The single-dose pharmacokinetics of midazolam and its primary metabolite in pediatric patients after oral and intravenous administration.

The first-dose pharmacokinetics of midazolam and its primary alpha-hydroxymetabolite were studied after single-dose administration. Eligible study patients were enrolled into one of three study arms: Arm I (midazolam/metabolite pharmacokinetic evaluation after oral administration of a syrup formulation), Arm II (the absolute bioavailability of midazolam syrup), and Arm III (midazolam and metabolite pharmacokinetics after IV administration). Complete blood sampling for pharmacokinetic analysis was available in 87 subjects. Midazolam absorption after administration of the oral syrupformulation was rapid, with adolescents absorbing the drug at approximately half the rate observed in younger children (ages 2 to < 12 years). Furthermore, midazolam t 1/2 was prolonged and CL/F reducedin adolescents as compared with younger children. Although the midazolam Vd/F appeared larger in the youngest age group after oral administration, this observation was not apparent after IV dosing, suggesting subject differences in bioavailability rather than distribution. Like midazolam, the disposition characteristics for a-hydroxymidazolam were also highly variable, with the greatest formation of metabolite (reflected by the AUC ratio) observed in children ages 2 to < 12 years. The A UC ratios of alpha-hydroxymidazolam to midazolam after IV dosing were similar across all age groups and were smaller than corresponding values following oral administration. The absolute bioavailability of midazolam averaged 36% with a very broad range (9%-71%). No relationship between midazolam bioavailability and age was observed. Overall, the disposition characteristics of midazolam and its a-hydroxy metabolite were highly variable, appeared independent of age and dose administered, and were linear over the dose range studied (0.25 to 1 mg/kg). These data suggest that an initial oral dose of 0.2 to 0.3 mg/kg should be adequateforsuccessful sedation of most pediatric patients. The inherent variability in midazolam bioavailability and metabolism underscores the importance of titrating midazolam dose to desired effect.

Pediatric pharmacodynamics of midazolam oral syrup. Pediatric Pharmacology Research Unit Network.

In this study, the authors evaluate the pharmacodynamics, safety, and acceptability of a new cherry-flavored oral syrup formulation of midazolam. This randomized, double-blind, parallel-group, dose-ranging clinical trial of oral midazolam was conducted at seven U.S. health care institutions focused on pediatric clinical pharmacology research (i.e., the PPRU Network). Pediatric patients (n = 85, ages 6 months through 15 years) underwent invasive procedures and were randomized to a single oral dose of midazolam syrup (0.25, 0.5, or 1.0 mg/kg). Patient taste acceptability of midazolam syrup was evaluated at the time of oral administration. Pharmacodynamic measurements included (1) sedation score using a 5-point scale at baseline and 10-, 20-, and 30-minute postdose intervals and (2) anxiety score using a 4-point scale at the time of separation from caretakers and, when applicable, at the time of mask anesthetic induction. Midazolam and alpha-hydroxymidazolam plasma concentrations were measured at all pharmacodynamic measurement time points. Adverse events were monitored continuously during the study. Most patients (99%) accepted the syrup without difficulty. Satisfactory sedation was achieved within 30 minutes by 81% of patients. The anxiety score at the time of caretaker separation and mask anesthetic induction was satisfactory for 87% and 91% of patients, respectively. A significant linear relationship between plasma drug concentration and maximal sedation score, but not anxiety score, was observed. The occurrence of adverse events was consistent with the known safety profile of midazolam. The most commonly reported adverse events were hiccoughing, hypoxemia, nausea, and emesis. It was concluded that a new oral syrup formulation of midazolam, 0.25 to 1.0 mg/kg, effectively induced rapid-onset, dose-related, adequate, and safe sedation and anxiolysis in pediatric patients who underwent operative procedures. Sedative effects were related to plasma concentrations of both midazolam and the primary metabolite, alpha-hydroxymidazolam. Oral midazolam, 1.0 mg/kg, administered within 30 minutes of the expected procedure or anesthetic induction should provide safe and effective sedation to a majority of children ages 6 months to 16 years.

Increased volume of distribution prolongs midazolam half-life.

It has recently been shown by several investigators that the half-life (t1/2) of midazolam is prolonged (greater than 7 h) in a small proportion of the population. One group has inferred that this subpopulation represents a group of slow metabolizers of midazolam to alpha-OH-midazolam. Others disagree and postulate that there is an increase in the volume of distribution (V) resulting in a prolonged t1/2. This controversy led us to report experience from 90 subjects and patients where t1/2, V, and clearance (CL) were determined by both model-dependent and -independent pharmacokinetic analysis. We found a 5.6% (5 of 90) incidence of prolonged t1/2, similar to that previously reported. V was clearly increased without a decrease in CL in the five subjects with prolonged t1/2. Thus, the prolonged t1/2 is secondary to an increase in V and not a result of alterations in CL and metabolism.

