Binding of a metabolite of triflusal (2-hydroxy-4-trifluoromethylbenzoic acid) to serum proteins in rat and man

Summary 2-hydroxy-4-trifluoromethylbenzoic acid (HTB) is the main active metabolite of the platelet anti-aggregant drug triflusal. Its binding to plasma proteins of rats and healthy volunteers in vitro and in vivo has been studied.Rats were given a single oral dose of 50 mg·kg^–1 triflusal and the healthy volunteers received 300 mg as a single oral dose or a multiple dose regimen of 600 mg every 24 h and 300 mg every 8 h, both for 13 days. Protein-free HTB was obtained by ultrafiltration. Unbound and total HTB concentrations were determined by HPLC.HTB was primarily bound to albumin in plasma. The Scatchard plots suggested two types of binding sites for HTB on the albumin molecule. In rats, the binding constants (K=intrinsic affinity constant, n=number of binding sites) were K₁=1.4×10⁵ l·mol^–1, n₁=1.23, and K₂=4.1×10³ l·mol^–1 and n₂=3.77. The mean plasma concentration in rats after oral administration was 185 (37) g·ml^–1 (protein-free HTB: 2.44 (0.77)%). The binding constants in human plasma were K₁=4.7×10⁵ l·mol^–1, n₁=1.93, K₂=4.3 l·mol^–1 and n₂=4.28.The plasma HTB concentration in man (n=8) was 35 g·ml^–1 (C_max) after a single oral dose of triflusal 300 mg, 172.96 g·ml^–1 (C_max·ss) during the multiple dosage regimen of 300 mg every 8 h, and 131 g·ml^–1 (C_max·ss) during the multiple oral dose regimen of 600 mg every 24 h. Unbound HTB ranged from 0.27 to 0.43%, depending on dose. HTB had high affinity for plasma albumin, which was not saturable after therapeutic doses. It showed linear elimination.     

Pharmacokinetics of fluconazole after oral administration in children with human immunodeficiency virus infection

The objective of this study was to determine the pharmacokinetics of fluconazole after oral administration in children with human immunodeficiency virus (HIV) infection. After an overnight fast, a single dose of either 2 mg·kg^–1 or 8 mg·kg^–1 was administered in a suspension; five children received 2 mg·kg^–1 and four 8 mg·kg^–1 (ages 5–13 years). Blood samples were collected at various times on day 1, and once daily on days 2–7 after the dose. Fluconazole serum concentrations were measured by gas chromatography. At the dose of 2 mg·kg^–1, the C_max, AUC (0–), and t_1/2 ranged from 2.3–4.4 g·ml^–1, 84.9–136 g·h·ml^–1, and 19.8–34.8 h, respectively. At the dose of 8 mg·kg^–1 the C_max, AUC (0–), and t_1/2 ranged from 5.4–12.1 g·ml^–1, 330–684 gh·ml^–1, and 25.6–42.3 h, respectively. When compared with published data in healthy adults, fluconazole achieved similar serum concentrations in the present group of children, indicating a nearly complete degree of absorption.     

Haemodilution therapy in ischaemic stroke: Plasma concentrations and plasma viscosity during long-term infusion of dextran 40 or hydroxyethyl starch 200/0.5

Summary In 21 patients with ischaemic strokes we have monitored plasma viscosity, total plasma concentration, numeric average molecular weight (Mn), and weight average molecular weight (Mw) of Dextran 40 (dextran) and hydroxyethylstarch 200/0.5 (HES) during 10 days of treatment (days 1–4, 2×500 ml; days 5–10, 1×500 ml). Plasma concentrations of dextran increased during the first 4 days (8.3 mg·ml^–1 on the first day to 18.0 mg·ml^–1 on the fifth day), reached an apparent steady state of 17.2 mg·ml^–1 during the next 6 days, and declined subsequently with a half-time (t_1/2) of 4.03 days. After ten days treatment Mn and Mw were shifted towards higher values. Plasma viscosity increased from 1.26 mPas to 1.69 mPas on Day 10 (p<0.01) and was linearly correlated with the total plasma concentration of dextran (p<0.001; r=0.88). Total plasma concentrations of HES averaged 11.7 mg·ml^–1 on Day 1 and 12.4 mg·ml^–1 on Day 5. The molecular weight distribution did not change during the infusions but decreased in comparison with the administered solution. Plasma viscosity fell from 1.40 mPas to 1.30 mPas at Day 10 (p<0.05) and was not related to the concentration of HES. The haemodiluting effect, as indicated by a decrease of the haematocrit, was 22% and 16.8% for dextran and HES respectively. These data suggest several advantages of HES compared with dextran in haemodilution therapy of ischaemic stroke.     

