Recovery and long-term renal excretion of propofol, its glucuronide, and two di-isopropylquinol glucuronides after propofol infusion during surgery.

BACKGROUND: The metabolism of the short-acting anaesthetic agent propofol has been described over the first 24 h. However, the long-term disposition of propofol and its metabolites is unclear. We describe the pharmacokinetics (renal excretion rates and renal clearance) of propofol and its metabolites over 60 h. METHODS: Ten patients undergoing lung surgery were included in the study. They received anaesthesia with continuous i.v. propofol at an average rate of 10 mg min(-1). During surgery and 60 h thereafter, we sampled blood and urine. Propofol and its metabolites were measured using gradient high performance liquid chromatography (HPLC). RESULTS: In nine patients, propofol and its glucuronides were found in the plasma over the first 15 h. In the urine, however, even after 60 h, propofol and its quinol glucuronides were still detectable. One patient had a markedly different pharmacokinetic profile, showing a limited renal excretion or absorption of 12% of the dose. CONCLUSIONS: After an infusion of propofol, patients excrete propofol and its metabolites in the urine over a period in excess of 60 h. We hypothesize that (re)absorption of propofol and its metabolites by the kidney is a major process in elimination and that the reabsorbed compounds are gradually conjugated in the kidney and excreted in the urine. One patient showed a different pharmacokinetic profile for which we currently have no explanation.

Sex-related differences in the pharmacokinetics of isosorbide-5-mononitrate (60 mg) after repeated oral administration of two different original prolonged release formulations.

OBJECTIVE: To identify differences in the disposition of isosorbide-5-mononitrate between male and female volunteers. METHOD: Plasma concentration and area under the concentration-time curve (AUC(SS)) data of isosorbide-5-mononitrate were obtained in a randomized, crossover, multiple-dose bioequivalence study in 24 subjects (12 females and 12 males). Participants received a single oral dose of 60 mg isosorbide-5-mononitrate prolonged-release tablet formulation (formulations I and II) on each of 6 consecutive days. Plasma isosorbide-5-mononitrate concentrations were determined according to validated methods involving liquid chromatography mass spectrometry. RESULTS: A total of 2 x 24 plasma concentration-time curves of the parent drug could be analyzed. The intersubject variation in plasma concentrations ranged from 25-50% (coefficient of variation). With both formulations, the mean plasma concentration-time curves for males and females ran parallel. The parameters Cmax, Cmin, AUC(SS), and AUC(SS)/kg in females were significantly higher than in males (p < 0.0001). This difference was solely attributed to the difference in body weight (p = 0.0024) and body mass index between males and females (p = 0.0113). Seven females showed a t = 0 = 24 h (Cmin) plasma concentration that was twice as high as the other 5 females and all the males; 125 +/- 12.2 ng/ml versus 59.3 +/- 9.2 ng/ml, respectively, in females (p < 0.0001) and 56.3 +/- 6.9 ng/ml in males (p < 0.0001). With both formulations, females in the n = 7 group had a longer t(1/2) and MRT than females in the n = 5 group, 5.06 +/- 0.76 h, 11.2 +/- 0.55 h versus 4.19 +/- 0.56, 9.40 +/- 0.62 h (p = 0.0057). The male group did not show this phenomenon, their disposition was similar to that of the female group of n = 5. CONCLUSION: The difference found in the Cmax and AUC(SS)/kg of isosorbide-5-mononitrate between male and female subjects must be due to the difference in dose/kg, following a standard dose of 60 mg. Fixed dose administration is common practice due to the available pharmaceutical formulations, while in the ideal situation the dose should be based on dose/kg or titrated to the required clinical effect.

Variable absorption of clavulanic acid after an oral dose of 25 mg/kg of Clavubactin and Synulox in healthy dogs.

