Epilepsy From Wikipedia, the free encyclopedia Jump to navigationJump to search "Epilepsia" and "Epileptic" redirect here. For the journal, see Epilepsia (journal). For the comics, see Epileptic (comics). Epilepsy Other names Seizure disorder The electroencephalogram recording of a person with childhood absence epilepsy showing a seizure. The waves are black on a white background. Generalized 3 Hz spike-and-wave discharges on an electroencephalogram Specialty Neurology Symptoms Periods of vigorous shaking, nearly undetectable spells[1] Duration Long term[1] Causes Unknown, brain injury, stroke, brain tumors, infections of the brain, birth defects[1][2][3] Diagnostic method Electroencephalogram, ruling out other possible causes[4] Differential diagnosis Fainting, alcohol withdrawal, electrolyte problems[4] Treatment Medication, surgery, neurostimulation, dietary changes[5][6] Prognosis Controllable in 69%[7] Frequency 39 million / 0.5% (2015)[8] Deaths 125,000 (2015)[9] Epilepsy is a group of non-communicable neurological disorders characterized by recurrent epileptic seizures.[10][11][12] Epileptic seizures can vary from brief and nearly undetectable periods to long periods of vigorous shaking due to abnormal electrical activity in the brain.[1] These episodes can result in physical injuries, either directly such as broken bones or through causing accidents.[1] In epilepsy, seizures tend to recur and may have no immediate underlying cause.[10] Isolated seizures that are provoked by a specific cause such as poisoning are not deemed to represent epilepsy.[13] People with epilepsy may be treated differently in various areas of the world and experience varying degrees of social stigma due to their condition.[1] The underlying mechanism of epileptic seizures is excessive and abnormal neuronal activity in the cortex of the brain[13] which can be observed in the electroencephalogram (EEG) of an individual. The reason this occurs in most cases of epilepsy is unknown (idiopathic);[1] some cases occur as the result of brain injury, stroke, brain tumors, infections of the brain, or birth defects through a process known as epileptogenesis.[1][2][3] Known genetic mutations are directly linked to a small proportion of cases.[4][14] The diagnosis involves ruling out other conditions that might cause similar symptoms, such as fainting, and determining if another cause of seizures is present, such as alcohol withdrawal or electrolyte problems.[4] This may be partly done by imaging the brain and performing blood tests.[4] Epilepsy can often be confirmed with an electroencephalogram (EEG), but a normal test does not rule out the condition.[4] Epilepsy that occurs as a result of other issues may be preventable.[1] Seizures are controllable with medication in about 69% of cases;[7] inexpensive anti-seizure medications are often available.[1] In those whose seizures do not respond to medication, surgery, neurostimulation or dietary changes may then be considered.[12][5][6] Not all cases of epilepsy are lifelong, and many people improve to the point that treatment is no longer needed.[1] As of 2020, about 50 million people suffer from epilepsy.[12] Nearly 80% of cases occur in the developing world.[1] In 2015, it resulted in 125,000 deaths, an increase from 112,000 in 1990.[9][15] Epilepsy is more common in older people.[16][17] In the developed world, onset of new cases occurs most frequently in babies and the elderly.[18] In the developing world, onset is more common in older children and young adults due to differences in the frequency of the underlying causes.[19] About 5–10% of people will have an unprovoked seizure by the age of 80,[20] with the chance of experiencing a second seizure rising to between 40% and 50%.[21] In many areas of the world, those with epilepsy either have restrictions placed on their ability to drive or are not permitted to drive until they are free of seizures for a specific length of time.[22] The word epilepsy is from Ancient Greek ἐπιλαμβάνειν, "to seize, possess, or afflict".[23] Contents 1 Signs and symptoms 1.1 Seizures 1.2 Post-ictal 1.3 Psychosocial 2 Causes 2.1 Genetics 2.2 Acquired 3 Mechanism 3.1 Epilepsy 3.2 Seizures 4 Diagnosis 4.1 Definition 4.2 Classification 4.3 Syndromes 4.4 Tests 4.5 Differential diagnosis 5 Prevention 6 Management 6.1 First aid 6.2 Medications 6.3 Surgery 6.4 Diet 6.5 Other 6.6 In pregnancy 6.7 Alternative medicine 7 Prognosis 7.1 Mortality 8 Epidemiology 9 History 10 Society and culture 10.1 Stigma 10.2 Economics 10.3 Vehicles 10.4 Support organizations 11 Research 11.1 Seizure prediction and modeling 11.2 Potential future therapies 12 Other animals 13 References 14 Further reading 15 External links Signs and symptoms A still image of a generalized seizure A bite to the tip of the tongue due to a seizure Epilepsy is characterized by a long-term risk of recurrent epileptic seizures.[24] These seizures may present in several ways depending on the parts of the brain involved and the person's age.[24][25] Seizures Main article: Epileptic seizure The most common type (60%) of seizures are convulsive which involve involuntary muscle contractions.[25] Of these, one-third begin as generalized seizures from the start, affecting both hemispheres of the brain and impairing consciousness.[25] Two-thirds begin as focal seizures (which affect one hemisphere of the brain) which may progress to generalized seizures.[25] The remaining 40% of seizures are non-convulsive. An example of this type is the absence seizure, which presents as a decreased level of consciousness and usually lasts about 10 seconds.[2][26] Certain experiences, known as auras often precede Focal seizures.[27] The seizures can include sensory (visual, hearing, or smell), psychic, autonomic, and motor phenomena depending on which part of the brain is involved.[2] Muscle jerks may start in a specific muscle group and spread to surrounding muscle groups in which case it is known as a Jacksonian march.[28] Automatisms may occur, which are non-consciously-generated activities and mostly simple repetitive movements like smacking the lips or more complex activities such as attempts to pick up something.[28] There are six main types of generalized seizures: tonic-clonic, tonic, clonic, myoclonic, absence, and atonic seizures.[29] They all involve loss of consciousness and typically happen without warning. Tonic-clonic seizures occur with a contraction of the limbs followed by their extension and arching of the back which lasts 10–30 seconds (the tonic phase). A cry may be heard due to contraction of the chest muscles, followed by a shaking of the limbs in unison (clonic phase). Tonic seizures produce constant contractions of the muscles. A person often turns blue as breathing is stopped. In clonic seizures there is shaking of the limbs in unison. After the shaking has stopped it may take 10–30 minutes for the person to return to normal; this period is called the "postictal state" or "postictal phase." Loss of bowel or bladder control may occur during a seizure.[30] People experiencing a seizure may bite their tongue, either the tip or on the sides;[31] in tonic-clonic seizure, bites to the sides are more common.[31] Tongue bites are also relatively common in psychogenic non-epileptic seizures.[31] Myoclonic seizures involve very brief spasms of muscles in either a few areas or all over.[32][33] These sometimes cause the person to fall, which can cause injury.[32] Absence seizures can be subtle with only a slight turn of the head or eye blinking with impaired consciousness;[2] typically, the person does not fall over and returns to normal right after it ends.[2] Atonic seizures involve losing muscle activity for greater than one second,[28] typically occurring on both sides of the body.[28] Rarer seizure types can cause involuntary unnatural laughter (gelastic), crying (dyscrastic), or more complex experiences such as déjà vu.[33] About 6% of those with epilepsy have seizures that are often triggered by specific events and are known as reflex seizures.[34] Those with reflex epilepsy have seizures that are only triggered by specific stimuli.[35] Common triggers include flashing lights and sudden noises.[34] In certain types of epilepsy, seizures happen more often during sleep,[36] and in other types they occur almost only when sleeping.[37] Post-ictal After the active portion of a seizure (the ictal state) there is typically a period of recovery during which there is confusion, referred to as the postictal period, before a normal level of consciousness returns.[27] It usually lasts 3 to 15 minutes[38] but may last for hours.[39] Other common symptoms include feeling tired, headache, difficulty speaking, and abnormal behavior.[39] Psychosis after a seizure is relatively common, occurring in 6–10% of people.[40] Often people do not remember what happened during this time.[39] Localized weakness, known as Todd's paralysis, may also occur after a focal seizure. It would typically last for seconds to minutes but may rarely last for a day or two.[41] Psychosocial Epilepsy can have adverse effects on social and psychological well-being.[25] These effects may include social isolation, stigmatization, or disability.[25] They may result in lower educational achievement and worse employment outcomes.[25] Learning disabilities are common in those with the condition, and especially among children with epilepsy.[25] The stigma of epilepsy can also affect the families of those with the disorder.[30] Certain disorders occur more often in people with epilepsy, depending partly on the epilepsy syndrome present. These include depression, anxiety, obsessive–compulsive disorder (OCD),[42] and migraine.[43] Attention deficit hyperactivity disorder (ADHD) affects three to five times more children with epilepsy than children without the condition.[44] ADHD and epilepsy have significant consequences on a child's behavioral, learning, and social development.[45] Epilepsy is also more common in children with autism.[46] Causes See also: Causes of seizures Epilepsy can have both genetic and acquired causes, with the interaction of these factors in many cases.[47] Established acquired causes include serious brain trauma, stroke, tumours, and brain problems resulting from a previous infection.[47] In about 60% of cases, the cause is unknown.[25][30] Epilepsies caused by genetic, congenital, or developmental conditions are more common among younger people, while brain tumors and strokes are more likely in older people.[25] Seizures may also occur as a consequence of other health problems;[29] if they occur right around a specific cause, such as a stroke, head injury, toxic ingestion, or metabolic problem, they are known as acute symptomatic seizures and are in the broader classification of seizure-related disorders rather than epilepsy itself.[48][49] Genetics Genetics is believed to be involved in the majority of cases, either directly or indirectly.[14] Some epilepsies are due to a single gene defect (1–2%); most are due to the interaction of multiple genes and environmental factors.[14] Each of the single gene defects is rare, with more than 200 in all described.[50] Most genes involved affect ion channels, either directly or indirectly.[47] These include genes for ion channels themselves, enzymes, GABA, and G protein-coupled receptors.[32] In identical twins, if one is affected, there is a 50–60% chance that the other will also be affected.[14] In non-identical twins, the risk is 15%.[14] These risks are greater in those with generalized rather than focal seizures.[14] If both twins are affected, most of the time they have the same epileptic syndrome (70–90%).[14] Other close relatives of a person with epilepsy have a risk five times that of the general population.[51] Between 1 and 10% of those with Down syndrome and 90% of those with Angelman syndrome have epilepsy.[51] Acquired Epilepsy may occur as a result of several other conditions, including tumors, strokes, head trauma, previous infections of the central nervous system, genetic abnormalities, and as a result of brain damage around the time of birth.[29][30] Of those with brain tumors, almost 30% have epilepsy, making them the cause of about 4% of cases.[51] The risk is greatest for tumors in the temporal lobe and those that grow slowly.[51] Other mass lesions such as cerebral cavernous malformations and arteriovenous malformations have risks as high as 40–60%.[51] Of those who have had a stroke, 2–4% develop epilepsy.[51] In the United Kingdom, strokes account for 15% of cases and they are believed to be the cause in 30% of the elderly.[25][51] Between 6 and 20% of epilepsy is believed to be due to head trauma.[51] Mild brain injury increases the risk about two-fold while severe brain injury increases the risk seven-fold.[51] In those who have experienced a high-powered gunshot wound to the head, the risk is about 50%.[51] Some evidence links epilepsy and celiac disease and non-celiac gluten sensitivity, while other evidence does not. There appears to be a specific syndrome that includes coeliac disease, epilepsy, and calcifications in the brain.[52][53] A 2012 review estimates that between 1% and 6% of people with epilepsy have coeliac disease while 1% of the general population has the condition.[53] The risk of epilepsy following meningitis is less than 10%; it more commonly causes seizures during the infection itself.[51] In herpes simplex encephalitis the risk of a seizure is around 50%[51] with a high risk of epilepsy following (up to 25%).[54][55] A form of an infection with the pork tapeworm (cysticercosis), in the brain, is known as neurocysticercosis, and is the cause of up to half of epilepsy cases in areas of the world where the parasite is common.[51] Epilepsy may also occur after other brain infections such as cerebral malaria, toxoplasmosis, and toxocariasis.[51] Chronic alcohol use increases the risk of epilepsy: those who drink six units of alcohol per day have a 2.5-fold increase in risk.[51] Other risks include Alzheimer's disease, multiple sclerosis, tuberous sclerosis, and autoimmune encephalitis.[51] Getting vaccinated does not increase the risk of epilepsy.[51] Malnutrition is a risk factor seen mostly in the developing world, although it is unclear however if it is a direct cause or an association.[19] People with cerebral palsy have an increased risk of epilepsy, with half of people with spastic quadriplegia and spastic hemiplegia having the disease.[56] Mechanism Normally brain electrical activity is non-synchronous, as large numbers of neurons do not normally fire at the same time, but rather fire in order as signals travel throughout the brain.[2] Neuron activity is regulated by various factors both within the cell and the cellular environment. Factors within the neuron include the type, number and distribution of ion channels, changes to receptors and changes of gene expression.[57] Factors around the neuron include ion concentrations, synaptic plasticity and regulation of transmitter breakdown by glial cells.[57][58] Epilepsy The exact mechanism for epilepsy is unknown,[59] but a little is known about its cellular and network mechanisms. However, it is unknown under which circumstances the brain shifts into the activity of a seizure with its excessive synchronization.[60][61] Changes in MicroRNAs (miRNAs) levels seems to play a leading role. MicroRNAs (miRNAs) are a family of small non-coding RNAs that control the expression levels of multiple proteins by decreasing mRNA stability and translation, and could therefore be key regulatory mechanisms and therapeutic targets in epilepsy [62] In epilepsy, the resistance of excitatory neurons to fire during this period is decreased.[2] This may occur due to changes in ion channels or inhibitory neurons not functioning properly.[2] This then results in a specific area from which seizures may develop, known as a "seizure focus".[2] Another mechanism of epilepsy may be the up-regulation of excitatory circuits or down-regulation of inhibitory circuits following an injury to the brain.[2][3] These secondary epilepsies occur through processes known as epileptogenesis.[2][3] Failure of the blood–brain barrier may also be a causal mechanism as it would allow substances in the blood to enter the brain.[63] Seizures There is evidence that epileptic seizures are usually not a random event. Seizures are often brought on by factors (also known as triggers) such as stress, excessive alcohol use, flickering light, or a lack of sleep, among others. The term seizure threshold is used to indicate the amount of stimulus necessary to bring about a seizure, this seizure threshold is lowered in epilepsy.[60] In epileptic seizures a group of neurons begin firing in an abnormal, excessive,[25] and synchronized manner.[2] This results in a wave of depolarization known as a paroxysmal depolarizing shift.[64] Normally, after an excitatory neuron fires it becomes more resistant to firing for a period of time.[2] This is due in part to the effect of inhibitory neurons, electrical changes within the excitatory neuron, and the negative effects of adenosine.[2] Focal seizures begin in one area of the brain while generalized seizures begin in both hemispheres.[29] Some types of seizures may change brain structure, while others appear to have little effect.[65] Gliosis, neuronal loss, and atrophy of specific areas of the brain are linked to epilepsy but it is unclear if epilepsy causes these changes or if these changes result in epilepsy.[65] The seizures can be described on different scales, from the cellular level[66] to the whole brain.[67] These are several concomitant factor, which on different scale can "drive" the brain to pathological states and trigger a seizure. Diagnosis An EEG can aid in locating the focus of the epileptic seizure. The diagnosis of epilepsy is typically made based on observation of the seizure onset and the underlying cause.[25] An electroencephalogram (EEG) to look for abnormal patterns of brain waves and neuroimaging (CT scan or MRI) to look at the structure of the brain are also usually part of the initial investigations.[25] While figuring out a specific epileptic syndrome is often attempted, it is not always possible.[25] Video and EEG monitoring may be useful in difficult cases.[68] Definition Epilepsy is a disorder of the brain defined by any of the following conditions:[11] At least two unprovoked (or reflex) seizures occurring more than 24 hours apart One unprovoked (or reflex) seizure and a probability of further seizures similar to the general recurrence risk (at least 60%) after two unprovoked seizures, occurring over the next 10 years Diagnosis of an epilepsy syndrome Furthermore, epilepsy is considered to be resolved for individuals who had an age-dependent epilepsy syndrome but are now past that age or those who have remained seizure-free for the last 10 years, with no seizure medicines for the last 5 years.[11] This 2014 definition of the International League Against Epilepsy[11] is a clarification of the ILAE 2005 conceptual definition, according to which epilepsy is "a disorder of the brain characterized by an enduring predisposition to generate epileptic seizures and by the neurobiologic, cognitive, psychological, and social consequences of this condition. The definition of epilepsy requires the occurrence of at least one epileptic seizure."[13][69] It is, therefore, possible to outgrow epilepsy or to undergo treatment that causes epilepsy to be resolved, but with no guarantee that it will not return. In the definition, epilepsy is now called a disease, rather than a disorder. This was a decision of the executive committee of the ILAE, taken because the word "disorder," while perhaps having less stigma than does "disease," also does not express the degree of seriousness that epilepsy deserves.[11] The definition is practical in nature and is designed for clinical use. In particular, it aims to clarify when an "enduring predisposition" according to the 2005 conceptual definition is present. Researchers, statistically-minded epidemiologists, and other specialized groups may choose to use the older definition or a definition of their own devising. The ILAE considers doing so is perfectly allowable, so long as it is clear what definition is being used.[11] Classification Revised operational scheme of seizure classification, ILAE, 2017 In contrast to the classification of seizures which focuses on what happens during a seizure, the classification of epilepsies focuses on the underlying causes. When a person is admitted to hospital after an epileptic seizure the diagnostic workup results preferably in the seizure itself being classified (e.g. tonic-clonic) and in the underlying disease being identified (e.g. hippocampal sclerosis).[68] The name of the diagnosis finally made depends on the available diagnostic results and the applied definitions and classifications (of seizures and epilepsies) and its respective terminology. The International League Against Epilepsy (ILAE) provided a classification of the epilepsies and epileptic syndromes in 1989 as follows:[70] Localization-related epilepsies and syndromes Unknown cause (e.g. benign childhood epilepsy with centrotemporal spikes) Symptomatic/cryptogenic (e.g. temporal lobe epilepsy) Generalized Unknown cause (e.g. childhood absence epilepsy) Cryptogenic or symptomatic (e.g. Lennox-Gastaut syndrome) Symptomatic (e.g. early infantile epileptic encephalopathy with burst suppression) Epilepsies and syndromes undetermined whether focal or generalized With both generalized and focal seizures (e.g. epilepsy with continuous spike-waves during slow wave sleep) Special syndromes (with situation-related seizures) This classification was widely accepted but has also been criticized mainly because the underlying causes of epilepsy (which are a major determinant of clinical course and prognosis) were not covered in detail.