THE EFFECT OF TRIFLUOPERAZINE ON BRONCHIAL RESPONSIVENESS IN ASTHMA

1. The protective effects of oral trifluoperazine (TFP) (7mg) against standardized methacholine and histamine inhalation tests (MIT and HIT) were examined 2 and 22 h post-treatment in eight stable asthmatics using a randomized double-blind protocol. 2. A preliminary study tested whether a preceding MIT influenced the result of a subsequent HIT. 3. The mean baseline forced expiratory volumes in 1 s (FEV₁) were similar prior to placebo and TFP. The mean FEV₁ values 2 h after ingestion of placebo or TFP were not different from the baseline values. 4. TFP did not alter bronchial responsiveness to inhaled methacholine or histamine 2 h postingestion, but at 22 h the PC₂₀ methacholine was greater than placebo, while PC₂₀ histamine did not change. This change in methacholine responsiveness was not clinically significant. 5. There was a correlation between geometric mean provocative concentration of histamine to cause 20% fall in FEV (PC₂₀H) for HIT performed in isolation ('separate day') and for HIT performed after MIT (‘same day’). 6. The effect of inhaled TFP (10 mg/ml, nebulized for 5 min) was examined single-blind and placebo-controlled in a separate group of six stable asthmatics. 7. Inhaled TFP had a bronchoconstrictor effect in all six asthmatics. The mean fall in FEV₁ was 36.4% after inhaled TFP and 2.1% after saline. 8. In the asthmatics studied, ingested TFP exhibited a weak anticholinergic effect 22 h pest-treatment, but a brisk spontaneously self reverting bronchoconstrictor response was invariably seen when TFP was inhaled.     

Pharmacokinetics of ibuprofen in febrile children

Summary Ibuprofen may be an alternative to acetaminophen to control fever in children but little is known about its pharmacokinetics in pediatric patients. We studied 17 patients (age 3–10 yr) with fever; the most prevalent diagnoses were streptococcal pharyngitis and otitis media. Ibuprofen liquid was given as a single dose, 5 mg/kg (9 patients) or 10 mg/kg (8 patients). Multiple blood samples were collected over 8 hours and analyzed by HPLC.The maximum observed serum concentrations of ibuprofen ranged from 17–42 m·ml^–1 at 5 mg·kg^–1 and 25–53 m·ml^–1 at 10 mg·kg^–1 doses. Pharmacokinetics did not appear to be affected by ibuprofen dose. Mean t_max, oral clearance and elimination half life were 1.1 h, 1.2 ml·min^–1·kg^–1, and 1.6 h, respectively in patients at 5 mg·kg^–1 doses; the corresponding values were 1.2 h, 1.4 ml·min^–1·kg^–1, and 1.6 h in those receiving 10 mg·kg^–1 doses. There was no relationship between age and ibuprofen kinetics. No adverse effects occurred in any patients.These data suggest that ibuprofen pharmacokinetics may not be affected by dose between 5 and 10 mg/kg or age between 3 and 10 years.     

Pharmacokinetics of diphemanil methylsulphate in infants

Summary The pharmacokinetics of diphemanil methylsulphate was evaluated after oral administration of a single 3 mg·kg^–1 dose to 5 infants being treated for symptomatic bradycardia.The mean pharmacokinetic parameters of oral diphemanil methylsulphate in infants were similar to those in adults. The mean half-life was 8.6 h. This would allow administration three times a day in infants instead of four to six times a day, as currently prescribed. The mean residence time decreases significantly with age (Spearman's r=–1), and there is a trend for the half-life to decrease with age (r=–0.9; NS), suggesting an influence of maturation on its elimination.     

