebo-controlled, cross-over study to quantitatively assess the effects of mefloquine at steady state on performance in 23 trainee airline pilots. Flying performance was assessed using a flight simulator, psychomotor function was evaluated, sleep and wake cycles were monitored, and symptoms and moods were assessed using standardized questionnaires. A simplified postural sway meter recorded sway in three test positions. In the mefloquine loading dose phase, there was one withdrawal due to dizziness, diarrhea, and flu-like symptoms, and three volunteers reported nonserious, sleep-related adverse events. There was no significant difference in flying performance, psychomotor functions, or mean sway for any test position. Nonsignificant reductions in mean total nocturnal sleep (mefloquine = 450 min versus placebo = 484 min) and poorer sleep quality were detected in the mefloquine phases. The mood findings indicated a predominance of positive states, with vigor the predominant mood in all phases. No significant performance deficit was documented under laboratory conditions during use of mefloquine at steady state.

Effects of mefloquine alone and with alcohol on psychomotor and driving performance

OBJECTIVE

To determine whether mefloquine, a quinoline antimalarial drug, affects psychomotor and actual driving performance when given in prophylactic regimen, alone or in combination with alcohol.

METHODS

Forty male and female volunteers were randomly assigned in equal numbers to two groups, and were treated double-blind for one month with mefloquine and placebo. The medication was taken in a 250 mg dose on the evenings of Days 1, 2, 3, 8, 15, 22 and 29. Testing was done on Days 4, 23 and 30, the latter after repeated doses of alcohol sufficient to sustain a blood concentration of about 0.35 mg.ml-1. Two real driving tests were used to measure prolonged (1 h) road tracking and car following performance. Critical Flicker/Fusion Frequency (CFF), critical instability tracking and body sway were also measured in the laboratory.

RESULTS

Mefloquine caused no significant impairment in any test at any time relative to placebo. It significantly improved road tracking performance on Day 4. A significant interaction between prior treatment and alcohol was found in the body sway test, as the alcohol-induced change was less after mefloquine than placebo. The sensitivity of the driving test and the CFF test were shown by the significant overall effect of alcohol which did not discriminate between the two prior treatments.

CONCLUSION

Mefloquine did not impair driving performance but rather improved it in the longer test, suggesting that the drug may possess psychostimulating properties.

The chemotherapy of rodent malaria. LII. Response of Plasmodium yoelii ssp. NS to mefloquine and its enantiomers

A comparison was made between the blood schizontocidal action in mice of racemic mefloquine hydrochloride and the free bases of its (+)- and (-)-enantiomers (Ro 13-7224 and Ro 13-7225) against chloroquine-resistant Plasmodium yoelii ssp. NS. The racemic hydrochloride was two to three times as active against this parasite in mice as either of the enantiomer free bases, which were of similar activity to each other. Under drug selection pressure, the parasites acquired resistance in approximately the same time for each of the three compounds.

Pharmacokinetics of ceftriaxone in patients with typhoid fever

Ceftriaxone in short courses has emerged as an effective alternative to chloramphenicol for the treatment of typhoid fever. To study the pharmacokinetics of ceftriaxone in acute typhoid fever, 10 febrile Nepalese adolescents and young adults with blood culture-positive illness were treated with 3 g of ceftriaxone (intravenous infusion for 30 min) daily for 3 days. On the 1st and 3rd day of treatment, blood and urine samples were collected at defined intervals for measurements of drug concentrations. Kinetic parameters including concentrations at the end of infusion (Cmax) and 24 h after the end of infusion (Cmin), elimination half-life (t1/2), area under the plasma concentration-time curve (AUC), total plasma clearance, renal clearance, percentage excreted in urine, and volume of distribution were estimated. On day 1, mean values were as follows: Cmax, 291 micrograms/ml; Cmin, 21.7 micrograms/ml; plasma t1/2, 5.2 h; AUC, 1,428 micrograms.h/ml; total plasma clearance, 37 ml/min; renal clearance, 19 ml/min; percentage excreted in urine, 49.7%; and volume of distribution, 16.1 liters. Mean values on day 3 were not significantly different from those on day 1. Compared with published values for healthy volunteers who received the same dose, our mean t1/2s and AUCs were lower and our mean total plasma clearances, renal clearances, and volumes of distribution were higher. The good clinical responses of these patients to therapy and the adequate Cmins support the use of ceftriaxone once daily for the treatment of typhoid fever.