[71] In 2010 the ILAE Commission for Classification of the Epilepsies addressed this issue and divided epilepsies into three categories (genetic, structural/metabolic, unknown cause)[72] that were refined in their 2011 recommendation into four categories and a number of subcategories reflecting recent technologic and scientific advances.[73] Unknown cause (mostly genetic or presumed genetic origin) Pure epilepsies due to single gene disorders Pure epilepsies with complex inheritance Symptomatic (associated with gross anatomic or pathologic abnormalities) Mostly genetic or developmental causation Childhood epilepsy syndromes Progressive myoclonic epilepsies Neurocutaneous syndromes Other neurologic single gene disorders Disorders of chromosome function Developmental anomalies of cerebral structure Mostly acquired causes Hippocampal sclerosis Perinatal and infantile causes Cerebral trauma, tumor or infection Cerebrovascular disorders Cerebral immunologic disorders Degenerative and other neurologic conditions Provoked (a specific systemic or environmental factor is the predominant cause of the seizures) Provoking factors Reflex epilepsies Cryptogenic (presumed symptomatic nature in which the cause has not been identified)[73] A revised, operational classification of seizure types has been introduced by the ILAE.[74] It allows more clearly understood terms and clearly defines focal and generalized onset dichotomy, when possible, even without observing the seizures based on description by patient or observers.[75] The essential changes in terminology are that "partial" is called "focal" with awareness used as a classifier for focal seizures -based on description focal seizures are now defined as behavioral arrest, automatisms, cognitive , autonomic, emotional or hyperkinetic variants while atonic, myoclonic, clonic, infantile spasms, and tonic seizures may be either focal or generalized based on their onset. Several terms that were not clear or consistent in description were removed such as dyscognitive, psychic, simple and complex partial, while "secondarily generalized" is replaced by a clearer term "focal to bilateral tonic clonic seizure". New seizure types now believed to be generalized are eyelid myoclonia, myoclonic atonic, myoclonic absence, and myoclonic tonic clonic. Sometimes it is possible to classify seizures as focal or generalized based on presenting features even though onset in not known. This system is based on the 1981 seizure classification modified in 2010 and principally is the same with an effort to improve the flexibility and clarity of use to understand seizures types better in keeping with current knowledge. Syndromes Main article: Epilepsy syndromes Cases of epilepsy may be organized into epilepsy syndromes by the specific features that are present. These features include the age that seizure begin, the seizure types, EEG findings, among others. Identifying an epilepsy syndrome is useful as it helps determine the underlying causes as well as what anti-seizure medication should be tried.[29][76] The ability to categorize a case of epilepsy into a specific syndrome occurs more often with children since the onset of seizures is commonly early.[49] Less serious examples are benign rolandic epilepsy (2.8 per 100,000), childhood absence epilepsy (0.8 per 100,000) and juvenile myoclonic epilepsy (0.7 per 100,000).[49] Severe syndromes with diffuse brain dysfunction caused, at least partly, by some aspect of epilepsy, are also referred to as developmental and epileptic encephalopathies. These are associated with frequent seizures that are resistant to treatment and cognitive dysfunction, for instance Lennox–Gastaut syndrome (1-2% of all persons with epilepsy),[77] Dravet syndrome(1: 15000-40000 worldwide[78]), and West syndrome(1-9: 100000[79]).[80] Genetics is believed to play an important role in epilepsies by a number of mechanisms. Simple and complex modes of inheritance have been identified for some of them. However, extensive screening have failed to identify many single gene variants of large effect.[81] More recent exome and genome sequencing studies have begun to reveal a number of de novo gene mutations that are responsible for some epileptic encephalopathies, including CHD2 and SYNGAP1[82][83][84] and DNM1, GABBR2, FASN and RYR3.[85] Syndromes in which causes are not clearly identified are difficult to match with categories of the current classification of epilepsy. Categorization for these cases was made somewhat arbitrarily.[73] The idiopathic (unknown cause) category of the 2011 classification includes syndromes in which the general clinical features and/or age specificity strongly point to a presumed genetic cause.[73] Some childhood epilepsy syndromes are included in the unknown cause category in which the cause is presumed genetic, for instance benign rolandic epilepsy. Others are included in symptomatic despite a presumed genetic cause (in at least in some cases), for instance Lennox-Gastaut syndrome.[73] Clinical syndromes in which epilepsy is not the main feature (e.g. Angelman syndrome) were categorized symptomatic but it was argued to include these within the category idiopathic.[73] Classification of epilepsies and particularly of epilepsy syndromes will change with advances in research. Tests An electroencephalogram (EEG) can assist in showing brain activity suggestive of an increased risk of seizures. It is only recommended for those who are likely to have had an epileptic seizure on the basis of symptoms. In the diagnosis of epilepsy, electroencephalography may help distinguish the type of seizure or syndrome present.[86] In children it is typically only needed after a second seizure unless specified by a specialist. It cannot be used to rule out the diagnosis and may be falsely positive in those without the disease.[86] In certain situations it may be useful to perform the EEG while the affected individual is sleeping or sleep deprived.[68] Diagnostic imaging by CT scan and MRI is recommended after a first non-febrile seizure to detect structural problems in and around the brain.[68] MRI is generally a better imaging test except when bleeding is suspected, for which CT is more sensitive and more easily available.[20] If someone attends the emergency room with a seizure but returns to normal quickly, imaging tests may be done at a later point.[20] If a person has a previous diagnosis of epilepsy with previous imaging, repeating the imaging is usually not needed even if there are subsequent seizures.[68][87] For adults, the testing of electrolyte, blood glucose and calcium levels is important to rule out problems with these as causes.[68] An electrocardiogram can rule out problems with the rhythm of the heart.[68] A lumbar puncture may be useful to diagnose a central nervous system infection but is not routinely needed.[20] In children additional tests may be required such as urine biochemistry and blood testing looking for metabolic disorders.[68][88] Together with EEG and neuroimaging, genetic testing is becoming one of the most important diagnostic technique for epilepsy, as a diagnosis might be achieved in a relevant proportion of cases with severe epilepsies, both in children and adults.[89] For those with negative genetic testing, in some it might be important to repeat or re-analyze previous genetic studies after 2–3 years.[90] A high blood prolactin level within the first 20 minutes following a seizure may be useful to help confirm an epileptic seizure as opposed to psychogenic non-epileptic seizure.[91][92] Serum prolactin level is less useful for detecting focal seizures.[93] If it is normal an epileptic seizure is still possible[92] and a serum prolactin does not separate epileptic seizures from syncope.[94] It is not recommended as a routine part of the diagnosis of epilepsy.[68] Differential diagnosis Diagnosis of epilepsy can be difficult. A number of other conditions may present very similar signs and symptoms to seizures, including syncope, hyperventilation, migraines, narcolepsy, panic attacks and psychogenic non-epileptic seizures (PNES).[95][96] In particular a syncope can be accompanied by a short episode of convulsions.[97] Nocturnal frontal lobe epilepsy, often misdiagnosed as nightmares, was considered to be a parasomnia but later identified to be an epilepsy syndrome.[98] Attacks of the movement disorder paroxysmal dyskinesia may be taken for epileptic seizures.[99] The cause of a drop attack can be, among many others, an atonic seizure.[96] Children may have behaviors that are easily mistaken for epileptic seizures but are not. These include breath-holding spells, bedwetting, night terrors, tics and shudder attacks.[96] Gastroesophageal reflux may cause arching of the back and twisting of the head to the side in infants, which may be mistaken for tonic-clonic seizures.[96] Misdiagnosis is frequent (occurring in about 5 to 30% of cases).[25] Different studies showed that in many cases seizure-like attacks in apparent treatment-resistant epilepsy have a cardiovascular cause.[97][100] Approximately 20% of the people seen at epilepsy clinics have PNES[20] and of those who have PNES about 10% also have epilepsy;[101] separating the two based on the seizure episode alone without further testing is often difficult.[101] Prevention While many cases are not preventable, efforts to reduce head injuries, provide good care around the time of birth, and reduce environmental parasites such as the pork tapeworm may be effective.[30] Efforts in one part of Central America to decrease rates of pork tapeworm resulted in a 50% decrease in new cases of epilepsy.[19] Management Wristbands or bracelets denoting their condition are occasionally worn by epileptics should they need medical assistance. Epilepsy is usually treated with daily medication once a second seizure has occurred,[25][68] while medication may be started after the first seizure in those at high risk for subsequent seizures.[68] Supporting people's self management of their condition may be useful.[102] In drug-resistant cases different management options may be looked at including a special diet, the implantation of a neurostimulator, or neurosurgery. First aid Rolling people with an active tonic-clonic seizure onto their side and into the recovery position helps prevent fluids from getting into the lungs.[103] Putting fingers, a bite block or tongue depressor in the mouth is not recommended as it might make the person vomit or result in the rescuer being bitten.[27][103] Efforts should be taken to prevent further self-injury.[27] Spinal precautions are generally not needed.[103] If a seizure lasts longer than 5 minutes or if there are more than two seizures in an hour without a return to a normal level of consciousness between them, it is considered a medical emergency known as status epilepticus.[68][104] This may require medical help to keep the airway open and protected;[68] a nasopharyngeal airway may be useful for this.[103] At home the recommended initial medication for seizure of a long duration is midazolam placed in the mouth.[105] Diazepam may also be used rectally.[105] In hospital, intravenous lorazepam is preferred.[68] If two doses of benzodiazepines are not effective, other medications such as phenytoin are recommended.[68] Convulsive status epilepticus that does not respond to initial treatment typically requires admission to the intensive care unit and treatment with stronger agents such as thiopentone or propofol.[68] Medications Anticonvulsants The mainstay treatment of epilepsy is anticonvulsant medications, possibly for the person's entire life.[12][25] The choice of anticonvulsant is based on seizure type, epilepsy syndrome, other medications used, other health problems, and the person's age and lifestyle.[105] A single medication is recommended initially;[106] if this is not effective, switching to a single other medication is recommended.[68] Two medications at once is recommended only if a single medication does not work.[68] In about half, the first agent is effective; a second single agent helps in about 13% and a third or two agents at the same time may help an additional 4%.[107] About 30% of people continue to have seizures despite anticonvulsant treatment.[7] There are a number of medications available including phenytoin, carbamazepine[108] and valproate. Evidence suggests that phenytoin, carbamazepine, and valproate may be equally effective in both focal and generalized seizures.[109][110] Controlled release carbamazepine appears to work as well as immediate release carbamazepine, and may have fewer side effects.[111] In the United Kingdom, carbamazepine or lamotrigine are recommended as first-line treatment for focal seizures, with levetiracetam and valproate as second-line due to issues of cost and side effects.[68] Valproate is recommended first-line for generalized seizures with lamotrigine being second-line.[68] In those with absence seizures, ethosuximide or valproate are recommended; valproate is particularly effective in myoclonic seizures and tonic or atonic seizures.[68] If seizures are well-controlled on a particular treatment, it is not usually necessary to routinely check the medication levels in the blood.[68] The least expensive anticonvulsant is phenobarbital at around US$5 a year.[19] The World Health Organization gives it a first-line recommendation in the developing world and it is commonly used there.[112][113] Access however may be difficult as some countries label it as a controlled drug.[19] Adverse effects from medications are reported in 10 to 90% of people, depending on how and from whom the data is collected.[114] Most adverse effects are dose-related and mild.[114] Some examples include mood changes, sleepiness, or an unsteadiness in gait.[114] Certain medications have side effects that are not related to dose such as rashes, liver toxicity, or suppression of the bone marrow.[114] Up to a quarter of people stop treatment due to adverse effects.[114] Some medications are associated with birth defects when used in pregnancy.[68] Many of the common used medications, such as valproate, phenytoin, carbamazepine, phenobarbital, and gabapentin have been reported to cause increased risk of birth defects,[115] especially when used during the first trimester.[116] Despite this, treatment is often continued once effective, because the risk of untreated epilepsy is believed to be greater than the risk of the medications.[116] Among the antiepileptic medications, levetiracetam and lamotrigine seem to carry the lowest risk of causing birth defects.[115] Slowly stopping medications may be reasonable in some people who do not have a seizure for two to four years; however, around a third of people have a recurrence, most often during the first six months.[68][117] Stopping is possible in about 70% of children and 60% of adults.[30] Measuring medication levels is not generally needed in those whose seizures are well controlled.[87] Surgery Epilepsy surgery may be an option for people with focal seizures that remain a problem despite other treatments.[118][119] These other treatments include at least a trial of two or three medications.[120] The goal of surgery is total control of seizures[121] and this may be achieved in 60–70% of cases.[120] Common procedures include cutting out the hippocampus via an anterior temporal lobe resection, removal of tumors, and removing parts of the neocortex.[120] Some procedures such as a corpus callosotomy are attempted in an effort to decrease the number of seizures rather than cure the condition.[120] Following surgery, medications may be slowly withdrawn in many cases.[120][118] Neurostimulation may be another option in those who are not candidates for surgery.[68] Three types have been used in those who do not respond to medications: vagus nerve stimulation, anterior thalamic stimulation, and closed-loop responsive stimulation.[5][122][123] Diet There is promising evidence that a ketogenic diet (high-fat, low-carbohydrate, adequate-protein) decreases the number of seizures and eliminates seizures in some; however, further research is necessary.[6] It is a reasonable option in those who have epilepsy that is not improved with medications and for whom surgery is not an option.[6] About 10% stay on the diet for a few years due to issues of effectiveness and tolerability.[6] Side effects include stomach and intestinal problems in 30%, and there are long-term concerns about heart disease.[6] Less radical diets are easier to tolerate and may be effective.[6] It is unclear why this diet works.[124] In people with coeliac disease or non-celiac gluten sensitivity and occipital calcifications, a gluten-free diet may decrease the frequency of seizures.[53] Other Avoidance therapy consists of minimizing or eliminating triggers. For example, those who are sensitive to light may have success with using a small television, avoiding video games, or wearing dark glasses.[125] Operant-based biofeedback based on the EEG waves has some support in those who do not respond to medications.[126] Psychological methods should not, however, be used to replace medications.[68] Exercise has been proposed as possibly useful for preventing seizures,[127] with some data to support this claim.[128] Some dogs, commonly referred to as seizure dogs, may help during or after a seizure.[129][130] It is not clear if dogs have the ability to predict seizures before they occur.[131] There is moderate-quality evidence supporting the use of psychological interventions along with other treatments in epilepsy.[132] This can improve quality of life, enhance emotional wellbeing, and reduce fatigue in adults and adolescents.[132] Psychological interventions may also improve seizure control for some individuals by promoting self-management and adherence.[132] As an add-on therapy in those who are not well controlled with other medications, cannabidiol appears to be useful in some children.[133] In 2018 the FDA approved this product for Lennox–Gastaut syndrome and Dravet syndrome.[134] In pregnancy In women of childbearing age, use of antiepileptic drugs is a major concern balancing possible side effects on the fetus against risk from uncontrolled seizures. Use of AEDs entail teratogenic effects including intrauterine growth retardation, major congenital malformations and developmental (neurocognitive) and behavioral issues, that need to be discussed with the patient at the time of starting the AEDs and before they plan pregnancy.[135] Most women with epilepsy receive safe and effective treatment and have normal children, however risks exist. The International League Against Epilepsy created a task force on women and epilepsy which published consensus recommendations to guide therapy decisions till more definitive evidence is available in the future.[135] Alternative medicine Alternative medicine, including acupuncture,[136] routine vitamins,[137] and yoga,[138] have no reliable evidence to support their use in epilepsy. Melatonin, as of 2016, is insufficiently supported by evidence.[139] The trials were of poor methodological quality and it was not possible to draw any definitive conclusions.[139] Prognosis Deaths due to epilepsy per million persons in 2012 0–7 8–10 11–13 14–17 18–21 22–28 29–37 38–67 68–100 101–232 Epilepsy cannot usually be cured, but medication can control seizures effectively in about 70% of cases.[7] Of those with generalized seizures, more than 80% can be well controlled with medications while this is true in only 50% of people with focal seizures.[5] One predictor of long-term outcome is the number of seizures that occur in the first six months.[25] Other factors increasing the risk of a poor outcome include little response to the initial treatment, generalized seizures, a family history of epilepsy, psychiatric problems, and waves on the EEG representing generalized epileptiform activity.[140] In the developing world, 75% of people are either untreated or not appropriately treated.[30] In Africa, 90% do not get treatment.[30] This is partly related to appropriate medications not being available or being too expensive.[30] Mortality People with epilepsy are at an increased risk of death.[141] This increase is between 1.6 and 4.1 fold greater than that of the general population.[142] The greatest increase in mortality from epilepsy is among the elderly.[142] Those with epilepsy due to an unknown cause have little increased risk.[142] Mortality is often related to: the underlying cause of the seizures, status epilepticus, suicide, trauma, and sudden unexpected death in epilepsy (SUDEP).[141] Death from status epilepticus is primarily due to an underlying problem rather than missing doses of medications.[141] The risk of suicide is between 2 and 6 times higher in those with epilepsy;[143][144] the cause of this is unclear.[143] SUDEP appears to be partly related to the frequency of generalized tonic-clonic seizures[145] and accounts for about 15% of epilepsy-related deaths;[140] it is unclear how to decrease its risk.[145] In the United Kingdom, it is estimated that 40–60% of deaths are possibly preventable.