Flumazenil kinetics in the elderly

Summary In an open design, randomised, two-way cross-over study, a single 2 mg i.v. dose and a single 30 mg oral dose of flumazenil were each administered to a group of healthy young (n=6) and elderly (n=12) volunteers (male: female 2/1). Plasma samples were collected at intervals and intact drug was assayed.Both the IV and oral doses of flumazenil were very well tolerated by both age groups and no severe or unexpected adverse effects were observed. The main complaints were dizziness and headache, mainly after oral dosing, probably due to the higher C_max and AUC following this route of administration. After 2 mg i. v. the disposition parameters in the two age groups (elderly/young) were very similar: volume of distribution (V_ss): 0.88/0.901·kg^–1; total body clearance (Cl_PL): 0.86/0.99 l·min^–1; terminal elimination half-life (t_1/2): 1.02/0.91 h. After the 30 mg oral dose the mean C_max of 87.6 ng·ml^–1 (elderly) and 78.4 ng·ml^–1 (young) were generally reached within 0.5 to 1 h. In 26% (elderly) and 23% (young), the absolute bioavailability of flumazenil was very similar.It is concluded that the absorption and disposition paramters of flumazenil were not significantly affected by aging.     

The tolerability,pharmacokinetics and lack of effect on plasma cholesterol of 447C88, an AcylCoA:Cholesterol Acyl Transferase (ACAT) inhibitor with low bioavailability,in healthy volunteers

447C88 (N-Heptyl-N-(2,4 difluoro-4-6-(2(-4-(2,2 dimethylpropyl)phenyl)ethyl)phenyl)urea) is an inhibitor of human microsomal AcylCoA:Cholesterol acyltransferase (ACAT) with an IC₅₀ of 10.2 ng·ml^–1 (23 nM). It is poorly absorbed but 5 mg·kg^–1·day^–1 completely abolishes the rise in plasma cholesterol in cholesterol-fed rats.In this study, twelve healthy, male volunteers received single, oral doses of 25, 50, 100, 200, 400 and 800 mg of 447C88 (n+8) or placebo (n+4) with food in a double-blind study with at least a week between occasions. The 400 mg dose was repeated after an overnight fast. Subsequently, fourteen different volunteers received a single 200 mg dose of 447C88 (n+8) or placebo (n+6) with food and, a week later, the same dose twice daily for 10 days; all doses were given with food.All doses were well tolerated with no significant changes in vital signs, full blood counts or plasma biochemical profiles. Plasma concentrations of 447C88 were unquantifiable after the fasting dose and low after all other doses. Mean C_max and AUC were 1.8 ng·ml^–1 and 9.0 ng·ml^–1·h after 200 mg rising to 5.4 ng·ml^–1 and 23.8 ng·ml^–1·h respectively after 800 mg; t_1/2 was 1.3 to 5.2 h. After 10 days dosing, plasma 447C88 concentrations were higher in the evening than the morning probably due to administration of the evening dose with more food. There were no significant changes in plasma triglcerides or total, LDL- or HDL-cholesterol after dosing with 447C88.     

Enprofylline: Pharmacokinetics and comparison with theophylline of acute effects on bronchial reactivity in normal subjects

Summary In a double blind, placebo controlled, crossover study the pharmacokinetics and acute effects of enprofylline and theophylline on airway reactivity during histamine challenge were investigated in 10 healthy volunteers. The pharmacokinetic parameters of enprofylline were (mean): elimination half-life 1.9 h, total body clearance 191.1 ml · kg^–1 · h^–1, volume of distribution 0.48 l · kg^–1, and protein binding 49%. Bronchial reactivity in the histamine inhalation test was expressed as the concentration causing a 20% fall in FEV_1.0 (PC₂₀). Mean PC₂₀ values were lowest after placebo and highest after theophylline with the enprofylline values in between. Only the difference in PC₂₀ ^Safter placebo and theophylline was statistically significant (p<0.05). At the time of determination of the PC₂₀, the serum concentration of enprofylline was between 16.5 and 11.8 µmol/l, and that of theophylline was between 78.3 and 61.1 µmol/l. Adverse actions of enprofylline were nausea (3/10) and cardiovascular reactions (2/10), whereas theophylline mainly caused restlessness (3/10) and tremor (2/10). Thus enprofylline, in one-fifth of the serum concentration of theophylline cannot be regarded as equipotent in terms of bronchoprotection.In fulfillment of his thesis (Dr. med.)     