Stereoselective pharmacokinetics of mefloquine in healthy Caucasians after multiple doses

Mefloquine (MQ) is a chiral antimalarial agent effective against chloroquine-resistant Plasmodium falciparum. It is commercially available as a racemic mixture of the (+) and (-) enantiomers for oral administration. The pharmacokinetics of the (+) and (-) enantiomers of MQ were studied in eight healthy volunteers after administration of a first oral dose of 250 mg of racemic MQ and at steady state after 13 repeated doses of 250 mg given at 1-week intervals. Plasma samples were collected, and concentrations of each enantiomer were determined using a previously described achiral-chiral double column-switching liquid chromatographic method. At each time point, higher plasma concentrations values were found for the (-) enantiomer (p < 0.001). At steady state, Cmax values of (-)-MQ were higher than those of (+)-MQ (1.42 +/- 0.19 versus 0.26 +/- 0.05 mg/L; p < 0.001). Similarly, the plasma concentrations 7 days after the final dose were higher for (-)-MQ (1.01 +/- 0.26 versus 0.11 +/- 0.04 mg/L; p < 0.001). AUC values at steady state were also higher for (-)-MQ (197.3 +/- 36.7 versus 30.1 +/- 8.9 mg/L x h; p < 0.001). The terminal half-life values (T1/2beta) were longer for (-)-MQ (430.4 +/- 225.2 versus 172.8 +/- 56.5 h; p < 0.001). This study shows that the pharmacokinetics of MQ is highly stereoselective.

Bioavailability and feasibility of subcutaneous 5-fluorouracil

Continuous intravenous (i.v.) infusion of 5-fluorouracil (5-FU) has been shown to be superior to bolus regimens in terms of response rates and toxicity. However, a continuous infusion is more expensive and prone to complications such as thromboembolism and infections. A way to circumvent these problems would be to administer 5-FU subcutaneously (s.c.). To assess feasibility and bioavailability of s.c. 5-FU, eight patients with advanced cancer received 250 mg 5-FU as an infusion over 90 min either intravenously (i.v.) or s.c. into the abdominal wall. The mean +/- s.d. bioavailability of s.c. 5-FU was 0.89 +/- 0.23. The interpatient variability for the area under the plasma concentration-time curve was 48% for the s.c. and 36% for the i.v. infusion. No local side effects were observed. To test the local tolerance of a more prolonged administration three patients received 930-1,000 mg m-2 5-FU by 24-h continuous s.c. infusion. The steady-state plasma levels were comparable to i.v. infusion. One patient developed a painless skin pigmentation at the s.c. infusion site. However, the same reaction was observed at the forearm after i.v. infusion. We conclude that at the dose studied s.c. 5-FU has an almost complete bioavailability and is well tolerated. Further work will show, whether prolonged s.c. infusion can be used as a safe and economical alternative to i.v. infusion.

Steady state pharmacokinetics of mefloquine in long-term travellers

Mefloquine is an antimalarial drug with a 3-week elimination half-life, which has led to concerns that toxic accumulation may occur during weekly administration for long-term malaria chemoprophylaxis. Despite the endorsement of weekly mefloquine by the World Health Organization and the United States Centers for Disease Control, mefloquine pharmacokinetics have been incompletely studied in subjects taking the drug once weekly for more than 4 weeks. Our objective was to study plasma mefloquine concentrations in travelers taking mefloquine 250 mg once weekly for 3 months. Multiple mefloquine concentrations were measured by high pressure liquid chromatography following the 1st, 2nd and 10th to 13th of 13 weekly doses of 250 mg mefloquine taken by 15 Canadian travellers (median age 23 years; 6 male, 14 white). Steady state was achieved in all subjects by or before the 10th dose. Mefloquine pharmacokinetic values were comparable to those previously reported by other investigators. In 7 subjects, 2 peaks of mefloquine and metabolite concentration followed ingestion, suggesting redistribution of mefloquine. Mefloquine concentration 14 d after the last dose was 74% of the level 7 d after the last dose. In conclusion, pharmacokinetic values determined by this study support mefloquine weekly dosing for long-term malaria chemoprophylaxis; toxic accumulation does not occur and weekly dosing is associated with significantly higher trough levels than 14 d dosing.

