Preclinical characterization of 5-amino-4-oxo-[6-11C]hexanoic acid as an imaging probe to estimate protoporphyrin IX accumulation induced by exogenous aminolevulinic acid.

UNLABELLED: Preoperative noninvasive imaging to estimate the quantity and spatial distribution of protoporphyrin IX (PpIX) accumulation in tumors induced by 5-aminolevulinic acid (ALA) administration is expected to improve the efficacy of ALA-based fluorescence-guided resection and photo- and sonodynamic therapies. PpIX synthesis from exogenous ALA has been reported to be regulated by ALA influx or ALA dehydratase (ALAD) activity, which catalyzes the first step of the synthesis. In this study, we characterized the properties of a (11)C-labeled ALA analog, 5-amino-4-oxo-[6-(11)C]hexanoic acid ((11)C-MALA), as a PET tracer to estimate PpIX accumulation. METHODS: In vitro uptake of (11)C-MALA and (3)H-ALA was determined in 5 tumor cell lines after 10-min incubation with each tracer at 37°C. The expression levels of ALAD were determined by Western blot analysis. In vivo distribution and dynamic PET studies were conducted in tumor-bearing mice. In vitro and in vivo accumulation of ALA-induced PpIX was determined by measuring fluorescence in extracts of cells or tumors. RESULTS: In vitro uptake of (11)C-MALA in 5 tumor cell lines was correlated with ALAD expression levels and PpIX accumulation. In vivo biodistribution and dynamic PET studies showed that (11)C-MALA was rapidly incorporated into tumors, and the tumor-to-muscle ratio of (11)C-MALA at 1 min after injection was significantly correlated with that of (3)H-ALA. (11)C-MALA in tumors was continuously decreased thereafter, and the elimination rate of (11)C-MALA from AsPC-1 tumors with the highest ALAD expression level was slower than from other tumors with lower expression levels. These results suggest that the influx and intracellular retention of (11)C-MALA reflect ALA influx and ALAD expression levels, respectively. Tumor accumulation of (11)C-MALA at 60 min after injection was strongly correlated with PpIX accumulation in tumor tissues. CONCLUSION: (11)C-MALA PET has the potential to noninvasively estimate the quantitative and spatial accumulation of exogenous ALA-induced PpIX.

Comparison of two peptide radiotracers for prostate carcinoma targeting.

OBJECTIVES: Scintigraphy is generally not the first choice treatment for prostate cancer, although successful studies using bombesin analog radiopeptides have been performed. Recently, a novel peptide obtained using a phage display library demonstrated an affinity for prostate tumor cells. The aim of this study was to compare the use of a bombesin analog to that of a phage display library peptide (DUP-1) radiolabeled with technetium-99m for the treatment of prostate carcinoma. The peptides were first conjugated to S-acetyl-MAG3 with a 6-carbon spacer, namely aminohexanoic acid. METHODS: The technetium-99m labeling required a sodium tartrate buffer. Radiochemical evaluation was performed using ITLC and was confirmed by high-performance liquid chromatography. The coefficient partition was determined, and in vitro studies were performed using human prostate tumor cells. Biodistribution was evaluated in healthy animals at various time points and also in mice bearing tumors. RESULTS: The radiochemical purity of both radiotracers was greater than 95%. The DUP-1 tracer was more hydrophilic (log P = -2.41) than the bombesin tracer (log P = -0.39). The biodistribution evaluation confirmed this hydrophilicity by revealing the greater kidney uptake of DUP-1. The bombesin concentration in the pancreas was greater than that of DUP-1 due to specific gastrin-releasing peptide receptors. Bombesin internalization occurred for 78.32% of the total binding in tumor cells. The DUP-1 tracer showed very low binding to tumor cells during the in vitro evaluation, although tumor uptake for both tracers was similar. The tumors were primarily blocked by DUP1 and the bombesin radiotracer primarily targeted the pancreas. CONCLUSION: Further studies with the radiolabeled DUP-1 peptide are recommended. With further structural changes, this molecule could become an efficient alternative tracer for prostate tumor diagnosis.