Pharmacokinetics and clinical study of cefotetan in bile: Prophylactic use in biliary tract surgery

The excretion of cefotetan, a 7-methoxycephalosporin, was studied in 27 patients undergoing biliary surgery. Pharmacokinetic parameters were determined after a single intravenous bolus dose of 1 g (10 patients) or 2 g (17 patients). Rapidly excreted in bile, cefotetan concentrations were considerably higher in bile [range: 92–2,594 mg·l^–1 (1 g); 35–4,610 mg·l^–1 (2 g)] than in plasma despite the presence of gall stones. Bile bactericidal activities againstStaphylococcus aureus (MIC 8 mg·l^–1) andBacteroides fragilis (MIC 2 mg·l^–1) correlated well with gall bladder cefotetan levels [r = 0.888 (1 g);r = 0.971 (2 g)]. No cefotetan was detected in the bile of 3 patients with nonfunctioning gall bladders. One other patient with very low activity and these three aside, the inhibitory quotients (cefotetan concentration/MIC) were >4 for both doses against both bacteria.     

Pharmacokinetics of methadone and its primary metabolite in 20 opiate addicts

In a closed metabolic ward the pharmacokinetics of methadone and its primary metabolite (EDDP) were studied in 20 long-term opiate addicts. After administration of the daily oral dose of methadone HCl (mean 60 mg, range 10–225 mg) blood samples were taken and analysed, using a newly developed high-performance liquid chromatography (HPLC) method. The steady-state plasma concentrations of the 20 subjects varied from 65–630 ng·ml^–1 and from 5 to 55 ng·ml^–1, whereas the peak concentrations were 124–1255 ng·ml^–1 and 10 – 301 ng·ml^–1 for methadone and EDDP, respectively. The calculated ratios between the area under the curve (AUC_{(0–24 h)}) for methadone and the AUC_{(0–24 h)} for EDDP varied from 5.9 to 44.6, indicating interindividual differences in metabolic activity. In 19 out of 20 subjects the pharmacokinetics of methadone are best described using a two-compartment model. The mean body clearance was 1.64 ml·min^–1·kg^–1, whereas the mean elimination rate constant () and plasma half-life (t _1/2) were 0.026·h^–1 (range 0.013–0.053·h^–1) and 31.2 h (range 13–53 h), respectively. Differences of gender were also found. A poor correlation was found between the methadone dose and the steady-state level. A much better correlation was found between the normalized steady-state level and the body clearance.     

A lack of pharmacokinetic interaction between ranitidine and piroxicam

Summary The effects of piroxicam (40 mg) on the pharmacokinetics of ranitidine (150 mg) and of ranitidine (150 mg bid) on the pharmacokinetics of piroxicam (20 mg) were assessed in two 2-way crossover studies in two groups of 18 healthy male subjects.In the first study there were no statistically significant differences between the pharmacokinetic variables for ranitidine in the presence or absence of piroxicam. The mean maximum plasma concentration (C_max) was 467 ng·ml^–1 for ranitidine alone and 466 ng·ml^–1 in the presence of piroxicam; mean area under the plasma concentration vs time curve (AUC) was 2460 h·ng ml^–1 and 2551 h·ng ml^–1 respectively; and the mean terminal half-life (t 1/2) was 3.6 h and 3.8 h respectively.In the second study there were no statistically significant differences between the pharmacokinetic variables for piroxicam in the presence or absence of ranitidine. The mean C_max was 2.1 ·ml^–1 in the presence of placebo and 2.0 g·ml^–1 in the presence of ranitidine respectively; mean AUC was 133 h·g ml^–1 and 137 h·g ml^–1 respectively, and the mean t 1/2 was 53.6 h and 54.5 h respectively.     