Ceftriaxone--bilirubin-albumin interactions in the neonate: an in vivo study

The in vivo bilirubin-albumin binding interaction of ceftriaxone (CRO) was investigated in 14 non-jaundiced newborns, aged 33-42 weeks of gestation, during the first few days of life after they had reached stable clinical condition. CRO (50 mg/kg) was infused intravenously over 30 min. The competitive binding effect of CRO on the bilirubin-albumin complex was estimated by determining the reserve albumin concentration (RAC) at baseline, at the end of CRO infusion, and at 15 and 60 min thereafter. Immediately after the end of drug administration, RAC decreased from 91.9 (+/- 25.1) mumol/l to 38.6 (+/- 10.1) mumol/l (P = 0.0001). At the same time the plasma bilirubin toxicity index (PBTI) increased from 0.64 (+/- 0.40) before drug infusion to 0.96 (+/- 0.44) thereafter (P = 0.0001). The highest displacement factor (DF) was calculated to be 2.8 (+/- 0.6) at the end of drug infusion. Average total serum bilirubin concentrations decreased from a baseline value of 59.6 (+/- 27.0) mumol/l to 55.2 (+/- 27.1) mumol/l (P = 0.026). Sixty minutes after the end of CRO infusion, RAC was 58.3 (+/- 21.7) mumol/l, PBTI regained baseline, but DF was still 1.9 (+/- 0.2). No adverse events were recorded. Our results demonstrate significant competitive interaction of CRO with bilirubin-albumin binding in vivo. Thus, ceftriaxone should not be given to the neonate at risk of developing bilirubin encephalopathy.

Pharmacokinetics of midazolam administered by continuous intravenous infusion to intensive care patients

OBJECTIVE

To determine the pharmacokinetics of continuously infused midazolam in patients during intensive care.

DESIGN

Descriptive trial.

SETTING

General ICU in a Swiss hospital.

SUBJECTS

Eight critically ill patients requiring mechanical ventilation.

INTERVENTIONS

To achieve an appropriate level of long-term sedation, the rate of iv infusion of midazolam in ICU patients was adjusted individually to between 6 and 15 mg/hr. Blood samples were taken during and after the continuous infusion of midazolam.

MEASUREMENTS

Measurements included plasma concentration time profiles of midazolam and pharmacokinetic parameters, such as elimination half-life, clearance, and volume of distribution.

RESULTS

The elimination half-life was prolonged (mean 5.4 vs. 2.3 hrs) and the volume of distribution was larger (3.1 vs. 0.9 L/kg) in patients vs. healthy volunteers. The clearance did not differ between groups (6.3 vs. 4.9 mL/min/kg in patients vs. volunteers, respectively).

CONCLUSIONS

The increased volume of distribution in our critically ill patients is the major determinant for the observed slower elimination of midazolam. It is unlikely that the hepatic metabolism of midazolam was impaired in these patients.

Electroencephalographic effects of benzodiazepines. II. Pharmacodynamic modeling of the electroencephalographic effects of midazolam and diazepam

The comparative pharmacodynamics of midazolam and diazepam were examined by use of the electroencephalogram as a measure of drug effect on the central nervous system. Intravenous doses of 7.5, 15, and 25 mg midazolam and 15, 30, and 50 mg diazepam were given on repeated occasions to three volunteers. Arterial plasma concentration and electroencephalogram voltage were related with nonparameteric and parametric pharmacodynamic models. The peak increases in voltage (maximal effect) and the slopes of the plasma concentration versus effect curve were similar for both drugs. The half-time of blood:brain equilibration was significantly longer for midazolam than diazepam (4.8 minutes versus 1.6 minutes). Midazolam was found to have an intrinsic steady-state potency that was approximately five times greater than that of diazepam (152 ng/ml versus 958 ng/ml).