The aims of this investigation were to calculate the pharmacokinetic parameters and to identify parameters, based on individual plasma concentration-time curves of amoxicillin and clavulanic acid in dogs, that may govern the observed differences in absorption of both drugs. The evaluation was based on the data from plasma concentration-time curves obtained following a single dose in an open, randomized, two-way crossover study involving 24 male Beagle dogs treated with two Amoxi-Clav formulations (A Clavubactin and B Synulox, each with 200/50 mg). Plasma amoxicillin and clavulanic acid concentrations were determined using validated bioassay methods. The half-life of elimination of amoxicillin was 1.5 h (t1/2 = 1.52 +/- 0.19 h, Cmax = 11.4 +/- 2.74 microg/mL), and that of clavulanic acid 0.76 h (t1/2 = 0.71 +/- 0.23 h, Cmax = 2.06 +/- 1.05 microg/mL). There was a fivefold variation in the AUCt of clavulanic acid for both formulations, while the AUCt of amoxicillin varied by a factor of 2. The mean ratio of the AUCt amoxicillin : clavulanic acid was 12.7 +/- 3.65 for formulation A and 11.8 +/- 5.22 for formulation B (P = 0.51).

Steady state bupivacaine plasma concentrations and safety of a femoral "3-in-1" nerve block with bupivacaine in patients over 80 years of age.

OBJECTIVES: Fracture of the upper femur is a common injury in the elderly. Several anesthetic techniques exist for surgery of traumatic hip fracture. The aim of this investigation was to study plasma concentrations and safety of 2 mg/kg bupivacaine in a femoral "3-in-1" nerve block in patients older than 80 years of age. SUBJECTS AND METHODS: A 3-in-1 femoral nerve block, combined with a general anesthetic was used in 10 elderly patients aged over 80 years. They were undergoing emergency surgery for stabilization of their fractured femur. Bupivacaine plasma concentrations of radial artery blood samples were assessed over a 6-hour period after a femoral 3-in-1 injection of 2 mg/kg bupivacaine 0.375% with epinephrine (1:400,000). RESULTS: No toxic reactions to bupivacaine were seen. In 8 of the 10 patients per- and postoperative analgesia were adequate as a result of the nerve block. Patients experienced loss of sensation and analgesia for 26.6 +/- 4.6 hours (mean +/- SD). This was inversely related to the apparent steady state concentration of bupivacaine. The mean of the individual peak plasma concentrations of bupivacaine (C(max) was 0.74+/- 0.64 microg/ml. The highest plasma concentration was 1.83 microg/ml. Large variations in plasma concentrations were detected in these patients. Bupivacaine metabolites were not detected. CONCLUSIONS: A femoral 3-in-1 nerve block, using 2 mg/kg bupivacaine with epinephrine, provides prolonged pain reliefwithout local anesthetic toxicity in elderly patients. It is a satisfactory supplementary analgesic technique for hip and knee surgery in the elderly.

Stability of oral oxytocics in tropical climates: Stability of oral oxytocics in tropical climates: results of simulation studies on oral ergometrine, oral methylergometrine, buccal oxytocin and buccal desamino-oxytocin

It reports on an assessment of stability patterns of common oral oxytocics to evaluate their usefulness in reducing postpartum haemorrhage in tropical areas. Simulation studies assessed the influence of packaging, humidity, light and heat on tablets of ergometrine, methylergometrine, buccal oxytocin and buccal desamino-oxytocin. Publication from 1994, 52 pages, available both in html and pdf formats.

Liver and gut mucosa acetylation of mesalazine in healthy volunteers.

AIM: The aim of this investigation was to identify which part of a dose mesalazine is acetylated by enzymes in the gut wall during the absorption process, and which part by the liver enzymes after absorption. METHOD: This study was based on data from four bioequivalence studies of different formulations of tablets (gastro-resistant single dose 500 mg (n = 24) and prolonged-release tablets (single dose 1000 mg, n = 18; multiple dose 1000 mg t.i.d. six days n = 28), suppositories (single 500 mg dose, n = 24) and a study with two i.v. administrations of 100 and 250 mg mesalazine (n = 6). In total, 200 administrations were carried out and plasma concentration-time curves obtained and analyzed. There was a large variability in the absorption of mesalazine for all formulations. The plasma concentration-time curves of parent drug and metabolite acetylmesalazine run nearly parallel, independent of the formulation and the dose. Plasma and urine mesalazine and acetylmesalazine concentrations were determined according to validated methods using HPLC analysis with coulometric or mass-spectrometric detection. RESULTS: As a result of the large variations in release and absorption of mesalazine in the pharmaceutical formulations and administrations, it was possible to demonstrate that acetylation occurs in the gut wall and in the liver. By comparing oral and rectal data to intravenous data, it was possible to indicate where (and to what extent) acetylation occurs in the gut wall, in the liver, or both. Rectal administration of a mesalazine suppository and intravenous administration results in hepatic acetylation. Oral administrations of mesalazine results in both gut wall and hepatic acetylation. Acetylation by the gut wall amounts to 30% of the dose for gastroresistant tablets and to 40% of the dose for prolonged-release tablets.

