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

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

Neurontin (Gabapentin) is indicated as an add-on treatment of partial epileptic seizures. Clinical studies demonstrating the efficacy of Neurontin as monotherapy are currently on going. This article describes the design of 2 clinical trials of Gabapentin as monotherapy for epileptic seizures.
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PMID:[Trials with gabapentin monotherapy in patients with complex partial or secondary generalized seizures]. 938 Oct 42

Between 30% and 60% of patients with epilepsy have not achieved adequate control with current medications, and side effects are a significant problem. In the past 2 years, three drugs for epilepsy have been approved. At least six more drugs are in the final stages of development, and there is an active "pipeline." None of the new drugs are panceas, but many have special advantages and meet important specific needs. Felbamate, despite a high incidence of aplastic anemia and hepatic failure, remains useful because of its lack of sedative effects and high efficacy. Gabapentin is remarkable for its favorable side effect profile, lack of interactions, and straightforward kinetics. Lamotrigine is also nonsedating and may be especially useful in generalized epilepsies. Topiramate and vigabatrin are both highly effective, although each is associated with a variety of cognitive or psychiatric side effects that may limit utility. Oxcarbazepine shares the efficacy of carbamazepine, with fewer side effects or drug interactions. Zonisamide seems to be effective and cause mild side effects, although the risk for renal stones indicates a need for cautious use. Tiagabine, like gabapentin, is a mild drug with a favorable side effect profile. New forms of old drugs will make for easier administration; fosphenytoin will increase the safety of parenchymal phenytoin use. The best of the new drugs help, at most, 10% of previously uncontrolled patients to become seizure-free. The development of new drugs remains an important need.
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PMID:New drugs for persons with epilepsy. 940 64

Within the last years five new antiepileptics have become available in Germany. Vigabatrin is a second choice drug against partial seizures, West syndrome and epilepsies in infant encephalopathy syndromes. Lamotrigine and Gabapentin can be used as add-on therapy in partial seizures in children above 12 years of age Felbamate has a high incidence of severe side-effects like aplastic anemia and liver failure. Therefore it should be restricted to the treatment of Lennox-Gastaut syndrome. Oxcarbazepine is not yet on the German market, but is available by import from Austria. Its therapeutic range is similar to carbamazepine with less side-effects. The new antiepileptics discussed have turned out to be useful additional therapeutics, especially in focal epilepsies. There is, however, still limited experience with these drugs in children. So none can as yet be considered a drug of first choice in any epileptic childhood disorder. The classical antiepileptic drugs remain essential in antiepileptic therapy.
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PMID:[Value of the new anticonvulsants in pediatrics]. 952 99

Gabapentin has been accepted worldwide as a novel antiepileptic drug with a favourable tolerability profile. However, movement disorders have been reported previously as rare side-effects in individual patients. We report on two patients who developed isolated severe ataxia under low-dose gabapentin which resolved abruptly after discontinuation of the drug. This side-effect probably resembled a rare idiosyncratic adverse reaction. We propose the gabapentin-specific neuronal binding site which has a high density in the cerebellum as a possible mechanism of action and suggest that the initiation of gabapentin requires caution if pre-existing cerebellar function impairment is evident.
Seizure 1997 Dec
PMID:Isolated ataxia as an idiosyncratic side-effect under gabapentin. 953 Sep 50

Gabapentin is a new antiepileptic drug. Its mechanism of action is not clearly understood, but it seems to differ from that of other antiepileptic drugs. The favourable pharmacokinetic properties of gabapentin make it simple to use. Our preliminary clinical observations with gabapentin at the National Center for Epilepsy are presented. 58 adult patients (mean age 28.9 years), mainly with refractory partial seizures, had gabapentin added to their existing medication. The follow-up period was 6.9 months on average. Only one patient experienced a reduction in seizures of more than 50%, while 25 patients experienced a moderate reduction in seizures (10-50%). The clinical effect was most favourable in patients with secondary generalized tonic-clonic seizures. Gabapentin was well tolerated, and no clinically significant interactions were encountered. Recent observations show that the doses of gabapentin used in our study may have been too low.
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PMID:[Gabapentin--a new antiepileptic agent]. 954 99