Pharmacokinetics of midazolam following intravenous and oral administration in patients with chronic liver disease and in healthy subjects

To study the effects of cirrhosis of the liver on the pharmacokinetics of midazolam single IV (7.5 mg as base) and p.o. (15.0 mg as base) doses of midazolam were administered to seven patients with cirrhosis of the liver and to seven healthy control subjects. One cirrhotic patient did not receive the oral dose. The distribution of midazolam in both study groups was alike as indicated by similar values of t1/2 alpha, V1 and Vss. Also the plasma protein binding of midazolam was unchanged in the patients with cirrhosis. The elimination of midazolam was significantly retarded in the patients as indicated by its lower total clearance (3.34 vs. 5.63 ml/min/kg), lower total elimination rate constant (0.400 vs. 0.721 h-1), and longer elimination half-life (7.36 vs. 3.80 h). The bioavailability of oral midazolam was significantly (P less than 0.05) higher in patients than controls (76% vs. 38%). The antipyrine-half-life was 32.4 h in the patients and 11.8 h in the controls. There were statistically significant (P less than 0.01) correlations between the clearances of the two drugs (r = 0.680) and between their half-lives (r = 0.755). The hypnotic effects of midazolam were similar in both groups. However, on a pharmacokinetic basis a reduced dosage of midazolam to patients with advanced cirrhosis of the liver is recommended.

A randomized comparison between midazolam and thiopental for elective cesarean section anesthesia: III. Placental transfer and elimination in neonates

Forty neonates delivered by cesarean section were studied, half being delivered of mothers in whom anesthesia was induced with midazolam (0.3 mg/kg intravenously) and half of mothers given thiopental (4 mg/kg). At delivery, blood samples from mother and the umbilical vein were drawn for determination of plasma concentrations of thiopental, midazolam, and alpha-hydroxymidazolam. Over the next 60 hours, three blood samples were drawn using a randomized procedure of two blood samples at 30 different times. Placental transfer, expressed as the umbilical/maternal concentration ratio, was 0.96, 0.66, and 0.28, respectively, for thiopental, midazolam, and alpha-hydroxymidazolam. The transfer of thiopental was significantly more rapid than the transfer of midazolam and alpha-hydroxymidazolam. The population average of elimination half-life in neonates was 6.3 hours for midazolam and 14.7 hours for thiopental. Both values are substantially larger than those found in previous studies in adults.

Dose equivalence of midazolam and triazolam. A psychometric study based on flicker sensitivity, reaction time and digit symbol substitution test

The pharmacodynamic potency of oral midazolam, a new ultrashort-acting hypnotic benzodiazepine, has been evaluated relative to a standard dose of triazolam, a well established oral benzodiazepine with a similar pharmacological profile. In a balanced design, double-blind cross-over study 6 healthy volunteers received 3.75, 7.5, and 15 mg midazolam and 0.25 mg triazolam orally, at 8 a.m., at weekly intervals. Drug effects were repeatedly measured over 8 h by a new psychometric method, the threshold amplitude for perception of flickering light (TPF) assessed at 5 and 30 Hz. Auditory reaction time, digit-symbol substitution test (DSST), and self-rating by subjects served as reference standards. Median midazolam doses equivalent to 0.25 mg triazolam, interpolated on dose-response curves for peak effects, were 5.2 mg (TPF 30 Hz), 6.4 mg (TPF 5 Hz), 6.5 mg (DSST), and 7.4 mg (reaction time), respectively. Alternative methods of data analysis gave similar results. Introduction of TPF as a highly reproducible and sensitive measure of the effect of benzodiazepines on the CNS offers new opportunities to compare the relative potencies of different benzodiazepines in man. Since clinical experience has shown 0.25 mg triazolam to be safe and effective, it is concluded that the corresponding single oral dose of midazolam is between 5 and 8 mg.