Comparison of two peptide radiotracers for prostate carcinoma targeting

OBJECTIVES: Scintigraphy is generally not the first choice treatment for prostate cancer, although successful studies using bombesin analog radiopeptides have been performed. Recently, a novel peptide obtained using a phage display library demonstrated an affinity for prostate tumor cells. The aim of this study was to compare the use of a bombesin analog to that of a phage display library peptide (DUP-1) radiolabeled with technetium-99m for the treatment of prostate carcinoma. The peptides were first conjugated to S-acetyl-MAG3 with a 6-carbon spacer, namely aminohexanoic acid. METHODS: The technetium-99m labeling required a sodium tartrate buffer. Radiochemical evaluation was performed using ITLC and was confirmed by high-performance liquid chromatography. The coefficient partition was determined, and in vitro studies were performed using human prostate tumor cells. Biodistribution was evaluated in healthy animals at various time points and also in mice bearing tumors. RESULTS: The radiochemical purity of both radiotracers was greater than 95 percent. The DUP-1 tracer was more hydrophilic (log P = -2.41) than the bombesin tracer (log P = -0.39). The biodistribution evaluation confirmed this hydrophilicity by revealing the greater kidney uptake of DUP-1. The bombesin concentration in the pancreas was greater than that of DUP-1 due to specific gastrin-releasing peptide receptors. Bombesin internalization occurred for 78.32 percent of the total binding in tumor cells. The DUP-1 tracer showed very low binding to tumor cells during the in vitro evaluation, although tumor uptake for both tracers was similar. The tumors were primarily blocked by DUP1 and the bombesin radiotracer primarily targeted the pancreas. CONCLUSION: Further studies with the radiolabeled DUP-1 peptide are recommended. With further structural changes, this molecule could become an efficient alternative tracer for prostate tumor diagnosis.

Discovery of inhibitors of human renin with high oral bioavailability.

Knowledge of the sequence of a bioactive protein (angiotensinogen) and the availability of a natural product inhibitor lead (pepstatin) were the starting point for discovery of potent penta- and hexapeptide renin inhibitors. Study of the metabolism and disposition of these substances forced the discovery of simpler inhibitors leading to the discovery of oral activity in Terlakiren (22). Modification of physical properties led to the synthesis of aminopiperidine 30, which was identified by oral efficacy profiling. Structural modification to give enzymatic stability produced the bioavailable benzylsuccinate inhibitor 34. Its bioactive monomethylamine metabolite (35, CP-108,671) was subsequently found to have uniformly high oral bioavailability and activity in various species including primates.

Antiepileptic drugs in development: prospects for the near future.

Among some 14 new antiepileptic drugs (AEDs), those most extensively tested in humans include felbamate (FBM), gabapentin (GBP), lamotrigine (LTG), oxcarbazepine (OCBZ), vigabatrin (VGB), and zonisamide (ZNS). All are currently marketed in some but not all countries. Although no large, comparative studies on efficacy have been conducted, all of these new AEDs are effective in adult localization-related epilepsies, and some have activity in specific syndromes. Although these drugs all have some CNS side effects, especially when administered in combination with other AEDs, they also all have low toxicity profiles. The availability of AEDs with different mechanisms of action may facilitate rational polytherapy. FBM is not teratogenic in animals. Half-life of FBM in humans is 11-28 h. Daily FBM dosages are 15-45 mg/kg in children and 2,400-4,800 mg in adults. Side effects include insomnia and anorexia, with weight loss. FBM increases phenytoin (PHT) and valproate (VPA) concentrations, and FBM concentration may be affected by other drugs. It is available in the United States for treatment of Lennox-Gastaut syndrome and partial seizures in adults. GBP is very water soluble. Half-life of GBP in humans is 5-7 h and daily dosages range from 900 to 2,400 mg in adults. Few side effects have been observed. GBP is not metabolized by the liver and has no drug interactions. It is available in the United Kingdom and the United States. LTG has no teratogenicity in animal models. Half-life of LTG in humans depends on co-medication: with enzyme inducers it is 15-24 h, and with VPA it is approximately 60 h. LTG dosages are 100-600 mg/day in adults. LTG is available in Europe. OCBZ is rapidly metabolized to 10,11-dihydro-10-hydroxy-carbazepine (MHD), the active compound. Animal studies have shown similar efficacy but superior toxicity to carbamazepine (CBZ) in animal models. For MHD, half-life ranges from 10 to 15 h in patients. OCBZ dosages range from 300 to 1,800 mg/day. VGB is a potent, irreversible inhibitor of GABA transaminase which elevates GABA levels in the CNS. Daily dosages of 2,000-4,000 mg of VGB are needed in adults. Although intramyelinic edema has developed in rats and dogs, it has not yet presented in other mammals or humans. ZNS is a sulfonamide effective in animal models of epilepsy. Half-life of ZNS is 27-36 h. ZNS daily dosage is 400-600 mg. ZNS has been effective in some cases of Baltic myoclonic epilepsy.

