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(Redirected from Anti-epileptic drugs) Class of medications

Anticonvulsant
Drug class
Class identifiers
SynonymsAntiepileptic drugs, antiseizure drugs
UseEpilepsy
ATC codeN03
Biological targetBrain
Legal status
In Wikidata

Anticonvulsants (also known as antiepileptic drugs, antiseizure drugs, or anti-seizure medications (ASM)) are a diverse group of pharmacological agents used in the treatment of epileptic seizures. Anticonvulsants are also increasingly being used in the treatment of bipolar disorder and borderline personality disorder, since many seem to act as mood stabilizers, and for the treatment of neuropathic pain. Anticonvulsants suppress the excessive rapid firing of neurons during seizures. Anticonvulsants also prevent the spread of the seizure within the brain.

Conventional antiepileptic drugs may block sodium channels or enhance γ-aminobutyric acid (GABA) function. Several antiepileptic drugs have multiple or uncertain mechanisms of action. Next to the voltage-gated sodium channels and components of the GABA system, their targets include GABAA receptors, the GABA transporter type 1, and GABA transaminase. Additional targets include voltage-gated calcium channels, SV2A, and α2δ. By blocking sodium or calcium channels, antiepileptic drugs reduce the release of excitatory glutamate, whose release is considered to be elevated in epilepsy, but also that of GABA. This is probably a side effect or even the actual mechanism of action for some antiepileptic drugs, since GABA can itself, directly or indirectly, act proconvulsively. Another potential target of antiepileptic drugs is the peroxisome proliferator-activated receptor alpha.

Some anticonvulsants have shown antiepileptogenic effects in animal models of epilepsy. That is, they either prevent the development of epilepsy or can halt or reverse the progression of epilepsy. However, no drug has been shown in human trials to prevent epileptogenesis (the development of epilepsy in an individual at risk, such as after a head injury).

Many anticonvulsants can cause birth defects in the unborn child if taken while pregnant.

Terminology

Anticonvulsants are more accurately called antiepileptic drugs (AEDs) because not every epileptic seizure involves convulsion, and vice versa, not every convulsion is caused by an epileptic seizure. They are also often referred to as antiseizure drugs because they provide symptomatic treatment only and have not been demonstrated to alter the course of epilepsy.

Approval

The usual method of achieving approval for a drug is to show it is effective when compared against placebo, or that it is more effective than an existing drug. In monotherapy (where only one drug is taken) it is considered unethical by most to conduct a trial with placebo on a new drug of uncertain efficacy. This is because untreated epilepsy leaves the patient at significant risk of death. Therefore, almost all new epilepsy drugs are initially approved only as adjunctive (add-on) therapies. Patients whose epilepsy is uncontrolled by their medication (i.e., it is refractory to treatment) are selected to see if supplementing the medication with the new drug leads to an improvement in seizure control. Any reduction in the frequency of seizures is compared against a placebo. The lack of superiority over existing treatment, combined with lacking placebo-controlled trials, means that few modern drugs have earned FDA approval as initial monotherapy. In contrast, Europe only requires equivalence to existing treatments and has approved many more. Despite their lack of FDA approval, the American Academy of Neurology and the American Epilepsy Society still recommend a number of these new drugs as initial monotherapy.

Drugs

In the following list, the dates in parentheses are the earliest approved use of the drug.

Aldehydes

Main article: Aldehyde

Aromatic allylic alcohols

Barbiturates

Main article: Barbiturate

Barbiturates are drugs that act as central nervous system (CNS) depressants, and by virtue of this they produce a wide spectrum of effects, from mild sedation to anesthesia. The following are classified as anticonvulsants:

Benzodiazepines

Main article: Benzodiazepine

The benzodiazepines are a class of drugs with hypnotic, anxiolytic, anticonvulsive, amnestic and muscle relaxant properties. Benzodiazepines act as a central nervous system depressant. The relative strength of each of these properties in any given benzodiazepine varies greatly and influences the indications for which it is prescribed. Long-term use can be problematic due to the development of tolerance to the anticonvulsant effects and dependency. Of many drugs in this class, only a few are used to treat epilepsy:

The following benzodiazepines are used to treat status epilepticus:

  • Diazepam (1963). Can be given rectally by trained care-givers.
  • Midazolam (N/A). Increasingly being used as an alternative to diazepam. This water-soluble drug is squirted into the side of the mouth but not swallowed. It is rapidly absorbed by the buccal mucosa.
  • Lorazepam (1972). Given by injection in hospital.

