INTRODUCTION	Section 2 of 11
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Background: Absence seizures are a type of generalized seizures. They were first described Poupart in 1705, and later by Tissot in 1770, who used the term petit access. In 1824, Calmeil used the term absence. In 1935, Gibbs, Davis, and Lennox described the association of impaired consciousness and 3-Hz spike-and-slow-wave complexes on electroencephalograms (EEGs).

Absence seizures occur in both idiopathic and symptomatic generalized epilepsies. Among the idiopathic, or primary, generalized epilepsies (ie, with age-related onset), absence seizures are seen in childhood absence epilepsy (CAE, or pyknolepsy), juvenile absence epilepsy (JAE), and juvenile myoclonic epilepsy (JME, or impulsive petit mal seizures). The seizures in these conditions are called typical absence seizures and usually associated with 3-Hz spike-and-slow-wave complexes on EEG. In CAE, seizures are frequent and brief, lasting just a few seconds (pyknoleptic). Some children can have hundreds of such seizures per day. In other epilepsies, particularly those with an older age of onset, the seizures can last several seconds to minutes and may occur only a few times a day (called nonpyknoleptic or spanioleptic absence seizures). Myoclonic and tonic-clonic seizures may also be present, especially in syndromes with an older age of onset. In these syndromes, the discharge frequency may be faster than 3 Hz.

In the symptomatic generalized epilepsies, absence seizures are often associated with slow spike-wave complexes of 1.5-2.5 Hz; these are also called sharp-and-slow-wave complexes. These seizures are termed atypical absence seizures.

Pathophysiology: The etiology of idiopathic epilepsies with age-related onset is genetic. About 15-40% of patients with these epilepsies have a family history of epilepsy; concordance in monozygotic twins is 75%. Family members may have other forms of idiopathic or genetic epilepsy (eg, febrile convulsions, generalized tonic-clonic [GTC] seizures).

Several animal models demonstrate the genetic basis for absence seizures. A strain of Wistar rat, ie, genetic absence epilepsy rats from Strasbourg (GAERS), is a polygenetic model in which all animals have clinical seizures consisting of a behavioral arrest with twitching of facial muscles. This is associated with bilateral synchronous spike-wave discharges. Several single-gene loci in mice, when mutated, result in generalized spike-wave epilepsy. The tottering (chromosome 8), lethargic (chromosome 2), stargazer (chromosome 15), mocha (chromosome 10), and ducky (chromosome 9) loci all have generalized 6-per-second spike-wave EEG paroxysms that are associated with clinical seizures consisting of behavioral arrest. All types respond to ethosuximide (ETX), but the underlying cellular mechanisms for the generation of the discharges are not identical.

Several mutations of genes which encode protein subunits in various ion channels have been found in patients and family members with idiopathic epilepsies. Some forms of JME and absence epilepsy have been shown to result from mutations in Ca⁺⁺ channels.

In symptomatic generalized epilepsies, absence seizures are due to a wide variety of causes that, at an early stage of neural development, result in diffuse or multifocal brain damage. The causes of secondary generalized epilepsies and the other seizure types that accompany them, and their management, are not discussed in this article.

The pathophysiology of absence seizures is not fully understood. In 1947, Jasper and Droogleever-Fortuyn electrically stimulated nuclei in the thalami of cats at 3 Hz and produced bilaterally synchronous spike-and-wave discharges on EEG. In 1953, bilaterally synchronous spike-and-wave discharges were recorded by using depth electrodes placed in the thalamus of a child with absence seizures.

In 1977, Gloor demonstrated that the bilaterally synchronous 3-Hz spike-wave discharges in the feline penicillin model of absence seizures were generated in the cortex. This led to the corticoreticular theory of primarily generalized seizures.

Abnormal oscillatory rhythms are believed to develop in thalamocortical pathways. This involves GABA-B–mediated inhibition alternating with glutamate-mediated excitation. The cellular mechanism is believed to involve T-type calcium currents. T channels of the GABAergic reticular thalamic nucleus neurons appear to play a major role in the spike-wave discharges of the GABAergic thalamic neurons. GABA-B inhibition appears to be altered in absence seizures, and potentiation of GABA-B inhibition with tiagabine (Gabitril), vigabatrin (Sabril), and possibly gabapentin (Neurontin) results in exacerbation of absence seizures. Enhanced burst firing in selected corticothalamic networks may increase GABAB receptor activation in the thalamus, leading to generalized spike-wave activity.

Frequency:

• In the US: The incidence is 1.9-8 cases per 100,000 population.

Mortality/Morbidity:

• No deaths result directly from absence seizures. Accidents from driving or operating dangerous machinery during absence may result in death. In children with absence seizures due to secondary generalized epilepsies, death is related to the underlying disease.

• The morbidity from typical absence seizures is related to the frequency and duration of the seizures, as well as to the patient's activities; effective treatment ameliorates these factors. Educational problems and behavioral problems are sequelae of unrecognized, frequent seizures.

Race: No racial predilection is known.

Sex:

• Absence seizures are generally believed to be more common in females and in males, with some studies showing a 2:1 female-to-male ratio. Other studies have shown no difference between the sexes.

• Absence epilepsy with myoclonus has a male predominance.

Age: The generalized idiopathic epilepsies have age-related onset. Onset of absence seizures in children with symptomatic generalized epilepsies depends on the underlying disorder. While many of these disorders may have their onset at an early (prenatal, perinatal, or postnatal) age, absence seizures do not appear until later in childhood.

An example is the Lennox-Gastaut syndrome. The cause may be a genetic disorder or a perinatal insult, but the absence seizures do not present until age 1-8 years.

• CAE onset is at age 4-8 years, with peak onset at age 6-7 years.

• JAE onset is at age 7-14 years, with peak onset at age 10-12 years. Onset of JAE with myoclonus averages about age 7 years.

• JME has a more varied age of onset (8-26 y), but 79% of patients have an onset at age 12-18 years. Because the absence and myoclonic seizures are brief, they often go unrecognized, and many patients do not present until they experience a tonic-clonic seizure.

	CLINICAL	Section 3 of 11
Author Information Introduction Clinical Differentials Workup Treatment Medication Follow-up Miscellaneous Pictures Bibliography

History:

• Children with idiopathic generalized epilepsies may present with a history of staring spells, but infrequent absence seizures may not be diagnosed until a GTC seizure has occurred.

• Other symptoms, such as behavioral problems, may be the presenting complaint. Although the brief attacks are unrecognized, the lapses of awareness interfere with following up what is happening; as a result, the child becomes frustrated.

• Decline in school performance may be an indication of the onset or breakthrough of absence seizures.