Effect of renal impairment on the pharmacokinetics of cibenzoline.

Sixteen subjects completed an open-label study designed to assess the effect of renal impairment on the disposition of cibenzoline. The study included 10 patients with mild or moderate renal impairment creatinine clearance less than 60 ml/min/70 kg) and six healthy subjects in the same age range, each of whom received a single 130 mg oral dose of cibenzoline. The pharmacokinetic parameters observed in the healthy volunteers were similar to those reported previously. Maximum plasma concentration, time of maximum concentration, and apparent volume of distribution after single doses in patients with renal impairment were in the same range as those observed in healthy volunteers. The elimination half-life increased with decreasing renal function from a mean value of approximately 8 hours in healthy volunteers to more than 20 hours in patients with moderate renal impairment. Renal clearance and the fraction of the dose excreted unchanged in the urine decreased with decreasing creatinine clearance. The results of this study suggest that the dosage of cibenzoline should be reduced or the dosage interval increased in patients with reduced renal function to avoid excessive drug accumulation.

Effect of oral cibenzoline on steady-state digoxin concentrations in healthy volunteers.

The effect of oral cibenzoline on steady-state digoxin concentrations was studied in 12 healthy subjects ranging from 41 to 55 years of age. Each subject received an oral dose of 0.25 mg or 0.375 mg digoxin once daily for 27 days. On days 14 to 21, 160 mg of oral cibenzoline were administered concomitantly every 12 hours for a total of 15 doses. Plasma digoxin concentration-time profiles obtained before, during, and after cibenzoline coadministration were compared to determine the effect of oral cibenzoline on steady-state digoxin concentrations. The maximum plasma concentration, time of maximum concentration, area under the curve during a dosing interval and steady-state trough plasma concentration for digoxin, during and after concomitant doses of cibenzoline were similar to those before administration, indicating that cibenzoline did not affect the pharmacokinetics of digoxin. In addition, plasma cibenzoline concentration-time profiles after the first and last dose of cibenzoline were similar to those observed in previous studies in which multiple doses of cibenzoline alone were administered. The results of this study indicate that there is no pharmacokinetic interaction between digoxin and cibenzoline when the two drugs are coadministered to healthy subjects in multiple doses.

Pharmacokinetics of cibenzoline after single and repetitive dosing in healthy volunteers.

Twenty-five healthy, adult male volunteers entered two open-label parallel studies, each designed to define the pharmacokinetics of single and multiple oral doses of cibenzoline. Each volunteer received a single 160-mg oral dose of cibenzoline followed two or three days later by 160 mg of cibenzoline q12h for seven days. Plasma concentration-time profiles and urinary excretion rate data were used to determine pharmacokinetic parameters for unchanged drug. The apparent half-life following administration of the last dose (9.7 hours) was slightly longer than that observed after the first dose (8.4 hours). Total body clearance and nonrenal clearance were decreased after the last dose compared with the first dose, whereas renal clearance was not significantly altered. After both the first and last dose, the renal clearance greatly exceeded the glomerular filtration rate, suggesting that tubular secretion participates in the renal excretion of cibenzoline. Plasma concentrations from samples collected during the multiple-dose regimen suggest that a slight but statistically significant diurnal variation in the absorption and/or clearance of drug occurred during the course of the study. Overall, the pharmacokinetics of cibenzoline are characterized by a slightly longer half-life during multiple dosing than that observed following a single dose, due to a decrease in the nonrenal clearance. The multiple-dose pharmacokinetics reported herein are consistent with bid dosing for the maintenance of therapeutic plasma concentrations in patients taking chronic therapy.

Effect of time of dosing on the disposition of oral cibenzoline.

Single oral doses of cibenzoline were administered to eight healthy volunteers on two different occasions, once at 8.00 am and once at 10.00 pm, in a randomized crossover design with at least one week separating treatments. A fast was maintained for 12 hours prior to and for 2 hours after the morning dose and the subjects did not lie down for at least 12 hours after dosing. A standard dinner was eaten 3 hours prior to the evening dose, and a fast was maintained for 10 hours after dosing; the subjects laid down 2 hours after dosing for at least 6 hours. Blood was collected at specific times for 72 hours and the total volume of urine voided was collected through 72 hours. Cibenzoline concentrations in plasma and urine were measured by HPLC. Cibenzoline absorption was slower in 7 of the 8 volunteers following the evening dose relative to the morning dose. Mean +/- S.D. tmax for the evening dose was 2.6 +/- 0.5 hours compared to 1.7 +/- 0.8 for the morning dose. The corresponding mean +/- S.D. Cmax following the morning dose was 446 +/- 124 ng ml-1 compared to 402 +/- 114 ng ml-1 after the evening dose. The mean +/- S.D. AUC was 3328 +/- 1101 ng . h . ml-1 after the morning dose and 3561 +/- 1430 ng . h . ml-1 after the evening dose. The harmonic mean half-life was 7.4 hours after both treatments. These data indicated that the total amount of drug absorbed and the elimination rate constant of the drug had not varied between treatments.(ABSTRACT TRUNCATED AT 250 WORDS)

Pharmacokinetics and pharmacodynamics of intravenous cibenzoline in normal volunteers.

