Neonatal seizure
Neonatal seizure | |
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Other names | Seizures in neonates |
A neonatal seizure is a seizure in a baby younger than age 4-weeks that is identifiable by an electrical recording of the brain.[1] It is an occurrence of abnormal, paroxysmal, and persistent ictal rhythm with an amplitude of 2 microvolts in the electroencephalogram,[2] detected in infants younger than 4 weeks. These may be manifested in form of stiffening or jerking of limbs or trunk. Sometimes random eye movements, cycling movements of legs, tonic eyeball movements, and lip-smacking movements may be observed. Alteration in heart rate, blood pressure, respiration, salivation, pupillary dilation, and other associated paroxysmal changes in the autonomic nervous system of infants may be caused due to these seizures. Often these changes are observed along with the observance of other clinical symptoms.[3] A neonatal seizure may or may not be epileptic. Some of them may be provoked by stimulation or suppressed by restraining them.[3]
According to the International League against Epilepsy (ILAE), seizures are basically abnormally excessive or synchronous neuronal activity in the brain that is manifested as signs or symptoms. This definition, however, excludes the electrographic-only seizures that comprise 40-60% of that found in critically ill neonates.[4] As per the classification system by the American Clinical Neurophysiology Society, seizures can be classified into electroclinical, clinical only, and electrographic-only seizures.[5]
Neonatal seizures have been classified into various types depending on various parameters. The earlier classification system, focused more on differentiating these neonatal seizures from those experienced in adult children. Neonates were found to experience either tonic or clonic seizures. They did not experience tonic-clonic seizures. If seizures were found to be focal, they were further classified into unifocal or multifocal.[6] Seizures in the neonatal population can be mainly categorized into acute symptomatic seizures and neonatal epilepsy that is related to genetic or structural factors.[7] Brain injury due to hypo-ischemic encephalopathy, ischemic stroke, intracranial hemorrhage or infection, inborn errors of metabolism, transient metabolic and brain malformations, lead to acute symptomatic seizures.[8] Neonatal epilepsy may be credited to genetic syndromes, developmental structural brain abnormalities, or metabolic diseases.[9] All the classification systems are found to be highly useful clinically.
The incidence of seizures is more common in the neonatal stage than in other stages of life.[10] Neonatal seizures are comparatively rare and affect 1 or 3.5 in 1000 infants born.[11] They are the most frequent neurological problem in the nursery that is associated with greater risks of morbidity and mortality,[12][13] often requiring evaluation and treatment in a neonatal intensive care unit. Better care delivered in neonatal care units, with improved healthcare facilities, has decreased the mortality rate associated with these seizures. However, the long-term morbidity rate remains approximately the same.[14] The increased risk of neonatal seizures may be attributed to risks related to delivery, gestation, post-natal period, and physiological factors.
Neonatal seizures are generally subclinical and their diagnosis based on the clinical observations is generally difficult.[15][16] Especially the seizures that involve senses are hard to detect in neonates. Diagnosis relies on identification of the cause of the seizure, and verification of actual seizure activity by measuring electrical activity with electroencephalography (EEG). The set of guidelines developed by the American Clinical Neurophysiology Society helps the healthcare providers know when the EEG is appropriate and corresponds to the seizures.[17] Treatment depends generally on the underlying cause of the seizure. Administration of deficient chemicals that lead to seizures treats it but if it still persists and is confirmed by EEG, pharmacologic treatment with anti-epileptic drugs is administered.
