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A REVIEW OF EPILEPSY
1. AIM AND OBJECTIVE:
Aim:
Review of pathophysiology and pharmacotherapeutics of Epilepsy.
Objectives:
1. To identify the treatment and pharmacotherapeutic treatment alternative for a patient
with a specific seizure disorder.
2. To describe significant adverse effect and drug interaction.
3. To develop pharmacotherapeutics.
4. To study monitoring parameter for agent used to treat the seizure.
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2. INTRODUCTION
Hardly any other illness can be traced back in medical history as far as epilepsy
can. Many pointers from early history indicate that this condition has been part of the
human lot from the very beginning. Then as now, it is one of the most common chronic
diseases that there are: 0.5% of all human beings suffer from epilepsy, which means that
in the U.K. alone around 300 000 to 600 000 people are affected.
When someone repeatedly has epileptic seizures then we say that that person is
suffering from epilepsy. An epileptic seizure itself is one of the many pathological forms
of reaction which can take place in the brain; it is the brain’s "response" or reaction to a
disturbing, irritating or damaging stimulus. This reaction to the stimulus is accompanied
by abnormal electro-chemical excitatory processes in the cerebral nerve cells. This
pathological process takes place when suddenly an unnaturally large number of nerve
cells are stimulated simultaneously, causing a difference in voltage between the outer
side of the cell wall and the inside of the cell (membrane potential).
These seizures are transient signs and/or symptoms of abnormal, excessive or
synchronous neuronal activity in the brain. About 50 million people worldwide have
epilepsy, with almost 90% of these people being in developing countries. Epilepsy is
more likely to occur in young children, or people over the age of 65 years, however it can
occur at any time. Epilepsy is usually controlled, but not cured, with medication,
although surgery may be considered in difficult cases. However, over 30% of people with
epilepsy do not have seizure control even with the best available medications. Not all
epilepsy syndromes are lifelong some forms are confined to particular stages of
childhood. Epilepsy should not be understood as a single disorder, but rather as
syndromic with vastly divergent symptoms but all involving episodic abnormal electrical
activity in the brain.(1)
A seizure is a short episode of symptoms caused by a burst of abnormal electrical
activity in the brain. Typically, a seizure lasts from a few seconds to a few minutes.
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(Older words for seizures include convulsions and fits.) The brain contains millions of
nerve cells (neurones). Normally, the nerve cells are constantly sending tiny electrical
messages down nerves to all parts of the body. Different parts of the brain control
different parts and functions of the body. Therefore, the symptoms that occur during a
seizure depend on where the abnormal burst of electrical activity occurs. Symptoms that
may occur during a seizure can affect your muscles, sensations, behaviour, emotions,
consciousness, or a combination of these.
If you have a single seizure, it does not necessarily mean that you have epilepsy.
About 1 in 20 people has a seizure at some time in their life. It may be the only one that
occurs. The definition of epilepsy is 'more than one seizure'. The frequency of seizures in
people with epilepsy varies. In some cases there may be years between seizures. At the
other extreme, in some cases the seizures occur every day. For others, the frequency of
seizures is somewhere in between these extremes. Epilepsy can affect anyone at any age.
Around 456,000 people in the UK have epilepsy. Epileptic seizures arise from within the
brain. A seizure can also be caused by external factors which may affect the brain. For
example, a high fever may cause a 'febrile convulsion’. (2)
2.1 Definition
According to the Epilepsy Foundation of America, epilepsy is a physical
condition that occurs when there is a sudden, brief change in how the brain works. When
brain cells are not working properly, a person's consciousness, movement, or actions may
be altered for a short time. These physical changes are called epileptic seizures. Epilepsy
is therefore sometimes called a seizure disorder. Epilepsy affects people in all nations and
of all races. (3)
2.2 History:
The Greek physician Hippocrates writes the first book on epilepsy, On the Sacred
Disease. Refuting the idea that epilepsy is a curse or a prophetic power, Hippocrates
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proves the truth: It's a brain disorder. "It is thus with regard to the disease called Sacred:
it appears to me to be nowise more divine nor more sacred than other diseases, but has
a. .natural cause like other affections.(4)
2.3 What is a seizure?
A seizure is a short episode of symptoms caused by a burst of abnormal electrical
activity in the brain. Typically, a seizure lasts from a few seconds to a few minutes. It is
a hyperexcitation of neurons in the brain leading to altered behaviour with or without
violent motor activity. The term describe varies experiences and behaviours. Two third of
people experience a siezure never have another while rest go on to have reccurent
siezures.
The changes seen during siezure depends upon on which part of is affected.Ideally
anything that irritates the brains, can produce sensation. A seizure usually last for 02-05
min. when it stops, the persons may have a headache, confusion, fatigue, unusual and
unpleasant sensation.
2.4 What is epilepsy?
It is disorder characterised by periodic and unpredictable occurrence of siezure
followed by spontaneous resolution. It is known as epileptic seizure It often causes
transient impairment of consciousness, leaving indivisual at risk bodily harm.
About 1-2%of whole population have epileptic seizure. In about 25% of these patients the
causes can be make out with the help of EEG and MRI. Rest of 75% are labelled as
idiopathic.
Scaring in small areas of brains due to injury at birth or later can leads to epilepsy.
The common factor that can precipitate the epileptic seizre are repetitive sound, flashing
lights video games low level of oxygen in blood, hypoglycemia.(2)
2.5 Characteristics:
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Although the symptoms listed below are not necessarily indicators of epilepsy, it is wise
to consult a doctor if you or a member of your family experiences one or more of them:
"Blackouts" or periods of confused memory;
Episodes of staring or unexplained periods of unresponsiveness;
Involuntary movement of arms and legs;
"Fainting spells" with incontinence or followed by excessive fatigue; or Odd
sounds, distorted perceptions, episodic feelings of fear that cannot be explained. (3)
3. NEURAL BASIS OF EPILEPSY:
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The exact neural basis of epilepsy is not clear and attributed to following mechanism
as per experimental findings.
The reduction in inhibitory synaptic activity or enhanced excitatory synaptic activity may
lead to seizures. The neurotransmitters like certain amino acids, GABA (inhibitory) and
glutamate (excitatory) are prominently involved.
The potassium stimulated glutamate release also plays role in epilepsy.
The state of Na+ ion channels plays an important role during neuronal firing, as
recovery from inactivated Na+ channel is essential for generation of action potential.
The fast recovery from inactivated form to activated form is seen in epilepsy.
Thus the epilepsy could be collective result of above mentioned neuronal alteration. (5)
Fig. No.1 Neural basis of epilepsy (5)
4. DIFFERENT TYPES OF SEIZURES
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Seizures are divided into two main types - generalised and partial. (There are also
other uncommon types of seizure.) If you have epilepsy you usually have recurrences of
the same type of seizure. However, some people have different types of seizure at
different times.
4.1 Generalised seizures:
Fig. No. 2 Generalised seizure (6)
These occur if the abnormal electrical activity affects all or most of the brain. The
symptoms tend to be 'general' and involve much of your body.
There are various types.
4.1.1 Atonic-clonic seizure:
It is the most common type of generalised seizure. With this type of seizure your
whole body stiffens, you lose consciousness, and then your body shakes (convulses) due
to uncontrollable muscle contractions
4.1.2 Absence seizure:
It is another type of generalised seizure. With this type of seizure you have a
brief loss of consciousness or awareness. There is no convulsion, you do not fall over,
and it usually lasts only seconds. Absence seizures mainly occur in children.
4.1.3 A myoclonic seizure:
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It is caused by a sudden contraction of the muscles, which causes a jerk. These
can affect the whole body but often occur in just one or both arms.
