The pharmacokinetics of midazolam in man

Midazolam, a new water-soluble benzodiazepine, was administered as: i) 5 mg intravenously, ii) a 10-mg oral solution and iii) a 10-mg oral tablet, to six volunteers whose informed consent had been obtained. Midazolam plasma concentrations were measured using an electron-capture gas-liquid chromatographic assay. After 5-mg intravenous midazolam, subjects fell asleep within 1-2 min and continued to sleep for an average of 1.33 h. After oral midazolam intake (solution or tablets), drowsiness appeared after a average of 0.38 h (range 0.25-0.55 h) and sleep continued for an average of 1.17 h. The time to reach peak plasma midazolam concentration after the 10-mg solution dose (0.37 +/- 0.45 h) did not differ significantly ('t' = 2.04, df = 10, p greater than 0.05) from the time to reach peak plasma midazolam level after the 10-mg tablet dose (0.74 +/- 0.45 h). The terminal half-life, (t 1/2), of midazolam in plasma was 1.77 +/- 0.83 h and there was no significant difference between the mean terminal half-life values obtained for the three midazolam formulations. The mean total clearance (Cl), of midazolam after 5-mg intravenous administration was 0.383 +/- 0.0941 . kg-1 . h-1. The first pass effect, F, determined experimentally (0.36 +/- 0.09) indicated the substantial first pass metabolism of midazolam. The percentage of the midazolam dose excreted unchanged in urine in four subjects during the 0-8-h urine collection interval was very small (0.011%-0.028%).

Outbreak of anticonvulsant intoxication in an Australian city

An outbreak of anticonvulsant intoxication occurred in epileptic patients in Australia during 1968-9. All affected patients studied in Brisbane were taking one brand of phenytoin. In 87% of them the blood phenytoin levels were above the therapeutic range. Reduction of phenytoin dosage relieved the intoxication in all patients. The excipient in the responsible phenytoin capsules had been changed several months before the outbreak, and this change was probably related causally to the altered blood phenytoin concentrations.

Foetal malformations and seizure control: 52 months data of the Australian Pregnancy Registry

The Australian Pregnancy Registry, affiliated European Register of Antiepileptic drugs in Pregnancy (EURAP), recruits informed consenting women with epilepsy on treatment with antiepileptic drugs (AEDs), those untreated, and women on AEDs for other indications. Enrolment is considered prospective if it has occurred before presence or absence of major foetal malformations (FMs) are known, or retrospective, if they had occurred after the birth of infant or detection of major FM. Telephone Interviews are conducted to ascertain pregnancy outcome and collect data about seizures. To date 630 women have been enrolled, with 565 known pregnancy outcomes. Valproate (VPA) above 1100 mg/day was associated with a significantly higher incidence of FMs than other AEDs (P < 0.05). This was independent of other AED use or potentially confounding factors on multivariate analysis (OR = 7.3, P < 0.0001). Lamotrigine (LTG) monotherapy (n = 65), has so far been free of malformations. Although seizure control was not a primary outcome, we noted that more patients on LTG than on VPA required dose adjustments to control seizures. Data indicate an increased risk of FM in women taking VPA in doses >1100 mg/day compared with other AEDs. The choice of AED for pregnant women with epilepsy requires assessment of balance of risks between teratogenicity and seizure control.