[25] In the developing world, many deaths are due to untreated epilepsy leading to falls or status epilepticus.[19] Epidemiology Epilepsy is one of the most common serious neurological disorders[146] affecting about 39 million people as of 2015.[8] It affects 1% of the population by age 20 and 3% of the population by age 75.[17] It is more common in males than females with the overall difference being small.[19][49] Most of those with the disorder (80%) are in low income populations[147] or the developing world.[30] The estimated prevalence of active epilepsy (as of 2012) is in the range 3–10 per 1,000, with active epilepsy defined as someone with epilepsy who has had a least one unprovoked seizure in the last five years.[49][148] Epilepsy begins each year in 40–70 per 100,000 in developed countries and 80–140 per 100,000 in developing countries.[30] Poverty is a risk and includes both being from a poor country and being poor relative to others within one's country.[19] In the developed world epilepsy most commonly starts either in the young or in the old.[19] In the developing world its onset is more common in older children and young adults due to the higher rates of trauma and infectious diseases.[19] In developed countries the number of cases a year has decreased in children and increased among the elderly between the 1970s and 2003.[148] This has been attributed partly to better survival following strokes in the elderly.[49] History See also: On the Sacred Disease Hippocrates, 17th century engraving by Peter Paul Rubens of an antique bust The oldest medical records show that epilepsy has been affecting people at least since the beginning of recorded history.[149] Throughout ancient history, the disease was thought to be a spiritual condition.[149] The world's oldest description of an epileptic seizure comes from a text in Akkadian (a language used in ancient Mesopotamia) and was written around 2000 BC.[23] The person described in the text was diagnosed as being under the influence of a moon god, and underwent an exorcism.[23] Epileptic seizures are listed in the Code of Hammurabi (c. 1790 BC) as reason for which a purchased slave may be returned for a refund,[23] and the Edwin Smith Papyrus (c. 1700 BC) describes cases of individuals with epileptic convulsions.[23] The oldest known detailed record of the disease itself is in the Sakikku, a Babylonian cuneiform medical text from 1067–1046 BC.[149] This text gives signs and symptoms, details treatment and likely outcomes,[23] and describes many features of the different seizure types.[149] As the Babylonians had no biomedical understanding of the nature of disease, they attributed the seizures to possession by evil spirits and called for treating the condition through spiritual means.[149] Around 900 BC, Punarvasu Atreya described epilepsy as loss of consciousness;[150] this definition was carried forward into the Ayurvedic text of Charaka Samhita (about 400 BC).[151] The ancient Greeks had contradictory views of the disease. They thought of epilepsy as a form of spiritual possession, but also associated the condition with genius and the divine. One of the names they gave to it was the sacred disease (ἠ ἱερὰ νόσος).[23][152] Epilepsy appears within Greek mythology: it is associated with the Moon goddesses Selene and Artemis, who afflicted those who upset them. The Greeks thought that important figures such as Julius Caesar and Hercules had the disease.[23] The notable exception to this divine and spiritual view was that of the school of Hippocrates. In the fifth century BC, Hippocrates rejected the idea that the disease was caused by spirits. In his landmark work On the Sacred Disease, he proposed that epilepsy was not divine in origin and instead was a medically treatable problem originating in the brain.[23][149] He accused those of attributing a sacred cause to the disease of spreading ignorance through a belief in superstitious magic.[23] Hippocrates proposed that heredity was important as a cause, described worse outcomes if the disease presents at an early age, and made note of the physical characteristics as well as the social shame associated with it.[23] Instead of referring to it as the sacred disease, he used the term great disease, giving rise to the modern term grand mal, used for tonic–clonic seizures.[23] Despite his work detailing the physical origins of the disease, his view was not accepted at the time.[149] Evil spirits continued to be blamed until at least the 17th century.[149] In Ancient Rome people did not eat or drink with the same pottery as that used by someone who was affected.[153] People of the time would spit on their chest believing that this would keep the problem from affecting them.[153] According to Apuleius and other ancient physicians, in order to detect epilepsy, it was common to light a piece of gagates, whose smoke would trigger the seizure.[154] Occasionally a spinning potter's wheel was used, perhaps a reference to photosensitive epilepsy.[155] In most cultures, persons with epilepsy have been stigmatized, shunned, or even imprisoned. As late as in the second half of the 20th century, in Tanzania and other parts of Africa epilepsy was associated with possession by evil spirits, witchcraft, or poisoning and was believed by many to be contagious.[156] In the Salpêtrière, the birthplace of modern neurology, Jean-Martin Charcot found people with epilepsy side by side with the mentally ill, those with chronic syphilis, and the criminally insane.[citation needed] In ancient Rome, epilepsy was known as the morbus comitialis ('disease of the assembly hall') and was seen as a curse from the gods. In northern Italy, epilepsy was once traditionally known as Saint Valentine's malady.[157] In the mid-19th century, the first effective anti-seizure medication, bromide, was introduced.[114] The first modern treatment, phenobarbital, was developed in 1912, with phenytoin coming into use in 1938.[158] Society and culture See also: List of people with epilepsy Stigma Stigma is commonly experienced, around the world, by those with epilepsy.[159] It can affect people economically, socially and culturally.[159] In India and China, epilepsy may be used as justification to deny marriage.[30] People in some areas still believe those with epilepsy to be cursed.[19] In parts of Africa, such as Tanzania and Uganda, epilepsy is incorrectly claimed to be associated with possession by evil spirits, witchcraft, or poisoning and is believed by many to be contagious.[156][19] Before 1971 in the United Kingdom, epilepsy was considered grounds for the annulment of marriage.[30] The stigma may result in some people with epilepsy denying that they have ever had seizures.[49] Economics Seizures result in direct economic costs of about one billion dollars in the United States.[20] Epilepsy resulted in economic costs in Europe of around 15.5 billion euros in 2004.[25] In India epilepsy is estimated to result in costs of US$1.7 billion or 0.5% of the GDP.[30] It is the cause of about 1% of emergency department visits (2% for emergency departments for children) in the United States.[160] Vehicles See also: Epilepsy and driving Those with epilepsy are at about twice the risk of being involved in a motor vehicular collision and thus in many areas of the world are not allowed to drive or only able to drive if certain conditions are met.[22] Diagnostic delay has been suggested to be a cause of some potentially avoidable motor vehicle collisions since at least one study showed that most motor vehicle accidents occurred in those with undiagnosed nonmotor seizures as opposed to those with motor seizures at epilepsy onset.[161] In some places physicians are required by law to report if a person has had a seizure to the licensing body while in others the requirement is only that they encourage the person in question to report it himself.[22] Countries that require physician reporting include Sweden, Austria, Denmark and Spain.[22] Countries that require the individual to report include the UK and New Zealand, and physicians may report if they believe the individual has not already.[22] In Canada, the United States and Australia the requirements around reporting vary by province or state.[22] If seizures are well controlled most feel allowing driving is reasonable.[162] The amount of time a person must be free from seizures before he can drive varies by country.[162] Many countries require one to three years without seizures.[162] In the United States the time needed without a seizure is determined by each state and is between three months and one year.[162] Those with epilepsy or seizures are typically denied a pilot license.[163] In Canada if an individual has had no more than one seizure, they may be considered after five years for a limited license if all other testing is normal.[164] Those with febrile seizures and drug related seizures may also be considered.[164] In the United States, the Federal Aviation Administration does not allow those with epilepsy to get a commercial pilot license.[165] Rarely, exceptions can be made for persons who have had an isolated seizure or febrile seizures and have remained free of seizures into adulthood without medication.[166] In the United Kingdom, a full national private pilot license requires the same standards as a professional driver's license.[167] This requires a period of ten years without seizures while off medications.[168] Those who do not meet this requirement may acquire a restricted license if free from seizures for five years.[167] Support organizations There are organizations that provide support for people and families affected by epilepsy. The Out of the Shadows campaign, a joint effort by the World Health Organization, the International League Against Epilepsy and the International Bureau for Epilepsy, provides help internationally.[30] In the United States, the Epilepsy Foundation is a national organization that works to increase the acceptance of those with the disorder, their ability to function in society and to promote research for a cure.[169] The Epilepsy Foundation, some hospitals, and some individuals also run support groups in the United States.[170] In Australia, the Epilepsy Foundation provides support, delivers education and training and funds research for people living with epilepsy. International Epilepsy Day (World Epilepsy Day) began in 2015 and occurs on the second Monday in February.[171][172] Research See also: Computational models in epilepsy Seizure prediction and modeling Seizure prediction refers to attempts to forecast epileptic seizures based on the EEG before they occur.[173] As of 2011, no effective mechanism to predict seizures has been developed.[173] Kindling, where repeated exposures to events that could cause seizures eventually causes seizures more easily, has been used to create animal models of epilepsy.[174] One of the hypotheses present in the literature is based on inflammatory pathways. Studies supporting this mechanism revealed that inflammatory, glycolipid, and oxidative factors are higher in epilepsy patients, especially those with generalized epilepsy.[175] Potential future therapies Gene therapy is being studied in some types of epilepsy.[176] Medications that alter immune function, such as intravenous immunoglobulins, are poorly supported by evidence.[177] Noninvasive stereotactic radiosurgery is, as of 2012, being compared to standard surgery for certain types of epilepsy.[178] Other animals Main article: Epilepsy in animals Epilepsy occurs in a number of other animals including dogs and cats; it is in fact the most common brain disorder in dogs.[179] It is typically treated with anticonvulsants such as phenobarbital or bromide in dogs and phenobarbital in cats.[179] Imepitoin is also used in dogs.[180] While generalized seizures in horses are fairly easy to diagnose, it may be more difficult in non-generalized seizures and EEGs may be useful.[181] References "Epilepsy Fact sheet". 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Epilepsy & Behavior. 10 (3): 363–76. doi:10.1016/j.yebeh.2007.01.005. PMID 17337248. S2CID 39107474. Shorvon S, Perucca E, Engel J, eds. (2009). The treatment of epilepsy (3rd ed.). Chichester, UK: Wiley-Blackwell. p. 28. ISBN 978-1-4443-1667-4. Archived from the original on 10 June 2016. Bagary M (April 2011). "Epilepsy, antiepileptic drugs and suicidality". Current Opinion in Neurology. 24 (2): 177–82. doi:10.1097/WCO.0b013e328344533e. PMID 21293270. Mula M, Sander JW (August 2013). "Suicide risk in people with epilepsy taking antiepileptic drugs". Bipolar Disorders. 15 (5): 622–7. doi:10.1111/bdi.12091. PMID 23755740. S2CID 40681400. Ryvlin P, Nashef L, Tomson T (May 2013). "Prevention of sudden unexpected death in epilepsy: a realistic goal?". Epilepsia. 54 Suppl 2: 23–8. doi:10.1111/epi.12180. PMID 23646967. Hirtz D, Thurman DJ, Gwinn-Hardy K, Mohamed M, Chaudhuri AR, Zalutsky R (January 2007). "How common are the "common" neurologic disorders?". Neurology. 68 (5): 326–37. doi:10.1212/01.wnl.0000252807.38124.a3. PMID 17261678. S2CID 208246679. Espinosa-Jovel, Camilo; Toledano, Rafael; Aledo-Serrano, Ángel; García-Morales, Irene; Gil-Nagel, Antonio (1 March 2018). "Epidemiological profile of epilepsy in low income populations". Seizure: European Journal of Epilepsy. 56: 67–72. doi:10.1016/j.seizure.2018.02.002. ISSN 1059-1311. PMID 29453113. Sander JW (April 2003). "The epidemiology of epilepsy revisited". Current Opinion in Neurology. 16 (2): 165–70. doi:10.1097/00019052-200304000-00008. PMID 12644744. Saraceno B, Avanzini G, Lee P, eds. (2005). Atlas: Epilepsy Care in the World (PDF). World Health Organization. ISBN 978-92-4-156303-1. Retrieved 20 December 2013. Eadie MJ, Bladin PF (2001). A Disease Once Sacred: A History of the Medical Understanding of Epilepsy. John Libbey Eurotext. ISBN 978-0-86196-607-3. "Epilepsy: An historical overview". World Health Organization. February 2001. Archived from the original on 30 October 2013. Retrieved 27 December 2013. "Epilepsy: historical overview". World Health Organization. Archived from the original on 20 January 2011. Retrieved 20 March 2011. Temkin O (1 March 1994). The Falling Sickness: A History of Epilepsy from the Greeks to the Beginnings of Modern Neurology. JHU Press. p. Section 1. ISBN 9781421400532. Stol M (1993). Epilepsy in Babylonia. BRILL. p. 143. ISBN 978-9072371638. Harding GF, Jeavons PM (1994). Photosensitive Epilepsy. Cambridge University Press. p. 2. ISBN 9781898683025. Jilek-Aall L (March 1999). "Morbus sacer in Africa: some religious aspects of epilepsy in traditional cultures". Epilepsia. 40 (3): 382–6. doi:10.1111/j.1528-1157.1999.tb00723.x. PMID 10080524. Illes J (2011). Encyclopedia of Mystics, Saints & Sages. HarperCollins. p. 1238. ISBN 978-0-06-209854-2. Archived from the original on 11 January 2014. Saint Valentine is invoked for healing as well as love. He protects against fainting and is requested to heal epilepsy and other seizure disorders. In northern Italy, epilepsy was once traditionally known as Saint Valentine's Malady. Caravati EM (2004). Medical toxicology (3rd ed.). Philadelphia [u.a.]: Lippincott Williams & Wilkins. p. 789. ISBN 978-0-7817-2845-4. de Boer HM (December 2010). "Epilepsy stigma: moving from a global problem to global solutions". Seizure. 19 (10): 630–6. doi:10.1016/j.seizure.2010.10.017. PMID 21075013. S2CID 17282975. Martindale JL, Goldstein JN, Pallin DJ (February 2011). "Emergency department seizure epidemiology". Emergency Medicine Clinics of North America. 29 (1): 15–27. doi:10.1016/j.emc.2010.08.002. PMID 21109099. Pellinen, Jacob; Tafuro, Erica; Yang, Annie; Price, Dana; Friedman, Daniel; Holmes, Manisha; Barnard, Sarah; Detyniecki, Kamil; Hegde, Manu; Hixson, John; Haut, Sheryl (2020). "Focal nonmotor versus motor seizures: The impact on diagnostic delay in focal epilepsy". Epilepsia. 61 (12): 2643–2652. doi:10.1111/epi.16707. ISSN 1528-1167. PMID 33078409. S2CID 224811014. Engel J, Pedley TA, eds. (2008). Epilepsy : a comprehensive textbook (2nd ed.). Philadelphia: Wolters Kluwer Health/Lippincott Williams & Wilkins. p. 2279. ISBN 978-0-7817-5777-5. Bor R (2012). Aviation Mental Health: Psychological Implications for Air Transportation. Ashgate Publishing. p. 148. ISBN 978-1-4094-8491-2. "Seizure Disorders". Transport Canada. Government of Canada. Archived from the original on 30 December 2013. Retrieved 29 December 2013. Wilner AN (2008). Epilepsy 199 answers : a doctor responds to his patients' questions (3rd ed.). New York: Demos Health. p. 52. ISBN 978-1-934559-96-3. Archived from the original on 17 May 2016. "Guide for Aviation Medical Examiners". Federal Aviation Administration. Archived from the original on 17 October 2013. Retrieved 29 December 2013. "National PPL (NPPL) Medical Requirements". Civil Aviation Authority. Archived from the original on 16 October 2013. Retrieved 29 December 2013. Drivers Medical Group (2013). "For Medical Practitioners: At a glance Guide to the current Medical Standards of Fitness to Drive" (PDF). p. 8. Archived (PDF) from the original on 30 December 2013. Retrieved 29 December 2013. "Epilepsy Foundation of America - EFA". Healthfinder.gov. US Department of Health and Human Services. 28 April 2011. Archived from the original on 16 July 2014. Retrieved 28 July 2014. Engel J, Pedley TA, eds. (2008). Epilepsy: a comprehensive textbook (2nd ed.). Philadelphia: Wolters Kluwer Health/Lippincott Williams & Wilkins. p. 2245. ISBN 9780781757775. Aleem, MA (February 2015). "Letter: World Epilepsy Day". Epilepsia. 56 (2): 168. doi:10.1111/epi.12814. PMID 25404065. S2CID 11256074. Perucca, Emilio (February 2015). "Commentary: Why an International Epilepsy Day?". Epilepsia. 56 (2): 170–171. doi:10.1111/epi.12813. PMID 25403985. Carney PR, Myers S, Geyer JD (December 2011). "Seizure prediction: methods". Epilepsy & Behavior. 22 Suppl 1: S94–101. doi:10.1016/j.yebeh.2011.09.001. PMC 3233702. PMID 22078526. Engel J, ed. (2008). Epilepsy: a comprehensive textbook (2nd ed.). Philadelphia: Wolters Kluwer Health/Lippincott Williams & Wilkins. p. 426. ISBN 9780781757775. Kegler, Aline; Pascotini, Eduardo T.; Caprara, Ana Letícia Fornari; Arend, Josi; Gabbi, Patricia; Duarte, Marta MMF.; Royes, Luiz Fernando Freire; Fighera, Michele Rechia (February 2021). "Relationship between seizure type, metabolic profile, and inflammatory markers in blood samples of patients with epilepsy". Epileptic Disorders. 23 (1): 74–84. doi:10.1684/epd.2021.1236. ISSN 1294-9361. PMID 33602662. S2CID 231962819. Walker MC, Schorge S, Kullmann DM, Wykes RC, Heeroma JH, Mantoan L (September 2013). "Gene therapy in status epilepticus" (PDF). Epilepsia. 54 Suppl 6: 43–5. doi:10.1111/epi.12275. PMID 24001071. S2CID 13942394. Walker L, Pirmohamed M, Marson AG (June 2013). "Immunomodulatory interventions for focal epilepsy syndromes". The Cochrane Database of Systematic Reviews. 6 (6): CD009945. doi:10.1002/14651858.CD009945.pub2. PMID 23803963. Quigg M, Rolston J, Barbaro NM (January 2012). "Radiosurgery for epilepsy: clinical experience and potential antiepileptic mechanisms". Epilepsia. 53 (1): 7–15. doi:10.1111/j.1528-1167.2011.03339.x. PMC 3519388. PMID 22191545. Thomas WB (January 2010). "Idiopathic epilepsy in dogs and cats". The Veterinary Clinics of North America. Small Animal Practice. 40 (1): 161–79. doi:10.1016/j.cvsm.2009.09.004. PMID 19942062. Rundfeldt C, Löscher W (January 2014). "The pharmacology of imepitoin: the first partial benzodiazepine receptor agonist developed for the treatment of epilepsy". CNS Drugs. 28 (1): 29–43. doi:10.1007/s40263-013-0129-z. PMID 24357084. S2CID 31627280. van der Ree M, Wijnberg I (2012). "A review on epilepsy in the horse and the potential of Ambulatory EEG as a diagnostic tool". The Veterinary Quarterly. 32 (3–4): 159–67. doi:10.1080/01652176.2012.744496. PMID 23163553. S2CID 24726314. Further reading World Health Organization, Department of Mental Health and Substance Abuse, Programme for Neurological Diseases and Neuroscience; Global Campaign against Epilepsy; International League against Epilepsy (2005). Atlas, epilepsy care in the world, 2005 (PDF). Geneva: Programme for Neurological Diseases and Neuroscience, Department of Mental Health and Substance Abuse, World Health Organization. ISBN 978-92-4-156303-1. Scheffer IE, Berkovic S, Capovilla G, Connolly MB, French J, Guilhoto L, Hirsch E, Jain S, Mathern GW, Moshé SL, Nordli DR, Perucca E, Tomson T, Wiebe S, Zhang YH, Zuberi SM (April 2017). "ILAE classification of the epilepsies: Position paper of the ILAE Commission for Classification and Terminology". Epilepsia. 58 (4): 512–521. doi:10.1111/epi.13709. PMC 5386840. PMID 28276062. External links Classification D ICD-10: G40-G41ICD-9-CM: 345MeSH: D004827DiseasesDB: 4366SNOMED CT: 84757009 External resources MedlinePlus: 000694eMedicine: neuro/415 Wikimedia Commons has media related to Epilepsy. Wikiquote has quotations related to: Epilepsy Epilepsy at Curlie World Health Organization fact sheet "Epilepsy Basics: An Overview for Behavioral Health Providers". YouTube. Epilepsy Foundation. 30 May 2019. Archived from the original on 11 December 2021. "What To Do If Someone Has A Seizure - First Aid Training - St John Ambulance". YouTube. St John Ambulance. 1 February 2017. Archived from the original on 11 December 2021. vte Diseases of the nervous system, primarily CNS vte Seizures and epilepsy Authority control Edit this at Wikidata Categories: EpilepsyDisorders causing seizuresNeurological disorders in children