Comparative pharmacokinetics of the newer antiepileptic drugs.

During the past few years a major increase has taken place in the number of drugs which have become available in the antiepileptic arsenal. In fact, 3 new antiepileptic drugs, vigabatrin, oxcarbazepine and lamotrigine, were recently approved in several European countries. Two other drugs, felbamate and gabapentin, are expected to be approved in the US in the near future. This review comparatively evaluates the pharmacokinetics of the following 10 new antiepileptic drugs: felbamate, flunarizine, gabapentin, lamotrigine, oxcarbazepine, remacemide, stiripentol, tiagabine, topiramate and vigabatrin. Three of the new drugs, gabapentin, topiramate and vigabatrin, are more promising on the basis of their pharmacokinetic features. They are well absorbed, excreted mainly unchanged in the urine, and are not susceptible to enzyme induction or inhibition. Their drug interaction potential appears to be minimal. About 50% of felbamate is excreted unchanged, with the rest eliminated by metabolism. The remaining drugs are eliminated by metabolic processes such as glucuronidation (lamotrigine), deglycine formation (remacemide) or oxidative metabolism (flunarizine and stiripentol). Oxcarbazepine and remacemide have high hepatic clearance and are biotransformed to hydroxy and deglycine metabolites, respectively, with the activity of their metabolites contributing to the antiepileptic activity of the parent drug after oral administration, despite high first-pass effect metabolism. Gabapentin and oxcarbazepine do not behave pharmacokinetically as their original design intended. Gabapentin is not effective as a chemical drug delivery system for gamma-aminobutyric acid (GABA), and oxcarbazepine serves as a prodrug to its hydroxy metabolite, but does not act as a drug on its own. Nevertheless, these 2 agents demonstrate efficacy in extensive preclinical and clinical trials. Although the pharmacokinetics features of these drugs are important, these features are secondary to their pharmacodynamic properties--i.e. to the requirement that new antiepileptic drugs have to have proven clinical efficacy and safety in epileptic patients.

Pharmacokinetics of vigabatrin following single and multiple oral doses in normal volunteers.

The pharmacokinetics of vigabatrin were investigated after single and multiple oral doses in two groups of 24 healthy male volunteers. Vigabatrin was well tolerated by the volunteers; headache was the most frequently reported adverse event. There were no clinically remarkable changes in serum chemistry, urinalysis, or hematology attributable to vigabatrin. For the single-dose study, a stepwise linear contrast method was used to assess dose proportionality. The results showed that vigabatrin exhibited dose linear pharmacokinetics after single oral doses ranging from 0.5 to 4.0 g. Slight changes in the terminal phase half-life and renal clearance were evident in the higher dosage groups. These changes with increasing dose of vigabatrin were relatively minor and not considered to be clinically important. Evaluation of the multiple-dose pharmacokinetics indicated that vigabatrin exhibited dose linearity over the range of 0.5 to 2.0 g administered every 12 hours. The terminal phase half-life and renal clearance of vigabatrin during multiple dosing were consistent with that after single doses. During multiple dosing, steady-state concentrations of vigabatrin were reached on the second day of dosing, and drug accumulation was minimal.