Pharmacokinetics of quinine in patients with chronic renal failure

Methods: We investigated the pharmacokinetics of quinine (Qn) following administration of a single oral dose of 600 mg Qn sulphate in six male Thai patients with a moderate degree of chronic renal failure (CRF), and six male Thai subjects with normal renal function. Results: The drug was well tolerated in both groups of subjects; no major adverse reactions were observed. A marked alteration in the pharmacokinetics of Qn was found in patients with CRF compared to healthy subjects; there were six signifiicant changes in the pharmacokinetic parameters. Absorption was delayed, but increased in CRF (t_max 4.5 vs 1.6 h, C_max 6.17 vs 3.45 g·ml^–1). Total clearance was significantly reduced 0.94 vs 2.84 ml·min^–1·kg^–1, whereas V_z/f remained unchanged (1.82 vs 2.78 1·kg^–1). This resulted in the increased values of AUC and prolongation of the t_1/2z and MRT in the patients (AUC 181.5 vs 61.8 g·min^–1·ml^–1, t_1/2z 26 vs 9.7 h, MRT 36.4 vs 11.3 h). Median concentrations of plasma unbound fraction of Qn collected at 4 h after drug administration in patients and healthy subjects were 7.3 vs 9.8%, respectively.     

The pharmacokinetics of amiloride-hydrochlorothiazide combination in the young and elderly

Summary The pharmacokinetics of amiloride and hydrochlorothiazide were studied in 12 healthy young volunteers following a single dose of a fixed combination of amiloride and hydrochlorothiazide and in 11 elderly hypertensive patients at steady-state. Following modelling of the single dose data, simulated steady-state plasma concentrations for the 2 drugs were generated to examine the effect of age and/or hypertension on pharmacokinetics.The apparent systemic plasma clearance for both amiloride and hydrochlorothiazide was significantly reduced in the elderly when compared to the young (from 753 to 325 ml·min^–1, amiloride; and from 418 to 157 ml·min^–1, hydrochlorothiazide). The plasma concentrations at steady state for both drugs were greatly increased in the elderly patients (Amiloride: from 7 to 25 ng·ml^–1, C_ss,max; from 2 to 8 ng·ml^–1, C_ss,min; and from 4 to 14 ng·ml^–1, C_av; Hydrochlorothiazide: from 184 to 651 ng·ml^–1, C_ss,max; from 31 to 121 ng·ml^–1, C_ss,min; and from 89 to 273 ng·ml^–1, C_av).The decreased clearance of the diuretics in the elderly was believed due to deterioration of renal function, and there was a significant correlation between the plasma clearance of hydrochlorothiazide and creatinine clearance in both age groups (r=0.62, young;r=0.72, elderly).As a result of the pharmacokinetic findings caution may be indicated in the clinical dosage of the diuretics particularly when in fixed dose combination.     

Studies on hydralazine

Summary After oral administration of a single 50 mg dose of hydralazine (Apresoline^®), the serum half-life (T1/2) and bioavailability (AUC_0–) were assessed in 16 healthy volunteers. The half-life was 2.57±0.14 h (S.E.) in 10 slow acetylators of sulphadimidine, and 2.18±0.15 h in 6 fast acetylators (difference not statistically significant). AUC_0– was significantly higher in slow acetylators, at 1.04±0.10 µg·hour·ml^–1, compared to 0.66±0.12 µg·hour·ml^–1 in the fast acetylators (p<0.025). Treatment with Apresoline^® 25 mg tid produced minimum serum concentrations at steady-state of 57.3±7.3 ng·ml^–1 and 33.4±4.2 ng·ml^–1 in 8 slow and 5 fast acetylators, respectively (p<0.05). The corresponding maximum concentrations were 228.8±20.3 ng·ml^–1 and 147.6±15.0 ng·ml^–1 in slow and fast acetylators, respectively (p<0.025). First-pass metabolism of hydralazine could explain the difference in bioavailability of the drug between fast and slow acetylators, without any corresponding difference in the elimination rate of the drug in the post-distributive phase.     

Alteration by burn injury of the pharmacokinetics and pharmacodynamics of cimetidine in children