 

Epilepsy

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Epilepsy
Other namesSeizure disorder
The electroencephalogram recording of a person with childhood absence epilepsy showing a seizure. The waves are black on a white background.
Generalized 3 Hz spike-and-wave discharges on an electroencephalogram
SpecialtyNeurology
SymptomsPeriods of vigorous shaking, nearly undetectable spells[1]
DurationLong term[1]
CausesUnknown, brain injurystrokebrain tumors, infections of the brain, birth defects[1][2][3]
Diagnostic methodElectroencephalogram, ruling out other possible causes[4]
Differential diagnosisFaintingalcohol withdrawalelectrolyte problems[4]
TreatmentMedication, surgeryneurostimulation, dietary changes[5][6]
PrognosisControllable in 69%[7]
Frequency39 million / 0.5% (2015)[8]
Deaths125,000 (2015)[9]

Epilepsy is a group of non-communicable neurological disorders characterized by recurrent epileptic seizures.[10][11][12] Epileptic seizures can vary from brief and nearly undetectable periods to long periods of vigorous shaking due to abnormal electrical activity in the brain.[1] These episodes can result in physical injuries, either directly such as broken bones or through causing accidents.[1] In epilepsy, seizures tend to recur and may have no immediate underlying cause.[10] Isolated seizures that are provoked by a specific cause such as poisoning are not deemed to represent epilepsy.[13] People with epilepsy may be treated differently in various areas of the world and experience varying degrees of social stigma due to their condition.[1]

The underlying mechanism of epileptic seizures is excessive and abnormal neuronal activity in the cortex of the brain[13] which can be observed in the electroencephalogram (EEG) of an individual. The reason this occurs in most cases of epilepsy is unknown (idiopathic);[1] some cases occur as the result of brain injurystrokebrain tumors, infections of the brain, or birth defects through a process known as epileptogenesis.[1][2][3] Known genetic mutations are directly linked to a small proportion of cases.[4][14] The diagnosis involves ruling out other conditions that might cause similar symptoms, such as fainting, and determining if another cause of seizures is present, such as alcohol withdrawal or electrolyte problems.[4] This may be partly done by imaging the brain and performing blood tests.[4] Epilepsy can often be confirmed with an electroencephalogram (EEG), but a normal test does not rule out the condition.[4]

Epilepsy that occurs as a result of other issues may be preventable.[1] Seizures are controllable with medication in about 69% of cases;[7] inexpensive anti-seizure medications are often available.[1] In those whose seizures do not respond to medication, surgeryneurostimulation or dietary changes may then be considered.[12][5][6] Not all cases of epilepsy are lifelong, and many people improve to the point that treatment is no longer needed.[1]

As of 2020, about 50 million people suffer from epilepsy.[12] Nearly 80% of cases occur in the developing world.[1] In 2015, it resulted in 125,000 deaths, an increase from 112,000 in 1990.[9][15] Epilepsy is more common in older people.[16][17] In the developed world, onset of new cases occurs most frequently in babies and the elderly.[18] In the developing world, onset is more common in older children and young adults due to differences in the frequency of the underlying causes.[19] About 5–10% of people will have an unprovoked seizure by the age of 80,[20] with the chance of experiencing a second seizure rising to between 40% and 50%.[21] In many areas of the world, those with epilepsy either have restrictions placed on their ability to drive or are not permitted to drive until they are free of seizures for a specific length of time.[22] The word epilepsy is from Ancient Greek ἐπιλαμβάνειν, "to seize, possess, or afflict".[23]

Signs and symptoms[edit]

A still image of a generalized seizure
A bite to the tip of the tongue due to a seizure

Epilepsy is characterized by a long-term risk of recurrent epileptic seizures.[24] These seizures may present in several ways depending on the parts of the brain involved and the person's age.[24][25]

Seizures[edit]

The most common type (60%) of seizures are convulsive which involve involuntary muscle contractions.[25] Of these, one-third begin as generalized seizures from the start, affecting both hemispheres of the brain and impairing consciousness.[25] Two-thirds begin as focal seizures (which affect one hemisphere of the brain) which may progress to generalized seizures.[25] The remaining 40% of seizures are non-convulsive. An example of this type is the absence seizure, which presents as a decreased level of consciousness and usually lasts about 10 seconds.[2][26]

Certain experiences, known as auras often precede Focal seizures.[27] The seizures can include sensory (visual, hearing, or smell), psychic, autonomic, and motor phenomena depending on which part of the brain is involved.[2] Muscle jerks may start in a specific muscle group and spread to surrounding muscle groups in which case it is known as a Jacksonian march.[28] Automatisms may occur, which are non-consciously-generated activities and mostly simple repetitive movements like smacking the lips or more complex activities such as attempts to pick up something.[28]

There are six main types of generalized seizures: tonic-clonictonicclonicmyoclonicabsence, and atonic seizures.[29] They all involve loss of consciousness and typically happen without warning.