Pharmacokinetics and metabolism of vigabatrin following a single oral dose of [14C]vigabatrin in healthy male volunteers.

14C-labeled vigabatrin (50 microCi), an antiepileptic drug, was administered to six healthy male volunteers as a single oral dose containing 1500 mg of vigabatrin to determine the disposition profile of 14C and parent drug, and to investigate the metabolism of vigabatrin in humans. Vigabatrin was well tolerated by all subjects. There were no clinically important changes in any clinical laboratory parameter. Plasma concentration profiles of both 14C and vigabatrin exhibited biexponential decay. AUC, Cmax, Tmax, and terminal phase t1/2, for 14C were consistently greater than vigabatrin (248.2 vs. 176.0 micrograms-hr/ml; 48.8 vs. 42.8 micrograms/ml; 0.7 vs. 0.6 hr; and 9.5 vs. 7.7 hr, respectively). Mean renal clearance, oral clearance, and volume of distribution for 14C was consistently lower than vigabatrin (1.20 vs. 1.45 ml/min/kg; 1.26 vs. 1.77 ml/min/kg; and 1.01 vs. 1.18 liters/kg, respectively). The mean percentage of recovery of 14C in urine was higher than vigabatrin (95.4 vs. 82.0%). The mean percentage of recovery of 14C in feces was 1.0%. Concentration ratios of 14C showed that vigabatrin distributes into red blood cells at a concentration of 30-80% of that in plasma. The concentration of vigabatrin in saliva was approximately 10% of that in the plasma. The main radioactive component eliminated in the urine was vigabatrin. Two minor urinary metabolites (< 5% of total dose) of vigabatrin were detected using liquid scintillation counting of HPLC eluant fractions. One urinary metabolite was identified by thermospray-LC/MS as the lactam metabolite of vigabatrin.

Vigabatrin.

OBJECTIVE: To introduce the reader to the use of a new agent, vigabatrin, in the treatment of refractory complex partial seizures. Clinical trials and pharmacokinetic data are reviewed, as well as neuropathology, adverse effects, drug interactions, and dosage guidelines. DATA SOURCES: A MEDLINE search through March 1992 was used to identify pertinent English-language literature, including clinical trials, reviews, abstracts, and conference proceedings. Indexing terms included vigabatrin and anticonvulsants. STUDY SELECTIONS: All clinical trials (total of 21) were reviewed, as were all pharmacokinetic studies (total of 8). Selected studies highlighting chemistry, pharmacology, neuropathology, and adverse effects were also reviewed. DATA EXTRACTION: Performed subjectively by the author. Trials were assessed by design, sample size, types of seizures of the subjects, and clinical response. DATA SYNTHESIS: Vigabatrin represents the first of a new class of antiepileptic drugs (AEDs)--the gamma-aminobutyric acid transaminase (GABA-T) inhibitors. Vigabatrin works by selective, irreversible inhibition of GABA-T, thus preventing the breakdown of GABA. It has been shown to produce dose-dependent increases in cerebrospinal fluid GABA concentrations, and decreases in GABA-T activity. Vigabatrin may also cause a decrease in excitation-related amino acids. It is well absorbed, is not protein bound, and is eliminated by glomerular filtration. However, even with a short half-life (5-7 h), vigabatrin may be given once or twice daily because of its mechanism of action. Few drug interactions have been reported with this agent, although decreases in phenytoin concentration may reach clinical significance. Concern over neuropathologic findings (microvacuolization of white matter) in animals caused trials of vigabatrin to be halted in 1983, but trials have now resumed as there is no evidence of toxicity in humans. Clinical efficacy of vigabatrin has been evaluated in controlled trials and appears to be most effective in complex partial seizures, producing a 50 percent or greater reduction in seizure frequency in approximately 50 percent of the adult patients studied. Efficacy in children with partial seizures also appears promising, and one uncontrolled study suggests that further study of vigabatrin in infantile spasms may be warranted. CONCLUSIONS: Vigabatrin appears to be effective in treating refractory complex partial seizures in adults and refractory partial seizures in children. Its relatively benign adverse-effect profile and few known drug interactions may given this agent an advantage over existing anticonvulsants. However, definitive conclusions about the role of vigabatrin in epilepsy treatment should await the completion of ongoing Phase II and Phase III trials.

