Status Epilepticus



Status Epilepticus


Jaishree Narayanan

Catherine A. Phillips



Definition and Classification

Status epilepticus (SE) was originally defined as seizures lasting longer than 30 minutes, or 30 minutes of recurrent seizures without return to baseline neurologic status between events [1]. This has been largely replaced by an operational definition of SE, which is a 5-minute duration of continued seizure activity, or two or more seizures between which there is incomplete recovery. SE is considered to be a condition in which there is “a failure of the ‘normal’ factors that serve to terminate a typical generalized tonic-clonic seizure” [2,3]. This approach is more clinically appropriate and promotes early treatment with antiepileptic medication. SE is usually divided into: (a) convulsive SE, in which the patient does not regain consciousness between repeated generalized tonic-clonic attacks; (b) simple partial SE, characterized by continuous or repetitive focal seizures without loss of consciousness [4]; and (c) nonconvulsive SE (NCSE), such as absence or complex partial SE, characterized by a prolonged confusional state of 30 minutes or longer. NCSE is also used to describe continued seizure activity in patients who have few or no clinical signs other than coma.


Convulsive Status Epilepticus

Most generalized tonic-clonic SE consists of partial seizures that have secondarily generalized; primary generalized SE is less common [5]. Most patients do not convulse continuously. Instead, seizures of a few minutes’ duration may be followed by a prolonged period of unconsciousness that leads to the next seizure. During convulsive SE, massive autonomic discharge occurs with tachycardia and hypertension. Corneal and pupillary reflexes are lost and plantar reflexes may be extensor. As SE continues, the motor manifestations may evolve into more subtle activity such as low-amplitude focal twitching, nystagmus, eye deviation, or recurrent pupillary hippus. This is sometimes called subtle generalized SE [4]. SE may also present in this more subtle form, without initial convulsive activity, in patients who are very encephalopathic; electroencephalography (EEG) is required to confirm the diagnosis. Myoclonic SE is often classified as a form of convulsive SE; it can occur in children with chronic epilepsy and mental retardation. It is characterized by repetitive, asynchronous myoclonus with variable clouding of consciousness and may evolve into generalized tonic-clonic SE. In adults, the myoclonic syndromes that occur are usually secondary to toxic or metabolic encephalopathies, most commonly severe cerebral anoxia [6]. The patients are usually comatose, and the prognosis is poor. In both forms of myoclonic SE, the EEG shows repetitive generalized epileptiform discharges.


Simple Partial Status Epilepticus

Simple partial status epilepticus is the second most common form of SE, after generalized tonic-clonic SE [4]. In partial motor SE, focal clonic or tonic-clonic activity is localized to the face or an extremity. This activity may spread, corresponding to the somatotopic organization of the motor cortex, known as a Jacksonian march. Alternatively, the partial motor seizures may be multifocal, in this case often precipitated by metabolic disorders, such as hyperglycemia with a hyperosmolar nonketotic state [7]. Epilepsia partialis continua refers to a form of partial motor SE characterized by continuous, highly localized seizures that do not secondarily generalize and in which consciousness is maintained.


Nonconvulsive Status Epilepticus

NCSE is an under-recognized cause of coma. In a recent study, NCSE was documented in 8% of all comatose patients, without signs of seizure activity [8]. In additional studies, 31% to 37% of patients with unexplained altered mental status in intensive care units were in NCSE. NCSE is more likely to occur in the setting of acute medical problems, both systemic and neurologic [8,9,10].

Nonconvulsive SE includes absence and complex partial SE [4]. Clinically, both absence and complex partial SE present with a prolonged period of altered behavior and can masquerade as a psychiatric fugue state. Absence SE involves a variable level of altered consciousness, which may be accompanied by subtle myoclonic movements of the face, eye blinking, and occasional automatisms of the face and hands. The EEG is diagnostic, revealing continuous or discontinuous generalized spike and slow-wave activity. Complex partial SE involves either a series of complex partial seizures with staring, unresponsiveness, and motor automatisms, separated by a confusional state, or a more prolonged state of partial responsiveness and semipurposeful automatisms. In both of these forms of SE, the patient is partially or totally amnestic for the episode.


Etiology

Some of the major underlying etiologies and precipitants of SE are shown in Table 172.1. Precipitants are factors that provoke SE where it otherwise would not have occurred, but they are not the underlying cause of the seizure disorder. Symptomatic SE, defined as SE resulting from an acute or chronic neurologic or metabolic insult, is typically more common than idiopathic SE (presumed genetic etiology for the seizures in an otherwise neurologically normal person) [5]. In most series, at least two-thirds of cases of SE are symptomatic. In adults, a major cause of SE is stroke, comprising more than 25% of the cases in one series [5]. Decreasing antiepileptic drugs was also a significant cause of SE in this same series, occurring in approximately 20% of the cases. Other major causes include alcohol withdrawal, anoxia, metabolic disease, viral encephalitis including Epstein–Barr virus or herpes simplex virus, HIV infection, and drug abuse [11,12]. The acute insults can cause SE in patients with or without epilepsy. Children younger than 1 year and adults older than 60 years represent the populations most at risk for developing SE [5].









