| HISTORICAL NOTE AND NOMENCLATURE
A disorder in which sleep induced an EEG pattern characterized by
"subclinical" spikes and waves occurring almost continuously during
slow sleep and appearing every night for a variable length of time
in children was reported in 1971 by Patry and coworkers under the
title of "subclinical electrical status epilepticus induced by sleep
in children" (Patry et al 1971). The disorder was later termed "electrical
status epilepticus during sleep" (Tassinari et al 1985).
The 1989 revised classification of epilepsies and epileptic syndromes
of the International League Against Epilepsy refers to this syndrome
as electrical status epilepticus during slow sleep and places the
disorder under "epilepsies and syndromes undetermined as to whether
they are focal or generalized"(Commission 1989).
CLINICAL MANIFESTATIONS
The clinical manifestations of this syndrome include:
- A heterogeneous epileptic disorder
- A deterioration of neuropsychological functions associated
with or independent from the epileptic disorder
- A deterioration of motor functions
The typical EEG pattern of continuous spikes and
waves during slow sleep is also an essential and absolute feature
for the recognition of the syndrome.
The epilepsy. The age at which the first seizure occurs ranges
between 2 months (Dalla Bernardina et al 1989) and 12 years (Bureau
1995), with a peak around 4 and 5 years (Tassinari et al 1985).
This event can be preceded by either normal psychomotor development
or abnormal signs indicating pre-existing encephalopathy, such as
hemiparesis, hemiplegia, spastic quadriplegia, diffuse hypotonia,
and ataxia.
The seizure types occurring in the disorder can be both partial
and generalized. They include unilateral or bilateral clonic seizures,
generalized tonic-clonic seizures, absences, partial motor seizures,
complex partial seizures or epileptic falls. They may occur during
wakefulness or sleep. Tonic seizures, however, never occur.
The first seizure is reported to be nocturnal and of unilateral
type in almost one half of the cases reported. At onset, the frequency
of seizure attacks is low. At the time of discovery of the typical
nocturnal EEG pattern, however, the epileptic seizures frequently
change in severity and frequency. Absences and epileptic falls herald
the appearance of continuous spikes and waves during slow sleep
and seizure frequency increases, both during wakefulness and sleep.
About 60% of patients also exhibit several types of seizures (Tassinari
et al 1985; 1992).
Neuropsychological deterioration. There is a constant and
severe deterioration in neuropsychological functions associated
with the disorder, and language capacity can be particularly affected.
Patients also may show a profound decrease in intellectual level,
poor memory, impaired temporospatial orientation, reduced attention
span, hyperkinesis, aggressive behavior, and even psychosis (Jayakar
and Seshia 1991; Tassinari et al 1992).
Motor impairment. Motor impairment, in the form of dyspraxia,
dystonia, ataxia, or unilateral deficit, has been emphasized as
one of the outstanding disturbances occurring in this syndrome (Dalla
Bernardina et al 1989; Neville et al 1998).
The characteristic feature of this disorder is the appearance of
continuous spike-wave discharges on the EEG during slow sleep.|{diagram:ecst1.bmp}{caption:Typical
case of electrical status epilepticus during slow wave sleep}{label:Continuous
and "generalized" spike waves during slow wave sleep in a 7-year-old
child.}||{video:ecst2.avi}{Caption:Electrical status epilepticus
during slow wave sleep; transition from wakefulness to sleep}{label:Left:
The patient is in the dark of the recording room. Right: The EEG
is normal during wakefulness but as soon as the patient falls asleep,
continuous and generalized spike waves appear.}| Most researchers
assert that more than 85% of NREM sleep is occupied by spike-wave
discharges; however, quantitative studies of different sleep stages
and of temporal evolution of this EEG disturbance have not been
carried out (Jayakar and Seshia 1991). The typical EEG changes appear
1 year to 2 years after the first seizure and are associated with
behavioral deterioration. Focal and generalized interictal spikes
occur before this time and persist during wakefulness and REM sleep
after the appearance of continuous spike waves during slow wave
sleep.
ETIOLOGY
The cause of electrical status epilepticus during slow sleep is
unknown. The affected children may have either normal psychomotor
development (cryptogenic cases) or abnormal signs indicating pre-existing
encephalopathy such as congenital hemiparesis, hemiplegia, spastic
quadriplegia, diffuse hypotonia, and ataxia (symptomatic cases)
before onset of the disorder. There is no increased incidence of
seizure disorders in the relatives of affected children (Jayakar
and Seshia 1991; Tassinari et al 1992).
BIOLOGICAL BASIS
The mechanism of neuropsychological impairment. Long-lasting
persistence of continuous spike waves during sleep is postulated
to be responsible for the neuropsychiatric abnormalities in electrical
status epilepticus during slow sleep. Three main arguments are in
favour of this hypothesis:
-
There is a close temporal association between
electrical status epilepticus during slow sleep and neurologic
regression (the latter beginning at the time electrical status
epilepticus during slow sleep is discovered and improving after
electrical status epilepticus during slow sleep disappearance)
(Tassinari et al 1985).