Summary We have studied the mechanisms of the increased dosage requirements of the H₂-receptor antagonist cimetidine in paediatric burned patients in a pharmacokinetic and pharmacodynamic study.Cimetidine (10–15 mg·kg^–1) was given to 21 burned children and multiple blood samples were obtained for determination of plasma cimetidine concentrations and pharmacokinetic analysis.The relation of gastric pH to plasma cimetidine concentrations was studied in five of these children who had nasogastric tubes. In an additional four patients the effects of cimetidine on gastric pH were studied during a continuous infusion of cimetidine, which maintained steady-state plasma cimetidine concentrations above 0.5 µg·ml^–1.The mean (SEM) clearance of cimetidine in burned children was 16.22 ml·kg^–1 and cimetidine half-life was 1.06 h. The cimetidine clearance and half-life values were significantly higher in burned children compared with our previously reported values for normal adult patients, 8.2 ml·min·kg^–1 and 2.21 h respectively.Endogenous creatinine clearance normalized to 70 kg in burned children was 190 ml·min^–1. In burned children 41% of the dose of intact cimetidine was excreted during 8 h of the study compared with 45% excretion during 24 h in healthy adult controls previously reported. The correlation coefficient between creatinine and cimetidine clearances was 0.93 (r ²=0.85).The plasma concentration of cimetidine needed to increase gastric pH to 4.0 was 1.0 µg·ml^–1, which contrasts with the value of >0.5 µg·ml^–1 required for adult burned patients.These findings support the hypothesis that the higher dosage requirements of cimetidine in burned children is due both to enhanced elimination kinetics and to alterations in target organ sensitivity, requiring higher than normal plasma concentrations for the desired effect. In burned children Cimetidine should be given in higher doses and/or more frequently.     

Receptor binding assays in analysing the bioavailability and pharmacodynamic bioequivalence of active drug moieties

The bioavailability and pharmacodynamic bioequivalence of a conventional and an experimental sustained-release formulation of 100 mg metoprolol tartrate were studied in a randomised cross-over study in seven healthy volunteers by assessing over 24 h the plasma kinetics of R,S-metoprolol, its ₁-adrenoceptor binding component, and by determining the extent to which the active drug moiety in plasma occupied rabbit lung ₁-and rat reticulocyte ₂-adrenoceptors.The formulations differed markedly in their kinetic characteristics: the peak plasma concentration (C_max) of R,S-metoprolol after administration of the conventional formulation was 140 ng·ml^–1, (n=7) and it was approximately one-third of that after the sustained-release formulation, 49 ng·ml^–1, (n=6); the AUC_{0–24 h}-values for the formulations were 700 and 310 ng·h·ml^–1, respectively. The C_max for the ₁-adrenoceptor binding component of metoprolol was 180 ng·ml^–1 (n=7) after administration of the conventional, and 74 ng·ml^–1 after administration of the sustained-release formulation. The corresponding AUC_{0–24 h}-values for the receptor binding component were 920 and 470 ng·h·ml^–1 (n=7).Thus, the kinetic differences between R,S-metoprolol and the ₁-receptor binding component were considerable and they were affected by the type of formulation. In general, after administration of the sustained-release formulation, the percentage ₁- and ₂-adrenoceptor occupancy of metoprolol in plasma was 5–15% less than after administration of the conventional formulation. At 0.5–1.5 h after drug intake the average ₁-adrenoceptor occupancy of the conventional formulation varied between 80–90% and that of the sustained release formulation between 20–76%. At these times the differences in receptor occupancy were significant; at 0.5–2 h after drug intake the average ₂-adrenoceptor occupancy of the conventional formulation varied from 20–30%, and that of the sustained-release formulation was 2–17%. At other times the difference in receptor occupancy between the formulations was not significant.The results demonstrate that plasma concentration-kinetics were more discriminating than -adrenoceptor-binding in analysing bioequivalence. It was possible to determine the bioavailability of the active ingredient of metoprolol and to study pharmacodynamic bioequivalence by using receptor binding assays.     

The Protective Effect of Inhaled Levomepromazine (Nozinan®) on Histamine-induced Bronchial Constriction

Summary: The effect of inhaled levomepromazine (Nozinan®, Veractil®) on bronchial responsiveness to inhaled histamine was investigated in asthmatics. In a double blind, randomized controlled study, 12 asthmatics (FEV₁% pred 52-96%, and PC₂₀ histamine 1.01 mg/ml (geometric mean)) were challenged before and after inhalation of levomepromazine in three different doses. Before and after each inhalation of levomepromazine, PC₂₀, FEV₁, the continuous reaction time (CRT) and the subjective sedation score (VAS) were determined. A dose-dependent increase in PC₂₀ was observed after inhalation of levomepromazine. PC₂₀ was increased by up to 4.02 two-fold concentration differences (doubling), i.e. up to a 38-fold increase from the basic values. Inhalation of the two higher doses of levomepromazine had a small sedative effect evaluated from an increase in CRT and the VAS-score and corresponding to the plasma concentrations. We conclude that inhaled levomepromazine has a dose-dependent protective effect on histamine-induced bronchial hyperresponsiveness in asthmatics and that inhalation of levomepromazine was well tolerated. The mechanism by which levomepromazine acts on histamine-induced bronchial hyperresponsiveness is not known but it could be partly explained by the antihistaminic effect. In this respect levomepromazine bears comparison with the most potent second generation antihistamines. The plasma concentrations of levomepromazine measured corresponded to those seen after oral intake of 5-10 mg levomepromazine.     

