UMLS:C0036572 - FACTA Search

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Query: UMLS:C0036572 (seizures)
80,221 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Tiagabine (TGB) hydrochloride is a novel antiepileptic drug (AED) that is a potent and specific inhibitor of gamma-aminobutyric acid (GABA) uptake into glial and neuronal elements. In accordance with medical and regulatory standards, the clinical development program for TGB as an AED has assessed the value of TGB in add-on treatment, focusing mainly on partial seizures, including secondarily generalized seizures. Five add-on, placebo-controlled trials and six noncomparative, open-label, long-term multicenter trials have been or are being conducted in Australia, Europe, and the U.S.A. The results of these trials, involving 2,261 patients, indicate that TGB has efficacy as add-on therapy in patients with epilepsy difficult to control with existing AEDs. Efficacy of TGB is also sustained with long-term treatment. A clear dose-response has been demonstrated, and the minimal effective dose level is 30 mg. TGB is also tolerated, and with long-term therapy no new or more severe types of adverse events develop. These studies have included a wide age range of patients, including adolescents and the elderly.
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PMID:International experience with tiagabine add-on therapy. 859 88

Tiagabine (TGB) hydrochloride, a nipecotic acid derivative linked to a lipophilic anchor, potently and specifically inhibits uptake of the inhibitory neurotransmitter gamma-aminobutyric acid (GABA) into astrocytes and neurons. With microdialysis, TGB has been shown to increase extracellular overflow of GABA in the midbrain of awake rats. TGB administration prolongs neuronal depolarization induced by iontophoretically applied GABA in hippocampal slices. TGB is effective in a wide range of seizure models, including pentylenetetrazol-induced, methyl-6,7-dimethoxy-4-ethyl-beta-carboline-3-carboxylate (DMCM)-induced tonic, amygdala-kindled and picrotoxin-induced convulsions, and maximal electroshock seizures in rodents. In humans, TGB absorption is rapid and complete. It is metabolized in the liver, largely by isoform 3A of the cytochrome P450 family of enzymes. The process of elimination is linear, with a half-life of 5-8 h. TGB does not induce or inhibit metabolic processes, although it provides a target for enzyme inducers that can lower its elimination half-life to 2-3 h. Accordingly, TGB does not alter the concentrations of other antiepileptic drugs (AEDs), with the possible exception of a small decrease in valproate levels. A controlled-release formulation of TGB would offset any potential clinical disadvantage of the short elimination half-life, particularly in patients receiving concurrent treatment with enzyme-induced AEDs.
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PMID:Tiagabine pharmacology in profile. 859 91

Tiagabine (TGB) and vigabatrin (VGB) are two novel anticonvulsant compounds reported to exert their pharmacological effects via an action on the gamma-aminobutyric acid (GABA) system. We have investigated the effects of acute exposure of these drugs on the uptake of GABA into rat cortical astrocytes in primary culture. Astrocytes were prepared from the cerebral cortices of one day-old rat pups by a mechanical dissociation technique and were assayed for GABA uptake activity after 21 days in culture. Tiagabine (100-300 nM) and VGB (100 microM) reduced GABA uptake when compared to control at four hours post-exposure. GABA uptake was also reduced following eight and 24 hour exposures to 200 nM TGB. A combination of TGB (200 nM) and VGB (100 microM) treatments reduced GABA uptake when compared to both control and VGB treated cultures. These results support the efficacy of TGB as a GABA uptake inhibitor and suggest that VGB may also exert an effect by this mechanism.
Seizure 1996 Sep
PMID:Effects of tiagabine and vigabatrin on GABA uptake into primary cultures of rat cortical astrocytes. 890 26

A new anti-epileptic drug, tiagabine, is a potent inhibitor of GABA uptake into neurons and glia. Tiagabine has shown promising efficacy and safety profiles as add-on treatment for partial seizures. We evaluated the long-term effects of tiagabine on cognition and EEG in 37 patients with partial epilepsy. The study protocol consisted of a randomized, double-blind, placebo-controlled, parallel-group add-on study and an open-label extension study. During the 3 month double-blind phase at low doses (30 mg/day) tiagabine treatment did not cause any cognitive or EEG changes as compared with placebo. Tiagabine treatment did not cause deterioration in cognitive performance or produce any rhythmic slow-wave activity or other constant, new abnormalities on EEG during longer follow-up with successful treatment on higher doses after 6-12 months (mean 65.7 mg/day, range 30-80 mg/day) and after 18-24 months (mean dose 67.6 mg/day, range 24-80 mg/day). The daily dosages in the long-term follow-up of the present study are higher than in the previous reports.
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PMID:Long-term cognitive and EEG effects of tiagabine in drug-resistant partial epilepsy. 895 29

Tiagabine is a novel antiepileptic drug that was designed to block gamma-aminobutyric acid uptake by presynaptic neurons and glial cells. It has been shown to be effective against partial seizures in adults and adolescents. Preliminary pediatric data are also encouraging. This article reviews the available animal and human data on the pharmacokinetics, efficacy, and safety of tiagabine.
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PMID:Tiagabine. 909 64