Pharmacokinetics of midazolam in patients recovering from cardiac surgery

The pharmacokinetics of midazolam has been studied in patients recovering from cardiac surgery, who required sedation for postoperative mechanical ventilation. Twelve males (mean age 64.5 years) with severe heart disease received an infusion of midazolam 15 mg.h-1 for 4 h, starting 1 to 3 h post surgery. Multiple blood samples were collected from each patient during the infusion and up to 48-93 h after it. The pharmacokinetic parameters of midazolam were determined using both moment analysis and the program NONMEM. The average terminal half-life was 10.6 h. The prolonged elimination was mainly due to a decrease in its metabolic clearance (0.25 l.min-1). The maintenance infusion dose of midazolam in such patients should be reduced. The time to recovery after stopping an infusion depends upon the amount of drug in the body at that time and a simulation of the plasma concentrations after various infusion regimens suggests that recovery will be delayed after prolonged (greater than 48 h) administration of midazolam to these patients. However, after shorter infusions (less than 12 h), redistribution of the drug away from the site of action was still occurring and recovery would be expected to be relatively rapid.

Plasma tenoxicam concentrations after single and multiple oral doses

The pharmacokinetics of single- and multiple-dose administration of tenoxicam 20 mg were evaluated in 8 healthy males. Maximum plasma concentration (Cmax) after the first dose was 2.76 +/- 0.48 micrograms/ml (mean +/- s.d.) and the time to reach Cmax (Tmax) was 5.0 +/- 3.0 h. The area under the plasma concentration-time curve (AUC0-infinity) after a single administration of tenoxicam was 242.5 +/- 73.5 micrograms x h/ml. The elimination half-life (t1/2) was 66.3 +/- 15.8 h and the plasma concentration at 24 hours after dosing (Cmin) was 1.84 +/- 0.33 micrograms/ml. Steady-state plasma concentrations of tenoxicam were virtually reached after 10 consecutive daily doses. At steady-state, Cmax averaged 13.63 +/- 3.33 micrograms/ml and Tmax remained 5.0 +/- 3.0 hours. AUC within a dosing interval at steady-state was 262.2 +/- 67.0 micrograms x h/ml, Cminss was 9.67 +/- 3.25 micrograms/ml, and t1/2 averaged 74.2 +/- 13.3 h. The average fluctuation during multiple-dose administration was 26.8 +/- 8.0% and the accumulation ratio was 5.82 +/- 0.60. Steady-state pharmacokinetic parameters predicted from the first-dose data slightly underestimated observed values, but the results supported the assumption of linear pharmacokinetics during multiple-dose tenoxicam administration.

Integrated plasma and synovial fluid pharmacokinetics of tenoxicam in patients with rheumatoid arthritis and osteoarthritis: factors determining the synovial fluid/plasma distribution ratio

Single oral doses of 40 mg of the nonsteroidal antiinflammatory drug, tenoxicam, were given to four patients (three with rheumatoid arthritis, one with osteoarthritis). The concentrations of the drug in synovial fluid and plasma were measured by a specific high-performance liquid chromatography method. The unbound fractions of the drug in both fluids were determined at pH 7.4 and 37 degrees C by equilibrium dialysis. The possible influence of the pH on the protein binding was also assessed. The total concentration time curves in plasma and synovial fluid were fitted to linear oral 1 and 2 compartment body models with an additional synovial fluid compartment connected to the central compartment. The unbound fractions of drug in synovial fluid and plasma were on average 0.015 and 0.011, respectively: not significantly different from each other. The protein binding of tenoxicam was pH dependent with increased free fractions at pH values less than 7.4. The average peak concentrations of tenoxicam in plasma and synovial fluid were 4.3 and 1.4 micrograms/ml, respectively. The mean ratio of the areas under the total concentration time curves in synovial fluid and plasma was 0.42, which corresponded to the steady state of equilibrium ratio of the total drug concentrations in the two body fluids. Two hypotheses were tested: hypothesis I assuming that equilibration across the synovial tissue takes place between the unbound, unionized tenoxicam molecules; hypothesis II assuming that equilibration across the synovial tissue is established between the unbound (unionized + ionized) tenoxicam molecules. Based on the available evidence hypothesis II was rejected.

[Plasma and tissue concentration of ceftriaxone following a one-time i.v. dose of 2 g]

The concentration of ceftriaxon found in plasma and in fatty, muscular and colonic tissue after a single intravenous dose of 2 g are reported. 20 patients undergoing elective surgery of the colon were divided into five groups of 4, and ceftriaxon was given 45 min, 3, 6, 12 and 24 h before surgery. Even after 24 h the plasma and tissue concentrations were above MIC 90 for most microorganisms sensitive to ceftriaxon.