Vigabatrin. Clinical pharmacokinetics.

Vigabatrin is a structural analogue of the inhibitory neurotransmitter gamma-aminobutyric acid (GABA). It is supplied as a racemic mixture, with the S(+) enantiomer possessing pharmacological activity. [R,S]-Vigabatrin plasma concentrations can be estimated using high-performance liquid chromatographic methods. Only gas chromatography-mass spectrometry methods allow quantification of the S(+) and R(-) enantiomers. Vigabatrin was rapidly absorbed reaching peak concentrations within 1 to 2h. Area under plasma concentration-time curves indicated dose-linear pharmacokinetics. There was no effect of food on the absorption of vigabatrin. The absorption characteristics of the enantiomers were similar to those of the [R,S]-vigabatrin. No chiral inversion was detected after administration of the pure S(+) enantiomer. Vigabatrin is not protein bound. The apparent volume of distribution of [R,S]-vigabatrin was approximately 0.8 L/kg. Despite the lack of protein binding, cerebrospinal concentrations of the [R,S]-vigabatrin were only 10% of the plasma concentration 6h after a single oral dose. The half-life of [R,S]-vigabatrin was between 5.3 and 7.4h, the half-life of the enantiomers were 7.5 and 8.1h for the S(+) and the R(-) forms, respectively. The major route of elimination was renal excretion; urinary recovery of the [R,S]-vigabatrin was close to 70%. Pharmacokinetic studies in epileptic children did not show any significant effect of maturation on the disposition of the S(+) enantiomer: the half-life and the renal clearance were similar to adult values. Data suggest a lower bioavailability in children. In adults with epilepsy, the half-life of the [R,S]-vigabatrin ranged from 4.2 and 5.6h, similar to that measured in healthy adults. In elderly nonepileptic volunteers the pharmacokinetics of the enantiomers of vigabatrin showed delayed absorption, a major increase in peak concentration and a prolonged half-life. These changes were attributed to decreased renal clearance of vigabatrin. A nonlinear relationship between renal clearance and creatinine clearance was suggested. Vigabatrin caused a 20% fall in plasma phenytoin concentrations, the mechanism of which has not been elucidated. There were no other interactions with most concurrently administered anticonvulsants. The usual dosage of vigabatrin as add-on treatment in adults is 2 to 4g daily. Higher dosages up to 80 mg/kg daily were required in children. A dosage adjustment was recommended in any patient with decreased renal clearance. Although anticonvulsant effects were clearly related to dosage, monitoring of plasma concentrations of vigabatrin as a guide to dosage is unlikely to be of as much value as with other antiepileptic drugs. The action of the drug long outlasts its presence in plasma.

Passage of S(+) and R(-) gamma-vinyl-GABA across the human isolated perfused placenta.

1. The maternal to foetal transfers of S(+)- and R(-)-gamma-vinyl-GABA (VGB) across the human isolated perfused placenta were low and comparable with those of acidic alpha-amino acids. 2. The placental uptake of the active S(+)-isomer from the maternal circulation exceeded that of the R(-)-isomer and this was reflected by a corresponding difference in placental tissue concentrations. 3. During perfusion with recirculation of the foetal medium, the two enantiomers were present at a similar concentration and did not concentrate in foetal perfusate, indicating that the excess amount of S(+)-VGB cleared from the maternal circulation was not accessible to the foetal perfusate. Furthermore, stable concentrations of both isomers in the foetal perfusate suggested a lack of placental metabolism. 4. Possible explanations of these findings include the operation of a stereoselective sodium-dependent-GABA placental uptake system on the maternal side, similar to that observed in neuronal tissue, or stereoselective binding to a placental GABA transaminase.

Antiepileptic medications in development.