Valproate-associated hepatotoxicity and its biochemical mechanisms

Intake of the anticonvulsant drug valproic acid, or its sodium salt, has been associated with occasional instances of severe and sometimes fatal hepatotoxicity. Probably at least 80 cases have occurred worldwide. The syndrome affects perhaps 1 in 10,000 persons taking the drug, and usually develops in the early weeks or months of therapy. Most instances have involved children, usually those receiving more than 1 anticonvulsant. Multiple cases have occurred in 2 families. The typical presentation is of worsening epilepsy, increasing depression of consciousness, and progressive clinical and biochemical evidence of liver failure. The liver has sometimes shown hepatocyte necrosis, and on other occasions widespread microvesicular steatosis, while cholestatic changes have also occurred. The appearances are interpreted as consistent with a drug toxicity reaction. During the hepatotoxicity increased amounts of unsaturated metabolites of valproate, notably 4-en-valproate, have been found in blood and urine. In 4 cases there has been evidence of impaired beta-oxidation of valproate with, in 1 case, accumulation of isomers of valproate glucuronide caused by intramolecular rearrangement of the conjugate. There are molecular structural similarities between 4-en-valproate and 2 known hepatotoxins (4-en-pentanoate and methylenecyclopropylacetic acid, the latter being responsible for hypoglycin poisoning). There are also clinical and histopathological similarities between valproate hepatotoxicity and both hypoglycin poisoning and certain spontaneous disorders of isoleucine metabolism (one pathway of valproate metabolism is analogous to oxidative degradation of isoleucine). Unsaturated metabolites of valproate, in particular 4-en-valproate, may contribute to the hepatotoxicity of the drug. However, since the hepatotoxicity appears to involve an element of idiosyncrasy, the primary defect in some cases may be an inherited or acquired deficiency in the drug's beta-oxidation. This defect may divert valproate metabolism towards omega-oxidation, with increased formation of the toxin 4-en-valproate, but may also allow increased formation of a toxic metabolite derived from isoleucine, since beta-oxidation of isoleucine derivatives will also be impaired.

Maternal valproate dosage and foetal malformations

OBJECTIVE- To study the possible dose dependence of the foetal malformation rate after exposure to sodium valproate in pregnancy METHODS- Analysis of records of all foetuses in the Australian Registry of Antiepileptic Drugs in Pregnancy exposed to valproate, to carbamazepine, lamotrigine or phenytoin in the absence of valproate, and to no antiepileptic drugs. RESULTS- The foetal malformation rate was higher (P<0.05) in the 110 foetuses exposed to valproate alone (17.1%), and in the 165 exposed to valproate, whether alone or together with the other antiepileptic drugs (15.2%), than in the 297 exposed to the other drugs without valproate (2.4%). It was also higher (P<0.10) than in the 40 not exposed to antiepileptic drugs (2.5%). Unlike the situation for the other drugs, the malformation rate in those exposed to valproate increased with increasing maternal drug dosage (P<0.05). The rate was not altered by simultaneous exposure to the other drugs. Valproate doses exceeding 1400 mg per day seemed to be associated with a more steeply increasing malformation rate than at lower doses and with a different pattern of foetal malformations. CONCLUSIONS- Foetal exposure to valproate during pregnancy is associated with particularly high, and dose-dependent risks of malformation compared with other antiepileptic drugs, and may possibly involve different teratogenetic mechanisms.

Plasma anticonvulsant concentrations during pregnancy

Plasma anticonvulsant levels were followed during pregnancy in 11 epileptic women taking phenytoin and/or phenobarbital or a drug metabolized in the body to phenobarbital. As judged from the relationship between plasma level and drug dose, phenytoin requirement increased in all 10 women taking this drug during pregnancy. The requirement fell again in the puerperium. Plasma phenobarbital levels decreased during pregnancy in all five women taking a constant daily dose of phenobarbital or a congener. These findings should be borne in mind if epileptics are to be protected against seizures during pregnancy and against anticonvulsant overdosage during the puerperium.