The pharmacokinetics of intravenous (IV) cibenzoline were studied in six healthy male volunteers ranging in age from 51 to 78 years. The subjects received intravenous (IV) cibenzoline 100 mg over 20 minutes, and plasma and urine specimens were collected for 48 hours. Cibenzoline plasma concentrations at the end of the infusion ranged from 730 to 1,420 ng/mL and exhibited triexponential decline thereafter. The following mean model independent pharmacokinetic parameters were calculated from the plasma and urine concentration data: terminal half-life, 9.8 hours (range, 8.5-11.9); plasma clearance, 523 mL/min (range, 387-687); volume of distribution, 445 L (range, 328-506); and renal clearance, 289 mL/min (range, 202-334). Approximately 31% to 59% of the dose was recovered unchanged in the urine in 48 hours. A triexponential pharmacokinetic equation with zero order input was used to curve fit the plasma and urine data, and the model-dependent parameters agreed well with the model-independent estimates. A hysteresis loop was observed in the relationship between cibenzoline plasma concentration and QRS prolongation, indicating an initial lag between plasma concentration and effect after IV administration. Based on these results, the following preliminary dosing regimen was proposed to rapidly achieve and maintain therapeutic plasma concentrations equal to or slightly greater than 200-400 ng/mL: 0.25 mg/kg/min IV bolus over one minute followed by 1-1.5 mg/kg/hr for one hour and 0.2-0.4 mg/kg/hr for long-term infusion.

Age and cibenzoline disposition.

Oral cibenzoline kinetics were followed in 36 healthy subjects aged from 22 to 78 yr divided into groups of six subjects per decade between 20 and 80 yr. Each received a single, oral, 160-mg dose of cibenzoline. Blood and urine samples were collected for 72 hr. Cibenzoline plasma and urine concentrations were measured by HPLC. Maximum plasma cibenzoline concentrations (Cmax) ranged from 283 to 1100 ng/ml and occurred 1 to 2.5 hr after dosing. Apparent oral clearance (ClT) ranged from 401 to 1677 ml/min and the t 1/2 ranged from 5.9 to 13.4 hr. Nonrenal clearance (ClNR) ranged from 65 to 1113 ml/min, renal clearance (ClR) ranged from 165 to 645 ml/min, and 31% to 86% of the dose was recovered unchanged in urine (Xu). The volume of distribution (Vd) was large, ranging from 236 to 948 l. There was a significant relationship between age and the following kinetic parameters: Cmax, Xu, t 1/2 (all of which increased with age), ClT, ClR, ClNR, the terminal elimination rate constant beta, and Vd (which decreased with age). Mean ClT was 999 +/- 371 ml/min in the 20- to 30-yr age group and was 465 +/- 78 ml/min in the 70- to 80-yr age group. The change in ClT with age resulted from a decreased in both ClR and ClNR. Mean t 1/2 varied from 7 hr in the youngest group to 10.5 hr in the oldest group. The age-related changes in cibenzoline kinetics occurred over the entire age range studied and the relationship between age and these kinetic parameters appeared to be linear.(ABSTRACT TRUNCATED AT 250 WORDS)

Single-dose pharmacokinetics and dose proportionality of oral cibenzoline.

The pharmacokinetics of cibenzoline were evaluated in four young healthy volunteers who received ascending oral doses of 65, 97.5, 130, 162.5, 195, 227.5, and 260 mg separated by one week. Cibenzoline plasma concentrations exhibited an apparent biexponential decline following oral absorption. Maximum plasma concentrations and area under the plasma concentration-time curve increased in proportion to the dose. The mean elimination half-life among subjects was independent of dose and ranged from 7.3 to 8.7 hours. Oral clearance ranged from 380 to 575 ml/min and was also independent of dose. A single pharmacokinetic equation was used to adequately describe the plasma concentration data over the entire range of doses for each subject, indicating dose-proportional and linear pharmacokinetics.

Pharmacokinetics of isotretinoin following a single oral dose.