Tonic-clonic seizures occur with a contraction of the limbs followed by their extension and arching of the back which lasts 10–30 seconds (the tonic phase). A cry may be heard due to contraction of the chest muscles, followed by a shaking of the limbs in unison (clonic phase). Tonic seizures produce constant contractions of the muscles. A person often turns blue as breathing is stopped. In clonic seizures there is shaking of the limbs in unison. After the shaking has stopped it may take 10–30 minutes for the person to return to normal; this period is called the "postictal state" or "postictal phase." Loss of bowel or bladder control may occur during a seizure.[30] People experiencing a seizure may bite their tongue, either the tip or on the sides;[31] in tonic-clonic seizure, bites to the sides are more common.[31] Tongue bites are also relatively common in psychogenic non-epileptic seizures.[31]

Myoclonic seizures involve very brief spasms of muscles in either a few areas or all over.[32][33] These sometimes cause the person to fall, which can cause injury.[32] Absence seizures can be subtle with only a slight turn of the head or eye blinking with impaired consciousness;[2] typically, the person does not fall over and returns to normal right after it ends.[2] Atonic seizures involve losing muscle activity for greater than one second,[28] typically occurring on both sides of the body.[28] Rarer seizure types can cause involuntary unnatural laughter (gelastic), crying (dyscrastic), or more complex experiences such as déjà vu.[33]

About 6% of those with epilepsy have seizures that are often triggered by specific events and are known as reflex seizures.[34] Those with reflex epilepsy have seizures that are only triggered by specific stimuli.[35] Common triggers include flashing lights and sudden noises.[34] In certain types of epilepsy, seizures happen more often during sleep,[36] and in other types they occur almost only when sleeping.[37]

Post-ictal[edit]

After the active portion of a seizure (the ictal state) there is typically a period of recovery during which there is confusion, referred to as the postictal period, before a normal level of consciousness returns.[27] It usually lasts 3 to 15 minutes[38] but may last for hours.[39] Other common symptoms include feeling tired, headache, difficulty speaking, and abnormal behavior.[39] Psychosis after a seizure is relatively common, occurring in 6–10% of people.[40] Often people do not remember what happened during this time.[39] Localized weakness, known as Todd's paralysis, may also occur after a focal seizure. It would typically last for seconds to minutes but may rarely last for a day or two.[41]

Psychosocial[edit]

Epilepsy can have adverse effects on social and psychological well-being.[25] These effects may include social isolation, stigmatization, or disability.[25] They may result in lower educational achievement and worse employment outcomes.[25] Learning disabilities are common in those with the condition, and especially among children with epilepsy.[25] The stigma of epilepsy can also affect the families of those with the disorder.[30]

Certain disorders occur more often in people with epilepsy, depending partly on the epilepsy syndrome present. These include depressionanxietyobsessive–compulsive disorder (OCD),[42] and migraine.[43] Attention deficit hyperactivity disorder (ADHD) affects three to five times more children with epilepsy than children without the condition.[44] ADHD and epilepsy have significant consequences on a child's behavioral, learning, and social development.[45] Epilepsy is also more common in children with autism.[46]

Causes[edit]

Epilepsy can have both genetic and acquired causes, with the interaction of these factors in many cases.[47] Established acquired causes include serious brain trauma, stroke, tumours, and brain problems resulting from a previous infection.[47] In about 60% of cases, the cause is unknown.[25][30] Epilepsies caused by geneticcongenital, or developmental conditions are more common among younger people, while brain tumors and strokes are more likely in older people.[25]

Seizures may also occur as a consequence of other health problems;[29] if they occur right around a specific cause, such as a stroke, head injury, toxic ingestion, or metabolic problem, they are known as acute symptomatic seizures and are in the broader classification of seizure-related disorders rather than epilepsy itself.[48][49]

Genetics[edit]

Genetics is believed to be involved in the majority of cases, either directly or indirectly.[14] Some epilepsies are due to a single gene defect (1–2%); most are due to the interaction of multiple genes and environmental factors.[14] Each of the single gene defects is rare, with more than 200 in all described.[50] Most genes involved affect ion channels, either directly or indirectly.[47] These include genes for ion channels themselves, enzymesGABA, and G protein-coupled receptors.[32]

In identical twins, if one is affected, there is a 50–60% chance that the other will also be affected.[14] In non-identical twins, the risk is 15%.[14] These risks are greater in those with generalized rather than focal seizures.[14] If both twins are affected, most of the time they have the same epileptic syndrome (70–90%).[14] Other close relatives of a person with epilepsy have a risk five times that of the general population.[51] Between 1 and 10% of those with Down syndrome and 90% of those with Angelman syndrome have epilepsy.[51]

Acquired[edit]

Epilepsy may occur as a result of several other conditions, including tumors, strokes, head trauma, previous infections of the central nervous system, genetic abnormalities, and as a result of brain damage around the time of birth.[29][30] Of those with brain tumors, almost 30% have epilepsy, making them the cause of about 4% of cases.[51] The risk is greatest for tumors in the temporal lobe and those that grow slowly.[51] Other mass lesions such as cerebral cavernous malformations and arteriovenous malformations have risks as high as 40–60%.[51] Of those who have had a stroke, 2–4% develop epilepsy.[51] In the United Kingdom, strokes account for 15% of cases and they are believed to be the cause in 30% of the elderly.[25][51] Between 6 and 20% of epilepsy is believed to be due to head trauma.[51] Mild brain injury increases the risk about two-fold while severe brain injury increases the risk seven-fold.[51] In those who have experienced a high-powered gunshot wound to the head, the risk is about 50%.[51]

Some evidence links epilepsy and celiac disease and non-celiac gluten sensitivity, while other evidence does not. There appears to be a specific syndrome that includes coeliac disease, epilepsy, and calcifications in the brain.[52][53] A 2012 review estimates that between 1% and 6% of people with epilepsy have coeliac disease while 1% of the general population has the condition.[53]

The risk of epilepsy following meningitis is less than 10%; it more commonly causes seizures during the infection itself.[51] In herpes simplex encephalitis the risk of a seizure is around 50%[51] with a high risk of epilepsy following (up to 25%).[54][55] A form of an infection with the pork tapeworm (cysticercosis), in the brain, is known as neurocysticercosis, and is the cause of up to half of epilepsy cases in areas of the world where the parasite is common.[51] Epilepsy may also occur after other brain infections such as cerebral malariatoxoplasmosis, and toxocariasis.[51] Chronic alcohol use increases the risk of epilepsy: those who drink six units of alcohol per day have a 2.5-fold increase in risk.[51] Other risks include Alzheimer's diseasemultiple sclerosistuberous sclerosis, and autoimmune encephalitis.[51] Getting vaccinated does not increase the risk of epilepsy.[51] Malnutrition is a risk factor seen mostly in the developing world, although it is unclear however if it is a direct cause or an association.[19] People with cerebral palsy have an increased risk of epilepsy, with half of people with spastic quadriplegia and spastic hemiplegia having the disease.[56]

Mechanism[edit]

Normally brain electrical activity is non-synchronous, as large numbers of neurons do not normally fire at the same time, but rather fire in order as signals travel throughout the brain.[2] Neuron activity is regulated by various factors both within the cell and the cellular environment. Factors within the neuron include the type, number and distribution of ion channels, changes to receptors and changes of gene expression.[57] Factors around the neuron include ion concentrations, synaptic plasticity and regulation of transmitter breakdown by glial cells.[57][58]

Epilepsy[edit]

The exact mechanism for epilepsy is unknown,[59] but a little is known about its cellular and network mechanisms. However, it is unknown under which circumstances the brain shifts into the activity of a seizure with its excessive synchronization.[60][61] Changes in MicroRNAs (miRNAs) levels seems to play a leading role. MicroRNAs (miRNAs) are a family of small non-coding RNAs that control the expression levels of multiple proteins by decreasing mRNA stability and translation, and could therefore be key regulatory mechanisms and therapeutic targets in epilepsy [62]

In epilepsy, the resistance of excitatory neurons to fire during this period is decreased.[2] This may occur due to changes in ion channels or inhibitory neurons not functioning properly.[2] This then results in a specific area from which seizures may develop, known as a "seizure focus".[2] Another mechanism of epilepsy may be the up-regulation of excitatory circuits or down-regulation of inhibitory circuits following an injury to the brain.[2][3] These secondary epilepsies occur through processes known as epileptogenesis.[2][3] Failure of the blood–brain barrier may also be a causal mechanism as it would allow substances in the blood to enter the brain.[63]

Seizures[edit]

There is evidence that epileptic seizures are usually not a random event. Seizures are often brought on by factors (also known as triggers) such as stress, excessive alcohol use, flickering light, or a lack of sleep, among others. The term seizure threshold is used to indicate the amount of stimulus necessary to bring about a seizure, this seizure threshold is lowered in epilepsy.[60]

In epileptic seizures a group of neurons begin firing in an abnormal, excessive,[25] and synchronized manner.[2] This results in a wave of depolarization known as a paroxysmal depolarizing shift.[64] Normally, after an excitatory neuron fires it becomes more resistant to firing for a period of time.[2] This is due in part to the effect of inhibitory neurons, electrical changes within the excitatory neuron, and the negative effects of adenosine.[2]

Focal seizures begin in one area of the brain while generalized seizures begin in both hemispheres.[29] Some types of seizures may change brain structure, while others appear to have little effect.[65] Gliosis, neuronal loss, and atrophy of specific areas of the brain are linked to epilepsy but it is unclear if epilepsy causes these changes or if these changes result in epilepsy.[65]

The seizures can be described on different scales, from the cellular level[66] to the whole brain.[67] These are several concomitant factor, which on different scale can "drive" the brain to pathological states and trigger a seizure.

Diagnosis[edit]

An EEG can aid in locating the focus of the epileptic seizure.

The diagnosis of epilepsy is typically made based on observation of the seizure onset and the underlying cause.[25] An electroencephalogram (EEG) to look for abnormal patterns of brain waves and neuroimaging (CT scan or MRI) to look at the structure of the brain are also usually part of the initial investigations.[25] While figuring out a specific epileptic syndrome is often attempted, it is not always possible.[25] Video and EEG monitoring may be useful in difficult cases.[68]

Definition[edit]

Epilepsy is a disorder of the brain defined by any of the following conditions:[11]

  1. At least two unprovoked (or reflex) seizures occurring more than 24 hours apart
  2. One unprovoked (or reflex) seizure and a probability of further seizures similar to the general recurrence risk (at least 60%) after two unprovoked seizures, occurring over the next 10 years
  3. Diagnosis of an epilepsy syndrome

Furthermore, epilepsy is considered to be resolved for individuals who had an age-dependent epilepsy syndrome but are now past that age or those who have remained seizure-free for the last 10 years, with no seizure medicines for the last 5 years.[11]

This 2014 definition of the International League Against Epilepsy[11] is a clarification of the ILAE 2005 conceptual definition, according to which epilepsy is "a disorder of the brain characterized by an enduring predisposition to generate epileptic seizures and by the neurobiologic, cognitive, psychological, and social consequences of this condition. The definition of epilepsy requires the occurrence of at least one epileptic seizure."[13][69]

It is, therefore, possible to outgrow epilepsy or to undergo treatment that causes epilepsy to be resolved, but with no guarantee that it will not return. In the definition, epilepsy is now called a disease, rather than a disorder. This was a decision of the executive committee of the ILAE, taken because the word "disorder," while perhaps having less stigma than does "disease," also does not express the degree of seriousness that epilepsy deserves.[11]

The definition is practical in nature and is designed for clinical use. In particular, it aims to clarify when an "enduring predisposition" according to the 2005 conceptual definition is present. Researchers, statistically-minded epidemiologists, and other specialized groups may choose to use the older definition or a definition of their own devising. The ILAE considers doing so is perfectly allowable, so long as it is clear what definition is being used.[11]

Classification[edit]

Revised operational scheme of seizure classification, ILAE, 2017

In contrast to the classification of seizures which focuses on what happens during a seizure, the classification of epilepsies focuses on the underlying causes. When a person is admitted to hospital after an epileptic seizure the diagnostic workup results preferably in the seizure itself being classified (e.g. tonic-clonic) and in the underlying disease being identified (e.g. hippocampal sclerosis).[68] The name of the diagnosis finally made depends on the available diagnostic results and the applied definitions and classifications (of seizures and epilepsies) and its respective terminology.