Effect of dosage increments on blood phenytoin concentrations

Blood phenytoin (diphenylhydantoin) concentrations were measured after each dosage change in 12 epileptic patients who were given increasing oral doses of phenytoin. In each of these patients a dosage increment beyond the dosage that produced a blood phenytoin level of 6-9 μg/ml. caused a disproportionately great increase in the blood concentration of drug. This effect might be expected if the limit of the body's capacity to metabolize phenytoin were being reached. As oral dosages were increased in one patient, measurements of the rate of urinary excretion of phenytoin metabolite showed that the phase of rapid rise in blood phenytoin concentration coincided with a failure to increase the rate of phenytoin metabolite excretion. Awareness of the non-linear relation between oral dose and blood concentration of phenytoin in the individual patient, and realization that the phase of rapid rise in blood phenytoin concentration occurs through the `therapeutic' range of 10-20 μg/ml., is of importance to those who use blood phenytoin levels as a guide to the adequacy of anticonvulsant therapy.

Plasma drug level monitoring in pregnancy

During pregnancy a number of continuously changing circumstances exist which might be expected to modify the relation between plasma drug levels and drug dosage. Alimentary tract motility may be decreased, the distribution of many drugs may be altered, glomerular filtration rate is greater and biotransformation capacity may be changed as pregnancy advances. However, relatively little has been published on the monitoring of plasma drug levels during pregnancy. It has been established that, in the presence of constant drug doses, plasma levels of phenytoin, phenobarbitone and certain other anticonvulsants tend to fall during pregnancy and rise again during the puerperium. Plasma lithium and possibly digoxin levels also fall relative to drug dose as pregnancy progress, and rise again in the puerperium. While the changes in lithium and digoxin levels are probably chiefly due to increased rate of glomerular filtration during pregnancy, the altered anticonvulsant requirement is more likely to depend mainly on an increased rate of biotransformation. Anticonvulsant plasma levels should be monitored regularly from the outset of pregnancy and more frequently after birth.

Plasma protein binding of carbamazepine

The binding of carbamazepine to the proteins of human plasma has been studied using ultrafiltration techniques. In vitro studies at 37 degrees C showed the relation between concentration of unbound drug and total drug to be linear through the range of total concentration of 5 to 50 mug/ml. The per cent unbound drug increased slightly as concentration increased. There was little difference between the extent of binding at 4 degrees C and 20 degrees C, but more carbamazepine was unbound at 37 degrees C. Under in vitro conditions, 6 other anticonvulsants, and aspirin, were tested individually, each at high therapeutic or toxic concentration, and shown not to displace carbamazepine from plasma proteins to a significant degree. The extent of binding of carbamazepine in vivo was determined in a total of 54 plasma samples collected from treated patients; 26.9 plus or minus SD 9.4 percent of the drug was unbound. In blood samples from 23 of these patients, the red cell concentration of carbamazepine averaged 38.3 plus or minus SD 17.9 percent of the plasma concentration. The effects of hepatic and renal diseases on the carbamazepine binding capacity of plasma proteins were assessed by comparing the binding capacity of plasma from disease persons with that from normal subjects. There was no significant difference in binding capacity between plasma from patients with renal disease and that from normal subjects. However, the plasma from patients with hepatic disease bound a slightly lower percentage of carbamazepine than did normal plasma (p smaller than 0.05). This alteration did not correlate with changes in any of 15 biochemical parameters measured in these patients. The clinical significance of these results is discussed.

Plasma antiepileptic drug concentrations during pregnancy

Steady-state plasma antiepileptic drug (AED) concentrations were measured at intervals throughout pregnancy and during the postnatal period in 105 women who underwent 134 pregnancies. Phenytoin (PHT) dosage had to be increased in 85% of pregnancies in which the drug was received, carbamazepine (CBZ) dosage in 70%, and phenobarbital (PB) or methylphenobarbital (MPB) dosage in 85%, in an attempt to prevent or correct a fall in plasma concentrations of the respective drugs as pregnancy progressed. The altered disposition of the AEDs usually began in the first 10 weeks of pregnancy (often before epileptic pregnant women are referred for neurological supervision), and had returned to baseline value within 4 weeks of childbirth in two thirds of the women receiving PHT. The return to the nonpregnant situation appeared to be slower for CBZ, PB, and MPB. In women studied during more than one pregnancy, the changes in AED dosage to plasma concentration ratios tended to be greater in the first than in the subsequent pregnancies. Full seizure control prior to pregnancy was associated with a more favorable outcome for freedom from seizures during pregnancy. However, the plasma level monitoring-dosage adjustment policy produced no marked improvement in overall seizure control in pregnancy. This may have occurred because some patients were seen too late in their pregnancies for the policy to have been applied optimally.