The considerable debate about the long-term consequence of a neonatal seizure exists between data and deductions reached through animal experimentations and those obtained through clinical investigations. The main conflicting issues are whether seizures in newborns can plant the roots for epileptogenesis and cause long-term deficits.[18] Fewer than half of the affected infants develop seizures in later life. Such neonatal seizures are considered self-limited, and thus the term neonatal epilepsy is not used to describe these seizures. It has been estimated that approximately 15% of neonatal seizures represent epilepsy syndrome.[19] The incidence of neonatal seizures has not been clearly established, although an estimated frequency of 80-120 cases per 100,000 neonates per year has been suggested. The incidence of seizures is higher in the neonatal period than at any other time of life,[20] and most often occurs in the first week of life.[21]
Signs and symptoms
Seizures in the neonatal population often present differently than in other age groups due to brain immaturity.[22] Electroclinical seizures are defined by evidence of seizure activity on electroencephalogram as well as clinical signs or symptoms.[23] However, in neonates, there may be no clinical movement abnormality (either because the seizures are subclinical or because they were not witnessed), so the only symptom may be the abnormal level of consciousness. When motor movements do occur, they cannot be suppressed by gentle restraint by a nurse or caregiver.
MOTOR SEIZURES:
Classification systems have been developed based on neonatal seizure motor manifestations, summarized below.[24]
- Focal or multifocal clonic
Clonic seizures are defined by repetitive contractions of groups of muscles, typically of the limbs, face, or trunk.[25] These may involve one group of muscles (focal) or multiple groups of muscles (multifocal). An isolated focal seizure can move or spread, and can even alternate from one side of the body to the other. If they occur on both sides of the body, they may occur simultaneously in an asynchronous manner.[26] If a multifocal seizure, is limited to muscles of one side of the body, it may occur synchronously or asynchronously.[26] Focal clonic seizures cannot be suppressed by repositioning of limbs or by physical suppression.[27] Due to the neonatal brain's immaturity, the typical Jacksonian march may not occur. Focal seizures typically have very close correlates on EEG, with measurable EEG abnormalities with each seizure movement. The rhythm of the clonic movements and EEG abnormalities is usually slow, at 1-3 movements per second.
- Focal tonic
Focal tonic seizures are characterized by sustained muscle contraction of facial, limb, axial, and other muscle groups. It often involves asymmetric positioning of the neck and trunk and appears as abnormal posturing of a single limb. Horizontal eye deviation may or may not be involved.[27] They may be symmetric, asymmetric, focal, or multifocal. Such seizures cannot be provoked by stimulation or suppressed by restraint.
- Generalized tonic
A focal tonic seizure can generalize, or the first seizure can occur as a generalized seizure, or seizures that impair the neonate's level of consciousness. Generalized tonic seizures typically appear as symmetric and sustained posturing of limbs in either an extensor or flexor distribution. Generalized tonic seizures often manifest with the tonic extension of the upper and lower limbs and also may involve the axial musculature in an opisthotonic fashion. Generalized tonic seizures mimic decorticate posturing; the majority are not associated with electrographic seizures.Such seizures can be initiated by stimulation and can be suppressed by restraint.
- Myoclonic
Myoclonic movements can either be caused by seizures or be benign neonatal sleep myoclonus, a common mimicker of seizures in neonates. Myoclonic seizures are characterized by isolated and fast contractions of muscle groups that are non-repetitive. It generally involves flexor muscle groups of upper extremities- trunk, diaphragm, face.[28] These movements typically occur in the limbs or face. Stimulation can provoke myoclonic seizures.