Codeine analgesia is due to codeine-6-glucuronide, not morphine.

Eighty per cent of codeine is conjugated with glucuronic acid to codeine-6-glucuronide. Only 5% of the dose is O-demethylated to morphine, which in turn is immediately glucuronidated at the 3- and 6-position and excreted renally. Based on the structural requirement of the opiate molecule for interaction with the mu-receptor to result in analgesia, codeine-6-glucuronide in analogy to morphine-6-glucuronide must be the active constituent of codeine. Poor metabolisers of codeine, those who lack the CYP450 2D6 isoenzyme for the O-demethylation to morphine, experience analgesia from codeine-6-glucuronide. Analgesia of codeine does not depend on the formation of morphine and the metaboliser phenotype.

Mono- and biphasic plasma concentration-time curves of mesalazine from a 500 mg suppository in healthy male volunteers controlled by the time of defecation before dosing.

This study was based on data from a bioequivalence study (n=24) of two different formulations of suppositories containing 500 mg mesalazine (formulation I and II), with a similar dissolution profile in phosphate buffer pH 6.8. There was a large intra- and intersubject variability in the plasma concentration-time curves of mesalazine from both suppositories. The aim of the investigation was to identify the parameters that caused the observed large variations in release and absorption of mesalazine in the rectum. Plasma mesalazine and acetylmesalazine, and urine acetylmesalazine concentrations were determined according to validated methods involving HPLC analysis with coulometric detection. Lower limit of quantitation values were respectively 10.4 and 19.4 ng mL(-1) in plasma and 0.96 microg mL(-1) in urine. The time of defecation before and after insertion was recorded. There was a clear distinction between subjects who showed monophasic mesalazine release/absorption and those who showed biphasic and more extended release/absorption. With formulation I there was a correlation between time of defecation before dosing and the type of absorption, monophasic and biphasic absorbers showed a significant difference in the time of defecation, e.g. 9.7+/-5.6 h vs 18.8+/-11.9 h (P = 0.0218). The impact of time of defecation before dosing was non-significant with formulation II, 16.7+/-7.2 h vs 15.1+/-4.2 h (P = 0.67). The impact of the time elapsed between administration and time of defecation after the insertion of the suppository was not significant for the type of release/absorption. The plasma concentration-time curves of the metabolite ran parallel to that of the parent drug, the more parent drug was released/absorbed, the more was acetylated (P = 0.0013) and excreted into the urine (P = 0.0004). After absorption the compound was metabolized into acetylmesalazine, and renally excreted (12-13% of the dose). Monophasic release/ absorption resulted in 7.1% metabolite with I and 10.3% with II (P = 0.0004), while biphasic release/absorption gave 16.8% metabolite with I and 15.5% with II. The renal clearance of the metabolite acetylmesalazine was independent of the observed defecation patterns (300 mL min(-1), P > 0.8), stool composition, and type of absorption.

Bioavailabilities of quercetin-3-glucoside and quercetin-4'-glucoside do not differ in humans.