4.1.4 A tonic seizure:
It causes a brief loss of consciousness, and you may become stiff and fall to the
ground.
4.1.5 An atonic seizure:
Causes you to become limp and to collapse, often with only a brief loss of
consciousness.
4.2 Partial seizures:
Fig. No.3 Partial seizure(6)
In these types of seizures the burst of electrical activity starts in, and stays in, one
part of the brain. Therefore, you tend to have localised or 'focal' symptoms. Different
parts of the brain control different functions and so symptoms depend on which part of
the brain is affected:
4.2.1 Simple partial seizures: are one type. You may have muscular jerks or strange
sensations in one arm or leg. You may develop an odd taste, or pins and needles in one
part of your body. You do not lose consciousness or awareness.
4.2.2 Complex partial seizures:. These commonly arise from a temporal lobe (a part of
the brain) but may start in any part of the brain. Therefore, this type is sometimes called
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'temporal lobe epilepsy'. Depending on the part of the brain affected, you may behave
strangely for a few seconds or minutes. For example, you may fiddle with an object, or
mumble, or wander aimlessly. In addition, you may have odd emotions, fears, feelings,
visions, or sensations. These differ from simple partial seizures in that your
consciousness is affected. You may not remember having a seizure. (2)
5. CLASSIFICATION OF EPILEPSY:
The epilepsy is classified into four type:
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5.1 Juvenile myoclonic epilepsy:
It is common among the age of 8-20 years and show characteristic myoclionic jerk
followed by generaalised tonic-clonic seizure.
5.2 Benign partial epilepsy in childhood:
It is common upto age 12 and starts with partial seizure which may result
generalized tonic-clonic seizure.The attack is more severe during sleep.
5.3 Solitary parenchymal cysts:
Single small cysts, a common form neurocystercosis is responcible. This is well
controlled by antiepileptic drug. Sometime therapy need augmentation of cysticidal (e.g.-
albendazol)
5.4 Reflex epilepsy:
In this type specific sensory stimuli or responsible for evoke the attack.
Photosensitivity, hot water is common stimuli. (3)
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6. EPILEPSY SYNDROMES:
There are over 40 different types of epilepsy, including: Absence seizures, atonic
seizures, benign Rolandic epilepsy, childhood absence, clonic seizures, complex partial
seizures, frontal lobe epilepsy, Febrile seizures, Infantile spasms, Juvenile Myoclonic
Epilepsy, Juvenile Absence Epilepsy, lennox-gastaut syndrom, Landau-Kleffner
Syndrome , myoclonic seizures, Mitochondrial Disorders, Progressive Myoclonic
Epilepsies, Psychogenic Seizures , Reflex Epilepsy, Rasmussen's Syndrome, Simple
Partial seizures, Secondarily Generalized Seizures, Temporal Lobe Epilepsy, Toni-clonic
seizures, Tonic seizures, Psychomotor Seizures, Limbic Epilepsy, Partial-Onset Seizures,
generalised-onset seizures, Status Epilepticus, Abdominal Epilepsy, Akinetic Seizures,
Auto-nomic seizures, Massive Bilateral Myoclonus, Catamenial Epilepsy, Drop seizures,
Emotional seizures, Focal seizures, Gelastic seizures, Jacksonian March, Lafora Disease,
Motor seizures, Multifocal seizures, Neonatal seizures, Nocturnal seizures,
Photosensitive seizure, Pseudo seizures, Sensory seizures, Subtle seizures, Sylvan
Seizures, Withdrawal seizures, Visual Reflex Seizures amongst others.
Each type of epilepsy presents with its own unique combination of seizure type, typical
age of onset, EEG findings, treatment, and prognosis. The most widespread classification
of the epilepsies [9] divides epilepsy syndromes by location or distribution of seizures (as
revealed by the appearance of the seizures and by EEG) and by cause. Syndromes are
divided into localization-related epilepsies, generalized epilepsies, or epilepsies of
unknown localization.
Localization-related epilepsies, sometimes termed partial or focal epilepsies, arise from
an epileptic focus, a small portion of the brain that serves as the irritant driving the
epileptic response. Generalized epilepsies, in contrast, arise from many independent foci
(multifocal epilepsies) or from epileptic circuits that involve the whole brain. Epilepsies
of unknown localization remain unclear whether they arise from a portion of the brain or
from more widespread circuits.
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Epilepsy syndromes are further divided by presumptive cause: idiopathic, symptomatic,
and cryptogenic. Idiopathic epilepsies are generally thought to arise from genetic
abnormalities that lead to alteration of basic neuronal regulation. Symptomatic
epilepsies arise from the effects of an epileptic lesion, whether that lesion is focal, such
as a tumor, or a defect in metabolism causing widespread injury to the brain.
Cryptogenic epilepsies involve a presumptive lesion that is otherwise difficult or
impossible to uncover during evaluation.
Some epileptic syndromes are difficult to fit within this classification scheme and fall in
the unknown localization/etiology category. People who only have had a single seizure,
or those with seizures that occur only after specific precipitants ("provoked seizures"),
have "epilepsies" that fall into this category. Febrile convulsions are an example of
seizures bound to a particular precipitant. Landau-Kleffner syndrome is another epilepsy
which, because of its variety of EEG distributions, falls uneasily in clear categories. More
confusingly, certain syndromes like West syndrome featuring seizures such as Infantile
spasms can be classified as idiopathic, syndromic, or cryptogenic depending on cause and
can arise from both focal or generalized epileptic lesions.
Below are some common seizure syndromes:
Autosomal dominant nocturnal frontal lobe epilepsy (ADNFLE) is an idiopathic
localization-related epilepsy that is an inherited epileptic disorder that causes
seizures during sleep. Onset is usually in childhood. These seizures arise from the
frontal lobes and consist of complex motor movements, such as hand clenching,
arm raising/lowering, and knee bending. Vocalizations such as shouting,
moaning, or crying are also common. ADNFLE is often misdiagnosed as
nightmares. ADNFLE has a genetic basis. These genes encode various nicotinic
acetylcholine receptors.
Benign centrotemporal lobe epilepsy of childhood or Benign rolandic epilepsy is
an idiopathic localization-related epilepsy that occurs in children between the ages
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of 3 and 13 years with peak onset in prepubertal late childhood. Apart from their
seizure disorder, these patients are otherwise normal. This syndrome features
simple partial seizures that involve facial muscles and frequently cause drooling.
Although most episodes are brief, seizures sometimes spread and generalize.
Seizures are typically nocturnal and confined to sleep. The EEG may demonstrate
spike discharges that occur over the centrotemporal scalp over the central sulcus
of the brain (the Rolandic sulcus) that are predisposed to occur during drowsiness
or light sleep. Seizures cease near puberty. Seizures may require anticonvulsant
treatment, but sometimes are infrequent enough to allow physicians to defer
treatment.
Benign occipital epilepsy of childhood (BOEC) is an idiopathic localization-
related epilepsy and consists of an evolving group of syndromes. Most authorities
include two subtypes, an early subtype with onset between 3–5 years and a late
onset between 7–10 years. Seizures in BOEC usually feature visual symptoms
such as scotoma or fortifications (brightly colored spots or lines) or amaurosis
(blindness or impairment of vision). Convulsions involving one half the body,
hemiconvulsions, or forced eye deviation or head turning are common. Younger
patients typically experience symptoms similar to migraine with nausea and
headache, and older patients typically complain of more visual symptoms. The
EEG in BOEC shows spikes recorded from the occipital (back of head) regions.
The EEG and genetic pattern suggest an autosomal dominant transmission as
described by Ruben Kuzniecky et al. Lately, a group of epilepsies termed
Panayiotopoulos syndrome that share some clinical features of BOEC but have a
wider variety of EEG findings are classified by some as BOEC.