- Spasms
Spasms include either flexor or extensor or both flexor and extensor. These occur in clusters and cannot be provoked by stimulation or suppressed by restraint.[3]
SUBTLE
Some clinicians use the term subtle seizures to describe seizures that appear to be more normal and there is an absence of distinct tonic or clonic movements but the presence of abnormal eye movements, stereotyped lip-smacking, or apneic events.[29] They are often overlooked and are generally assumed to be non-epileptic.[29] The random eye movement in them may be stimulated or increased by tactile stimulation while the progression movements such as bicycling, swimming, etc. can be restrained by repositioning.[26] Both the progression movements and oral-buccal lingual movements can be intensified and provoked upon stimulation.[26] Sometimes in subtle seizures complex limbic hyperactivity that is purposeless along with crying could be observed.[29]
BENIGN
Benign neonatal seizures are not classified as epilepsy.[30] A benign familial neonatal seizure onsets as early as 3 days of birth and may involve one or both sides of the brain.Recurrent seizure episodes are observed to occur in neonates.Electroencephalogram of infants with BFNS often have normal readings.Sometimes, they may show theta pointy, a specific abnormality. They usually begin with tonic stiffening accompanied by apnea.Later clonic jerks are witnessed.Electroencephalogram of infants with BFNS often have normal readings.Sometimes, they may show theta pointy, a specific abnormality.It occurs in 1 in every 1,00,000 newborns.[31]
This condition is usually inherited and is passed on in autosomal dominant manner. This condition is also caused due to mutation in KCNQ2 or KCNQ3 gene that may be carried by people bearing no family history of benign familial neonatal seizure. Mutation in these genes lead to excessive excitiability of neurons. Generally, patients with it are seen to bear mutation in KCNQ2 gene.[31]
Most of the infants with BFNS develop normally but some neonates with it may later develop intellectual disability which becomes evident in early childhood.In some patients approximately 15%, epilepsy occurs once in life after seizures associated with BFNS are gone away. Myokymia is also witnessed in a few cases.[31]
Pathophysiology
During the neonatal developmental stages, numerous pathophysiological mechanisms, lead to excessive excitation and reduced inhibition, which lowers their seizure threshold when compared with that of adults. This has been proved in animal(rodent) models wherein the adult and infant models are administered with the chemoconvulsant agent and their threshold seizure potential is compared.[32] This lowered seizure threshold potential makes the neonatal brain susceptible to acute symptomatic seizures.
- SEIZURE RISK DUE TO DECREASED INHIBITION: Gamma-butyric acid (GABA) is the main inhibitory neurotransmitter in adult humans. Upon binding with its receptor i.e. GABAa, it causes hyperpolarisation of the neuronal membrane by causing the net influx of chloride ions. This hyperpolarisation leads to inhibition of further action potentials. However, in neonates, there is a relatively high expression of NKCC1(sodium-potassium-chloride cotransporter 1) than KCC2(potassium-chloride cotransporter 2). NKCC1 causes net efflux of chloride ions[33] while KCC2 is responsible for causing a net influx of chloride ions. Increased expression of NKCC1 leads to depolarisation of the neuronal membrane. This depolarisation removes voltage-dependent Mg from N-methyl-D-aspartate(NMDA) receptors and triggers calcium influx. The binding of calcium to the receptors causes the generation of secondary messengers that increases the risks of seizures and increase the excitability of the brain.[34][35]
- SEIZURE RISK DUE TO INCREASED ACTIVATION: Glutamate is the primary excitatory neurotransmitter and the expression of its receptor is developmentally regulated.[36] It binds to NMDA receptors, kainite receptors, and AMPA receptors. In course of the developmental stages, in several parts of the brain, a subunit of NMDA receptor-GluN2B is highly expressed which increases calcium influx. This mechanism increases the duration of postsynaptic currents in the immature brain in comparison to adult brains.[37]
Causes
Neonatal seizures have a number of causes. Determining the cause of a confirmed seizure is important because treatment and prognosis vary based on underlying etiology of the seizure. In contrast to seizures that occur in other age groups, seizures that occur during the neonatal period are most often caused by the following processes:
- Hypoxic-Ischemic Encephalopathy: This is the most common cause of seizures in the neonatal period[38] and is an underlying cause for 40-45% of neonatal seizures. The onset of seizure associated with it occurs within first 12 to 24 hrs of life. In HIE, identification of occurrence of seizure is important as it occurs in approximately 25-50℅ of people with this condition. If it's not diagnosed it may further increase the brain injury. Seizure semiology and severity varies with the location and size of injured region of the brain. Use of EEG becomes extremely necessary for seizure cases that are subclinical.