The flavonoid quercetin is an antioxidant which occurs in foods mainly as glycosides. The sugar moiety in quercetin glycosides affects their bioavailability in humans. Quercetin-3-rutinoside is an important form of quercetin in foods, but its bioavailability in humans is only 20% of that of quercetin-4'-glucoside. Quercetin-3-rutinoside can be transformed into quercetin-3-glucoside by splitting off a rhamnose molecule. We studied whether this 3-glucoside has the same high bioavailability as the quercetin-4'-glucoside. To that end we fed five healthy men and four healthy women (19-57 y) a single dose of 325 micromol of pure quercetin-3-glucoside and a single dose of 331 micromol of pure quercetin-4'-glucoside and followed the plasma quercetin concentrations. The bioavailability was the same for both quercetin glucosides. The mean peak plasma concentration of quercetin was 5.0+/-1.0 micromol/L (+/-SE) after subjects had ingested quercetin-3-glucoside and 4.5+/-0.7 micromol/L after quercetin-4'-glucoside consumption. Peak concentration was reached 37 +/-12 min after ingestion of quercetin-3-glucoside and 27+/-5 min after quercetin-4'-glucoside. Half-life of elimination of quercetin from blood was 18.5+/-0.8 h after ingestion of quercetin-3-glucoside and 17.7+/-0.9 h after quercetin-4'-glucoside. We conclude that quercetin glucosides are rapidly absorbed in humans, irrespective of the position of the glucose moiety. Conversion of quercetin glycosides into glucosides is a promising strategy to enhance bioavailability of quercetin from foods.

Skeletal muscle relaxants: pharmacodynamics and pharmacokinetics in different patient groups.

Muscle relaxants can be safely administered during anaesthesia, providing the basic pharmacodynamic and pharmacokinetic characteristics of the compounds together with the physiological status of the patient are known. In this review the pharmacodynamics and pharmacokinetics of the neuromuscular blocking agents are discussed and related to the physical health or disease state of groups of patients.

Similar motor block effects with different disposition kinetics between lidocaine and (+ or -) articaine in patients undergoing axillary brachial plexus block during day case surgery.

AIM: The aim of this investigation was to compare the clinical effects and pharmacokinetics of lidocaine and articaine in two groups of 15 patients undergoing axillary brachial plexus anesthesia. METHOD: The study had a randomized design. Thirty patients were allocated to one of the two groups. Each patient received either lidocaine (600 mg = 2.561 mMol + 5 microg/ml adrenaline) or articaine (600 mg = 2.113 mMol + 5 microg/ml adrenaline), injected via the axilla of the brachial plexus over a period of 30 seconds. Onset of surgical analgesia was defined as the period from the end of the injection of the local anesthetic to the loss of pinprick sensation in the distribution of all three nerves. RESULTS: The mean onset time of sensory block of the median nerve of both lidocaine and articaine were approximately 10 min. Lidocaine is biexponentially eliminated with a t1/2alpha of 9.95 +/- 14.3 min and a t1/2beta of 2.86 +/- 1.55 h. Lidocaine is metabolized into MEGX (mono-ethyl-glycyl-xilidide) (t(max) 2.31 +/- 0.84 h; C(max) 0.32 +/- 0.13 mg/l; t1/2beta 2.36 +/- 2.35 h). Lidocaine total body clearance was 67.9 +/- 28.9 l/h. Articaine is rapidly and monoexponentially eliminated with a t1/2beta of 0.95 +/- 0.39 h. The total body clearance of articaine is higher than that of lidocaine, 1,133 +/- 582 l/h vs 67.9 +/- 28.9 l/h, respectively (p < 0.0001). The volume of distribution (V(d)), of articaine is a factor 16 higher times than that of lidocaine (p < 0.0001). CONCLUSION: For the axillary administration, lidocaine and articaine show similar pharmacodynamics with a different pharmacokinetic behavior and can therefore be used to the clinical preference for this regional anesthetic technique.

High-performance liquid-chromatographic-atmospheric-pressure chemical-ionization ion-trap mass-spectrometric identification of isomeric C6-hydroxy and C20-hydroxy metabolites of methylprednisolone in the urine of patients receiving high-dose pulse therapy.