Catamenial epilepsy (CE) is when seizures cluster around certain phases of a
woman's menstrual cycle.
Childhood absence epilepsy (CAE) is an idiopathic generalized epilepsy that
affects children between the ages of 4 and 12 years of age, although peak onset is
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around 5–6 years old. These patients have recurrent absence seizures, brief
episodes of unresponsive staring, sometimes with minor motor features such as
eye blinking or subtle chewing. The EEG finding in CAE is generalized 3 Hz
spike and wave discharges. Some go on to develop generalized tonic-clonic
seizures. This condition carries a good prognosis because children do not usually
show cognitive decline or neurological deficits, and the seizures in the majority
cease spontaneously with onging maturation.
Dravet's syndrome Severe myoclonic epilepsy of infancy (SMEI). This
generalized epilepsy syndrome is distinguished from benign myoclonic epilepsy
by its severity and must be differentiated from the Lennox-Gastaut syndrome and
Doose’s myoclonic-astatic epilepsy. Onset is in the first year of life and
symptoms peak at about 5 months of age with febrile hemiclonic or generalized
status epilepticus. Boys are twice as often affected as girls. Prognosis is poor.
Most cases are sporadic. Family history of epilepsy and febrile convulsions is
present in around 25 percent of the cases.
Frontal lobe epilepsy, usually a symptomatic or cryptogenic localization-related
epilepsy, arises from lesions causing seizures that occur in the frontal lobes of the
brain. These epilepsies can be difficult to diagnose because the symptoms of
seizures can easily be confused with nonepileptic spells and, because of
limitations of the EEG, be difficult to "see" with standard scalp EEG.
Juvenile absence epilepsy is an idiopathic generalized epilepsy with later onset
that CAE, typically in prepubertal adolescence, with the most frequent seizure
type being absence seizures. Generalized tonic-clonic seizures can occur. 3 Hz
spike-wave or multiple spike discharges can be seen on EEG. Prognosis is mixed,
with some patients going on to a syndrome that is poorly distinguishable from
JME.
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Juvenile myoclonic epilepsy (JME) is an idiopathic generalized epilepsy that
occurs in patients aged 8 to 20 years. Patients have normal cognition and are
otherwise neurologically intact. The most common seizures are myoclonic jerks,
although generalized tonic-clonic seizures and absence seizures may occur as
well. Myoclonic jerks usually cluster in the early morning after awakening. The
EEG reveals generalized 4–6 Hz spike wave discharges or multiple spike
discharges. Interestingly, these patients are often first diagnosed when they have
their first generalized tonic-clonic seizure later in life when they experience sleep
deprivation (e.g., freshman year in college after staying up late to study for
exams). Alcohol withdrawal can also be a major contributing factor in
breakthrough seizures as well. The risk of the tendency to have seizures is
lifelong; however, the majority have well-controlled seizures with anticonvulsant
medication and avoidance of seizure precipitants.
Lennox-Gastaut syndrome (LGS) is a generalized epilepsy that consists of a triad
of developmental delay or childhood dementia, mixed generalized seizures, and
EEG demonstrating a pattern of approximately 2 Hz "slow" spike-wave. Onset
occurs between 2–18 years. As in West syndrome, LGS result from idiopathic,
symptomatic, or cryptogenic causes, and many patients first have West syndrome.
Authorities emphasize different seizure types as important in LGS, but most have
astatic seizures (drop attacks), tonic seizures, tonic-clonic seizures, atypical
absence seizures, and sometimes, complex partial seizures. Anticonvulsants are
usually only partially successful in treatment.
Ohtahara Syndrome is a rare but severe form of epilepsy syndrome combined
with cerebral palsy and characterised with frequent seizures which typically start
in the first few days of life. Sufferers trend to be severely disabled and their lives
short (they are unlikely to reach adulthood).
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Primary reading epilepsy is a reflex epilepsy classified as an idiopathic
localization-related epilepsy. Reading in susceptible individuals triggers
characteristic seizures.
Progressive myoclonic epilepsies define a group of symptomatic generalized
epilepsies characterized by progressive dementia and myoclonic seizures. Tonic-
clonic seizures may occur as well. Diseases usually classified in this group are
Unverricht-Lundborg disease, myoclonus epilepsy with ragged red fibers
(MERRF syndrome), Lafora disease, neuronal ceroid lipofucinosis, and sialdosis.
Rasmussen's encephalitis is a symptomatic localization-related epilepsy that is a
progressive, inflammatory lesion affecting children with onset before the age of
10. Seizures start as separate simple partial or complex partial seizures and may
progress to epilepsia partialis continuata (simple partial status epilepticus).
Neuroimaging shows inflammatory encephalitis on one side of the brain that may
spread if not treated. Dementia and hemiparesis are other problems. The cause is
hypothesized to involve an immulogical attack against glutamate receptors, a
common neurotransmitter in the brain.
Symptomatic localization-related epilepsies Symptomatic localization-related
epilepsies are divided by the location in the brain of the epileptic lesion, since the
symptoms of the seizures are more closely tied to the brain location rather than
the cause of the lesion. Tumors, atriovenous malformations, cavernous
malformations, trauma, and cerebral infarcts can all be causes of epileptic foci in
different brain regions.
Temporal lobe epilepsy (TLE), a symptomatic localization-related epilepsy, is the
most common epilepsy of adults who experience seizures poorly controlled with
anticonvulsant medications. In most cases, the epileptogenic region is found in the
midline (mesial) temporal structures (e.g., the hippocampus, amygdala, and
parahippocampal gyrus). Seizures begin in late childhood and adolescence. Most
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of these patients have complex partial seizures sometimes preceded by an aura,
and some TLE patients also suffer from secondary generalized tonic-clonic
seizures. If the patient does not respond sufficiently to medical treatment, epilepsy
surgery may be considered.
West syndrome is a triad of developmental delay, seizures termed infantile
spasms, and EEG demonstrating a pattern termed hypsarrhythmia. Onset occurs
between 3 months and 2 years, with peak onset between 8–9 months. West
syndrome may arise from idiopathic, symptomatic, or cryptogenic causes. The
most common cause is tuberous sclerosis. The prognosis varies with the
underlying cause. In general most surviving patients remain with significant
cognitive impairment and continuing seizures and may evolve to another
eponymic syndrome, Lennox-Gastaut syndrome.(1)
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7. CAUSES
The diagnosis of epilepsy usually requires that the seizures occur spontaneously.
Nevertheless, certain epilepsy syndromes require particular precipitants or triggers for
seizures to occur. These are termed reflex epilepsy. For example, patients with primary
reading epilepsy have seizures triggered by reading. Photosensitive epilepsy can be
limited to seizures triggered by flashing lights. Other precipitants can trigger an epileptic
seizure in patients who otherwise would be susceptible to spontaneous seizures. For
example, children with childhood absence epilepsy may be susceptible to
Fig. No. 4 The Causes of Epilepsy(6)
hyperventilation. In fact, flashing lights and hyperventilation are activating procedures
used in clinical EEG to help trigger seizures to aid diagnosis. Finally, other precipitants
can facilitate, rather than obligately trigger, seizures in susceptible individuals. Emotional
stress, sleep deprivation, sleep itself, and febrile illness are examples of precipitants cited
by patients with epilepsy. Notably, the influence of various precipitants varies with the
epilepsy syndrome. Likewise, the menstrual cycle in women with epilepsy can influence
patterns of seizure recurrence. Catamenial epilepsy is the term denoting seizures linked to
the menstrual cycle. (1)
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8. PATHOPHYSIOLOGY
Mutations in several genes have been linked to some types of epilepsy. Several genes that
code for protein subunits of voltage-gated and ligand-gated ion channels have been
associated with forms of generalized epilepsy and infantile seizure syndromes. Several
ligand-gated ion channels have been linked to some types of frontal and generalized
epilepsies. One speculated mechanism for some forms of inherited epilepsy are mutations
of the genes which code for sodium channel proteins; these defective sodium channels
stay open for too long thus making the neuron hyper-excitable. Glutamate, an excitatory
neurotransmitter, may thereby be released from these neurons in large amounts which—
by binding with nearby glumtamanergic neurons—triggers excessive Ca++ release in these
post-synaptic cells. Such excessive calcium release can be neurotoxic to the affected cell.