-
The duration of electrical status epilepticus
during slow sleep is correlated with the final neuropsychological
outcome (Rousselle and Revol 1995).
-
There is a strict association between the pattern
of neuropsychological derangement and the location of the interictal
focus (Rousselle and Revol 1995). A deterioration of language
is observed in cases showing the predominance of paroxysmal
abnormalities over one or both temporal regions (Billard et
al 1982), whereas a mental deterioration and an autistic behaviour
evoking a frontal lobe syndrome has been described in children
exhibiting interictal frontal foci or clear cut anterior predominance
of the discharges (Roulet Perez et al 1995). On the other hand,
causative factors for motor impairment in the form of dyspraxia,
dystonia, ataxia, or unilateral deficit observed in some children
during the period of continuous spikes and waves during slow
sleep would be a predominant involvement of motor areas by continuous
spike-wave activity and the appearance of negative myoclonus
during wakefulness (Dalla Bernardina et al 1989; Neville et
al 1998).
The above observations suggest that electrical
status epilepticus during slow sleep is a model for prolonged cognitive
impairment induced by so called "interictal paroxysmal activity"(Tassinari
1995). "Interictal paroxysmal activity" may interfere with different
cognitive processes, as demonstrated by neurophysiological, neuropsychological,
and biochemical studies (Binnie 1993; Wasterlain et al 1993; Seri
1998). There is now increasing evidence that many autistic children
with a history of language regression have epileptiform abnormalities,
suggesting a role of subclinical epileptic discharges in relatively
common developmental syndromes of infancy (Ballaban-Gil et al 1998;
Goldberg et al 1998; Sotero De Menezes et al 1998).
The mechanism generating electrical status epilepticus during
slow sleep. Secondary bilateral synchrony is the mechanism underlying
continuous spikes and waves during slow sleep. In this respect the
apparently generalized seizures (absences, tonic-clonic attacks)
occurring in this condition have, in fact, a focal onset (Tassinari
1995), as demonstrated by interhemispheric peak latencies of their
EEG correlates (Morikawa et al 1989; Morrell 1995), phase reversal
of spikes on unilateral frontal regions (Morikawa et al 1985), and
studies of coherence and phase analyses (Kobayashi et al 1990; 1994).
A localized metabolic abnormality has been also revealed by means
of PET studies (Maquet et al 1990). Therefore, although electrical
status epilepticus during slow sleep is currently classified among
the epilepsies undetermined whether focal or generalized, consistent
data support the view that this syndrome is to be included in the
domain of localization-related epilepsies, of cryptogenic or symptomatic
nature.
EPIDEMIOLOGY
Electrical status epilepticus during slow sleep is a rare disorder.
One study revealed an incidence of 0.5% among 12,854 children evaluated
during a 10-year period (Morikawa et al 1989). There is no obvious
gender preponderance (Tassinari et al 1985).
PREVENTION
No information is available.
DIFFERENTIAL DIAGNOSIS
Lennox Gastaut syndrome. In the presence of atypical absence
seizures, deterioration of intellectual levels, and behavioral and
language disturbances, electrical status epilepticus during slow
sleep can be confused with the Lennox-Gastaut syndrome. The distinguishing
features include the characteristic EEG pattern, as well as the
following: (1) partial motor seizures often occur in electrical
status epilepticus during slow sleep but are rare in Lennox-Gastaut
syndrome; (2) tonic seizures occur commonly in Lennox-Gastaut syndrome
but are essentially absent in electrical status epilepticus during
slow sleep; and (3) in electrical status epilepticus during slow
sleep, seizure frequency declines over the course of the illness,
whereas seizures usually remain frequent throughout the evolution
of the Lennox -Gastaut syndrome.
Acquired epileptic aphasia. The distinction between electrical
status epilepticus during slow sleep and the Landau-Kleffner syndrome
or acquired epileptic aphasia is disputed. All-night EEGs reveal
that many children diagnosed with the Landau-Kleffner disorder actually
have the electrical status epilepticus during slow sleep. In Landau-Kleffner
syndrome, however, acquired aphasia is the most predominant neuropsychological
symptom; bilateral temporal EEG spikes are present but epileptic
seizures do not always occur. In our opinion, electrical status
epilepticus during slow sleep and Landau Kleffner syndrome are two
facets of a same entity, in which the type of neuropsychological
dysfunction depends on the location (frontal in continuous spike
and waves during slow wave sleep and temporal in Landau Kleffner
syndrome) of interictal foci (Tassinari 1995; De Negri 1997).