Pharmacokinetic and pharmacodynamic modelling with pancuronium

Summary The pharmacokinetics and pharmacodynamics of pancuronium were studied following intravenous infusion in eleven patients undergoing surgical anaesthesia. Measurement of the plasma concentrations (C_p) of the neuromuscular blocking agent (NMBA) and the concomitant intensities of paralysis allowed their simultaneous modelling. The pharmacokinetic parameters derived for pancuronium were in the range of previously reported values, except that the mean total systemic plasma clearance (0.79±0.28 ml·min^–1·kg^–1) was reduced and the mean terminal phase half-life (169 min) was longer in these patients. Plasma concentration and % paralysis data were successfully fitted to a previously proposed pharmacodynamic model. This model assumes a separate effect compartment which exchanges drug directly with the central kinetic compartment (integrated effect model). The steady-state C_p necessary to produce 50% paralysis (EC_pss(50)) was estimated to be 0.21±0.08 µg·ml^–1 (mechanical response) and 0.18±0.05 µg·ml^–1 (EMG response). An analysis using the Hill equation of the C_p-response relationship, during and after the constantrate infusion of pancuronium bromide, resulted in effective plasma concentrations for 50% paralysis (EC_p50) of 0.35±0.06 µg·ml^–1 and 0.20±0.09 µg·ml^–1, respectively, for mechanical twitch response. The corresponding values for EMG response were 0.32±0.06 µg·ml^–1 and 0.17±0.06 µg·ml^–1. Using this latter approach, the EC_p50 estimated during onset of paralysis was significantly higher than that estimated during offset of paralysis (p<0.05); no such difference was apparent between this latter parameter and the EC_pss(50) of the integrated effect model (p>0.05). No significant differences were observed between any of the pharmacodynamic parameter estimates generated from the data obtained from the two methods of assessment of neuromuscular function (mechanical vs. EMG response) (p>0.05).     

Absolute Bioavailability and Absorption Profile of Cyanamide in Man

A pharmacokinetic study of cyanamide, an inhibitor of aldehyde dehydrogenase (EC1.2.1.3) used as an adjuvant in the aversive therapy of chronic alcoholism, has been carried out in healthy male volunteers following intravenous and oral administration. Cyanamide plasma levels were determined by a sensitive HPLC assay, specific for cyanamide. After intravenous administration cyanamide displayed a disposition profile according to a two-compartmental open model. Elimination half-life and total plasma clearance values ranged from 42.2 to 61.3 min and from 0.0123 to 0.0190 L · kg ^–1 · min^–1, respectively. After oral administration of 0.3, 1.0, and 1.5 mg/kg ± SEM values of C_max, t_max (median) and AUC were 0.18 ± 0.03, 0.91 ± 0.11, and 1.65 ± 0.27 g · ml ^–1 ; 13.5, 13.5, and 12 min; and 8.59 ± 1.32, 45.39 ± 1.62, and 77.86 ± 17.49 g · ml ^–1 · min, respectively. Absorption was not complete and the oral bioavailability, 45.55 ± 9.22, 70.12 ± 4.73, and 80.78 ± 8.19% for the 0.3, 1.0, and 1.5 mg/kg doses, respectively, increased with the dose administered. The models that consider a first-order absorption process alone (whether with a fixed or variable bioavailability value as a function of dose) or with loss of drug due to presystemic metabolism (with zero-order or Michaelis–Menten kinetics) were simultaneously fitted to plasma level data obtained following 1 mg/kg iv and 0.3, 1.0, and 1.5 mg/kg oral administrations. The model that best fit the data was that with a first-order absorption process plus a loss by presystemic metabolism with Michaelis–Menten kinetics, suggesting the presence of a saturable first-pass effect.