The International League Against Epilepsy (ILAE) provided a classification of the epilepsies and epileptic syndromes in 1989 as follows:[70]

  1. Localization-related epilepsies and syndromes
    1. Unknown cause (e.g. benign childhood epilepsy with centrotemporal spikes)
    2. Symptomatic/cryptogenic (e.g. temporal lobe epilepsy)
  2. Generalized
    1. Unknown cause (e.g. childhood absence epilepsy)
    2. Cryptogenic or symptomatic (e.g. Lennox-Gastaut syndrome)
    3. Symptomatic (e.g. early infantile epileptic encephalopathy with burst suppression)
  3. Epilepsies and syndromes undetermined whether focal or generalized
    1. With both generalized and focal seizures (e.g. epilepsy with continuous spike-waves during slow wave sleep)
  4. Special syndromes (with situation-related seizures)

This classification was widely accepted but has also been criticized mainly because the underlying causes of epilepsy (which are a major determinant of clinical course and prognosis) were not covered in detail.[71] In 2010 the ILAE Commission for Classification of the Epilepsies addressed this issue and divided epilepsies into three categories (genetic, structural/metabolic, unknown cause)[72] that were refined in their 2011 recommendation into four categories and a number of subcategories reflecting recent technologic and scientific advances.[73]

  1. Unknown cause (mostly genetic or presumed genetic origin)
    1. Pure epilepsies due to single gene disorders
    2. Pure epilepsies with complex inheritance
  2. Symptomatic (associated with gross anatomic or pathologic abnormalities)
    1. Mostly genetic or developmental causation
      1. Childhood epilepsy syndromes
      2. Progressive myoclonic epilepsies
      3. Neurocutaneous syndromes
      4. Other neurologic single gene disorders
      5. Disorders of chromosome function
      6. Developmental anomalies of cerebral structure
    2. Mostly acquired causes
      1. Hippocampal sclerosis
      2. Perinatal and infantile causes
      3. Cerebral trauma, tumor or infection
      4. Cerebrovascular disorders
      5. Cerebral immunologic disorders
      6. Degenerative and other neurologic conditions
  3. Provoked (a specific systemic or environmental factor is the predominant cause of the seizures)
    1. Provoking factors
    2. Reflex epilepsies
  4. Cryptogenic (presumed symptomatic nature in which the cause has not been identified)[73]
A revised, operational classification of seizure types has been introduced by the ILAE.[74] It allows more clearly understood terms and clearly defines focal and generalized onset dichotomy, when possible, even without observing the seizures based on description by patient or observers.[75] The essential changes in terminology are that "partial" is called "focal" with awareness used as a classifier for focal seizures -based on description focal seizures are now defined as behavioral arrest, automatisms, cognitive , autonomic, emotional or hyperkinetic variants while atonic, myoclonic, clonic, infantile spasms, and tonic seizures may be either focal or generalized based on their onset. Several terms that were not clear or consistent in description were removed such as dyscognitive, psychic, simple and complex partial, while "secondarily generalized" is replaced by a clearer term "focal to bilateral tonic clonic seizure". New seizure types now believed to be generalized are eyelid myoclonia, myoclonic atonic, myoclonic absence, and myoclonic tonic clonic. Sometimes it is possible to classify seizures as focal or generalized based on presenting features even though onset in not known. This system is based on the 1981 seizure classification modified in 2010 and principally is the same with an effort to improve the flexibility and clarity of use to understand seizures types better in keeping with current knowledge.

Syndromes[edit]

Cases of epilepsy may be organized into epilepsy syndromes by the specific features that are present. These features include the age that seizure begin, the seizure types, EEG findings, among others. Identifying an epilepsy syndrome is useful as it helps determine the underlying causes as well as what anti-seizure medication should be tried.[29][76]

The ability to categorize a case of epilepsy into a specific syndrome occurs more often with children since the onset of seizures is commonly early.[49] Less serious examples are benign rolandic epilepsy (2.8 per 100,000), childhood absence epilepsy (0.8 per 100,000) and juvenile myoclonic epilepsy (0.7 per 100,000).[49] Severe syndromes with diffuse brain dysfunction caused, at least partly, by some aspect of epilepsy, are also referred to as developmental and epileptic encephalopathies. These are associated with frequent seizures that are resistant to treatment and cognitive dysfunction, for instance Lennox–Gastaut syndrome (1-2% of all persons with epilepsy),[77] Dravet syndrome(1: 15000-40000 worldwide[78]), and West syndrome(1-9: 100000[79]).[80] Genetics is believed to play an important role in epilepsies by a number of mechanisms. Simple and complex modes of inheritance have been identified for some of them. However, extensive screening have failed to identify many single gene variants of large effect.[81] More recent exome and genome sequencing studies have begun to reveal a number of de novo gene mutations that are responsible for some epileptic encephalopathies, including CHD2 and SYNGAP1[82][83][84] and DNM1GABBR2FASN and RYR3.[85]

Syndromes in which causes are not clearly identified are difficult to match with categories of the current classification of epilepsy. Categorization for these cases was made somewhat arbitrarily.[73] The idiopathic (unknown cause) category of the 2011 classification includes syndromes in which the general clinical features and/or age specificity strongly point to a presumed genetic cause.[73] Some childhood epilepsy syndromes are included in the unknown cause category in which the cause is presumed genetic, for instance benign rolandic epilepsy. Others are included in symptomatic despite a presumed genetic cause (in at least in some cases), for instance Lennox-Gastaut syndrome.[73] Clinical syndromes in which epilepsy is not the main feature (e.g. Angelman syndrome) were categorized symptomatic but it was argued to include these within the category idiopathic.[73] Classification of epilepsies and particularly of epilepsy syndromes will change with advances in research.

Tests[edit]

An electroencephalogram (EEG) can assist in showing brain activity suggestive of an increased risk of seizures. It is only recommended for those who are likely to have had an epileptic seizure on the basis of symptoms. In the diagnosis of epilepsy, electroencephalography may help distinguish the type of seizure or syndrome present.[86] In children it is typically only needed after a second seizure unless specified by a specialist. It cannot be used to rule out the diagnosis and may be falsely positive in those without the disease.[86] In certain situations it may be useful to perform the EEG while the affected individual is sleeping or sleep deprived.[68]

Diagnostic imaging by CT scan and MRI is recommended after a first non-febrile seizure to detect structural problems in and around the brain.[68] MRI is generally a better imaging test except when bleeding is suspected, for which CT is more sensitive and more easily available.[20] If someone attends the emergency room with a seizure but returns to normal quickly, imaging tests may be done at a later point.[20] If a person has a previous diagnosis of epilepsy with previous imaging, repeating the imaging is usually not needed even if there are subsequent seizures.[68][87]

For adults, the testing of electrolyte, blood glucose and calcium levels is important to rule out problems with these as causes.[68] An electrocardiogram can rule out problems with the rhythm of the heart.[68] A lumbar puncture may be useful to diagnose a central nervous system infection but is not routinely needed.[20] In children additional tests may be required such as urine biochemistry and blood testing looking for metabolic disorders.[68][88] Together with EEG and neuroimaging, genetic testing is becoming one of the most important diagnostic technique for epilepsy, as a diagnosis might be achieved in a relevant proportion of cases with severe epilepsies, both in children and adults.[89] For those with negative genetic testing, in some it might be important to repeat or re-analyze previous genetic studies after 2–3 years.[90]

A high blood prolactin level within the first 20 minutes following a seizure may be useful to help confirm an epileptic seizure as opposed to psychogenic non-epileptic seizure.[91][92] Serum prolactin level is less useful for detecting focal seizures.[93] If it is normal an epileptic seizure is still possible[92] and a serum prolactin does not separate epileptic seizures from syncope.[94] It is not recommended as a routine part of the diagnosis of epilepsy.[68]

Differential diagnosis[edit]

Diagnosis of epilepsy can be difficult. A number of other conditions may present very similar signs and symptoms to seizures, including syncopehyperventilationmigrainesnarcolepsypanic attacks and psychogenic non-epileptic seizures (PNES).[95][96] In particular a syncope can be accompanied by a short episode of convulsions.[97] Nocturnal frontal lobe epilepsy, often misdiagnosed as nightmares, was considered to be a parasomnia but later identified to be an epilepsy syndrome.[98] Attacks of the movement disorder paroxysmal dyskinesia may be taken for epileptic seizures.[99] The cause of a drop attack can be, among many others, an atonic seizure.[96]

Children may have behaviors that are easily mistaken for epileptic seizures but are not. These include breath-holding spellsbedwettingnight terrorstics and shudder attacks.[96] Gastroesophageal reflux may cause arching of the back and twisting of the head to the side in infants, which may be mistaken for tonic-clonic seizures.[96]

Misdiagnosis is frequent (occurring in about 5 to 30% of cases).[25] Different studies showed that in many cases seizure-like attacks in apparent treatment-resistant epilepsy have a cardiovascular cause.[97][100] Approximately 20% of the people seen at epilepsy clinics have PNES[20] and of those who have PNES about 10% also have epilepsy;[101] separating the two based on the seizure episode alone without further testing is often difficult.[101]

Prevention[edit]

While many cases are not preventable, efforts to reduce head injuries, provide good care around the time of birth, and reduce environmental parasites such as the pork tapeworm may be effective.[30] Efforts in one part of Central America to decrease rates of pork tapeworm resulted in a 50% decrease in new cases of epilepsy.[19]

Management[edit]

Wristbands or bracelets denoting their condition are occasionally worn by epileptics should they need medical assistance.

Epilepsy is usually treated with daily medication once a second seizure has occurred,[25][68] while medication may be started after the first seizure in those at high risk for subsequent seizures.[68] Supporting people's self management of their condition may be useful.[102] In drug-resistant cases different management options may be looked at including a special diet, the implantation of a neurostimulator, or neurosurgery.

First aid[edit]

Rolling people with an active tonic-clonic seizure onto their side and into the recovery position helps prevent fluids from getting into the lungs.[103] Putting fingers, a bite block or tongue depressor in the mouth is not recommended as it might make the person vomit or result in the rescuer being bitten.[27][103] Efforts should be taken to prevent further self-injury.[27] Spinal precautions are generally not needed.[103]

If a seizure lasts longer than 5 minutes or if there are more than two seizures in an hour without a return to a normal level of consciousness between them, it is considered a medical emergency known as status epilepticus.[68][104] This may require medical help to keep the airway open and protected;[68] a nasopharyngeal airway may be useful for this.[103] At home the recommended initial medication for seizure of a long duration is midazolam placed in the mouth.[105] Diazepam may also be used rectally.[105] In hospital, intravenous lorazepam is preferred.[68] If two doses of benzodiazepines are not effective, other medications such as phenytoin are recommended.[68] Convulsive status epilepticus that does not respond to initial treatment typically requires admission to the intensive care unit and treatment with stronger agents such as thiopentone or propofol.[68]

Medications[edit]

Anticonvulsants

The mainstay treatment of epilepsy is anticonvulsant medications, possibly for the person's entire life.[12][25] The choice of anticonvulsant is based on seizure type, epilepsy syndrome, other medications used, other health problems, and the person's age and lifestyle.[105] A single medication is recommended initially;[106] if this is not effective, switching to a single other medication is recommended.[68] Two medications at once is recommended only if a single medication does not work.[68] In about half, the first agent is effective; a second single agent helps in about 13% and a third or two agents at the same time may help an additional 4%.[107] About 30% of people continue to have seizures despite anticonvulsant treatment.[7]

There are a number of medications available including phenytoincarbamazepine[108] and valproate. Evidence suggests that phenytoin, carbamazepine, and valproate may be equally effective in both focal and generalized seizures.[109][110] Controlled release carbamazepine appears to work as well as immediate release carbamazepine, and may have fewer side effects.[111] In the United Kingdom, carbamazepine or lamotrigine are recommended as first-line treatment for focal seizures, with levetiracetam and valproate as second-line due to issues of cost and side effects.[68] Valproate is recommended first-line for generalized seizures with lamotrigine being second-line.[68] In those with absence seizures, ethosuximide or valproate are recommended; valproate is particularly effective in myoclonic seizures and tonic or atonic seizures.[68] If seizures are well-controlled on a particular treatment, it is not usually necessary to routinely check the medication levels in the blood.[68]

The least expensive anticonvulsant is phenobarbital at around US$5 a year.[19] The World Health Organization gives it a first-line recommendation in the developing world and it is commonly used there.[112][113] Access however may be difficult as some countries label it as a controlled drug.[19]

Adverse effects from medications are reported in 10 to 90% of people, depending on how and from whom the data is collected.[114] Most adverse effects are dose-related and mild.[114] Some examples include mood changes, sleepiness, or an unsteadiness in gait.[114] Certain medications have side effects that are not related to dose such as rashes, liver toxicity, or suppression of the bone marrow.[114] Up to a quarter of people stop treatment due to adverse effects.[114] Some medications are associated with birth defects when used in pregnancy.[68] Many of the common used medications, such as valproate, phenytoin, carbamazepine, phenobarbital, and gabapentin have been reported to cause increased risk of birth defects,[115] especially when used during the first trimester.[116] Despite this, treatment is often continued once effective, because the risk of untreated epilepsy is believed to be greater than the risk of the medications.[116] Among the antiepileptic medications, levetiracetam and lamotrigine seem to carry the lowest risk of causing birth defects.[115]

Slowly stopping medications may be reasonable in some people who do not have a seizure for two to four years; however, around a third of people have a recurrence, most often during the first six months.[68][117] Stopping is possible in about 70% of children and 60% of adults.[30] Measuring medication levels is not generally needed in those whose seizures are well controlled.[87]

Surgery[edit]

Epilepsy surgery may be an option for people with focal seizures that remain a problem despite other treatments.[118][119] These other treatments include at least a trial of two or three medications.[120] The goal of surgery is total control of seizures[121] and this may be achieved in 60–70% of cases.[120] Common procedures include cutting out the hippocampus via an anterior temporal lobe resection, removal of tumors, and removing parts of the neocortex.[120] Some procedures such as a corpus callosotomy are attempted in an effort to decrease the number of seizures rather than cure the condition.[120] Following surgery, medications may be slowly withdrawn in many cases.[120][118]

Neurostimulation may be another option in those who are not candidates for surgery.[68] Three types have been used in those who do not respond to medications: vagus nerve stimulationanterior thalamic stimulation, and closed-loop responsive stimulation.[5][122][123]

Diet[edit]

There is promising evidence that a ketogenic diet (high-fatlow-carbohydrate, adequate-protein) decreases the number of seizures and eliminates seizures in some; however, further research is necessary.[6] It is a reasonable option in those who have epilepsy that is not improved with medications and for whom surgery is not an option.[6] About 10% stay on the diet for a few years due to issues of effectiveness and tolerability.[6] Side effects include stomach and intestinal problems in 30%, and there are long-term concerns about heart disease.[6] Less radical diets are easier to tolerate and may be effective.[6] It is unclear why this diet works.[124] In people with coeliac disease or non-celiac gluten sensitivity and occipital calcifications, a gluten-free diet may decrease the frequency of seizures.[53]

Other[edit]

Avoidance therapy consists of minimizing or eliminating triggers. For example, those who are sensitive to light may have success with using a small television, avoiding video games, or wearing dark glasses.[125] Operant-based biofeedback based on the EEG waves has some support in those who do not respond to medications.[126] Psychological methods should not, however, be used to replace medications.[68]

Exercise has been proposed as possibly useful for preventing seizures,[127] with some data to support this claim.[128] Some dogs, commonly referred to as seizure dogs, may help during or after a seizure.[129][130] It is not clear if dogs have the ability to predict seizures before they occur.[131]

There is moderate-quality evidence supporting the use of psychological interventions along with other treatments in epilepsy.[132] This can improve quality of life, enhance emotional wellbeing, and reduce fatigue in adults and adolescents.[132] Psychological interventions may also improve seizure control for some individuals by promoting self-management and adherence.[132]

As an add-on therapy in those who are not well controlled with other medications, cannabidiol appears to be useful in some children.[133] In 2018 the FDA approved this product for Lennox–Gastaut syndrome and Dravet syndrome.[134]