Nitrazepam, temazepam, and especially nimetazepam are powerful anticonvulsant agents, however their use is rare due to an increased incidence of side effects and strong sedative and motor-impairing properties.

Bromides

Main article: Bromide
  • Potassium bromide (1857). The earliest effective treatment for epilepsy. There would not be a better drug until phenobarbital in 1912. It is still used as an anticonvulsant for dogs and cats but is no longer used in humans.

Carbamates

Main article: Carbamate
  • Felbamate (1993). This effective anticonvulsant has had its usage severely restricted due to rare but life-threatening side effects.
  • Cenobamate (2019).

Carboxamides

Carbamazepine
Main article: Carboxamide

The following are carboxamides:

  • Carbamazepine (1963). A popular anticonvulsant that is available in generic formulations.
  • Oxcarbazepine (1990). A derivative of carbamazepine that has similar efficacy and is better tolerated and is also available generically.
  • Eslicarbazepine acetate (2009).
  • Photoswitchable analogues of carbamazepine (2024) are research compounds developed to control its pharmacological activity locally and on demand using light, with the purpose to reduce adverse systemic effects. One of these compounds (carbadiazocine, based on a bridged azobenzene) has been shown to produce analgesia with noninvasive illumination in a rat model of neuropathic pain.

Fatty acids

Main article: Fatty acid

The following are fatty-acids:

Vigabatrin and progabide are also analogs of GABA.

Fructose derivatives

Main article: Fructose

Gabapentinoids

Main article: Gabapentinoid GABA analoguesGABA analoguesBinding sites of pregabalin and the non-gabapentenoid ziconotide to the voltage-gated calcium channel complex.Voltage-gated calcium channel

Gabapentinoids are used in epilepsy, neuropathic pain, fibromyalgia, restless leg syndrome, opioid withdrawal and generalized anxiety disorder (GAD). Gabapentinoids block voltage-gated calcium channels, mainly the N-Type, and P/Q-type calcium channels. The following are gabapentinoids:

Gabapentinoids are analogs of GABA, but they do not act on GABA receptors. They have analgesic, anticonvulsant, and anxiolytic effects.

Hydantoins

Main article: Hydantoin

The following are hydantoins:

Oxazolidinediones

Main article: 2,4-Oxazolidinedione

The following are oxazolidinediones:

Propionates

Main article: Propionate

Pyrimidinediones

Main article: Pyrimidinedione

Pyrrolidines

Main article: Pyrrolidine

Succinimides

Main article: Succinimide

The following are succinimides:

Sulfonamides

Main article: Sulfonamide (medicine)

Triazines

Main article: Triazine

Ureas

Main article: Urea

Valproylamides

Main article: Amide

Other

A Non-pharmaceutical anticonvulsants

Further information: Epilepsy § Management

The ketogenic diet and vagus nerve stimulation are alternative treatments for epilepsy without the involvement of pharmaceuticals. The ketogenic diet consists of a high-fat, low-carbohydrate diet, and has shown good results in patients whose epilepsy has not responded to medications and who cannot receive surgery. The vagus nerve stimulator is a device that can be implanted into patients with epilepsy, especially that which originates from a specific part of the brain. However, both of these treatment options can cause severe adverse effects. Additionally, while seizure frequency typically decreases, they often do not stop entirely.

Treatment guidelines

According to guidelines by the American Academy of Neurology and American Epilepsy Society, mainly based on a major article review in 2004, patients with newly diagnosed epilepsy who require treatment can be initiated on standard anticonvulsants such as carbamazepine, phenytoin, valproic acid/valproate semisodium, phenobarbital, or on the newer anticonvulsants gabapentin, lamotrigine, oxcarbazepine or topiramate. The choice of anticonvulsants depends on individual patient characteristics. Both newer and older drugs are generally equally effective in new onset epilepsy. The newer drugs tend to have fewer side effects. For newly diagnosed partial or mixed seizures, there is evidence for using gabapentin, lamotrigine, oxcarbazepine or topiramate as monotherapy. Lamotrigine can be included in the options for children with newly diagnosed absence seizures.