A pharmacokinetic profile was developed following oral administration of a single 100-mg oral dose of isotretinoin to 12 normal male volunteers. Concentrations of isotretinoin and its isomer, tretinoin, were measured in blood samples from 12 subjects and in urine and fecal samples from three of the 12 subjects. Blood concentration-time data during a 72-hour sampling interval were variable and, in five of the 12 cases, showed pronounced secondary and tertiary concentration maxima which were consistent with the theory of enterohepatic circulation (EHC) of isotretinoin in man. In five of the 12 subjects, adequate fits of the data could not be obtained using classical bi- or triexponential equations but were successfully fitted using a recently developed recycling model. Maximum blood concentrations of isotretinoin ranged from 74 to 511 ng/ml and occurred between 1 and 4 hours after dosing. Secondary maxima generally occurred between 6 and 24 hours after dosing. The harmonic mean elimination half-life was approximately 20 hours. These findings suggest that steady-state blood concentrations should be observed within one week. Negligible amounts of unchanged isotretinoin were excreted in urine, whereas 53 to 74 per cent of the dose was recovered as intact isotretinoin in the feces. The amount of intact drug in the feces could reflect biliary excretion of the conjugate of isotretinoin that is deconjugated beyond the site where absorption may occur, as well as unabsorbed drug.

Clinical bioavailability evaluation of a controlled release formulation of diazepam.

A controlled release formulation of diazepam was compared to equal daily dose of the trade tablet under single day and steady-state conditions. Virtually no differences were found in the mean steady-state concentrations of diazepam or its metabolites, N-desmethyldiazepam, when the subjects received the 5 mg trade table three times daily or the 15 mg controlled release formulation once daily. Similarly, there was no difference in mean diazepam or N-desmethyldiazepam plasma concentrations when single doses of the controlled release formulation were give to fed or fasted volunteers. These data indicate that the controlled release formulation produces plasma concentrations of diazepam and N-desmethyldiazepam comparable to those achieved with the same daily dose of the trade product given three times daily, suggesting that these regimens can be used interchangeably.

Influence of phenytoin and phenobarbital on the disposition of a single oral dose of clonazepam.

Clonazepam (CZP) was measured in the plasma of eight subjects for 48 hr after a 0.03-mg/kg oral dose. After pretreatment for 19 days with phenytoin (DPH, 4.3 mg/kg/day), plasma CZP concentrations were determined in the same subjects after another 0.03 mg/kg oral dose of CZP. The same protocol was followed in eight additional subjects using phenobarbital (PB, 1.4 mg/kg/day) instead of DPH. DPH pretreatment lowered mean plasma CZP concentration in 8 of the 12 time points. DPH pretreatment increased CZP clearance by 46% to 58% and decreased CZP half-life (t1/2) by 31%. Both changes were statistically significant. After PB pretreatment the mean plasma CZP concentration was lowered by an average of 11%, but the decrease was statistically significant for only 1 of the 12 time points. PB decreased mean CZP t1/2 by 11% and increased CZP clearance by 19% to 24%, but only the increase in clearance was statistically significant. Both DPH and PB increased CZP clearances and decreased the areas under the plasma concentration-time curves without altering the volumes of distribution. This observation is consistent with induction of CZP metabolism. The overall effect of DPH (4.3 mg/kg/day) was greater than the effect of PB (1.4 mg/kg/day). Neither the DPH or PB had a significant effect on the extent of CZP protein binding.

Determination of clonazepam and its amino and acetamido metaoblites in human plasma by combined gas chromatography chemical ionization mass spectrometry and selected ion monitoring.

Our previously published gas chromatography chemical ionization mass spectrometry stable isotope dilution assay for clonazepam and its 7-amino metabolite in plasma has been modified to obtain more consistent recoveries of the amine metabolite and to permit the determination of the 7-acetamido metabolite of clonazepam. In addition, the manuscript describes the details of a method for a least squares analysis of the nonlinear standard curves associated with the use of certain stable isotope labeled analogs as internal standard.

Rapid determination of diazepam and nordiazepam in plasma by electron capture gas--liquid chromatography. Application in clinical pharmacokinetic studies.

A rapid method was developed for the determination of diazepam and nordiazepam (N-desmethyldiazepam) in human plasma using electron capture gas--liquid chromatography (GLC--ECE). The concentration of diazepam and nordiazepam is determined using 0.5 ml of plasma extracted with 1.0 ml of benzene containing 25 ng/ml of methylnitrazepam as the internal standard. The benzene extract is removed and an aliquot is subjected to automated GLC-ECD analysis. The method has a sensitivity limit of 5 ng diazepam and 10ng nordiazepam per milliliter of plasma. The method was used to determine the plasma levels in man following the first 5-mg diazepam dose, as well as during chronic oral administration of 5 mg diazepam three times daily and 15 mg diazepam once a day.