In pregnancy[edit]

In women of childbearing age, use of antiepileptic drugs is a major concern balancing possible side effects on the fetus against risk from uncontrolled seizures. Use of AEDs entail teratogenic effects including intrauterine growth retardation, major congenital malformations and developmental (neurocognitive) and behavioral issues, that need to be discussed with the patient at the time of starting the AEDs and before they plan pregnancy.[135] Most women with epilepsy receive safe and effective treatment and have normal children, however risks exist. The International League Against Epilepsy created a task force on women and epilepsy which published consensus recommendations to guide therapy decisions till more definitive evidence is available in the future.[135]

Alternative medicine[edit]

Alternative medicine, including acupuncture,[136] routine vitamins,[137] and yoga,[138] have no reliable evidence to support their use in epilepsy. Melatonin, as of 2016, is insufficiently supported by evidence.[139] The trials were of poor methodological quality and it was not possible to draw any definitive conclusions.[139]

Prognosis[edit]

Deaths due to epilepsy per million persons in 2012
  0–7
  8–10
  11–13
  14–17
  18–21
  22–28
  29–37
  38–67
  68–100
  101–232

Epilepsy cannot usually be cured, but medication can control seizures effectively in about 70% of cases.[7] Of those with generalized seizures, more than 80% can be well controlled with medications while this is true in only 50% of people with focal seizures.[5] One predictor of long-term outcome is the number of seizures that occur in the first six months.[25] Other factors increasing the risk of a poor outcome include little response to the initial treatment, generalized seizures, a family history of epilepsy, psychiatric problems, and waves on the EEG representing generalized epileptiform activity.[140] In the developing world, 75% of people are either untreated or not appropriately treated.[30] In Africa, 90% do not get treatment.[30] This is partly related to appropriate medications not being available or being too expensive.[30]

Mortality[edit]

People with epilepsy are at an increased risk of death.[141] This increase is between 1.6 and 4.1 fold greater than that of the general population.[142] The greatest increase in mortality from epilepsy is among the elderly.[142] Those with epilepsy due to an unknown cause have little increased risk.[142]

Mortality is often related to: the underlying cause of the seizures, status epilepticussuicidetrauma, and sudden unexpected death in epilepsy (SUDEP).[141] Death from status epilepticus is primarily due to an underlying problem rather than missing doses of medications.[141] The risk of suicide is between 2 and 6 times higher in those with epilepsy;[143][144] the cause of this is unclear.[143] SUDEP appears to be partly related to the frequency of generalized tonic-clonic seizures[145] and accounts for about 15% of epilepsy-related deaths;[140] it is unclear how to decrease its risk.[145]

In the United Kingdom, it is estimated that 40–60% of deaths are possibly preventable.[25] In the developing world, many deaths are due to untreated epilepsy leading to falls or status epilepticus.[19]

Epidemiology[edit]

Epilepsy is one of the most common serious neurological disorders[146] affecting about 39 million people as of 2015.[8] It affects 1% of the population by age 20 and 3% of the population by age 75.[17] It is more common in males than females with the overall difference being small.[19][49] Most of those with the disorder (80%) are in low income populations[147] or the developing world.[30]

The estimated prevalence of active epilepsy (as of 2012) is in the range 3–10 per 1,000, with active epilepsy defined as someone with epilepsy who has had a least one unprovoked seizure in the last five years.[49][148] Epilepsy begins each year in 40–70 per 100,000 in developed countries and 80–140 per 100,000 in developing countries.[30] Poverty is a risk and includes both being from a poor country and being poor relative to others within one's country.[19] In the developed world epilepsy most commonly starts either in the young or in the old.[19] In the developing world its onset is more common in older children and young adults due to the higher rates of trauma and infectious diseases.[19] In developed countries the number of cases a year has decreased in children and increased among the elderly between the 1970s and 2003.[148] This has been attributed partly to better survival following strokes in the elderly.[49]

History[edit]

Hippocrates, 17th century engraving by Peter Paul Rubens of an antique bust

The oldest medical records show that epilepsy has been affecting people at least since the beginning of recorded history.[149] Throughout ancient history, the disease was thought to be a spiritual condition.[149] The world's oldest description of an epileptic seizure comes from a text in Akkadian (a language used in ancient Mesopotamia) and was written around 2000 BC.[23] The person described in the text was diagnosed as being under the influence of a moon god, and underwent an exorcism.[23] Epileptic seizures are listed in the Code of Hammurabi (c. 1790 BC) as reason for which a purchased slave may be returned for a refund,[23] and the Edwin Smith Papyrus (c. 1700 BC) describes cases of individuals with epileptic convulsions.[23]

The oldest known detailed record of the disease itself is in the Sakikku, a Babylonian cuneiform medical text from 1067–1046 BC.[149] This text gives signs and symptoms, details treatment and likely outcomes,[23] and describes many features of the different seizure types.[149] As the Babylonians had no biomedical understanding of the nature of disease, they attributed the seizures to possession by evil spirits and called for treating the condition through spiritual means.[149] Around 900 BC, Punarvasu Atreya described epilepsy as loss of consciousness;[150] this definition was carried forward into the Ayurvedic text of Charaka Samhita (about 400 BC).[151]

The ancient Greeks had contradictory views of the disease. They thought of epilepsy as a form of spiritual possession, but also associated the condition with genius and the divine. One of the names they gave to it was the sacred disease (ἠ ἱερὰ νόσος).[23][152] Epilepsy appears within Greek mythology: it is associated with the Moon goddesses Selene and Artemis, who afflicted those who upset them. The Greeks thought that important figures such as Julius Caesar and Hercules had the disease.[23] The notable exception to this divine and spiritual view was that of the school of Hippocrates. In the fifth century BC, Hippocrates rejected the idea that the disease was caused by spirits. In his landmark work On the Sacred Disease, he proposed that epilepsy was not divine in origin and instead was a medically treatable problem originating in the brain.[23][149] He accused those of attributing a sacred cause to the disease of spreading ignorance through a belief in superstitious magic.[23] Hippocrates proposed that heredity was important as a cause, described worse outcomes if the disease presents at an early age, and made note of the physical characteristics as well as the social shame associated with it.[23] Instead of referring to it as the sacred disease, he used the term great disease, giving rise to the modern term grand mal, used for tonic–clonic seizures.[23] Despite his work detailing the physical origins of the disease, his view was not accepted at the time.[149] Evil spirits continued to be blamed until at least the 17th century.[149]

In Ancient Rome people did not eat or drink with the same pottery as that used by someone who was affected.[153] People of the time would spit on their chest believing that this would keep the problem from affecting them.[153] According to Apuleius and other ancient physicians, in order to detect epilepsy, it was common to light a piece of gagates, whose smoke would trigger the seizure.[154] Occasionally a spinning potter's wheel was used, perhaps a reference to photosensitive epilepsy.[155]

In most cultures, persons with epilepsy have been stigmatized, shunned, or even imprisoned. As late as in the second half of the 20th century, in Tanzania and other parts of Africa epilepsy was associated with possession by evil spirits, witchcraft, or poisoning and was believed by many to be contagious.[156] In the Salpêtrière, the birthplace of modern neurology, Jean-Martin Charcot found people with epilepsy side by side with the mentally ill, those with chronic syphilis, and the criminally insane.[citation needed] In ancient Rome, epilepsy was known as the morbus comitialis ('disease of the assembly hall') and was seen as a curse from the gods. In northern Italy, epilepsy was once traditionally known as Saint Valentine's malady.[157]

In the mid-19th century, the first effective anti-seizure medication, bromide, was introduced.[114] The first modern treatment, phenobarbital, was developed in 1912, with phenytoin coming into use in 1938.[158]

Society and culture[edit]

Stigma[edit]

Stigma is commonly experienced, around the world, by those with epilepsy.[159] It can affect people economically, socially and culturally.[159] In India and China, epilepsy may be used as justification to deny marriage.[30] People in some areas still believe those with epilepsy to be cursed.[19] In parts of Africa, such as Tanzania and Uganda, epilepsy is incorrectly claimed to be associated with possession by evil spirits, witchcraft, or poisoning and is believed by many to be contagious.[156][19] Before 1971 in the United Kingdom, epilepsy was considered grounds for the annulment of marriage.[30] The stigma may result in some people with epilepsy denying that they have ever had seizures.[49]

Economics[edit]

Seizures result in direct economic costs of about one billion dollars in the United States.[20] Epilepsy resulted in economic costs in Europe of around 15.5 billion euros in 2004.[25] In India epilepsy is estimated to result in costs of US$1.7 billion or 0.5% of the GDP.[30] It is the cause of about 1% of emergency department visits (2% for emergency departments for children) in the United States.[160]

Vehicles[edit]

Those with epilepsy are at about twice the risk of being involved in a motor vehicular collision and thus in many areas of the world are not allowed to drive or only able to drive if certain conditions are met.[22] Diagnostic delay has been suggested to be a cause of some potentially avoidable motor vehicle collisions since at least one study showed that most motor vehicle accidents occurred in those with undiagnosed nonmotor seizures as opposed to those with motor seizures at epilepsy onset.[161] In some places physicians are required by law to report if a person has had a seizure to the licensing body while in others the requirement is only that they encourage the person in question to report it himself.[22] Countries that require physician reporting include Sweden, Austria, Denmark and Spain.[22] Countries that require the individual to report include the UK and New Zealand, and physicians may report if they believe the individual has not already.[22] In Canada, the United States and Australia the requirements around reporting vary by province or state.[22] If seizures are well controlled most feel allowing driving is reasonable.[162] The amount of time a person must be free from seizures before he can drive varies by country.[162] Many countries require one to three years without seizures.[162] In the United States the time needed without a seizure is determined by each state and is between three months and one year.[162]

Those with epilepsy or seizures are typically denied a pilot license.[163] In Canada if an individual has had no more than one seizure, they may be considered after five years for a limited license if all other testing is normal.[164] Those with febrile seizures and drug related seizures may also be considered.[164] In the United States, the Federal Aviation Administration does not allow those with epilepsy to get a commercial pilot license.[165] Rarely, exceptions can be made for persons who have had an isolated seizure or febrile seizures and have remained free of seizures into adulthood without medication.[166] In the United Kingdom, a full national private pilot license requires the same standards as a professional driver's license.[167] This requires a period of ten years without seizures while off medications.[168] Those who do not meet this requirement may acquire a restricted license if free from seizures for five years.[167]

Support organizations[edit]

There are organizations that provide support for people and families affected by epilepsy. The Out of the Shadows campaign, a joint effort by the World Health Organization, the International League Against Epilepsy and the International Bureau for Epilepsy, provides help internationally.[30] In the United States, the Epilepsy Foundation is a national organization that works to increase the acceptance of those with the disorder, their ability to function in society and to promote research for a cure.[169] The Epilepsy Foundation, some hospitals, and some individuals also run support groups in the United States.[170] In Australia, the Epilepsy Foundation provides support, delivers education and training and funds research for people living with epilepsy.

International Epilepsy Day (World Epilepsy Day) began in 2015 and occurs on the second Monday in February.[171][172]

Research[edit]

Seizure prediction and modeling[edit]

Seizure prediction refers to attempts to forecast epileptic seizures based on the EEG before they occur.[173] As of 2011, no effective mechanism to predict seizures has been developed.[173] Kindling, where repeated exposures to events that could cause seizures eventually causes seizures more easily, has been used to create animal models of epilepsy.[174] One of the hypotheses present in the literature is based on inflammatory pathways. Studies supporting this mechanism revealed that inflammatory, glycolipid, and oxidative factors are higher in epilepsy patients, especially those with generalized epilepsy.[175]

Potential future therapies[edit]

Gene therapy is being studied in some types of epilepsy.[176] Medications that alter immune function, such as intravenous immunoglobulins, are poorly supported by evidence.[177] Noninvasive stereotactic radiosurgery is, as of 2012, being compared to standard surgery for certain types of epilepsy.[178]

Other animals[edit]

Epilepsy occurs in a number of other animals including dogs and cats; it is in fact the most common brain disorder in dogs.[179] It is typically treated with anticonvulsants such as phenobarbital or bromide in dogs and phenobarbital in cats.[179] Imepitoin is also used in dogs.[180] While generalized seizures in horses are fairly easy to diagnose, it may be more difficult in non-generalized seizures and EEGs may be useful.[181]

References[edit]