Benign epilepsy with rolandic spikes. Both benign childhood
epilepsy with centrotemporal spikes and epilepsy with continuous
spikes and waves discharges during slow wave sleep commonly present
with nocturnal seizures, interictal focal spikes on the EEG, and
a marked activation of the discharges during sleep. The diagnosis
of benign childhood epilepsy is usually made apparent by the characteristic
interictal EEG spike morphology and the absence of severe behavioral
deterioration. However, when neuropsychological impairment or motor
impairment or both occurs in patients with a diagnosis of benign
epilepsy with rolandic spikes, the electrical status epilepticus
during slow sleep pattern should be looked for and is usually present
(Dalla Bernardina et al 1989; Colamaria et al 1991).
DIAGNOSTIC WORKUP
After the seizures appear, but before the continuous spike waves
during slow wave sleep develop, the EEG during wakefulness may show
both diffuse spike waves, sometimes in bursts, and focal abnormalities
such as spikes and slow spikes, with or without associated slow
waves, which usually involve the frontotemporal or the centrotemporal
region. Sleep EEG performed at an early stage shows an increase
of the aforementioned abnormalities without the features of the
continuous spike waves during slow wave sleep (Tassinari et al 1985).
After "electrical status" develops, the wakeful EEG patterns do
not differ much from the previous ones, except that both the diffuse
and focal abnormalities tend to increase in frequency. Tassinari
and coworkers emphasized the occurrence of diffuse spike waves at
2- to 3-Hz, organized in bursts, with or without clinical manifestations
(Tassinari et al 1985; 1992). When the affected child falls asleep,
however, the characteristic continuous bilateral and diffuse slow
spike waves (electrical status) appear abruptly, lasting throughout
almost the entirety of slow wave sleep. The spike-wave index ranges
from 85% to 100%. Cases with relatively focal albeit continuous
discharges mainly involving the temporal or frontal regions or markedly
asymmetrical spike-wave activity over the two hemispheres have been
also described (Billard et al 1982; Morikawa et al 1985).
During REM sleep, electrical status disappears suddenly and paroxysms
become either bursts of diffuse spike waves or focal, predominantly
frontal, discharges. The cyclic organization of sleep, however,
in which NREM sleep occupies 80% and REM 20% of the sleeping period,
remains grossly unchanged.
Diagnosis of electrical status epilepticus during slow sleep can
be suspected with brief sleep recordings but all-night sleep recordings
are highly recommended. Computed tomography may be unremarkable
or show unilateral or bilateral atrophic features (Morikawa et al
1985).
PROGNOSIS AND COMPLICATIONS
The seizures in electrical status epilepticus during slow sleep
are self-limited and disappear in the mid-teens. The good seizure
outcome is independent of the etiology and is observed also in cases
with cortical malformations such as multilobar polymicrogyria (Guerrini
et al 1998). The characteristic EEG patterns during slow wave sleep
also disappear at approximately the same time, but focal interictal
spikes may persist (Morikawa et al 1989; Bureau 1995). Improvement
in language dysfunction, mental retardation, and psychiatric disturbances
generally occurs but is variable and individualized. The majority
of affected children never return to normal levels, particularly
in the verbal area and attention (Roulet Perez et al 1993; Morikawa
et al 1985).
MANAGEMENT
Epileptic seizures may or may not respond to a variety of drugs
including benzodiazepines, valproate, ethosuximide, carbamazepine,
and phenytoin. Despite the fact that the seizures may be refractory
to therapy for months to years, the long-term prognosis of epilepsy
is favorable with disappearance of seizures in all cases. Only benzodiazepines
and adrenocorticotrophic hormone have been reported to suppress
the electrical status and perhaps to improve language function.
However, the positive effects are often transient (Tassinari et
al 1985). In individual cases, chronic oral treatment with clobazam,
lorazepam, and clonazepam, associated with other antiepileptic drugs,
usually valproate, seemed to have a long-lasting effect (Yasuhara
et al 1991). Short cycles (3 to 4 weeks) of relatively high daily
doses of diazepam (0.5 mg/kg) following a rectal diazepam bolus
of 1 mg/kg have also been reported to be effective (De Negri 1997).
At the present time, the combined use of benzodiazepines and valproate
is considered the treatment of choice in this condition. On the
other hand, polytherapy should be avoided. A detailed evaluation
of antiepileptic regimens in 88 patients demonstrated that the reduction
in polytherapy coincided with an improvement of the syndrome (Van
Lierde 1995). It was also suggested that the drug overload and some
medications (such as carbamazepine) could play a role in the maintenance
of continuous spikes and waves during slow sleep (Van Lierde 1995).
In cases of electrical status epilepticus during sleep with severe
language impairment, a progressive and long-lasting improvement
of the language function has been obtained applying the surgical
procedure of multiple subpial transections in the region of focal
epileptic discharges (Morrell 1995).
PREGNANCY
No information is available.
ANESTHESIA
No information is available.
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