History

The first anticonvulsant was bromide, suggested in 1857 by the British gynecologist Charles Locock who used it to treat women with "hysterical epilepsy" (probably catamenial epilepsy). Bromides are effective against epilepsy, and also cause impotence, which is not related to its anti-epileptic effects. Bromide also suffered from the way it affected behaviour, introducing the idea of the "epileptic personality" which was actually a result of medication. Phenobarbital was first used in 1912 for both its sedative and antiepileptic properties. By the 1930s, the development of animal models in epilepsy research led to the development of phenytoin by Tracy Putnam and H. Houston Merritt, which had the distinct advantage of treating epileptic seizures with less sedation. By the 1970s, a National Institutes of Health initiative, the Anticonvulsant Screening Program, headed by J. Kiffin Penry, served as a mechanism for drawing the interest and abilities of pharmaceutical companies in the development of new anticonvulsant medications.

Marketing approval history

The following table lists anticonvulsant drugs together with the date their marketing was approved in the US, UK and France. Data for the UK and France are incomplete. The European Medicines Agency approves drugs throughout the European Union. Some of the drugs are no longer marketed.

Drug Brand US UK France
acetazolamide Diamox 1953-07-2727 July 1953 1988
brivaracetam Briviact 2016-02-1818 February 2016
carbamazepine Tegretol 1974-07-1515 July 1974 1965 1963
cenobamate Xcopri 2019-11-2121 November 2019
clobazam Onfi/Frisium 2011-10-2121 October 2011 1979
clonazepam Klonopin/Rivotril 1975-06-044 June 1975 1974
diazepam Valium 1963-11-1515 November 1963
divalproex sodium Depakote 1983-03-1010 March 1983
eslicarbazepine Aptiom 2013-08-1111 August 2013
ethosuximide Zarontin 1960-11-022 November 1960 1955 1962
ethotoin Peganone 1957-04-2222 April 1957
everolimus Afinitor/Votubia 2009-03-3030 January 2009
felbamate Felbatol 1993-07-2929 July 1993
fosphenytoin Cerebyx 1996-08-055 August 1996
gabapentin Neurontin 1993-12-3030 December 1993 1993-05May 1993 1994-10October 1994
lacosamide Vimpat 2008-10-2828 October 2008
lamotrigine Lamictal 1994-12-2727 December 1994 1991-10October 1991 1995-05May 1995
levetiracetam Keppra 1999-11-3030 November 1999 2000-09-2929 September 2000 2000-09-2929 September 2000
mephenytoin Mesantoin 1946-10-2323 October 1946
metharbital Gemonil 1952
methsuximide Celontin 1957-02-088 February 1957
methazolamide Neptazane 1959-01-2626 January 1959
oxcarbazepine Trileptal 2000-01-1414 January 2000 2000
phenobarbital Luminal Unknown 1912 1920
phenytoin Dilantin/Epanutin 1938 1938 1941
piracetam Nootropil never approved
phensuximide Milontin 1953
pregabalin Lyrica 2004-12-3030 December 2004 2004-07-066 July 2004 2004-07-066 July 2004
primidone Mysoline 1954-03-088 March 1954 1952 1953
rufinamide Banzel/Inovelon 2008-11-1414 November 2008
sodium valproate Epilim Unknown 1977-12December 1977 1967-06June 1967
stiripentol Diacomit 2018-08-2020 August 2018 2007-01January 2007 2007-01January 2007
tiagabine Gabitril 1997-09-3030 September 1997 1998 1997-11November 1997
topiramate Topamax 1996-12-2424 December 1996 1995
trimethadione Tridione 1946-01-2525 January 1946
valproic acid Depakene/Convulex 1978-02-2828 February 1978 1993
vigabatrin Sabril 2009-08-2121 August 2009 1989
zonisamide Zonegran 2000-03-2727 March 2000 2005-03-1010 March 2005 2005-03-1010 March 2005