- Perinatal Arterial Stroke: Arterial stroke can be caused by intra-arterial thrombosis or embolism from the heart or placenta. The risk for perinatal arterial stroke increases with a variety of conditions that occur due to material factors during birth (oligohydramnios, chorioamnionitis, placental abnormalities) or neonatal factors (clotting disorders, congenital heart defects,[38] coagulation problems, systemic infection, male sex, placental abnormalities). The onset of seizures associated with focal strokes begin after 24hrs to 48 hrs of birth. Focal clonic seizure is generally associated with it due to involvement of motor cortex in middle cerebral artery region.
- Intraventricular hemorrhage: It causes generally causes seizures in term infants except large hemorrhage involving injury to parenchyma.
- Central Nervous System Infection: CNS Infection are found in 3-10% of neonates who seize, though exact incidence varies between studies.[38] Bacterial meningitis and viral meningoencephalitis are most prevalent, though fungal infections can occur in antenatal, perinatal and prenatal brain of neonates. Infections caused due to late streptococcus B and herpes simplex virus often occur at any time during the neonatal period. Lumbar puncture help in diagnosis of neonates suspected of it. In case of the infant is unstable for it, empirical treatment of meningoencephalitis is warranted. Seizures related to it persist longer than those associated with HIE or ICH.
- Congenital central nervous system malformations: Lissencephaly, polymicrogyria, and tuberous sclerosis are specific entities known to cause seizures due to defects in brain tissue development. Since prognosis is poor and often these disorders are genetic, identification of this etiology is of utmost importance to be able to counsel parents appropriately.
- Inborn errors of metabolism: Inborn errors of metabolism can cause physiologic conditions that result in seizures. These errors are genetic and often are accompanied by other symptoms such as lethargy, poor feeding, and low tone.[38] Diagnosis often involves specific laboratory tests of metabolic products as well as genetic tests. Several classification systems exist for seizures caused by inborn errors of metabolism, one of which separates causes into problems with neurotransmitter metabolism, energy production, and biosynthetic substances crucial for brain formation.[39]
- Electrolyte abnormalities: Metabolic abnormalities such as hypoglycemia, hyponatremia, and hypocalcemia can manifest as seizures.
- Substance-Related: Neonatal abstinence syndrome occurs when maternal drug use before birth results in a fetal withdrawal syndrome. Substances include alcohol, cocaine, narcotics, tricyclclic antidepressants, or other sedatives. Seizures can be prevented from occurring if the symptoms of withdrawal are recognized and treated early.[38]
Diagnosis
Seizure activity in a neonate is difficult to diagnose, as many seizures have no clinical correlate. Altered level of consciousness is often the only clue, and in a neonate this can be difficult to accurately assess. Thus, diagnosis relies on attempting to directly measurement the abnormal electrical activity in the brain with electroencephalography (EEG). EEG is combined with video recording of the infant to correlate any seizure movements with EEG recordings.
There are several modes of EEG that are commonly used in the NICU to diagnose neonatal seizures. Conventional continuous multichannel conventional EEG is the gold standard for diagnosis of epileptiform activity, but requires expert interpretation. Newer amplitude integrated EEG (aEEG) (also termed cerebral function monitoring, or CFM) allows easier monitoring of brain activity, but may not allow identification of short duration, low amplitude, or very high frequency seizure activity.[40] Often, both modes are displayed concurrently.
Determining the cause
Since many causes of seizures can be rapidly reversed and longterm sequelae prevented, evaluation of underlying cause is of utmost importance. Evaluation for infection (with blood counts, lumbar puncture, and empiric treatment with antibiotics) often occurs during EEG monitoring. Blood glucose and electrolyte testing can identify metabolic problems that can be corrected. Further testing includes evaluation for genetic causes and other more rare metabolic causes.[41] Brain injury such as cerebral infarction or hemorrhage can be evaluated with imaging techniques such as magnetic resonance imaging (MRI) and brain ultrasound to avoid unnecessary radiation exposure.