Fourteen metabolites of methylprednisolone have been analysed by gradient-elution high-performance liquid chromatography coupled with tandem mass spectrometry (LC-MS-MS). The compounds were separated on a Cp Spherisorb 5 microm ODS column connected to a guard column packed with pellicular reversed phase. The mobile phase was an acetonitrile- 1.0% aqueous acetic acid gradient at a flow rate of 1.5 mL min(-1) The analysis gave a complete picture of parent drug, prodrugs and metabolites, and the alpha/beta stereochemistry was resolved. The short (1-2 h) elimination half-life of methylprednisolone is explained by extensive metabolism. The overall picture of the metabolic pathways of methylprednisolone is apparently simple-reduction of the C20 carbonyl group and further oxidation of the C20,C21 side chain (into C21COOH and C20COOH), in competition with or in addition to oxidation at the C6 position.

High-performance liquid chromatography analysis, preliminary pharmacokinetics, metabolism and renal excretion of methylprednisolone with its C6 and C20 hydroxy metabolites in multiple sclerosis patients receiving high-dose pulse therapy.

A gradient eluent HPLC analysis in human plasma and urine was developed and validated for methylprednisolone (MP), its prodrug methylprednisolone-21-hemisuccinate (MPS) with the metabolites 6beta-hydroxy-6alpha-methylprednisolone (MPA), 20-hydroxymethylprednisolone (MPC), 6beta-hydroxy-20alpha-hydroxymethylprednisolone (MPB), 6beta-hydroxy-20beta-hydroxymethylprednisolone (MPE), 20-carboxymethylprednisolone (MPD), methylprednisolone-glucuronide (MPF) and 21-carboxymethylprednisolone (MPX). The column was Cp Spherisorb C8 5 microm, 250 mm x 4.6 mm I.D. (Chrompack, Bergen op Zoom, The Netherlands) with a guard column 75 mm x 2.1 mm, packed with pellicular reversed-phase. The eluent was a mixture of acetonitrile and 0.067 M KH2PO4 buffer, pH 4.5. At t=O, the eluent consisted of 2% acetonitrile and 98% buffer (v/v). Over the following 35 min the eluent changed linearly until it attained a composition of 50% acetonitrile and 50% buffer (v/v). At 37 min (t=37) the eluent was changed over 5 min to the initial composition, followed by equilibration over 3 min. The flow-rate was 1.5 ml/min and UV detection was achieved at 248 nm. Preliminary pharmacokinetic data were obtained from one patient who showed illustrative plasma concentration-time curves and renal excretion-time profiles after a short-lasting infusion (0.5 h) of 1 g of methylprednisolone hemisuccinate. The half-life of prodrug methylprednisolone-21-hemisuccinate (MPS) was 0.3 h, that of metabolite MPX (21-carboxy MP) was 0.4 h and that of the parent drug methylprednisolone (MP) was 1.4 h. The half-lives of the metabolites are almost similar (4 h). The main compounds in the urine are methylprednisolone hemisuccinate (prodrug, 15.0%), methylprednisolone (parent drug, 14.6%), metabolite MPD (20-carboxy, 11.7%), and metabolite MPB (13.2%). The renal clearance values of metabolites MPB, MPC and MPD are approximately 500 ml/min, that of MP is 100 ml/min.

Absolute bioavailability, pharmacokinetics, renal and biliary clearance of distigmine after a single oral dose in comparison to i.v. administration of 14C-distigmine-bromide in healthy volunteers.

AIM: The aim of the study was to determine the absolute bioavailability and pharmacokinetics after a single dose oral administration in comparison to i.v. administration of 14C-labelled distigmine-bromide (14C-Ubretid) in healthy male volunteers. RESULTS: After the intravenous administration, distigmine is eliminated from the body by renal excretion (85%), and for a small fraction by biliary excretion in the feces (4%). This situation is reversed after an oral administration, where 6.5% of the dose is recovered from the urine and 88% from the feces. This means that distigmine after oral administration is hardly absorbed, the calculated bioavailability is 4.65%. CONCLUSION: The mean absorption time (MAT) after oral administration was 10 h, influencing the t(1/2alpha) (1.4 vs 4.5 h) and the t(1/2beta) (60 vs 70 h) to higher values than after the i.v. administration (p < 0.05).

Isolation and identification of the C6-hydroxy and C20-hydroxy metabolites and glucuronide conjugate of methylprednisolone by preparative high-performance liquid chromatography from urine of patients receiving high-dose pulse therapy.