Recently, there has been an increase in the research devoted to the study of investigational antiepileptic medications. This has led to extensive clinical trials of several new compounds. This review focuses on four of these antiepileptic medications in development: felbamate, gabapentin, lamotrigine, and vigabatrin. Each has a unique mechanism of action and great potential for the treatment of epilepsy.

Relationship between platelet and brain GABA transaminase inhibition by single and multiple doses of vigabatrin in rats.

Vigabatrin (gamma-vinyl-GABA, GVG) is an inhibitor of brain GABA transaminase (GABA-T) that also inhibits platelet GABA-T in rats and humans. We have compared the effects of single and multiple doses of GVG on both enzymes in 19 groups of 10 adult male Wistar rats, treated with increasing GVG doses (0-1,600 mg/kg/day) for 1, 8, and 28 days. The platelet GABA-T was more sensitive to the inhibitory effects of GVG than the brain enzyme was especially with low dosages of GVG. After 8 days of treatment, higher GVG plasma levels and a higher inhibition of both enzymes were shown. However, after 28 days, lower GVG plasma levels and similar inhibition of both enzymes compared to the eighth day were found. Correlations between platelet and brain GABA-T for individual rats were statistically significant after 1 day (r = 0.40, p less than 0.01) but not after 8 and 28 days of treatment because of the total inhibition of platelet GABA-T and only partial inhibition of brain GABA-T. We concluded the following: (a) platelet GABA-T is more inhibited than brain GABA-T when low doses of GVG are used and (b) multiple doses reach a higher inhibition of both enzymes than single doses, which could be explained by an increase in GVG concentrations.

Vigabatrin. A review of its pharmacodynamic and pharmacokinetic properties, and therapeutic potential in epilepsy and disorders of motor control.

Vigabatrin was specifically designed to enhance gamma-aminobutyric acid (GABA) function in the CNS. By increasing brain concentrations of this inhibitory neurotransmitter the drug appears to decrease propagation of abnormal hypersynchronous discharges, thereby reducing seizure activity. At this stage in its development, clinical experience with vigabatrin is limited primarily to patients with refractory seizure disorders. In this difficult-to-treat population, 'add-on' therapy with vigabatrin greater than or equal to 2 g/day has shown impressive efficacy, reducing seizure frequency by greater than or equal to 50% in approximately half of patients. Clinical efficacy does seem to vary with seizure type with the best response reported in adults with complex partial seizures with or without generalisation and in children with cryptogenic partial epilepsy or symptomatic infantile spasm. Vigabatrin appears to have a negative effect on absences and myoclonic seizures. Some disorders of motor control may also be amenable to enhanced GABAergic function. In the small number of patients with tardive dyskinesia treated to date, vigabatrin produced mild to moderate improvement in hyperkinetic symptom scores but Parkinsonism or schizophrenic symptoms occasionally worsened. The best response was reported in a study of patients who had been withdrawn from neuroleptic therapy. In a small but well-controlled comparative trial, vigabatrin was as effective as baclofen in reducing spasm and improving some parameters of spasticity in patients with spinal cord lesions or multiple sclerosis. Most adverse reactions to vigabatrin are mild and transient with central nervous system (CNS) changes being reported most frequently. Of particular note, serial evoked potential studies and the few available histology reports have not found evidence of intramyelinic oedema during therapeutic use, as was reported in rats and dogs on chronic high-dose treatment. Thus, vigabatrin is a promising new anticonvulsant drug. Current evidence supports a trial of this agent as adjunctive therapy in patients with refractory seizure disorders, and future investigation of vigabatrin monotherapy and its efficacy relative to established agents is awaited with interest. Wider experience should help to clarify which patients - by seizure type and concurrent CNS pathology - are likely to benefit from vigabatrin and ongoing monitoring should further clarify the potential detrimental effects, if any, of long term use. In the meantime, it is a welcome addition in the difficult setting of resistant epilepsy.

Effect of long-term vigabatrin therapy on selected neurotransmitter concentrations in cerebrospinal fluid.