Tiagabine blocks the uptake by neurons or glia of synaptically released GABA resulting in prolonged GABAergic activity and decreased likelihood of epileptic seizures. We evaluated the cognitive and quality of life effects of tiagabine in a double-blind, add-on, placebo-controlled, parallel, multicenter, dose-response efficacy study in patients with focal epilepsy whose complex partial seizures were difficult to control. One hundred sixty-two patients provided cognitive and quality of life data for the analyses and received the following treatments: placebo (n = 57), 16 mg/d tiagabine (n = 34), 32 mg/d tiagabine (n = 45), or 56 mg/d tiagabine (n = 26) at a fixed-dose for 12 weeks after a 4-week dose titration period. Eight cognitive tests and three measures of mood and adjustment were administered during the baseline period and again during the double-blind period near the end of treatment (or at the time of dropout). The patient groups were similar at entry into the study. Results showed no clinically important changes with the addition of tiagabine on the test battery. Although this is an encouraging finding, it remains for future investigations to determine the cognitive and behavioral effects of tiagabine either as monotherapy or in relation to other antiepileptic drugs.
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PMID:Cognitive and quality of life effects of differing dosages of tiagabine in epilepsy. 910 94

Some patients with acute hereditary porphyrias have seizures and require anticonvulsant therapy, but many anticonvulsants induce exacerbations of the hepatic porphyrias. Recently, several new anticonvulsants have become available. Among these are gabapentin, vigabatrin, felbamate, lamotrigine, and tiagabine. Little is known about their potential for induction of porphyric attacks. We used a cell culture model of primary chicken embryo liver cells, which maintain intact heme synthesis and regulation, to study the effects of these new anticonvulsants on porphyrin accumulation. Treatment of the cells with deferoxamine (250 microM) led to a partial block in heme synthesis, simulating the conditions encountered in human beings with porphyria. Concomitant exposure of these cells to phenobarbital (2 mM) strongly induced accumulation of porphyrins, serving as a positive control in this model. Cells were treated for 20 hours with increasing doses (3.2 to 1,000 microM) of the newer anticonvulsants, with or without deferoxamine. For most of these anticonvulsants 5 to 100 microM is representative of the concentrations achieved in humans with therapeutic doses. Porphyrins were measured spectrofluorometrically as uro-, copro-, and protoporphyrins. Results were confirmed by high-pressure liquid chromatography. Neither vigabatrin nor gabapentin treatment, with or without deferoxamine, led to any increase in porphyrin accumulation. Similar doses of felbamate (with deferoxamine) led to a marked increase in (mainly proto-) porphyrin levels, qualitatively and quantitatively almost identical to the accumulation produced by phenobarbital. Lamotrigine or tiagabine (with deferoxamine) caused similar porphyrin accumulation. Tiagabine treatment up to 100 microM (with deferoxamine) also resulted in very high levels of predominantly proto-porphyrin. In contrast to the other anticonvulsants tested, tiagabine without deferoxamine led to mild porphyrin accumulation. In the presence of deferoxamine, phenobarbital, felbamate, lamotrigine, or tiagabine, but not gabapentin or vigabatrin, increased levels of the mRNA of ALA synthase, the first and rate-controlling enzyme of porphyrin synthesis. Such enzyme induction is a sine qua non for acute porphyric attacks. We conclude that neither vigabatrin nor gabapentin is porphyrogenic, whereas felbamate, lamotrigine, and, especially, tiagabine lead to much accumulation of porphyrins. The latter three anticonvulsants, therefore, may precipitate or exacerbate acute porphyric attacks in humans. We recommend use of vigabatrin or gabapentin, but not felbamate, lamotrigine, or tiagabine, in patients with acute porphyria and seizures.
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PMID:Effects of new anticonvulsant medications on porphyrin synthesis in cultured liver cells: potential implications for patients with acute porphyria. 922 76

Tiagabine (TGB) is a novel antiepileptic drug whose anticonvulsant effects are due to inhibition of gamma-aminobutyric acid (GABA) transport mediated by the GABA transporter-1. We have previously shown that TGB is effective in acute amygdala kindled seizures, and consequently we wanted to test the hypothesis that TGB also could suppress the development of kindling epileptogenesis. Rats had stereotaxically implanted stimulating/recording electrodes in the basolateral amygdala and recording electrode in the contralateral occipital cortex. Rats were divided in three groups (n = 8 for each group) intraperitoneally (i.p.) administered vehicle, TGB 7.3 micromol/kg and TGB 24.3 micromol/kg, respectively, 30 min before stimulation. TGB dose-dependently suppressed the development of the behavioral seizure score and afterdischarge (AD) duration recorded from the amygdala and cortex. Vehicle treated animals displayed at the 16th stimulation an average behavioral score of 4.7 +/- 0.2 (mean +/- SEM) compared to 3.9 +/- 0.2 in the 7.3 micromol/kg TGB treated group and 1.4 +/- 0.3 in the 24.3 micromol/kg TGB treated group. Amygdaloid AD in controls on the 16th stimulation was 92 +/- 10 s compared to 56 +/- 12 s in group 2 and 25 +/- 3 s in group 3. Cortical AD was at the same time 92 +/- 10, 55 +/- 13 and 20 +/- 5 s, respectively. Groups 2 and 3 required four and seven further stimulations, respectively, without TGB administration to reach the AD level in the control group. At the 17th stimulation, rats in group 1 were administered TGB 24.3 micromol/kg and displayed an average behavioral score of 0.5 +/- 0.2. Amygdaloid and cortical AD were both 6 +/- 1 s. Tiagabine 24.3 micromol/kg suppresses both the kindling process and the expression of the fully kindled seizure.
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PMID:Tiagabine exerts an anti-epileptogenic effect in amygdala kindling epileptogenesis in the rat. 922 9