The hippocampus, which contains a large volume of just such glutamanergic neurons is
especially vulnerable to epileptic seizure, subsequent spread of excitation, and possible
neuronal death. Another possible mechanism involves mutations leading to ineffective
GABA (the brain's most common inhibitory neurotransmitter) action. Epilepsy-related
mutations in some non-ion channel genes have also been identified.
Epileptogenesis is the process by which a normal brain develops epilepsy after an insult.
One interesting finding in animals is that repeated low-level electrical stimulation to
some brain sites can lead to permanent increases in seizure susceptibility: in other words,
a permanent decrease in seizure "threshold." This phenomenon, known as kindling (by
analogy with the use of burning twigs to start a larger fire) was discovered by Dr.
Graham Goddard in 1967. Chemical stimulation can also induce seizures; repeated
exposures to some pesticides have been shown to induce seizures in both humans and
animals. One mechanism proposed for this is called excitotoxicity. The roles of kindling
and excitotoxicity, if any, in human epilepsy are currently hotly debated.
Other causes of epilepsy are brain lesions, where there is scar tissue or another abnormal
mass of tissue in an area of the brain.
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The complexity of understanding what seizures are have led to considerable efforts to use
computational models of epilepsy to both interpret experimental and clinical data, as well
as guide strategies for therapy.(1)
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9. EPIDEMIOLOGY
Epilepsy is one of the most common of the serious neurological disorders. Genetic,
congenital, and developmental conditions are mostly associated with it among younger
patients; tumors are more likely over age 40; head trauma and central nervous system
infections may occur at any age. The prevalence of active epilepsy is roughly in the range
5–10 per 1000 people. Up to 5% of people experience non febrile seizures at some point
in life; epilepsy's lifetime prevalence is relatively high because most patients either stop
having seizures or (less commonly) die of it. Epilepsy's approximate annual incidence
rate is 40–70 per 100,000 in industrialized countries and 100–190 per 100,000 in
resource-poor countries; socioeconomically deprived people are at higher risk. In
industrialized countries the incidence rate decreased in children but increased among the
elderly during the three decades prior to 2003, for reasons not fully understood.[41]
Beyond symptoms of the underlying diseases that can be a part of certain epilepsies,
people with epilepsy are at risk for death from four main problems: status epilepticus
(most often associated with anticonvulsant noncompliance), suicide associated with
depression, trauma from seizures, and sudden unexpected death in epilepsy Those at
highest risk for epilepsy-related deaths usually have underlying neurological impairment
or poorly controlled seizures; those with more benign epilepsy syndromes have little risk
for epilepsy-related death.
The NICE National Sentinel Audit of Epilepsy-Related Deaths, led by "Epilepsy
Bereaved" drew attention to this important problem. The Audit revealed; "1,000 deaths
occur every year in the UK as a result of epilepsy" and most of them are associated with
seizure. (1)
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10. MANAGEMENT
Epilepsy is usually treated with medication prescribed by a physician; primary caregivers,
neurologists, and neurosurgeons all frequently care for people with epilepsy. In some
cases the implantation of a stimulator of the vagus nerve, or a special diet can be helpful.
Neurosurgical operations for epilepsy can be palliative, reducing the frequency or
severity of seizures; or, in some patients, an operation can be curative.
10.1 Responding to a seizure
In most cases, the proper emergency response to a generalized tonic-clonic epileptic
seizure is simply to prevent the patient from self-injury by moving him or her away from
sharp edges, placing something soft beneath the head, and carefully rolling the person
into the recovery position to avoid asphyxiation. In some cases the person may seem to
start snoring loudly following a seizure, before coming to. This merely indicates that the
person is beginning to breathe properly and does not mean he or she is suffocating.
Should the person regurgitate, the material should be allowed to drip out the side of the
person's mouth by itself. If a seizure lasts longer than 5 minutes, or if the seizures begin
coming in 'waves' one after the other - then Emergency Medical Services should be
contacted immediately. Prolonged seizures may develop into status epilepticus, a
dangerous condition requiring hospitalization and emergency treatment.
Objects should never be placed in a person's mouth by anybody - including paramedics -
during a seizure as this could result in serious injury to either party. Despite common
folklore, it is not possible for a person to swallow their own tongue during a seizure.
However, it is possible that the person will bite their own tongue, especially if an object
is placed in the mouth.
With other types of seizures such as simple partial seizures and complex partial seizures
where the person is not convulsing but may be hallucinating, disoriented, distressed, or
unconscious, the person should be reassured, gently guided away from danger, and
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sometimes it may be necessary to protect the person from self-injury, but physical force
should be used only as a last resort as this could distress the person even more. In
complex partial seizures where the person is unconscious, attempts to rouse the person
should not be made as the seizure must take its full course. After a seizure, the person
may pass into a deep sleep or otherwise they will be disoriented and often unaware that
they have just had a seizure, as amnesia is common with complex partial seizures. The
person should remain observed until they have completely recovered, as with a tonic-
clonic seizure.
After a seizure, it is typical for a person to be exhausted and confused. (this is known as
post-ictal state). Often the person is not immediately aware that they have just had a
seizure. During this time one should stay with the person - reassuring and comforting
them - until they appear to act as they normally would. Seldom during seizures do people
lose bladder or bowel control. In some instances the person may vomit after coming to.
People should not be allowed to wander about unsupervised until they have returned to
their normal level of awareness. Many patients will sleep deeply for a few hours after a
seizure - this is common for those having just experienced a more violent type of seizure
such as a tonic-clonic. In about 50% of people with epilepsy, headaches may occur after a
seizure. These headaches share many features with migraines, and respond to the same
medications.
It is helpful if those present at the time of a seizure make note of how long and how
severe the seizure was. It is also helpful to note any mannerisms displayed during the
seizure. For example, the individual may twist the body to the right or left, may blink,
might mumble nonsense words, or might pull at clothing. Any observed behaviors, when
relayed to a neurologist, may be of help in diagnosing the type of seizure which occurred.
10.2 Pharmacologic treatment
The mainstay of treatment of epilepsy is anticonvulsant medications. Often,
anticonvulsant medication treatment will be lifelong and can have major effects on
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quality of life. The choice among anticonvulsants and their effectiveness differs by
epilepsy syndrome. Mechanisms, effectiveness for particular epilepsy syndromes, and
side effects, of course, differ among the individual anticonvulsant medications. Some
general findings about the use of anticonvulsants are outlined below.
10.2.1 History and Availability-
The first anticonvulsant was bromide, suggested in 1857 by Charles Locock who used it
to treat women with "hysterical epilepsy" (probably catamenial epilepsy). Potassium
bromide was also noted to cause impotence in men. Authorities concluded that potassium
bromide would dampen sexual excitement thought to cause the seizures. In fact, bromides
were effective against epilepsy, and also caused impotence; it is now known that
impotence is a side effect of bromide treatment, which is not related to its anti-epileptic
effects. It also suffered from the way it affected behaviour, introducing the idea of the
'epileptic personality' which was actually a result of the 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 lead 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, an 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.