Ten patients, suffering from drug-resistant complex partial seizures were treated for a period of up to 3 years with vigabatrin (Sabril). Vigabatrin is a novel antiepileptic agent, whose action is based on the inhibition of gamma-aminobutyric acid (GABA) aminotransferase, the enzyme responsible for the catabolism of the neurotransmitter GABA. Samples of lumbar cerebrospinal fluid were obtained from the patients prior to commencing vigabatrin therapy, and thereafter at 6 months, 1 year, 2 years, and up to 3 years following the initiation of vigabatrin treatment. The influence of vigabatrin on the cerebrospinal fluid concentrations of free and total GABA, homocarnosine, homovanillic acid, 5-hydroxyindoleacetic acid, and 3-methoxy-4-hydroxyphenylethylene glycol, as well as of the drug itself, was assessed. All patients demonstrated a clinical response to vigabatrin, and the drug was well tolerated over the entire observation period. Mean (+/- SD) reduction of seizure frequency was 65% +/- 23% (range, 26% to 100%) when comparing the end of the treatment period to the previgabatrin baseline. The cerebrospinal fluid concentrations of both free and total GABA and of the dipeptide homocarnosine showed approximately 2- to 5-fold increases over baseline values, with free GABA and homocarnosine being the more sensitive variables. Cerebrospinal fluid concentrations of homovanillic acid, 5-hydroxyindoleacetic acid, and 3-methoxy-4-hydroxyphenylethylene glycol were not altered in a significant manner over the observation period. These findings support the concept that the effects of vigabatrin are restricted to an effect on GABA catabolism and do not extend to the neurotransmitters dopamine and norepinephrine. Clinical efficacy and elevation of GABA and homocarnosine concentration were sustained over the period of observation.

Pharmacology and clinical pharmacology of vigabatrin.

Vigabatrin is an enzyme-activated, irreversible inhibitor of gamma-aminobutyric acid (GABA) aminotransferase, which causes a marked increase in cerebral GABA concentration and a resulting anticonvulsant action. Recovery from its effects requires the synthesis of new enzyme, and this may take several days following a single dose. The pharmacokinetics of vigabatrin are not a good guide to its duration of action. It is cleared rapidly by renal elimination (giving a plasma half-life of approximately 7 to 9 hours), and therefore the effect of the drug long outlasts its presence in the body. Plasma drug level monitoring is therefore of little value in regulating vigabatrin therapy. The drug is not bound to plasma proteins. Interactions with other drugs would not be expected because of its predominant renal elimination and its lack of protein binding. Also, vigabatrin does not induce liver enzymes, as do many of the standard antiepileptic drugs. In several trials, however, a small but significant reduction in phenytoin levels has been seen following the addition of vigabatrin to the antiepileptic medication. The mechanism for this reduction in phenytoin levels has not yet been elucidated, though it does not appear to be of clinical significance.

Pharmacokinetics of the individual enantiomers of vigabatrin (gamma-vinyl GABA) in epileptic children.

1. The pharmacokinetics of the enantiomers of vigabatrin were investigated after oral administration of a single 50 mg kg-1 dose of the racemate to two groups of six epileptic children (I: 5 months-2 years, II: 4-14 years). 2. The mean (+/- s.d.) values of maximum plasma concentration and area under the plasma concentration-time curve of the R(-) enantiomer were significantly higher than those of S(+) vigabatrin in both groups: R(-) Cmax: 21 +/- 6.6 (I)-41.3 +/- 13.9 (II) vs S(+) Cmax: 13.9 +/- 4.5 (I)-23.8 +/- 12.2 (II) mg l-1; R(-) AUC: 106 +/- 28.5 (I)-147 +/- 34 (II) vs S(+) AUC: 90.9 +/- 27.9 (I)-117 +/- 26 (II) mg l-1 h. In group I, the half-life of the R(-) isomer was significantly shorter than that of the S(+) isomer; in group II, the half-lives were comparable. 3. For the R(-) enantiomer the area under the curve, and the elimination half-life increased linearly with age. 4. During chronic administration (50 mg kg-1 vigabatrin racemate twice a day for 4 days), the morning trough plasma drug concentrations did not increase.