In the present study metabolites of methylprednisolone were detected using gradient elution high-performance liquid chromatography. Separation was performed by a Cp Spherisorb ODS 5 microm (250 mmx4.6 mm I.D.) column, connected to a guard column, packed with pellicular reversed phase. The mobile phase was a mixture of acetonitrile and 1% acetic acid in water. At t = 0, this phase consisted of 2% acetonitrile and 98% acetic acid 1% in water (v/v). During the following 35 min the phase changed linearly until it attained a composition of acetonitrile-buffer (50:50, v/v). At 40 min (t = 40) the mobile phase was changed over 5 min to the initial composition, followed by equilibration during 2 min. The flow-rate was 1.5 ml/min. UV detection was achieved at 248 nm. We have isolated the respective compounds with the most abundant concentration and suggested their chemical structure based on NMR, IR, UV, MS, retention behaviour and melting points. The c/, stereochemistry could not be solved in this study. The overall picture of the metabolic pathways of methylprednisolone is apparently simple: reduction of the C20 carbonyl group and further oxidation of the C20-C21 side chain (into C21-COOH and C20-COOH), in competition with or additional to the oxidation at the C6-position.

Clinical consequences of the biphasic elimination kinetics for the diuretic effect of furosemide and its acyl glucuronide in humans.

This review discusses the possibility of whether furosemide acyl glucuronide, a metabolite of furosemide, contributes to the clinical effect of diuresis. First an analytical method (e.g. HPLC) must be available to measure both parent drug and furosemide acyl glucuronide. Then, with correctly treated plasma and urine samples (light protected, pH 5) from volunteers and furosemide-treated patients, the kinetic curves of both furosemide as well as its acyl glucuronide can be measured. The acyl glucuronide is formed in part by the kidney tubules and it is possible that the compound is pharmacologically active through inhibition of the Na+/2Cl-/K+ co-transport system; up to now the mechanism of action has been solely attributed to furosemide. The total body clearance of furosemide occurs by hepatic and renal glucuronidation (50%) and by renal excretion (50%). Enterohepatic cycling of furosemide acyl glucuronide, followed by hydrolysis, results in a second and slow elimination phase with a half-life of 20-30 h. This slow elimination phase coincides with a pharmacodynamic rebound phase of urine retention. After each dosage of furosemide, there is first a short stimulation of urine flow (4 h), which is followed by a 3-day recovery period of the body. The following clinical implications arise from study of the elimination kinetics of furosemide. Repetitive dosing must result in accumulation of the recovery period. Accumulation of furosemide and its acyl glucuronide in patients with end-stage renal failure results from infinite hepatic cycling. Impaired kidney function may result in impaired glucuronidation and diuresis. While kidney impairment normally requires a dose reduction for those compounds which are mainly eliminated by renal excretion, for diuretics, a dose increment is required in order to maintain a required level of diuresis. The full clinical impact of the accumulation of furosemide and its acyl glucuronide in patients with end-stage renal failure has to be determined.

Direct high-performance liquid chromatography determination of propofol and its metabolite quinol with their glucuronide conjugates and preliminary pharmacokinetics in plasma and urine of man.

Propofol (P) is metabolized in humans by oxidation to 1,4-di-isopropylquinol (Q). P and Q are in turn conjugated with glucuronic acid to the respective glucuronides, propofol glucuronide (Pgluc), quinol-1-glucuronide (Q1G) and quinol-4-glucuronide (Q4G). Propofol and quinol with their glucuronide conjugates can be measured directly by gradient high-performance liquid chromatographic analysis without enzymic hydrolysis. The glucuronide conjugates were isolated by preparative HPLC from human urine samples. The glucuronides of P and Q were present in plasma and urine, P and Q were present in plasma, but not in urine. Quinol in plasma was present in the oxidised form, the quinone. Calibration curves of the respective glucuronides were constructed by enzymic deconjugation of isolated samples containing different concentrations of the glucuronides. The limit of quantitation of P and quinone in plasma are respectively 0.119 and 0.138 microg/ml. The limit of quantitation of the glucuronides in plasma are respectively: Pgluc 0.370 microg/ml, Q1G 1.02 microg/ml and Q4G 0.278 microg/ml. The corresponding values in urine are: Pgluc 0.264 microg/ml, Q1G 0.731 microg/ml and Q4G 0.199 microg/ml. A pharmacokinetic profile of P with its metabolites is shown, and some preliminary pharmacokinetic parameters of P and Q glucuronides are given.