Differential diagnosis
Infants can exhibit stereotyped movements that may be hard to distinguish from seizure activity. Since many of these non-seizure movements are not dangerous and require no treatment, differentiation from actual seizure activity is useful. Jitteriness is common in the neonatal period and is seen in upwards of 2/3 of neonates. It is characterized by a tremor that is especially prominent during sleep or periods of agitation. Gaze deviation or eye movements do not occur. Benign neonatal sleep myoclonus (BNSM) is another common movement that can be mistaken for a seizure. It is characterized by jerking limb movements only during sleep, and stop with waking of the infant. BNSM typically occurs later in infancy, but can occur during the neonatal period.
Treatment
Once diagnosis is made, the goals of management are to identify the cause of the seizure, stop the seizure activity, and maintain physiologic parameters such as oxygenation, ventilation, blood glucose, and temperature.
Treatment greatly depends on the cause of the seizure. For example, infectious causes of seizures (meningitis, meningoencephalitis), are often treated with antimicrobials (antibiotic, antifungal, or antiviral medications). Similarly, electrolyte or glucose abnormalities are treated by repleting or lowering the offending electrolyte or sugar.
If the cause of the seizures are unlikely to be easily or quickly corrected, once diagnosis of a seizure is made, the mainstay of treatment is pharmacotherapy with anti-epileptic drugs. A 2013 systematic review found that most practitioners use phenobarbital or phenytoin.[42] This study found that phenobarbital has the safest side effect profile and longest history of use in neonates.Hence, phenobarbital is used for first-line of treatment. After just one dose of 20 mg/kg of it, seizures are in control, in approximately half of the patients diagnosed with acute symptomatic seizures.[43] A NEOLEV2 study was conducted in the year 2020 to compare the efficiency of levetiracetam and phenobarbital as the first line of therapy. 80% of patients who were administered phenobarbital became seizure-free in 24hrs whereas merely 28% patients became seziure free in case of levetiracetam administration. Benzodiazepines are often used as second-line treatment if treatment with phenobarbital does not result in clinical improvement. Almost 66% of patients with acute symptomatic seizures, don't have a complete response to the initial dose administered. This is valid for any type of medication selected.[44] Research is ongoing on the use of other anti-epileptics that are commonly used in older children and adults and are safe or efficacious to use in neonates. Part of the challenge of anticonvulsant drug treatment during the neonatal period is that the immature excitatory and inhibitory neurotransmitter system results in few effective drug targets.[41] There are some drugs that are effective in controlling seizures. "Phenobarbitone remains the first-line treatment for seizures in most countries throughout the world, though off-label use of newer anticonvulsants is widespread in the USA[45]". The United States prefers to use unprescribed drugs to help slow down neonatal seizures, but they also use prescribed drugs if needed. Drugs are the only option infants are given, even though they are not 100% effective, they are the best option in helping take control of the seizures to stop them from occurring.
The following table lists the dosage of the respective medicine:[46]
MEDICINE | DOSE |
---|---|
PHENOBARBITONE | TARGET LEVEL: 40mcg/mL
MAINTENANCE DOSAGE: 3–6 mg/kg/d LOADING DOSAGE: Intravenously 20 mg/kg, repeat once when required |
PHENYTOIN | TARGET LEVEL: 10-20mcg/ml to be administered over ten minutes
MAINTENANCE DOSAGE: 2.5–5 mg/kg/d to be administered in two equal doses. LOADING DOSE: 20 mg/kg phenytoin equivalent intravenous over 20 minutes |
LEVETIRACETAM | TARGET LEVEL: Unknown
MAINTENANCE DOSAGE: 30–60 mg/kg/d in three equal doses LOADING DOSAGE: Intravenously 40–60 mg/kg/d |
Outcomes
With earlier diagnosis and increasingly prompt diagnosis, mortality after diagnosis of neonatal seizures has decreased dramatically from an estimated 33% in the 1990s to around 10% in the 2010s.[47] Underlying cause of the seizure remains the greatest predictor of ongoing seizures and neurologic problems later in life. Controversy remains with the extent of damage the seizures themselves cause. Clinician consensus is that frequent or intractable seizures (status epilepticus) leads to neuronal damage and are associated with later neurodevelopment problems.[48]
Developmental delay, cerebral palsy, and problems with vision and hearing are the most common poor outcomes following neonatal seizures.[47] Severity of impairment ranges greatly and many infants develop normally once the initial seizure cause is treated.