Currently there are 20 medications approved by the Food and Drug Administration for
the use of treatment of epileptic seizures in the US: carbamazepine (common US brand
name Tegretol), clorazepate (Tranxene), clonazepam (Klonopin), ethosuximide
(Zarontin), felbamate (Felbatol), fosphenytoin (Cerebyx), gabapentin (Neurontin),
lacosamide (Vimpat), lamotrigine (Lamictal), levetiracetam (Keppra), oxcarbazepine
(Trileptal), phenobarbital (Luminal), phenytoin (Dilantin), pregabalin (Lyrica), primidone
(Mysoline), tiagabine (Gabitril), topiramate (Topamax), valproate semisodium
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(Depakote), valproic acid (Depakene), and zonisamide (Zonegran). Most of these
appeared after 1990.
Medications commonly available outside the US but still labelled as "investigational"
within the US are clobazam (Frisium) and vigabatrin (Sabril). Medications currently
under clinical trial under the supervision of the FDA include retigabine, brivaracetam,
and seletracetam.
Other drugs are commonly used to abort an active seizure or interrupt a seizure flurry;
these include diazepam (Valium, Diastat) and lorazepam (Ativan). Drugs used only in the
treatment of refractory status epilepticus include paraldehyde (Paral), midazolam
(Versed), and pentobarbital (Nembutal).
Some anticonvulsant medications do not have primary FDA-approved uses in epilepsy
but are used in limited trials, remain in rare use in difficult cases, have limited
"grandfather" status, are bound to particular severe epilepsies, or are under current
investigation. These include acetazolamide (Diamox), progesterone, adrenocorticotropic
hormone (ACTH), various corticotropic steroid hormones (prednisone), or bromide.
10.2.2 Effectiveness:
The definition of "effective" varies. FDA-approval usually requires that 50% of
the patient treatment group had at least a 50% improvement in the rate of epileptic
seizures. About 20% of patients with epilepsy continue to have breakthrough epileptic
seizures despite best anticonvulsant treatment.
10.2.3 Safety and Side Effects:
88% of patients with epilepsy, in a European survey, reported at least one
anticonvulsant related side effect. Most side effects are mild and "dose-related" and can
often be avoided or minimized by the use of the smallest effective amount. Some
examples include mood changes, sleepiness, or unsteadiness in gait. Some anticonvulsant
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medications have "idiosyncratic" side-effects that can not be predicted by dose. Some
examples include drug rashes, liver toxicity (hepatitis), or aplastic anemia. Safety
includes the consideration of teratogenicity (the effects of medications on fetal
development) when women with epilepsy become pregnant.
10.2.4 Principles of Anticonvulsant Use:
The goal for individual patients is, of course, no seizures and no side effects, and
the job of the physician is to aid the patient to find the best balance between the two
during the prescribing of anticonvulsants. Most patients can achieve this balance best
with monotherapy, the use of a single anticonvulsant medication. Some patients,
however, require polypharmacy; the use of two or more anticonvulsants.
Serum levels of AEDs can be checked to determine medication compliance, to assess the
effects of new drug-drug interactions upon previous stable medication levels, or to help
establish if particular symptoms such as instability or sleepiness can be considered a drug
side-effect or are due to different causes. Children or impaired adults who may not be
able to communicate side effects may benefit from routine screening of drug levels.
Beyond baseline screening, however, trials of recurrent, routine blood or urine
monitoring show no proven benefits and may lead to unnecessary medication adjustments
in most older children and adults using routine anticonvulsants.
If a person's epilepsy cannot be brought under control after adequate trials of two or three
(experts vary here) different drugs, that person's epilepsy is generally said to be
medically refractory. A study of patients with previously untreated epilepsy
demonstrated that 47% achieved control of seizures with the use of their first single drug.
14% became seizure free during treatment with a second or third drug. An additional 3%
became seizure-free with the use of two drugs simultaneously. Other treatments, in
addition to or instead of, anticonvulsant medications may be considered by those people
with continuing seizures.
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10.3 Surgical treatment
Epilepsy surgery is an option for patients whose seizures remain resistant to treatment
with anticonvulsant medications who also have symptomatic localization-related
epilepsy; a focal abnormality that can be located and therefore removed. The goal for
these procedures is total control of epileptic seizures, although anticonvulsant
medications may still be required.
The evaluation for epilepsy surgery is designed to locate the "epileptic focus" (the
location of the epileptic abnormality) and to determine if respective surgery will affect
normal brain function. Physicians will also confirm the diagnosis of epilepsy to make
sure that spells arise from epilepsy (as opposed to non-epileptic seizures). The evaluation
typically includes neurological examination, routine EEG, Long-term video-EEG
monitoring, neuropsychological evaluation, and neuroimaging such as MRI, Single
photon emission computed tomography (SPECT), positron emission tomography (PET).
Some epilepsy centers use intracarotid sodium amobarbital test (Wada test), functional
MRI or Magnetoencephalography (MEG) as supplementary tests.
Certain lesions require Long-term video-EEG monitoring with the use of intracranial
electrodes if noninvasive testing was inadequate to identify the epileptic focus or
distinguish the surgical target from normal brain tissue and function. Brain mapping by
the technique of cortical electrical stimulation or Electrocorticography are other
procedures used in the process of invasive testing in some patients.
The most common surgeries are the resection of lesions like tumors or arteriovenous
malformations which, in the process of treating the underlying lesion, often result in
control of epileptic seizures caused by these lesions.
Other lesions are more subtle and feature epilepsy as the main or sole symptom. The most
common form of intractable epilepsy in these disorders in adults is temporal lobe
epilepsy with hippocampal sclerosis, and the most common type of epilepsy surgery is
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the anterior temporal lobectomy, or the removal of the front portion of the temporal lobe
including the amygdala and hippocampus. Some neurosurgeons recommend selective
amygdalahippocampectomy because of possible benefits in postoperative memory or
language function. Surgery for temporal lobe epilepsy is effective, durable, and results in
decreased health care costs.. Despite the efficacy of epilepsy surgery, some patients
decide not to undergo surgery owing to fear or the uncertainty of having a brain
operation.
Palliative surgery for epilepsy is intended to reduce the frequency or severity of seizures.
Examples are callosotomy or commissurotomy to prevent seizures from generalizing
(spreading to involve the entire brain), which results in a loss of consciousness. This
procedure can therefore prevent injury due to the person falling to the ground after losing
consciousness. It is performed only when the seizures cannot be controlled by other
means. Multiple subpial transection can also be used to decrease the spread of seizures
across the cortex especially when the epileptic focus is located near important functional
areas of the cortex. Resective surgery can be considered palliative if it is undertaken with
the expectation that it will reduce but not eliminate seizures.
Hemispherectomy involves removal or a functional disconnection of most or all of one
half of the cerebrum. It is reserved for people suffering from the most catastrophic
epilepsies, such as those due to Rasmussen syndrome. If the surgery is performed on very
young patients (2–5 years old), the remaining hemisphere may acquire some rudimentary
motor control of the ipsilateral body; in older patients, paralysis results on the side of the
body opposite to the part of the brain that was removed. Because of these and other side
effects it is usually reserved for patients who have exhausted other treatment options.
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10.4 Other treatment
10.4.1 Ketogenic diet:
A high fat, low carbohydrate diet developed in the 1920s, largely forgotten with
the advent of effective anticonvulsants, and resurrected in the 1990s. The mechanism of
action is unknown. It is used mainly in the treatment of children with severe, medically-
intractable epilepsies.