Ergot alkaloids. Current status and review of clinical pharmacology and therapeutic use compared with other oxytocics in obstetrics and gynaecology.

Ergot alkaloids are well known preparations. Ergot alkaloids used in obstetrics and gynaecology are ergometrine (ergonovine; EM), methylergometrine (methergine; ME) and bromocriptine. The pharmaceutical properties of ME EM) are critical. To guarantee stability, ME and EM ampoules should be stored in a cool, dark place. ME and EM tablets are unstable in all conditions and they show an unpredictable bioavailability, which prevents oral use of the drugs for any purpose. ME and EM are known for their strong uterotonic effect and, compared with other ergot alkaloids, for their relatively slight vasoconstrictive abilities. ME and EM do have a place in the management of the third stage of labour as they are strong uterotonics. They act differently from oxytocin and prostaglandins, and have different adverse effects. Oxytocin should be used as prophylaxis or a the drug of first choice; next, ME or EM should be used, and if none of these drugs produce the desired effects, prostaglandins should be used to control bleeding. Ergot alkaloid use in gynaecology has been limited and today is discouraged even in essential menorrhagia. It is suggested that EM and ME be used (parenterally) only in first trimester abortion curettage, to reduce blood loss. Bromocriptine has been used for lactation suppression. However, alternatives such as cabergoline, which possess fewer adverse effects, are now available and therefore preferred for this indication. In sum, there is no place for the prophylactic use of ME and EM in obstetrics or gynaecology. They can be used for therapeutic purposes in the third stage of labour. During use, the practitioner must be alert for adverse effects.

Enterohepatic cycling and pharmacokinetics of oestradiol in postmenopausal women.

The pharmacokinetics and enterohepatic cycling of oestradiol have been studied after three oral, single-dose administrations of equimolar doses of oestradiol alone, oestradiol plus desogestrel and oestradiol valerate, in a 3-way cross-over mode in 18 healthy postmenopausal women. Oestradiol was readily absorbed and metabolized to oestrone, which reached much higher serum concentrations (140pgmL(-1)) than its parent compound (35pgmL(-1)). All three formulations had the same kinetic profile and were bioequivalent on testing. Noticeable first and second absorption phases were apparent from the oestradiol and oestrone serum concentration-time curves for all oestradiol formulations. The mean serum concentration-time curves of the metabolite oestrone (corrected for endogenous oestrone) showed a second maximum at approximately 25h. By means of line feathering, serum concentration-time curves were constructed which belonged to the first, second and third phases of absorption. The maximum serum concentration, Cmax, of the second absorption or recirculation of oestrone was 20% that of the first, and the Cmax of the third circulation was 50% that of the second. The areas under the serum-concentration-time curves (AUC) for the second and third recirculations were similar-each comprised 12-13% of the total AUC. The oral clearance values of the recirculations were constant (590Lh(-1)). Enterohepatic recirculation of endogenous compounds is aimed at maintaining a steady-state serum concentration for immediate use and hydrolysis in the target organs. It is concluded that exogenously added oestradiol and its metabolites follow the recirculation pathways of the endogenous oestrogen pool.

Accelerated recovery and disposition from rocuronium in an end-stage renal failure patient on chronic anticonvulsant therapy with sodium valproate and primidone.

An end-stage renal failure patient, receiving chronic treatment with the anticonvulsants, sodium valproate and primidone, showed accelerated recovery with enhanced elimination (T1/2(z) = 52 min) and clearance (Cl = 14.4 ml min-1 kg-1) of rocuronium. The pharmacokinetic and pharmacodynamic effects of rocuronium in this patient are compared with those published for healthy and renal failure patients. Increased hepatic binding of rocuronium rather than metabolism is suggested as the possible cause of this effect.