Anticonvulsant drugs. An update

A considerable amount of information is now available concerning the clinical pharmacology of the anticonvulsant drugs. Some of the more important data are reviewed in this article. In recent years, valproic acid (or sodium valproate) has found a place as a major anticonvulsant agent, while older drugs such as troxidone and sulthiame seem to be disappearing from use. Although much information is available, the essential mechanisms of action of the anticonvulsant drugs are still not understood, either at a molecular or at an electrophysiological level. The pharmacokinetics of the anticonvulsants in common use are now reasonably well documented, though some minor questions are still to be answered. Numerous interactions between anticonvulsants and endogenous substances or other drugs administered concurrently (including other anticonvulsants) have been recorded, but much work still needs to be done to elucidate the frequency and mechanisms of the various interactions. Many adverse effects of the anticonvulsants are known, but further unwanted effects of long-established drugs continue to emerge from time to time, including the still somewhat controversial matter of anticonvulsant-related dysmorphogenesis. The use of valproic acid and its sodium salt has been associated with a worrying incidence of serious liver and pancreatic toxicity. Adequate basic data are now available to put the clinical use of anticonvulsants on a rational basis, but much work remains to be done in this area. In particular, the question of 'therapeutic ranges' of plasma concentrations of the various drugs needs to be reinvestigated in a rigorous statistical fashion, and in relation to different clinical types of epilepsy. The usefulness of monitoring free rather than total drug concentrations also needs further investigation. The ultimate test of the validity of all background scientific pharmacological information about anticonvulsants is its usefulness in the treatment of patients with epilepsy.

Phenytoin impairs the bioavailability of dexamethasone in neurological and neurosurgical patients

Plasma concentration-time data after oral and intravenous administration of dexamethasone have been subjected to pharmacokinetic analysis in six neurological or neurosurgical patients taking the steroid with phenytoin, and in nine patients (one studied twice) taking dexamethasone without phenytoin. An additional patient was studied before and during phenytoin intake. Apparent volume of distribution was similar in the two groups, but the group treated with phenytoin had an almost statistically significantly shorter dexamethasone mean terminal half-life, an approximately trebled mean plasma clearance, and a mean oral bioavailability of the steroid of only 33%, compared with a mean 84% oral bioavailability in those not receiving phenytoin. To achieve a given plasma dexamethasone concentration, patients treated with the steroid and phenytoin may need oral dexamethasone doses several times those required by patients not receiving phenytoin.

Therapeutic drug monitoring--antiepileptic drugs

AIMS

To provide a brief critical review of the basis and contemporary practice of monitoring the concentrations of antiepileptic drugs in biological fluids.

METHODS

The review is based on literature data and observations from clinical practice.

RESULTS

As experience has accumulated, monitoring of antiepileptic drug concentrations has come to be applied mainly to certain of the drugs when present in whole plasma. For these drugs there is a reasonably established relationship between drug concentrations and biological effects, but attention still needs to be paid to issues such as the timing of the measurements in relation to drug intake, the presence or absence of steady-state conditions, the presence in plasma of active metabolites and possible nonlinear pharmacokinetics of particular agents e.g. phenytoin.

CONCLUSIONS

Plasma antiepileptic drug concentration monitoring is coming to be used in a more thoughtful and critical manner. Lack of adequate knowledge of matters such as the relationship between the plasma concentrations and antiepileptic and toxic effects of the drugs, not only the newer, but also the longer established ones, in particular clinical situations, remains more important than deficiencies in analytical methodology in limiting the clinical usefulness of antiepileptic drug concentration monitoring.