10.4.2 Electrical stimulation:
Methods of anticonvulsant treatment with both currently approved and
investigational uses. A currently approved device is vagus nerve stimulation (VNS).
Investigational devices include the responsive neurostimulation system and deep
brain stimulation.
10.4.3 Vagus nerve stimulation (VNS):
The VNS consists of a computerized electrical device similar in size, shape and
implant location to a heart pacemaker that connects to the vagus nerve in the neck. The
device stimulates the vagus nerve at pre-set intervals and intensities of current. Efficacy
has been tested in patients with localization-related epilepsies demonstrating that 50% of
patients experience a 50% improvement in seizure rate. Case series have demonstrated
similar efficacies in certain generalized epilepsies such as Lennox-Gastaut syndrome.
Although success rates are not usually equal to that of epilepsy surgery, it is a reasonable
alternative when the patient is reluctant to proceed with any required invasive
monitoring, when appropriate presurgical evaluation fails to uncover the location of
epileptic foci, or when there are multiple epileptic foci.
Responsive Neurostimulator System (RNS) (manufacturer Neuropace) consists of an
computerized electrical device implanted in the skull with electrodes implanted in
presumed epileptic foci within the brain. The brain electrodes send EEG signal to the
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device which contains seizure-detection software. When certain EEG seizure criteria are
met, the device delivers a small electrical charge to other electrodes near the epileptic
focus and disrupt the seizure. The efficacy of the RNS is under current investigation with
the goal of FDA approval.
Deep brain stimulation (DBS) (US manufacturer Medtronic) consists of computerized
electrical device implanted in the chest in a manner similar to the VNS, but electrical
stimulation is delivered to deep brain structures through depth electrodes implanted
through the skull. In epilepsy, the electrode target is the anterior nucleus of the thalamus.
The efficacy of the DBS in localization-related epilepsies is currently under investigation.
Noninvasive surgery- The use of the Gamma Knife or other devices used in radiosurgery
are currently being investigated as alternatives to traditional open surgery in patients who
would otherwise qualify for anterior temporal lobectomy.
Avoidance therapy- Avoidance therapy consists of minimizing or eliminating triggers in
patients whose seizures are particularly susceptible to seizure precipitants For example,
sunglasses that counter exposure to particular light wavelengths can improve seizure
control in certain photosensitive epilepsies.
Warning systems- A seizure response dog is a form of service dog that is trained to
summon help or ensure personal safety when a seizure occurs. These are not suitable for
everybody and not all dogs can be so trained. Rarely, a dog may develop the ability to
sense a seizure before it occurs. Development of electronic forms of seizure detection
systems are currently under investigation.
Alternative or complementary medicine- A number of systematic reviews by the
Cochrane Collaboration into treatments for epilepsy looked at acupuncture, psychological
interventions, vitamins and yoga and found there is no reliable evidence to support the
use of these as treatments for epilepsy.(1)
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11. ANTIEPILEPTIC DRUG
Classification (7)
The antiepileptic drug may be classified according to chemical structure as under:
11.1. Anticonvulsant Barbiturates:
Phenobarbital, Mephobarbital, Methabital.
11.2. Hydantoins:
Phenytoin, Ethatoin, Mephenytoin.
11.3. Oxazlidinediones:
Trimthadione. Paramethadione.
11.4. Succinimides:
Ethosuximide, Methsuximide, Phensuximide.
11.5. Iminostilbines:
Carbamazepine.
11.6. Benzodiazepines:
Clonazepam, Diazepam, Nitrazepam.
11.7. Valproic acid derivatives:
Valproic acid, Valproate
11.8. Chemically unrelated anticonvulsant:
Primidone, Acetozolamide.
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11.1 Anti convulsant barbiturates:
11.1.1 Phenobarbital
All barbiturates can abolish seizures at doses sufficient to produce
anesthesia. Phenobarbital is effective antiepileptics at sub hypnotic doses.They exert a
prolong action. (7)
Fig. No. 5. Structure of Phenobarbital(8)
Mode of action :
The antiepileptic activity of barbiturates involved several mechanisms,
1. The excitability of the nerve cell is reduced due to their increased firing threshold.
2. Decreased neuronal excitability limits the spread of the abnormal discharge.
3. The active transport of ion across the neuronal membranes is impaired, which lowers
their firing rate.
Therapeutic uses:
1. Treatment of grand mal seizures used alone in infants and children’s and in
combination with phenytoin in adults.
2. Generalized myoclonic jerks and cortical focal seizures.
3. Control of status epilepticus.
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Adverse reactions:
Drowsiness, Lethargy and Dizziness are most frequently noted side effects. Less
common adverse reactions are bradycardia, hypotension, hypoventilation, bronchospasm,
laryngospasm, skin rash, confusion, hallucinations and aggressive behavior. (7)
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11.2 Hydantoins:
11.2.1 Phenytoin
The hydantoins are the most effective drugs for the treatment of grand mal
seizures and can also be used to control psychomotor epilepsy. Phenytoin is the most
frequently prescribed drug out of the hydantoins. (7)
Fig. No.6. Structure of Phenytoin(9)
Availability Form:
Phenytoin sodium has been marketed as:
Phenytek by Mylan Laboratories, previously Bertek Pharmaceuticals
Dilantin Kapseals and Dilantin Infatabs in the USA,
Eptoin by Abbott Group in India and PhydumTM in form of tab./inj. by Quadra labs
pvt. ltd. in India.(9)
Mechanism of action
The hydantoins inhibit the spread of seizures activity to neurons surrounding the
seizures focus. The motor cortex is the primary site of action These drugs produce a
stabilization of the neuronal membrane, i.e. the threshold of excitability is increased and
the duration of after-discharge is reduced. Perhaps by increasing Na+-K+ adenosine
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triphosphatase (ATPase) activity, sodium efflux from neuronal cells is stimulated,
blocking post-titanic potentiation (PTP). This prevent focal seizure activity to spread to
adjacent areas. Increased released or activity of GABA has been postulated asan
additional possible mechanism of action.
Therapeutic Uses
1. Control of grand mal seizures.
2. Treatment of psychomotor epilepsy
3. Adjunctive treatment of trigeminal neuralgia and alcohol withdrawal syndrome.
Adverse reaction
The side effects sluggishness, slurred speech nystagmus and confusion.
The other adverse reactions include:
GI- nausea, vomiting, dysphagia.
CNS- headache, tremors, behavioural disturbances.
Dermatology- skin rashes, urticaria
Haematopoietic- megaloblastic anaemia. bone marrow depression.
Other- gingimal hyperplasia hepatitis hyperglycaemia pulmonary fibrosis. (7)
11.3 Oxazolidinediones
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11.3.1 Trimethadione
These are effective drugs for the control of simple absence seizure.but incident of adverse
reactionis high. Their use reversed for patients who are intolerant or refractory to other
less toxic agents. (7)
Fig. No. 7. Structure of trimethadione (10)
Mechanism of action
Repetitive discharge in the thalamocortical system are responsible for absence
seizure. The drug which prolong the recovery period of the postsynapticneurons in these
systems, thereby exerting an antiseizure effect. They elevate the seizure threshold in the
thalamus, and interfere with prolongation pf seizure activity. They posses little sedative-
hypnotic effect and have an analgesic effect.
Therapeutic Use
The drug is used in treatment of simple absence (petit mal) seizures.
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Adverse reaction
Common side effect are drowsiness GI distress hiccup and photophobia.
The other adverse reactions are
GI- nausea, vomiting, anorexia
CNS-vertigo irritability, personality changes, precipitation of grand mal seizures.
Haematologic- mucosal bleeding, neutropenia.
Others- skin rashes exfoliative dermatitis, albimnuria.