Although the cellular mechanisms of pharmacological actions of gabapentin (Neurontin) remain incompletely described, several hypotheses have been proposed. It is possible that different mechanisms account for anticonvulsant, antinociceptive, anxiolytic and neuroprotective activity in animal models. Gabapentin is an amino acid, with a mechanism that differs from those of other anticonvulsant drugs such as phenytoin, carbamazepine or valproate. Radiotracer studies with [14C]gabapentin suggest that gabapentin is rapidly accessible to brain cell cytosol. Several hypotheses of cellular mechanisms have been proposed to explain the pharmacology of gabapentin: 1. Gabapentin crosses several membrane barriers in the body via a specific amino acid transporter (system L) and competes with leucine, isoleucine, valine and phenylalanine for transport. 2. Gabapentin increases the concentration and probably the rate of synthesis of GABA in brain, which may enhance non-vesicular GABA release during seizures. 3. Gabapentin binds with high affinity to a novel binding site in brain tissues that is associated with an auxiliary subunit of voltage-sensitive Ca2+ channels. Recent electrophysiology results suggest that gabapentin may modulate certain types of Ca2+ current. 4. Gabapentin reduces the release of several monoamine neurotransmitters. 5. Electrophysiology suggests that gabapentin inhibits voltage-activated Na+ channels, but other results contradict these findings. 6. Gabapentin increases serotonin concentrations in human whole blood, which may be relevant to neurobehavioral actions. 7. Gabapentin prevents neuronal death in several models including those designed to mimic amyotrophic lateral sclerosis (ALS). This may occur by inhibition of glutamate synthesis by branched-chain amino acid aminotransferase (BCAA-t).
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PMID:A summary of mechanistic hypotheses of gabapentin pharmacology. 955 85

Gabapentin (1-50 mg/kg, intraperitoneally (i.p.)) was able to antagonize audiogenic seizures in Dilute Brown Agouti DBA2J (DBA/2) mice in a dose-dependent manner. Gabapentin at dose of 2.5 mg/kg i.p., which per se did not significantly affect the occurrence of audiogenic seizures in DBA/2 mice, potentiated the anticonvulsant activity of carbamazepine, diazepam, felbamate, lamotrigine, phenytoin, phenobarbital and valproate against sound-induced seizures in DBA/2 mice. The potentiation induced by gabapentin was greatest for diazepam, phenobarbital and valproate, less for felbamate and phenytoin and least for carbamazepine and lamotrigine. The increase in anticonvulsant activity was associated with a comparable increase in motor impairment. However, the therapeutic index of combined treatment of the above drugs + gabapentin was more favourable than that of the same drugs + saline. Since gabapentin did not significantly influence the total and free plasma levels of the anticonvulsant drugs studied, we suggest that pharmacokinetic interactions, in terms of total or free plasma levels, are not probable. However, the possibility that gabapentin can modify the clearance from the brain of the anticonvulsant drugs studied can not be excluded. In addition, gabapentin did not significantly affect the hypothermic effects of the anticonvulsants tested. In conclusion, gabapentin showed an additive effect when administered in combination with certain classical anticonvulsants, most notably diazepam, phenobarbital, felbamate, phenytoin and valproate.
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PMID:Gabapentin potentiates the antiseizure activity of certain anticonvulsants in DBA/2 mice. 967 Oct 96

The chemical structure of gabapentin (Neurontin) is derived by addition of a cyclohexyl group to the backbone of gamma-aminobutyric acid (GABA). Gabapentin prevents seizures in a wide variety of models in animals, including generalized tonic-clonic and partial seizures. Gabapentin has no activity at GABAA or GABAB receptors of GABA uptake carriers of brain. Gabapentin interacts with a high-affinity binding site in brain membranes, which has recently been identified as an auxiliary subunit of voltage-sensitive Ca2+ channels. However, the functional correlate of gabapentin binding is unclear and remains under study. Gabapentin crosses several lipid membrane barriers via system L amino acid transporters. In vitro, gabapentin modulates the action of the GABA synthetic enzyme, glutamic acid decarboxylase (GAD) and the glutamate synthesizing enzyme, branched-chain amino acid transaminase. Results with human and rat brain NMR spectroscopy indicate that gabapentin increases GABA synthesis. Gabapentin increases non-synaptic GABA responses from neuronal tissues in vitro. In vitro, gabapentin reduces the release of several mono-amine neurotransmitters. Gabapentin prevents pain responses in several animal models of hyperalgesia and prevents neuronal death in vitro and in vivo with models of the neurodegenerative disease amyotrophic lateral sclerosis (ALS). Gabapentin is also active in models that detect anxiolytic activity. Although gabapentin may have several different pharmacological actions, it appears that modulation of GABA synthesis and glutamate synthesis may be important.
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PMID:Mechanisms of action of gabapentin. 968 47

Gabapentin is an antiepileptic drug used in the treatment of partial and generalized tonic-clonic seizures. Its antiepileptic mechanism of action is not known. The transport of gabapentin across membranes and its demonstrated effects on voltage-gated ion channels (sodium, calcium), presynaptic mechanisms that can enhance GABAergic inhibition, and ligand-gated ion channels (GABA receptors and glutamate receptors) are reviewed.
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PMID:Gabapentin. Antiepileptic mechanism of action. 977 1

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