Plasma level monitoring of anticonvulsants

The plasma concentrations of anticonvulsant drugs, and of certain of their biologically active metabolites, tend to be proportionate to the antiepileptic effects of these drugs. Consequently, anticonvulsant drug levels in plasma are monitored to help guide the clinician in managing his patients' epilepsies. In making use of the measurements, the clinician needs to know the relation between plasma level and biological effect for the various drugs. He also needs to have some awareness of simple pharmacokinetic principles. These are important in deciding when plasma levels should be monitored in relation to the patients' clinical state, to the dosage interval, and to change in the dosage of anticonvulsant or other drug. The clinician also requires pharmacokinetic knowledge in altering anticonvulsant drug dosage in his patients, and in interpreting plasma anticonvulsant level data, particularly when the patient is concurrently suffering from non-neurological disease. The ability to monitor plasma anticonvulsant levels has appreciably improved the treatment of epilepsy, but to obtain maximum benefits from the method, both pharmacokinetic insight and clinical wisdom are required.

Chloroquine myopathy

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Urinary excretion of valproate and some metabolites in chronically treated patients

Urinary excretion of the antiepileptic agent valproic acid (VPA) and major metabolites from its glucuronidation, beta-oxidation, and omega- and omega 1-hydroxylation pathways were studied under steady state conditions in 24 epileptic patients. Some 55 +/- 18% (SD) of the daily dose was recovered in urine, 33 +/- 14% in the form of VPA-glucuronide, 15 +/- 8% as beta-oxidation products, and 4 +/- 2% and 2 +/- 1% as products of the omega- and omega 1-hydroxylation pathways, respectively. Only 1 +/- 2% of the dose was excreted unchanged. The proportion metabolized by direct glucuronidation tended to increase with dose at the expense of the oxidative pathways, particularly beta-oxidation. However, the wide variation in the patterns of urinary metabolite excretion precludes use of routinely collected urinary excretion data as a basis for detecting any but severe noncomplicance with VPA therapy or abnormalities of VPA metabolism.

Hyponatraemia during oxcarbazepine therapy

A clinical and pharmacokinetic study was carried out progressively substituting a new anticonvulsant oxcarbazepine for its congener carbamazepine in a group of patients with refractory epilepsy. Although oxcarbazepine showed possible though not statistically significant advantages of better seizure control and was probably less sedating, its use was associated with a dose-dependent reduction in plasma sodium levels in 12 of 15 patients. The mean plasma sodium level fell from 137.5 +/- 5.2 (s.d.) to 128.5 +/- 6.1 mE/l. Imposed restriction of fluid intake may have minimized the degree of hyponatraemia. This adverse effect may limit the role of the drug as an anticonvulsant or necessitate special precautions when it is used. However, the possibility of employing the drug in diabetes insipidus may be worth exploring.

Effect of felbamate on valproic acid disposition in healthy volunteers: inhibition of beta-oxidation

We assessed the effects of felbamate (FBM) on the disposition of valpr oic acid (VPA) in healthy volunteer men. Eighteen subjects received sodium VPA, 400 mg/day for 21 days. Plasma and urine samples were taken on day 7 to document the steady-state disposition of VPA alone. From day 8 to day 21, subjects received placebo or FBM at the following doses (mg/day): 1,200, 2,400, 3,000, or 3,600 (n = 2-4 per group). Many adverse events (AE) occurred from about day 10; 2 subjects dropped out and 1 continued on a reduced FBM dose. Pharmacokinetic studies were repeated on day 21 for the 16 subjects who completed the study. FBM was measured in plasma and urine by high-performance liquid chromatography (HPLC). VPA and its 2-en, 4-en, and 3-oxo metabolites in plasma, and VPA (nonconjugated and total), and its 3-oxo and 4-hydroxy metabolites in urine were measured by gas chromatography/mass spectrometry (GC/MS). Mean plasma FBM trough concentrations on day 21 ranged from 26.9 mu g/ml (1,200 mg dose) to 76.8 mu g/ml (3,600-mg dose). Mean plasma VPA C max values were 32-42 mu g/ml in the various subgroups when VPA only was administered. Higher plasma VPA levels were observed when FBM was administered concurrently (55.4-63.8 mu g/ml). The excretion of 3-oxo-VPA in urine was significantly lower on day 21 than on day 7, whereas VPA-glucuronide was significantly increased. The effects of FBM on VPA disposition were dose dependent and were maximal at approximately 2400 mg/day. FBM has caused significant inhibition of the beta-oxidation pathway for VPA metabolic clearance, and this had been largely compensated by increased VPA glucuronidation.