This drug should not be used during pregnancy. (7)
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11.4 Succinimides
11.4.1 Ethosucximide:
The succinimides are the drug of choice for treatment of absence (petit mal)
seizures. They are not more effective than the oxazolidinediones, but are less toxic
compare to other alternative drugs. (7)
Fig. No. 8. Structure of Ethosuximide(11)
Availability:
Ethosuximide is marketed under the trade names Emeside and Zarontin.
However, both capsule preparations were discontinued from production, leaving only
generic preparations available. Emeside capsules were discontinued by their
manufacturer, Laboratories for Applied Biology, in 2005.[1] Similarly, Zarontin capsules
were discontinued by Pfizer in 2007.[2] Syrup preparations of both brands are still
available (11).
Mechanism of action :
The succinimides resemble oxazolidinediones in that they suppress the 3/sec.
spike wave EEG pattern characteristic of absence seizures. They have a dippresant effect
on the motor cortex and elevate the firing threshold of cortical neurons. In addition, the
succinimides depress inhibitory mechanisms descending from the reticular formation.
Therapeutic uses:
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1) They are drugs of choice for simple absence (petit mal ) seizures.
2) It is also used as adjunctive treatment of psychomotor and other minor motor seizures.
Adverse reaction:
Common side effect are GI distress, Drowsiness, Ataxia and Dizziness
Other adverse effect include :
CNS: Nervousness, Euphria, Hyperactivity, Aggresivness, Confusion, Dipression,
Sleep disturbance.
Ocular: Myopia, Blurred vision, Photophobia, Periorbital oedema.
Haematologic: blood dyscrasias.
Dermatologic: Urticaria, Systemic lupuserythematosus.
Others : Vaginal bleeding, Hirsutisn and swelling of the tongue.(1)
11.5 Immunostilbines:
11.5.1 Carbamazepine:
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Carbamazepine is structurally related to tricyclic antidepressant and has
actions similar to phenytoine. It is a fairly toxic agent and used for the treatment of grand
mal and psychomotor seizures in patient refractory to other less toxic drug. (7)
Fig.No.9. Structure of Carbamazepine(12)
Availability:
Carbamazepine has been sold under the names Tegretol, Biston, Calepsin, Carbatrol,
Epitol, Equetro, Finlepsin, Sirtal, Stazepine, Telesmin, Teril, Timonil, Triaminic,
Epimaz, Carbama/Carbamaze (New Zealand), Amizepin (Poland), Degranol (South
Africa).(12)
Mechanism of action:
Carbamazepine increases latency, decreases responsivety and suppresses
after discharge in polysynaptic pathways associated with cortical and limbic function. It
also reduce post titanic potentiation in addition carbazepamine has anti cholinergic, anti
depressant and muscle relaxant actions.
Therapeutic uses :
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1) Treatment of psychomotor seizures.
2) Treatment of grand mal seizures with phenytoin.
3) Adjunctive treatment of mixed seizures or complex partial seizures.
4) Relief of pain associated with trigeminal neuralgia.
Adverse reactions :
Common side effect are Drowsiness, Ataxia , Dizziness, nausea.
Other adverse reaction include :
CNS: Confusion, Incordination, Speech disturbances, Visual hallucinations,
Dipression.
Dermatologic: sweating, urticaria, Dermatits.
GI: Abdominal pain, Xerostomia.
CVS: Hypotension, Arrhythmias, AV block, hypertension, Congestive cardiac failure.
Others: Abnormal liver function, Jaundice, Osteomalasia. (7)
11.6 Benzodiazepines:
11.6.1 Clonazepam: (Clonopin)
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Clonazepam is a benzodiazepine derivative with anticonvulsant, muscle relaxant, and
anxiolytic properties. It is marketed by Roche under the trade-names Klonopin in the
United States, and Ravotril in Chile. Other names like Rivotril or Rivatril are known
throughout the large majority of the rest of the world. Clonazepam is a chlorinated
derivative of nitrazepam[3] and therefore a nitrobenzodiazepine.
Fig. No. 10. Structure of Clonazepam(13)
Availability:
Clonazepam was approved in the United States as a generic drug in 1997 and is now
manufactured and marketed by several companies.Clonazepam is available in the U.S. as
tablets (0.5, 1.0, and 2 mg) and orally disintegrating tablets (wafers) (0.125, 0.25, 0.5,
1.0, and 2 mg). In other countries, clonazepam is usually available as tablets (0.5 and
2 mg), orally disintegrating tablets (0.25, 0.5, 1 and 2 mg) oral solution (drops,
2.5 mg/ml), as well as solution for injection or intravenous infusion, containing 1 mg
clonazepam per ampoule (e.g. Rivotril inj.).
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Klonopin 0.5 mg Klonopin 1 mg
Fig. No.11.Tablets Available In Market.
Mechanism of action
Clonazepam exerts its action by binding to the benzodiazepine site of the GABA
receptors, which causes an enhancement of the electric effect of GABA binding on
neurons, resulting in an increased influx of chloride ions into the neurons. This results in
an inhibition of synaptic transmission across the central nervous system.
Benzodiazepines, however, do not have any effect on the levels of GABA in the brain.
Clonazepam has no effect on GABA levels and has no effect on gamma-aminobutyric
acid transaminase. Clonazepam does however affect glutamate decarboxylase activity. It
differs insofar from other anticonvulsant drugs it was compared to in a study.
Benzodiazepine receptors are found in the central nervous system but are also found in a
wide range of peripheral tissues such as longitudinal smooth muscle-myenteric plexus
layer, lung, liver and kidney as well as mast cells, platelets, lymphocytes, heart and
numerous neuronal and non-neuronal cell lines.
Pharmacology
Clonazepam's primary mechanism of action is via modulating GABA function in the
brain, via the benzodiazepine receptor, which, in turn, leads to enhanced GABAergic
inhibition of neuronal firing. In addition clonazepam decreases the utilization of 5-HT
(serotonin) by neurons and has been shown to bind tightly to central type benzodiazepine
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receptors. Because of its strong anxiolytic, anticonvulsant and euphoric properties, it is
said to be among the class of "highly potent" benzodiazepines. The anticonvulsant
properties of benzodiazepines are due to enhancement of synaptic GABA responses and
inhibition of sustained high frequency repetitive firing.
Benzodiazepines, including clonazepam, bind to mouse glial cell membranes with high
affinity. Clonazepam decreases release of acetylcholine in cat brain and decreases
prolactin release in rats. Benzodiazepines inhibit cold-induced thyroid stimulating
hormone (also known as TSH or thyrotropin) release. Benzodiazepines acted via
micromolar benzodiazepine binding sites as Ca2+ channel blockers and significantly
inhibit depolarization-sensitive calcium uptake in experimentation on rat brain cell
components. This has been conjectured as a mechanism for high-dose effects on seizures
in the study.
Clonazepam therapeutically used as :
Epilepsy
Anxiety disorders
Panic disorder
Initial treatment of mania or acute psychosis together with firstline drugs such as
lithium, haloperidol or risperidone
Hyperekplexia
Bruxism
Restless legs syndrome and some other forms of parasomnia ; Rapid eye
movement behavior disorder (low doses).