Pharmacokinetics of midazolam and alpha-hydroxy-midazolam following rectal and intravenous administration

1. In an open cross-over trial, plasma concentrations of midazolam were measured in eight healthy male volunteers following administration of 0.3 mg kg-1 body weight given by the rectal and intravenous routes. 2. Maximum plasma concentrations of 92-156 ng ml-1 (mean 118 ng ml-1) were recorded from 20 to 50 min (mean 31 min) after rectal application. The rectal bioavailability was 40-65% (mean 52%) and the terminal half-life was 114-305 min (mean 161 min). 3. A substantial first-pass hepatic effect was observed following rectal administration. 4. No systemic or local intolerance was noted. 5. In conclusion, the rectal route of administration provides a rapid and reliable absorption of midazolam.

Lack of influence of etretinate on the intestinal absorption of D-xylose and of phytomenadione (vitamin K1) as representatives of hydrophilic and lipophilic compounds

The possible influence of the aromatic retinoid etretinate (Tigason ) on the intestinal absorption of D-xylose and phytomenadione (vitamin K1) has been studied in 7 healthy male volunteers between 22 and 25 years of age. D-xylose and phytomenadione were selected as being representative of water-soluble and fat-soluble test compounds, respectively. Following an oral dose of 25 g D-xylose the plasma levels and urinary excretion pattern of the compound were followed over 6 h. The plasma concentrations of phytomenadione after an oral dose of 20 mg of the vitamin were measured over 14 h. These absorption tests were performed before (baseline) and at the end of a 3-week treatment period with 25 mg b.i.d. etretinate. In addition some parameters on the serum lipid status pre and post etretinate treatment were monitored. The pharmacokinetic and biochemical determinants after treatment with etretinate were referenced to the pretreatment values and nonparametric confidence intervals (a less than 0.05) for these ratios were calculated. With respect to the area, AUC, under the D-xylose plasma concentration--time curve (0.79 less than or equal to RAUC = 1.00 less than or equal to 1.17) as well as to the cumulative amount excreted into urine over 6 h (0.90 less than or equal to RSUM = 1.04 less than or equal to 1.28) and to renal clearance (0.91 less than or equal to Rcl = 1.05 less than or equal to 1.25), no effect of etretinate on absorption and/or renal handling of D-xylose was discernible.(ABSTRACT TRUNCATED AT 250 WORDS)

Bioavailability of L-dopa after Madopar HBS administration in healthy volunteers

Eight healthy male and fasted volunteers received alternatively either one HBS capsule of Madopar 125 or two HBS capsules of Madopar 125 or one standard capsule of Madopar 125 at weekly intervals with and without benserazide pretreatment (50 mg t.i.d. for 6 days). In this trial the Madopar formulations were administered 9.5 h after the last dose of benserazide. Serial blood samples were collected at various time intervals up to 12 h after Madopar dosing. Levodopa plasma concentrations were measured by high-performance liquid chromatography with electrochemical detection. After Madopar HBS without benserazide pretreatment the peak concentration (Cmax) of levodopa was lower and occurred at later times (tmax) than after standard Madopar. The mean values for tmax were 2.4, 2.8 and 0.8 h, whereas those for Cmax were 0.25, 0.56 and 1.38 micrograms/ml for one HBS capsule, two HBS capsules and standard Madopar, respectively. The mean relative bioavailability (versus standard Madopar) was 58 and 67% (value normalized to dose) for one and two HBS capsules, respectively. The parameter of half-value duration (= time span where plasma concentrations are equal to or higher than the half Cmax) was on average 3.5, 3.8 and 0.8 h for one HBS capsule, two HBS capsules and standard Madopar, respectively. Following benserazide pretreatment the mean tmax values for levodopa were 2.8, 2.3 and 0.8 h and the mean Cmax values were 0.35, 0.60 and 1.33 micrograms/ml, respectively, for one HBS capsule, two HBS capsules and standard Madopar. The relative bioavailability (versus standard Madopar) was 57 +/- 14 and 63 +/- 21% (value normalized to dose) for one and two HBS capsules, respectively. The mean values of the half-value duration were 3.6, 4.2 and 1.3 h for one HBS capsule, two HBS capsules and standard Madopar, respectively. For most of the parameters measured, the interindividual variability after Madopar HBS was less pronounced than after standard Madopar. In conclusion, according to these kinetic data, Madopar HBS shows the characteristics of a controlled-release formulation. The reduced bioavailability of the HBS form (60% of that of the standard form) suggests that a higher daily dose of Madopar HBS should be used for clinical practice.