Pregnancy

See also: Epilepsy and pregnancy

Many of the commonly used anticonvulsant/anti-seizure medications (ASMs), such as valproate, phenytoin, carbamazepine, phenobarbitol, gabapentin have been reported to cause an increased risk of birth defects including major congenital malformations such as neural tube defects. The risk of birth defects associated with taking these medications while pregnant may be dependent on the dose and on the timing of gestation (how well developed the baby is). While trying to conceive a child and during pregnancy, medical advice should be followed to optimize the management of the person's epilepsy in order to keep the person and the unborn baby safe from epileptic seizures and also ensure that the risk of birth defects due to in utero exposure of anticonvulsants is as low as possible. Use of anticonvulsant medications should be carefully monitored during use in pregnancy. For example, since the first trimester is the most susceptible period for fetal development, planning a routine antiepileptic drug dose that is safer for the first trimester could be beneficial to prevent pregnancy complications.

Valproic acid, and its derivatives such as sodium valproate and divalproex sodium, causes cognitive deficit in the child, with an increased dose causing decreased intelligence quotient and use is associated with adverse neurodevelopmental outcomes (cognitive and behavioral)  in children. On the other hand, evidence is conflicting for carbamazepine regarding any increased risk of congenital physical anomalies or neurodevelopmental disorders by intrauterine exposure. Similarly, children exposed lamotrigine or phenytoin in the womb do not seem to differ in their skills compared to those who were exposed to carbamazepine.

There is inadequate evidence to determine if newborns of women with epilepsy taking anticonvulsants have a substantially increased risk of hemorrhagic disease of the newborn.

There is little evidence to suggest that anticonvulsant/ASM exposure through breastmilk has clinical effects on newborns. The Maternal Outcomes and Neurodevelopmental Effects of Antiepileptic Drugs (MONEAD) study showed that most blood concentrations in breastfed infants of mothers taking carbamazepine, oxcarbazepine, valproate, levetiracetam, and topiramate were quite low, especially in relationship to the mother's level and what the fetal level would have been during pregnancy. (Note: valproic acid is NOT a recommended ASM for people with epilepsy who are considering having children.)

Infant exposure to newer ASMs (cenobamate, perampanel, brivaracetam, eslicarbazepine, rufinamide, levetiracetam, topiramate, gabapentin, oxcarbazepine, lamotrigine, and vigabatrin) via breastmilk was not associated with negative neurodevelopment (such as lower IQ and autism spectrum disorder) at 36 months.

Several studies that followed children exposed to ASMs during pregnancy showed that a number of widely used ones (including lamotrigine and levetiracetam) carried a low risk of adverse neurodevelopmental outcomes (cognitive and behavioral) in children when compared to children born to mothers without epilepsy and children born to mothers taking other anti-seizure medications. Data from several pregnancy registries showed that children exposed to levetiracetam or lamotrigine during pregnancy had the lowest risk of developing major congenital malformations compared to those exposed to other ASMs. The risk of major congenital malformations for children exposed to these ASMs were within the range for children who were not exposed to any ASMs during pregnancy.

People with epilepsy can have healthy pregnancies and healthy babies. However, proper planning and care is essential to minimize the risk of congenital malformations or adverse neurocognitive outcomes for the fetus while maintaining seizure control for the pregnant person with epilepsy. If possible, when planning pregnancy, people with epilepsy should switch to ASMs with the lowest teratogenic risk for major congenital malformations as well as the least risk of adverse neurodevelopmental outcomes (e.g., lower IQ or autism spectrum disorder). They should also work with their healthcare providers to identify the lowest effective ASM dosage that will maintain their seizure control while regularly checking medication levels throughout pregnancy.

Data from studies conducted on women taking antiepileptic drugs for non-epileptic reasons, including depression and bipolar disorder, show that if high doses of the drugs are taken during the first trimester of pregnancy then there is the potential of an increased risk of congenital malformations.

Research

The mechanism of how anticonvulsants cause birth defects is not entirely clear. During pregnancy, the metabolism of many anticonvulsants is affected. There may be an increase in the clearance and resultant decrease in the blood concentration of lamotrigine, phenytoin, and to a lesser extent carbamazepine, and possibly decreases the level of levetiracetam and the active oxcarbazepine metabolite, the monohydroxy derivative. In animal models, several anticonvulsant drugs have been demonstrated to induce neuronal apoptosis in the developing brain.

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Further reading

  • Anti epileptic activity of novel substituted fluorothiazole derivatives by Devid Chutia, RGUHS

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