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Side-effects
Common
Drowsiness
Impairment of cognition, judgment, or memory
Irritability and aggression
Psychomotor agitation
Lack of motivation
Loss of libido
Impaired motor function
o Impaired coordination
o Impaired balance
o Dizziness
o Diarrhea
Cognitive impairments
o Increased sleepwalking (If used in treatment of sleepwalking)
o Auditory hallucinations
o Short-term memory loss(13)
11.7 Valproic acid derivatives :
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11.7.1 Valproic acid (sodium valproate)
It is branched chain aliphatic carboxylic acid with a broad spectrum anti
conversant action. It is more potent in blocking PTZ seizures than in modified maximal
electroshock(14)
Fig. No. 12. Structure of Valproic Acid(15)
Availability Form:
Branded products include:
Depakene (Abbott Laboratories in U.S. & Canada)
Convulex (Pfizer in the UK and in South Africa)
Deprakine (Sanofi Aventis Finland)
Epival (Abbott Laboratories U.S. & Canada)
Epilim (Sanofi Synthelabo in Australia)
Encorate (Sun Pharmaceuticals in India)
Valcote (Abbott Laboratories in Argentina)(15)
Mechanism of action :
Valproate appears to act by multiple mechanisms ……
1) A phenitoin like frequency dependant prolongation of sodium channel inactivation.
2) Weak attenuation of Ca2+ mediated current (Ethosuximide like).
3) Augmentation of release of inhibitory transmitter GABA by inhibiting its degradation
(by GABA transaminase) as well as probably by increasing its synthesis from
glutamic acid however, responses to exogenously applied GABA are not altered.
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Therapeutic uses :
1) Valproic acid is the drug of choice for absence seizures.
2) Myoclonic and atonic seizures control is often incomplete, but valproate is the drug
of choice.
4) Valproate has some prophylactic efficacy in migraine.
Adverse reaction :
The toxicity of valproate is low. Anorexia, vomiting, heart burn are common . The
drowsiness, atexia, triemor are dose relayed side effect. Alopecia, Curling of hairs and
increased bleeding tendency has been observed. The rashes and thrombocytopenia are
infrequent hypersensitivity phenomena. Used during pregnancy, It has spina bifida and
other neural tube defects in the offspring. (14)
11.8 Other unrelated anticonvulsants :
11.8.1 Primidone (mysoline):
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Primidone is an anticonvulsant of the pyrimidinedione[4] class whose active metabolites,
phenobarbital (major) and phenylethylmalonamide (PEMA) (minor), are also
anticonvulsants. It is used mainly to treat complex partial, simple partials, generalized
tonic-clonic seizures, myoclonic, akinetic seizures and since the 1980s it has been a
valuable alternative to propranolol in the treatment of essential tremor. Unlike other
anticonvulsants such as carbamazepine and valproic acid, primidone is rarely used in the
treatment of bipolar disorder or any other psychiatric problem. It is also not widely used
in treatment of neuropathic pain, trigeminal neuralgia, or migraine. Primidone has been
occasionally used to treat long QT syndrome, cerebral palsy, and athetosis.
Fig. No.13. Structure of Primidone(16)
Available forms
Primidone is available as a 250 mg/5mL suspension, and in the form of 50 mg, 125 mg,
and 250 tablets. It is also available in a chewable tablet formulation in Canada.
It is marketed as several different brands including:
Mysoline (Canada, Ireland, Japan, the United Kingdom, and the United States,
Prysoline (Israel, Rekah Pharmaceutical Products, Ltd.).
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Primidone has been available in the United States as a generic drug from Lannett since
1978.
Mechanism of action
The exact mechanism of primidone's anticonvulsant action is still unknown after over
fifty years. It is believed to work via interactions with voltage-gated sodium channels
which inhibit high-frequency repetitive firing of action potentials. The effect of
primidone in essential tremor is not mediated by PEMA.
Therapeutic uses :
, primidone is approved for adjunctive (in combination with other drugs) and
monotherapy (by itself) use in generalized tonic-clonic seizures, simple partial seizures,
and complex partimple partial seizures, and myoclonic seizures. In juvenile myoclonic
epilepsy. it is a second-line therapy, reserved for when the vaporizes and/or lamotrigine
do not work and when other second-line therapies—[acetazolamid work either].
Adverse Effects
Primidone can cause drowsiness, listlessness, ataxia, visual disturbances, nystagmus,
headache, and dizziness. These side effects are the most common, occurring in more than
1% of users. Transient nausea and vomiting are also common side effects.
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Fig. No. 14. Dupuytren's contracture of the fourth digit (ring finger).
Dupuytren's contracture, a disease of the fasciae in the palm and fingers that permanently
bends the fingers (usually the little and ring fingers) toward the palm, was first noted to
be highly prevalent in epileptic people in 1941 by a Dr. Lund, fourteen years before
primidone was on the market. Lund also noted that it was equally prevalent in individuals
with idiopathic and symptomatic epilepsy and that the severity of the epilepsy did not
matter. However, only one quarter of the women were affected vs. half of the men.
Less than 1% of primidone users will experience a rash. Compared to
carbamazepine, lamotrigine, and phenytoin, this is very low. The rate is comparable to
that of felbamate, vigabatrin, and topiramate. Primidone also causes exfoliative
dermatitis, Stevens-Johnson syndrome, and toxic epidermal necrolysis.
Fig. No. 15. Radiograph of a rickets sufferer
Primidone, along with phenytoin and phenobarbital, is one of the anticonvulsants most
heavily associated with bone diseases such as osteoporosis, osteopenia (which can
precede osteoporosis), osteomalacia and fractures. The populations usually said to be
most at risk are institutionalized people, postmenopausal women, older men, people
taking more than one anticonvulsant, and children, who are also at risk of rickets.
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Primidone is one of the anticonvulsants associated with anticonvulsant hypersensitivity
syndrome, others being carbamazepine, phenytoin, and phenobarbital. This syndrome
consists of fever, rash, peripheral leukocytosis, lymphadenopathy, and occasionally
hepatic necrosis. (16)
12. CONCLUSION
Many people with epilepsy lead productive and outwardly normal lives. Many
medical and research advances in the past two decades have led to a better understanding
of epilepsy and seizures than ever before. Advanced brain scans and other techniques
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A REVIEW OF EPILEPSY
allow greater accuracy in diagnosing epilepsy and determining when a patient may be
helped by surgery.
More than 20 different medications and a variety of surgical techniques are now
available and provide good control of seizures for most people with epilepsy. Other
treatment options include the ketogenic diet and the first implantable device, the vagus
nerve stimulator. Research on the underlying causes of epilepsy, including identification
of genes for some forms of epilepsy and febrile seizures, has led to a greatly improved
understanding of epilepsy that may lead to more effective treatments or even new ways of
preventing epilepsy in the future.
13. REFERENCE
1) http://en.wikipedia.org/wiki/epilepsy
2) http://www.patiant.w.uk/health/epilepsy-A Genaral-Introduction.htm
3) http://www.kidneeds.com/diagnostic_catagories/articles/epilepsy definition.com
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4) http:/www.epilepsy.com/epilepsy/history
5) Bodhankar S. L.,Vhywahare N. S. “pathophysiology” Nirali prakashan Pragati book
PVT. Ltd. Page no.3.4-3.5
6) http://www.epilepsiemuseum.de/alt/introen.html
7) Barar.F,S,K. “Essentials of Pharmacotherapeutics”, Chand S. and Company LTD.,
Ram Nagar,New Delhi,Page no.96-101
8) http://en.wikipedia.org/wiki/phenobarbital
9) http://en.wikipedia.org/wiki/phenytoin
10) http://en.wikipedia.org/wiki/trimethadione
11 ) http://en.wikipedia.org/wiki/ethosuximide
12) http://en.wikipedia.org/wiki/carbamazepine
13) http://en.wikipedia.org/wiki/clonazepam
14) Tripathi K, D. “Essentials of Medical Pharmacolgy” Jaypee Brothers medical
Publisher, 6th Edition, Page no. 407.
15) http://en.wikipedia.org/wiki/valproic acid
16) http://en.wikipedia.org/wiki/primidone
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