[Relation between the clinical effect and plasma concentration of midazolam in volunteers]

In 12 healthy volunteers, the pharmacological effects of midazolam were investigated following intravenous (0.15 mg X kg-1 and 12.5 mg in 6 subjects each), intramuscular (12.5 mg in 6 subjects) and oral administration (20 mg in 6 subjects and 10 mg in 4 subjects). The findings were correlated with the plasma concentrations of midazolam and its alpha-hydroxy metabolite. The effects were assessed using objective and subjective methods (reaction time, memory test and subjects' self-assessment with an analog scale covering the degree of sedation). Plasma samples were assayed for midazolam and its alpha-hydroxy metabolite by gas chromatography. The results of the memory test showed that mnemonic retention and recall of a number remained intact for the period preceding intravenous or intramuscular administration. The maximum impairment occurred at 30 min after injection for recall of a number presented at the 15th min. The impairment was no longer detectable 4 h after injection. The plasma concentration time course was similar to that of the reaction time after administration of an identical intravenous or intramuscular dose. The maximum effect was attained within 15 min and 30 min after intravenous and intramuscular administration respectively. Within 2 to 4 h after parenteral administration, the reaction time had returned to normal. At identical plasma concentrations of midazolam, the reaction time was slightly longer in the period immediately following oral administration than after parenteral administration. This result suggested that the alpha-hydroxy metabolite contributed actively to the effect of midazolam. After its intravenous injection, this metabolite's sedative effects attained their maximum with 15 min, having disappeared 4 h later.

Relationship between plasma concentration and effect of midazolam after oral and intravenous administration

In a double-blind, cross-over study in six healthy volunteers, the effects of different oral doses of midazolam (10, 20 and 40 mg), or 0.15 mg kg-1 midazolam administered intravenously and of placebo were investigated. Plasma concentrations of midazolam and of its active alpha-hydroxy metabolite were measured at the same time. The effect was assessed using objective and subjective methods (reaction time, tracing test, subjects' self-assessment and investigator's subjective assessment). The respective time courses of the plasma concentration and of the effect (reaction time, number of errors in the tracing test) were almost identical. Peak plasma levels and maximum effects were attained within 30 min. In general, the effect after intravenous injection of 0.15 mg kg-1 and after an oral dose of 10 mg midazolam lasted for 2 h following administration and its duration was doubled (i.e. to 4 h) after the 20 mg oral dose. Between the logarithm of the plasma concentration and the effect, there is a sigmoidal relationship that is virtually time independent. Particularly in the first few hours after oral administration the effect is intensified by the alpha-hydroxy metabolite of midazolam which is formed by first-pass metabolism. At identical plasma concentrations of midazolam, the oral dose produced more marked effects than did the intravenous administration. Correlation of the measured effects with the total (midazolam + alpha-hydroxy midazolam) plasma concentration reveals a closer sigmoidal relationship.

5-Fluorouracil: a comparative pharmacokinetic study and preliminary results of a clinical phase I study

Until now it was unknown, whether 5-fluorouracil (5-FU) would be absorbed sufficiently after oral application, so that therapeutical effects could be expected. For this reason a comparative pharmacokinetic study of intravenous versus oral application was performed on six patients, as well as a pilot study on 13 patients with adenocarcinomas of different origins. The results show that 5-FU is absorbed rapidly. The biological availability increases with higher dose, which would indicate a saturation of the "first pass" in the liver. The clinical study shows partial remission in seven patients, with hepatoma and tolerable signs of bone marrow depression, decrease of hemoglobin, leukocytes and platelets after oral application of 5-FU in doses of 1,000-1,250 mg on days 1, 3, 5, 8, 10, and 12. 5-FU can therefore be given successfully at an adequate dose by the oral route.