Seletracetam


Seletracetam is a pyrrolidone-derived drug of the racetam family that is structurally related to levetiracetam. It was under development by UCB Pharmaceuticals as a more potent and effective anticonvulsant drug to replace levetiracetam but its development has been halted.
There are two main mechanisms of action for seletracetam. The first is its high-affinity stereospecific binding to synaptic vesicle glycoprotein 2A. Seletracetam has shown potent seizure suppression in models of acquired and genetic epilepsy, and has been well tolerated by various animal models. The second is its binding to N-type calcium channels and preventing influx of Ca2+ during high-voltage activation that is typical of epilepsy.
While similar in structure to nootropic drugs, it is not expected to have cognitive enhancing properties. Seletracetam was in Phase II clinical trials under the supervision of the U.S. Food and Drug Administration but its production is on hold.

Synthesis

Seletracetam's molecular structure contains elements common to other anticonvulsants, including levetiracetam and brivaracetam, such as a nitrogen heterocyclic system. Like brivaracetam, seletracetam is a derivative of levetiracetam.
Structure and activity relationship studies have concluded that the most potent anticonvulsant activity was at the imide nitrogen atom and that this activity was further enhanced by nearby electronegative functional groups such as the di-fluoro group on seletracetam.

Administration

Seletracetam is an orally administered drug, after which it is quickly and efficiently absorbed. The typical dosage is 0.03–10 mg/kg per day.

Mechanism of action

Seletracetam's anti-epileptic effects are due to its high affinity binding to synaptic vesicle glycoprotein 2A —part of a calcium ion regulator. The SV2A protein assists with the coordination of synaptic vesicle exocytosis, which induces neurotransmitter release in the presence of an influx in Ca2+. A correlation has been drawn between the binding affinity of seletracetam to SV2A and the degree of seizure prevention in animal models.
In addition, studies of ion currents have shown that seletracetam significantly decreases the amount of high-voltage derived Ca2+ currents which have been implicated in causing the high intracellular Ca2+ influx during epileptic activity. It is thought that seletracetam binds to N-type Ca2+ channels and inhibits their ability to allow calcium ions to enter the cell, although the drug does not bind to T-type channels that mediate low-voltage activated Ca2+ currents. Seletracetam thereby decreases cellular excitation, but it does not seem to affect voltage-gated Na+ or K+ currents. Selectracetam has been demonstrated to not significantly affect currents gated by NMDA, AMPA, GABA, glycine, or kainic acid.
The dual effect of seletracetam is an overall decrease in the amount of Ca2+ influx in the cell during an action potential due to binding at N-type channels, which prevents over-excitation of the neuron, as well as a decrease in neurotransmitter release as a product of cellular excitation due to the interaction of the drug with SV2A, which reduces the spread of excitation to nearby cells.
Compared to levetiracetam, which binds at the same site, seletracetam binds to SV2A with ten times higher affinity.
The nature of why the seletracetam molecule binds so specifically to SV2A and how SV2A affects exocytosis is unclear.

Pharmacodynamics and pharmacokinetics

The oral bioavailability of seletracetam is >90% and its half-life is approximately 8 hours. 25% of ingested seletracetam is metabolized and excreted unchanged and about 53% is excreted in the form of an inactive carboxylic acid metabolite. The main metabolic mechanism is the hydrolysis of an acetamide to a carboxylic acid.
Seletracetam exhibits first-order mono-compartmental pharmacokinetics, in which there is a simple linear relationship between the amount of drug that was administered, the time that has passed, and the amount of drug subsequently remaining in the body. This contrasts the nonlinear pharmacokinetics typical of previously available anticonvulsants such as phenobarbital, phenytolin, valproate and carbamazepine. The benefit of linear kinetics is that the steady-state concentration of the drug is directly and reliably related to the dose of the drug that is administered; this allows for simple and reliable dose adjustments.

''In vitro'' studies

In vitro studies performed in rodent hippocampal slices found that seletracetam causes a complete reversal of the increases in activity of population spike amplitude in epilepsy models. These reductions in in vitro epilepsy symptoms were present at extracellular concentrations of 3.2 μM. This is approximately 10% of the most effective concentration of levetiracetam in similar tests.

Animal studies

Seletracetam has been tested on various animal models for epilepsy, with mixed results.
Unlike drugs that act on voltage-gated sodium channels, seletracetam was demonstrated to have no significant effect on the maximal electroshock seizure test results in mice. It similarly had no relieving effects in mice of the other most common acute seizure model, the pentylenetetrazol convulsion-induction model.
Seletracetam did, however, show promising results in acquired and genetic epilepsy models. In the mouse model of corneal kindling, which exhibits the anticonvulsant capability of generalized motor seizures, doses as low as 0.07 mg/kg intraperitoneal injection, and ED50 of 0.31 mg/kg i.p. were effective. Occurrence of audiogenic seizures—those induced by white noise—in mice were also significantly reduced by an ED50 of 0.17 mg/kg i.p., which suggests that selectracetam reduces convulsions caused by clonic seizures.
In hippocampal kindling model rats, seizure severity was significantly reduced by seletracetam oral doses of 0.23 mg/kg. This provides further evidence of the potential benefits of selectracetam on generalized motor seizures. Seletracetam also performed well as a method to reduce the suppression of spontaneous spike-and-wave discharges that are often associated with absence epilepsy activity. This was demonstrated by its effect on Strasbourg genetic absence epilepsy rats. This model had an ED50 of 0.15 mg/kg i.p.
Rodents were found to have negligible behavioral deficits as a result of seletracetam administration, as measured by performance on a rotarod task.

Adverse effects and tolerance

Unlike currently prescribed anticonvulsants such as phenytoin, valproate, and phenobarbital, seletracetam shows few central nervous system side effects and is predicted to have low levels of drug-drug interactions due to its low binding to plasma proteins. There have been, however, no formal studies conducted on drug-drug interactions with seletracetam.
Other than SV2A and the high-voltage-activated Ca2+ channels, seletracetam does not significantly bind to other CNS receptors, ion channels, or uptake mechanisms. Seletracetam has, however, shown a slight selectivity for glycine receptors. This drug neither inhibits nor unnecessarily induces the action of any major human metabolizing enzymes, which further reduces adverse effects.
Early data from phase I trials were optimistic, and found seletracetam to be well tolerated by human volunteers.
In phase II trials side effects were limited to the CNS in origin, were of mild to moderate severity, and most were resolved within 24 hours and with no medical intervention. The most frequently reported adverse effects of seletracetam were dizziness, feeling drunk, euphoria, nausea, and somnolence.
Seletracetam was well tolerated by healthy individuals after single oral doses ranging from 2 to 600 mg, as well as after b.i.d. doses of 200 mg. Toxicology studies have shown that this drug has low acute oral toxicity and no significant negative effects on the CNS, cardiac, or respiratory systems. High doses of 2000 mg/kg per day and greater than 600 mg/kg per day were poorly tolerated.

FDA approval status

Phase II clinical trials of seletracetam were ongoing but in July 2007 the company stated that the drug's development has been put on hold. Although the conducted Phase II trials showed success, it was less than expected given the performance of seletracetam in animal models. There have been no known Phase IIb or Phase III trials.
In 2010, development of seletracetam was halted in favor of the development of brivaracetam, a newer variation of the drug.