Table 172.1 Etiologies and Precipitants of Status Epilepticus




Etiologies
   Structural brain lesion
      Brain trauma
      Brain tumors
      Strokes
      Hemorrhage
   Central nervous system infections
      Encephalitis
      Meningitis
   Toxic
      Drugs (e.g., theophylline, lidocaine, penicillin)
      Withdrawal states (e.g., alcohol, barbiturate)
   Metabolic
      Hypocalcemia
      Hypomagnesemia
      Hypoglycemia, hyperglycemia
      Hyponatremia
      Hyperosmolar state
      Anoxia
      Uremia
Precipitants
   Changes in anticonvulsant blood levels
      Errors in medication
      Change in drug regimens
      Altered drug absorption
      Noncompliance
   Intercurrent infection
      Fever (e.g., upper respiratory or gastrointestinal infections)
   Alcohol withdrawal


Prognosis and Sequelae of Status Epilepticus

Mortality in SE depends on the specific etiology, duration of the episode, and the age of the patient [13]. The acute insult triggering SE is one of the most important factors influencing mortality. Among the etiologic groups, anoxia has been associated with the highest mortality rate, followed by hemorrhage, tumor, metabolic disorders, and systemic infection. Alcohol withdrawal and antiepileptic drug discontinuation have been associated with a low mortality rate. Patients with idiopathic SE have a low mortality rate. The duration of SE strongly affects the ultimate prognosis. In one study, patients with seizure duration of longer than 60 minutes had a mortality of 32.0%, whereas patients with seizure duration of shorter than 60 minutes had a mortality of 2.7% [13]. Age is significantly associated with mortality, with patients above the age of 70 having a dramatically greater mortality [5,13,14]. Despite improved medical care, convulsive SE still has an overall mortality rate in the range of 7% to 25% [5,13,14,15]. The mortality of complex partial SE was 18% in one study [16]. Other adverse outcomes include intellectual deterioration, permanent neurologic deficits, and chronic epilepsy.

SE itself can produce profound neuronal damage. Neuropathologic studies of the brains of children and adults who died shortly after SE reveal ischemic neuronal changes in the hippocampus, middle layers of the cerebral cortex, cerebellum (Purkinje cells), basal ganglia, thalamus, and hypothalamus [17]. These changes mimic those of severe hypoxia or hypoglycemia. The degree of hyperthermia during an episode of SE has also been shown to correlate closely with the degree of central nervous system (CNS) damage [18].

The perpetuation of SE is most likely caused by an imbalance between excitotoxic (primarily mediated by glutamate) and inhibitory (primarily mediated by γ-aminobutyric acid [GABA]) mechanisms [15,16]. This can be related to downregulation in GABA receptors or excitotoxic mechanisms involving glutamate receptors—both NMDA (N-methyl-D-aspartate) and non-NMDA receptors [3,15,19]. Calcium influx during excitation appears to be a critical component of neuronal injury and cell death, with activation of proteases and lipases leading to degradation of intracellular elements [19].

Abnormal neuronal activity alone can cause permanent neurologic injury. This is supported by the observation that patients with complex partial or partial motor SE who do not have concomitant hypotension, hypoxia, or hyperpyrexia can still have subsequent neurologic injury in the region of the brain associated with the seizure. Chronic memory impairment may follow complex partial SE [20], and focal neuronal necrosis (and edema) in the region of the brain involved with seizure activity has been found after partial motor status [21,22]. Focal magnetic resonance imaging (MRI) changes can be seen after prolonged epileptic activity, particularly on diffusion-weighted and perfusion MRI [23].

The natural history of NCSE is not well defined, especially mortality and morbidity. This is partly due to methodological issues, such as the lack of a uniform accurate definition of NCSE, and not assigning appropriate significance to the underlying etiology, mental status changes, and associated complications [24,25,26]. Kaplan [27,28] reviewed the prognosis of NCSE and suggested that prognosis depends not only on detailed assessment of NCSE type, but also on level of consciousness. In another study designed specifically to determine the rate of morbidity and mortality, mortality was associated with an acute medical cause as the underlying etiology, severe mental status impairment, and development of acute complications, but not the type of EEG changes [10].

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Sep 5, 2016 | Posted by in CRITICAL CARE | Comments Off on Status Epilepticus

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