Changing patterns of antiepileptic drug use in pregnant Australian women

OBJECTIVE

To trace the pattern of antiepileptic drug (AED) use in pregnant Australian women annually from 1999 to 2007, and correlate it with the pattern of AED use in the wider community.

METHODS

Analysis of data from the Australian Register of AEDs in Pregnancy, related to Australian population data for AED prescriptions.

RESULTS

Over the study period, prescribing of carbamazepine, phenytoin and valproate for pregnant women decreased, and prescribing of lamotrigine, topiramate and levetiracetam increased. These changes tended to parallel prescribing trends in the wider community, except for valproate, whose prescribing in the overall community increased as its prescribing, and its dosage prescribed, decreased in pregnancy. Concomitant with this, there was a trend towards fewer births of foetuses with abnormalities.

CONCLUSIONS

While otherwise following national AED prescribing trends, Australian prescribers are reducing the use and dose of valproate in pregnant women, likely in recognition of the teratogenic hazards of this drug.

Factors influencing plasma phenobarbitone levels in epileptic patients

1 Various statistical techniques were used to study the effects of age, sex and concurrent therapy with other anticonvulsants on the relation between plasma phenobarbitone levels and doses of (i) phenobarbtione, (ii) methylphenobarbitone or (iii) primidone, in epileptic patients. 2 Methylphenobarbitone and primidone are converted to phenobarbitone in the body. The mean doses of phenobarbitone, methylphenobarbitone and primidone which produced the same plasma phenobarbitone level (15 microgram/ml) were, respectively, 1.75,2.75 and 7.75 mg kg-1 day-1. 3 For both phenobarbitone and methylphenobarbitone dose requirement to achieve a given plasma phenobarbitone level fell progressively with age. Sex influenced the relation between plasma phenobarbitone level and phenobarbitone or methylphenobarbitone dose. Interactions were detected between primidone and both phenytoin and carbamazepine. 4 In individual patients, within the limits of dosage studied, the relation between plasma phenobarbitone level and drug dose was not rectilinear if phenobarbitone itself was taken, but was rectilinear if methylphenobarbitone was taken.

Extent of urinary excretion of p-hydroxyphenytoin in healthy subjects given phenytoin

Urinary excretion of p-hydroxyphenytoin and its glucuronide conjugate was measured in eight healthy young adults in a comparative bioavailability study of oral sodium phenytoin (approximately 5 mg/kg/dose). Among these subjects the percentage of the phenytoin dose converted to p-hydroxyphenytoin and appearing in urine was relatively similar (mean 79%, range 67-88%). The great majority of the p-hydroxyphenytoin appeared in urine as conjugates; only 1.4-3.4% of the excreted p-hydroxyphenytoin was in the form of unconjugated metabolite. The proportion of a single phenytoin dose excreted in urine as p-hydroxyphenytoin or its conjugate increased from the first dose (mean +/- SD) 74.9 +/- 4.6% to the second dose, given 2 weeks later 79.3 +/- 4.6% (p less than 0.05). This finding suggests that autoinduction of phenytoin metabolism may occur after relatively brief exposure to the drug.