Studies have identified risk factors for poor outcomes after neonatal seizures. Infants that are premature, have hypoxemic ischemic encephalopathy, CNS infection, severe intraventricular hemorrhage, structural central nervous system defect, or severely abnormal EEG tracings tend to do worse than infants with focal strokes, transient metabolic issues (hypoglycemia, hypocalcemia), or clinical seizures without EEG abnormalities.[47] There are many other risk factors for neonatal seizures. "Some of the risk factors that we have detected, such as low Apgar score, need for resuscitation at birth, and perinatal distress, were previously reported[49]". An apgar score indicates how a baby is immediately after birth. Perinatal distress is when a mother experiences a lot of stress during pregnancy. This shows how serious neonatal seizures really are, and not many people knew that.
Risk of epilepsy later during childhood is a common question asked by parents in the neonatal intensive care unit (NICU). Unfortunately, the answer is rarely clear cut as it depends greatly on the underlying cause. For all infants with neonatal seizures regardless of cause, the rate of subsequent seizures during childhood is estimated between 10 and 20%.[50] Infants who survive severe global HIE have the highest rate of epilepsy later in life.[47]
Epidemiology
It is difficult to determine the incidence of seizures in the neonatal period. Estimations range between 1-5 per 1,000 live births,[41] though the actual rate of seizures during this period may be higher due to a lack of accurate diagnosis of sub-clinical seizure activity without continuous EEG monitoring. The epidemiology moreover varies in high-income countries (HIC) from that in low-income ones (LIC). The incidence is estimated to be 1-3 per 1000 live births in HIC whereas it ranges from 36 to 90 per live birth in LIC. Acute causes of seizures (hypoxemic ischemic encephalopathy, infection, intracranial hemorrhage, stroke, etc.) are more common than the first episode of neonatal epilepsy syndromes. Watching the EEG monitor and detecting when a seizure occurs can help the preterm infant survive these seizures. "Continuous monitoring and cranial imaging in the setting of neonatal seizures now compromise the standard of care at many centers, and these technologies are being used to guide management, diagnosis, and prognosis[51]". As the monitoring devices for neonatal seizures become more advanced, the closer researchers are to finding how these seizures occur and how they can be stopped.
Seizures occur during the neonatal period at a higher rate than in any other period of life. Seizures in the developing brain are more common than in a mature brain for several reasons. First, the developing brain is hyperexcitable due to excess in excitatory glutaminergic neurons and immaturity of inhibitory gamma-amino butyric acid (GABA) neurons. Preterm infants are at especially high risk for seizures for this reason.[47]
Research directions
Since interpretation of continuous EEG monitoring requires a trained neurologist, automated interpretation software has been proposed. Algorithms and machine learning have been studied, however logistical and mathematic challenges remain.
See also
References
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- ^ Shellhaas, Renée A.; Chang, Taeun; Tsuchida, Tammy; Scher, Mark S.; Riviello, James J.; Abend, Nicholas S.; Nguyen, Sylvie; Wusthoff, Courtney J.; Clancy, Robert R. (December 2011). "The American Clinical Neurophysiology Society's Guideline on Continuous Electroencephalography Monitoring in Neonates". Journal of Clinical Neurophysiology. 28 (6): 611–617. doi:10.1097/WNP.0b013e31823e96d7. ISSN 0736-0258. PMID 22146359.
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