Tiagabine is a novel antiepileptic drug which has clinical efficacy against complex refractory and myoclonic seizures. The anticonvulsant mechanism of action of tiagabine results from its blockade of neuronal and glial GABA-uptake, thereby increasing GABA levels in the synaptic cleft. Here we present a comparison of the preclinical anticonvulsant profile of tiagabine with that of lamotrigine, gabapentin and vigabatrin in the following tests (all antiepileptic drugs were administered i.p.): seizures induced by pentylentetrazol (PTZ), 6,7-dimethoxy-4-ethyl-b-carboline-3-carboxylate (DMCM) and maximal electroshock (MES); sound induced seizures in DBA/2 mice and finally acute amygdala kindled seizures. Tiagabine was the most potent drug in antagonizing tonic convulsions induced by PTZ, DMCM and sound induced seizures in DBA/2 mice with ED50 values of 2, 2 and 1 mumol/kg, respectively, followed by lamotrigine with ED50 values of 9, 43 and 6 mumol/kg, respectively. Gabapentin and vigabatrin had ED50 values in the same tests of 185, 452, 66 mumol/kg and 2322, > 7740, 3883 mumol/kg, respectively. Tiagabine was the only drug capable of blocking PTZ-induced clonic convulsions (ED50 = 5 mumol/kg), an effect seen at low but not high doses of tiagabine. Lamotrigine was the only drug which antagonized tonic convulsions in the MES test (ED50 = 36 mumol/kg). Therapeutic index (TI) of antiepileptic drugs in NMRI- and DBA/2-mice ranked with decreasing TI lamotrigine > gabapentin > vigabatrin > tiagabine. All drugs reduced the generalized seizures in amygdala kindled rats, but tiagabine and gabapentin furthermore attenuated afterdischarge duration of amygdala kindled seizures. However, an ED50 value against amygdala kindled focal seizures was only obtained for tiagabine (36 mumol/kg). The data here presented show that tiagabine, lamotrigine, gabapentin and vigabatrin possess different preclinical anticonvulsant profiles which is of relevance to the clinical anticonvulsant profiles of the drugs.
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PMID:Comparison of the preclinical anticonvulsant profiles of tiagabine, lamotrigine, gabapentin and vigabatrin. 925

In the last few years a number of new anticonvulsants have been introduced into clinical practice mainly as add-on therapy in patients who do not become seizure-free while receiving established anticonvulsants. Up to now, no single drug has been shown to be more effective at controlling seizures of a particular type than another, so other factors such as mechanism of action, pharmacokinetics, dosage regimens or the spectrum of adverse drug reactions and interactions are used when making a choice between one agent and another. The mechanism of action of tiagabine and vigabatrin is very specific; both agents increase gamma-aminobutyric acid (GABA) levels through inhibition of reuptake and catabolism respectively. However, the mechanism of action of gabapentin is unknown and those of felbamate, lamotrigine and topiramate are not sufficiently clarified as yet, and may be multiple. Great advances have been made in improving the pharmacokinetic characteristics of these newer anticonvulsants. Gabapentin and vigabatrin exhibit relatively ideal pharmacokinetic properties as they are not bound to proteins, are excreted mostly unchanged in the urine and show linear pharmacokinetics. Lamotrigine possesses a highly variable elimination half-life depending on the co-medication. Tiagabine is highly protein bound and zonisamide shows nonlinear pharmacokinetics; both these drugs are extensively metabolised. Problematic drug interactions between newer anticonvulsants and other drugs in general occur rarely when these agents are given concomitantly. However, in common with most new drugs, there are very few data on the use of the newer anticonvulsants in women of childbearing age. Studies done so far on interactions with oral contraceptives used low anticonvulsant dosages for a very short time. The newer anticonvulsants elicit adverse reactions that, while not being unique, are particularly associated with that drug. For example, felbamate may cause aplastic anaemia and fulminant liver failure, lamotrigine is prone to cause skin rash, and oxcarbazepine may cause symptomatic hyponatraemia. Topiramate and zonisamide cause kidney stones, and vigabatrin may induce psychiatric syndromes. Although highly diverse in structure and activity, these newer drugs offer new possibilities for treating refractory epilepsy. However, since no single factor can dictate the choice of drug nor predict the success of treatment, prescribing of these rather expensive drugs has to depend upon careful consideration of the aims of treatment, the characteristics of the drug and the needs of the individual patient.
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PMID:Newer anticonvulsant drugs: role of pharmacology, drug interactions and adverse reactions in drug choice. 935 59

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