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  132. Jump up to:a b c Michaelis R, Tang V, Wagner JL, Modi AC, LaFrance Jr WC, Goldstein LH, Lundgren T, Reuber M (October 2017). "Psychological treatments for people with epilepsy"Cochrane Database of Systematic Reviews10 (10): CD012081. doi:10.1002/14651858.CD012081.pub2PMC 6485515PMID 29078005.
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  135. Jump up to:a b Tomson T, Battino D, Bromley R, Kochen S, Meador K, Pennell P, Thomas SV (December 2019). "Management of epilepsy in pregnancy: a report from the International League Against Epilepsy Task Force on Women and Pregnancy". Epileptic Disord21 (6): 497–517. doi:10.1684/epd.2019.1105 (inactive 31 October 2021). PMID 31782407.
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  139. Jump up to:a b Brigo F, Igwe SC, Del Felice A (August 2016). "Melatonin as add-on treatment for epilepsy"The Cochrane Database of Systematic Reviews2016 (8): CD006967. doi:10.1002/14651858.CD006967.pub4PMC 7386917PMID 27513702.
  140. Jump up to:a b Kwan P (2012). Fast facts : epilepsy (5th ed.). Abingdon, Oxford, UK: Health Press. p. 10. ISBN 978-1-908541-12-3.
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  142. Jump up to:a b c Shorvon S, Perucca E, Engel J, eds. (2009). The treatment of epilepsy (3rd ed.). Chichester, UK: Wiley-Blackwell. p. 28. ISBN 978-1-4443-1667-4Archived from the original on 10 June 2016.
  143. Jump up to:a b Bagary M (April 2011). "Epilepsy, antiepileptic drugs and suicidality". Current Opinion in Neurology24 (2): 177–82. doi:10.1097/WCO.0b013e328344533ePMID 21293270.
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  145. Jump up to:a b Ryvlin P, Nashef L, Tomson T (May 2013). "Prevention of sudden unexpected death in epilepsy: a realistic goal?"Epilepsia. 54 Suppl 2: 23–8. doi:10.1111/epi.12180PMID 23646967.
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  149. Jump up to:a b c d e f g h Saraceno B, Avanzini G, Lee P, eds. (2005). Atlas: Epilepsy Care in the World (PDF). World Health Organization. ISBN 978-92-4-156303-1. Retrieved 20 December 2013.
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  157. ^ Illes J (2011). Encyclopedia of Mystics, Saints & Sages. HarperCollins. p. 1238. ISBN 978-0-06-209854-2Archived from the original on 11 January 2014. Saint Valentine is invoked for healing as well as love. He protects against fainting and is requested to heal epilepsy and other seizure disorders. In northern Italy, epilepsy was once traditionally known as Saint Valentine's Malady.
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  162. Jump up to:a b c d Engel J, Pedley TA, eds. (2008). Epilepsy : a comprehensive textbook (2nd ed.). Philadelphia: Wolters Kluwer Health/Lippincott Williams & Wilkins. p. 2279. ISBN 978-0-7817-5777-5.
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  167. Jump up to:a b "National PPL (NPPL) Medical Requirements"Civil Aviation AuthorityArchived from the original on 16 October 2013. Retrieved 29 December 2013.
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  171. ^ Aleem, MA (February 2015). "Letter: World Epilepsy Day". Epilepsia56 (2): 168. doi:10.1111/epi.12814PMID 25404065S2CID 11256074.
  172. ^ Perucca, Emilio (February 2015). "Commentary: Why an International Epilepsy Day?"Epilepsia56 (2): 170–171. doi:10.1111/epi.12813PMID 25403985.
  173. Jump up to:a b Carney PR, Myers S, Geyer JD (December 2011). "Seizure prediction: methods"Epilepsy & Behavior. 22 Suppl 1: S94–101. doi:10.1016/j.yebeh.2011.09.001PMC 3233702PMID 22078526.
  174. ^ Engel J, ed. (2008). Epilepsy: a comprehensive textbook (2nd ed.). Philadelphia: Wolters Kluwer Health/Lippincott Williams & Wilkins. p. 426. ISBN 9780781757775.
  175. ^ Kegler, Aline; Pascotini, Eduardo T.; Caprara, Ana Letícia Fornari; Arend, Josi; Gabbi, Patricia; Duarte, Marta MMF.; Royes, Luiz Fernando Freire; Fighera, Michele Rechia (February 2021). "Relationship between seizure type, metabolic profile, and inflammatory markers in blood samples of patients with epilepsy"Epileptic Disorders23 (1): 74–84. doi:10.1684/epd.2021.1236ISSN 1294-9361PMID 33602662S2CID 231962819.
  176. ^ Walker MC, Schorge S, Kullmann DM, Wykes RC, Heeroma JH, Mantoan L (September 2013). "Gene therapy in status epilepticus" (PDF)Epilepsia. 54 Suppl 6: 43–5. doi:10.1111/epi.12275PMID 24001071S2CID 13942394.
  177. ^ Walker L, Pirmohamed M, Marson AG (June 2013). "Immunomodulatory interventions for focal epilepsy syndromes". The Cochrane Database of Systematic Reviews6 (6): CD009945. doi:10.1002/14651858.CD009945.pub2PMID 23803963.
  178. ^ Quigg M, Rolston J, Barbaro NM (January 2012). "Radiosurgery for epilepsy: clinical experience and potential antiepileptic mechanisms"Epilepsia53 (1): 7–15. doi:10.1111/j.1528-1167.2011.03339.xPMC 3519388PMID 22191545.
  179. Jump up to:a b Thomas WB (January 2010). "Idiopathic epilepsy in dogs and cats". The Veterinary Clinics of North America. Small Animal Practice40 (1): 161–79. doi:10.1016/j.cvsm.2009.09.004PMID 19942062.
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  181. ^ van der Ree M, Wijnberg I (2012). "A review on epilepsy in the horse and the potential of Ambulatory EEG as a diagnostic tool". The Veterinary Quarterly32 (3–4): 159–67. doi:10.1080/01652176.2012.744496PMID 23163553S2CID 24726314.

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인격장애 위키백과, 우리 모두의 백과사전. Entete médecine.png 인격장애 진료과 정신의학, 심리학 위키데이터에서 편집하기 인격장애(人格障碍, 영어: personality disorder) 또는 성격장애(性格障碍)는 습관, 성격, 사고방식 등이 사회적 기준에서 지속적이게 극단적으로 벗어나서 사회 생활에 문제를 일으키는 장애를 가리킨다. 대부분 상황에서 변함없이 나타난다. 청소년기 또는 성인기 초기에 발생하며 환자에게 고통을 안겨준다.[1] 목차 1 DSM-5 섹션III 2 특징 2.1 진단기준 3 원인 4 유형 4.1 A군(Cluster A), 기이형 4.1.1 편집성 인격장애 4.1.2 분열형 인격장애 4.1.3 분열성 인격장애 4.2 B군(Cluster B), 충동형 4.2.1 반사회성 인격장애 4.2.2 경계선 인격장애 4.2.3 자기애성 인격장애 4.2.4 연극성 인격장애 4.3 C군(Cluster C), 불안형 4.3.1 회피성 인격장애 4.3.2 의존성 인격장애 4.3.3 강박성 인격장애 5 기타 6 치료 7 같이 보기 8 각주 9 참고 문헌 10 외부 링크 DSM-5 섹션III 정신질환 진단 및 통계 편람(DSM) DSM-IV에서 DSM-5로의 개정 작업시 성격장애에 대하여 추가적으로 차원적 접근을 강조한 개선된 연속적이고 범주적인 접근의 진단절차를 진행하였으나 최종적으로 반영되지는 않았다. 따라서 진단절차를 기술한 DSM-5의 섹션II(section II)에서는 여전히 기존 DSM-IV의 범주적 접근이 주로 언급되고있으나 지속적인 진행계획을 기술하는 DSM-5의 섹션III(section III)에서 이러한 개선된 진단절차의 작업이 차후에 반영될수있는 하이브리드 모델(Hybrid model)이 언급되어있다.[2][3][4] 특징 이 문단의 내용은 출처가 분명하지 않습니다. 이 문단을 편집하여, 신뢰할 수 있는 출처를 표기해 주세요. 검증되지 않은 내용은 삭제될 수도 있습니다. 내용에 대한 의견은 토론 문서에서 나누어 주세요. (2013년 5월) 인격이라는 인간이 갖는 인격장애는 불안, 대인관계에서의 부적응, 타인을 괴롭히는 경향, 자기중심적인 인간관계 중 몇 가지를 나타낸다. 이러한 특징들은 상당한 장애를 초래할 수 있고, 시간이 지나도 비교적 고정적이며, 가까운 사람에게 고통을 줄 수 있다. 인격장애 환자에게서 나타나는 또 하나의 특징은 자기 자신에 대해 설명할 때 제대로 된 설명을 하지 않는다는 점이다. 예를 들어 반사회성 인격장애의 경우 거짓말을 하는 경우가 많고 자기애 성향의 경우는 자신의 단점을 숨기려 하고 장점을 과장하는 측면, 편집증적 인격 장애의 경우는 자신이 매우 정직하다고 믿는 경향이 있다. 따라서 의사는 환자에게 자기 보고형 검사를 하는 경우 아무 효과가 없을 수 있음을 인지해야 한다.[5] 진단기준 DSM-IV-TR에서 언급하는 인격 장애의 진단기준은 다음과 같다. 사회의 기대에서 현저히 벗어난 내적 경험과 행동이 지속적으로 나타난다. 이러한 일탈이 다음 사항의 2가지 이상의 영역에서 나타난다. 인지(자신, 타인, 사건의 지각과 해석 방식) 정동(정서반응의 범위, 강도, 가변성, 적절성) 대인관계 기능 충동 조절 일탈이 개인적 상황과 사회적 상황 전반에 걸쳐 나타난다. 개인적인 고통, 사회적 환경에 대한 적의 등이 나타난다. 일탈의 패턴이 변하지 않고 오랜 기간 지속되어 왔고[6] 발병 시기는 적어도 청소년기나 성인기 초기 이전으로 거슬러 올라간다. 성인기 이후에 발생하는 인격 장애에 대해서는 인정하지 않는다.[7] 일탈이 다른 정신 장애의 증상이나 결과때문이 아니다. 일탈이 뇌병변이나 뇌손상때문이 아니다. 세계 보건 기구(WHO)에서 정의하는 인격 장애는 DSM에서의 인격 장애와 다소 차이가 있는데 WHO 국제질병분류체계(International Classification of Diseases: ICD-10, 1992)에서는 성인기에 두 가지 인격 장애가 생길 수 있다고 본다.(충격적 경험에 따른 이차적 성격 변화, 심각한 정신 장애에서 기인하는 이차적 성격 변화)[7] 인격 장애는 다른 질병과 구분하는 것이 헷갈리는 경우도 있고(예를 들어 사회공포증과 회피성 인격장애) 한 사람에게서 두 가지 인격 장애가 나타나는 등 진단이 어려울 수 있다.[8] 노년기에 내원한 환자를 진단하는 경우는 더욱 까다롭다. 증상이 청소년기 또는 초기 성인기부터 지속되어 온 것인지 판단을 내릴만한 확실한 평가 도구들이 2002년 기준으로 아직은 개발되어있지 않다.[6] 원인 이 문단의 내용은 출처가 분명하지 않습니다. 이 문단을 편집하여, 신뢰할 수 있는 출처를 표기해 주세요. 검증되지 않은 내용은 삭제될 수도 있습니다. 내용에 대한 의견은 토론 문서에서 나누어 주세요. (2013년 5월) 신체적, 정서적, 성적 학대 등이 뇌의 발달에 부정적인 영향을 주어서 뇌의 기능과 구조에 문제가 발생하여 인격장애를 유발할 수 있다. 학자들 사이에서는 여러가지 가설이 제시되고 있는 상태이다. 유형 정신질환 진단 및 통계 편람(DSM)-IV에서는 3개의 부류로 나뉘는 10가지의 인격장애를 제시하였다. 편람은 또한 이러한 10가지 장애와 맞지 않는 인격장애의 행동양식(Personality Disorder NOS)을 포함하고 있다. A군(Cluster A), 기이형 편집성 인격장애 편집성 인격장애 문서를 참고하십시오. 편집성 인격장애(paranoid personality disorder, PPD)는 타인에게 부당한 의심을 과도하게 갖는 경우로 이 유형에 속하는 사람은 남들에게 자신을 잘 드러내지 않는 특징을 지니고 있으며, 늘 긴장하며 타인에게 질투심도 심하다. DSM-IV-TR 진단 기준은 다음과 같다. A. 다른 사람들의 동기를 악의적으로 해석하는 것과 같은 광범위한 불신과 의심이 초기 성인기에 시작되어 다양한 상황에서 다음 중 4가지 이상의 항목으로 나타난다. 충분한 근거 없이 타인들이 자신을 착취, 상해 또는 속인다고 의심한다. 친구나 동료의 성실성이나 신용에 대한 부당한 의심에 집착한다. 정보가 자신에게 악의적으로 사용될 것이라는 확인되지 않은 두려움으로 터놓고 얘기하기를 꺼린다. 온정적인 말이나 사건을 자신을 폄하하려거나 위협적 의미가 감추어져 있는 것으로 해석한다. 지속적으로 원한을 품는다. (모욕, 상해, 경멸을 용서하지 않음) 제3자에게는 그렇게 보이지 않는 행동이나 상황도 자신의 성격이나 평판에 대한 공격으로 여기고 즉각적으로 화를 내며 대응하거나 반격한다. 정당한 이유 없이 배우자나 성적 파트너의 정절에 대해 반복적으로 의심한다. B. 조현증, 정신증 양상이 있는 기분 장애 또는 기타 정신증 장애의 경과 중에만 나타나는 것이 아니고, 일반적인 의학적 상태(medical conditions)의 직접적인 생리적 효과에 의한 것이 아니다. 분열형 인격장애 분열형 인격장애 문서를 참고하십시오. 분열형 인격장애(Schizotypal Personality Disorder, STPD)는 사회적 고립, 마술적 사고, 피해의식, 관계 망상, 착각 등의 특징으로 일반 사람들이 보기에도 이상하게 보인다. 조현증(정신분열증)과 비슷한 면이 있지만 변별될수있으며 정신분열 스펙트럼으로 다루어질수도 있다. DSM-IV-TR 진단 기준은 다음과 같다. A. 사회성 및 대인관계 결핍의 광범위한 양상이 인지 또는 지각 왜곡과 행동의 기이함뿐 아니라 친밀한 관계에서의 심각한 불편감 및 감소된 능력으로, 초기 성인기에서 시작되어 다양한 상황에서 다음 9가지중 5개 이상의 항목으로 나타난다. 관계망상적 사고 - 분명한 관계망상은 제외한다. 행동에 영향을 미치고 하위문화의 기준에 부합되지 않는 기이한 믿음이나 마술적 사고(예 : 미신, 천리안에 대한 믿음, 텔레파시나 육감, 아동이나 청소년에게서 보이는 기이한 환상이나 집착) 신체적 착각을 포함한 유별난 지각 경험 기이한 사고와 언어 (예 : 모호하고 우회적이고 은유적이고 지나치게 자세하게 묘사하거나 혹은 상동증적인 사고와 언어) 의심이나 편집증적인 사고 부적절하거나 메마른 정동 기이하고 엉뚱하거나 특이한 행동이나 외모 직계 가족 외에는 가까운 친구나 마음을 털어놓을 수 있는 사람이 없다. 자신에 대한 부정적인 판단보다는 편집증적인 두려움과 연관되어 있는, 친밀해져도 줄어들지 않는 과도한 사회적 불안. B. 조현증, 정신증 양상이 있는 기분 장애 또는 기타 정신증 장애의 경과 중에만 나타나는 것이 아니고, 일반적인 의학적 상태의 직접적인 생리적 효과에 의한 것이 아니다. 분열성 인격장애 분열성 인격장애 문서를 참고하십시오. 분열성 인격장애(Schizoid personality disorder, SPD, SzPD)는 감정 표현을 제대로 하지 않으며 활동적인 일에 관심이 없는 등 사회로부터 고립되어 있는 특징을 보인다. 이 유형에 속하는 사람은 타인과의 관계 형성이 힘들어 비정상적인 외톨이처럼 보인다. DSM-IV-TR 진단 기준은 다음과 같다. A. 사회적 관계에서 고립되고 대인관계 상황에서 감정 표현이 제한되는 특성이 성인기 초기부터 생활 전반에 나타나며, 다음 중 4가지 이상의 항목을 충족시킨다. 가족의 일원이 되는 것을 포함하여 친밀한 관계를 바라지도 즐기지도 않는다. 거의 항상 혼자 하는 활동을 선택한다. 타인과 성 경험을 갖는 일에 거의 흥미가 없다. 흥미를 갖는 활동이 거의 없다. 직계 가족 외에는 가까운 친구나 마음을 털어놓을 수 있는 사람이 없다. 타인의 칭찬이나 비평에 무관심해 보인다. 정서적 냉담, 이탈 또는 단조로운 정동을 보인다. B. 조현증, 정신증 양상이 있는 기분 장애 또는 기타 정신증 장애의 경과 중에만 나타나는 것이 아니고, 일반적인 의학적 상태의 직접적인 생리적 효과에 의한 것이 아니다. B군(Cluster B), 충동형 반사회성 인격장애 반사회성 인격장애 문서를 참고하십시오. 반사회성 인격장애(Antisocial Personality Disorder, ASPD, APD)는 타인들을 속이고, 범죄 행위를 하는 데에 죄책감을 느끼지 않으며, 착취적이며 지나친 야망과 우월한 태도를 보여 타인에 공감하지 못하며 감정 기복이 심하다. 또한 환경에 대한 비난을 많이 하고 15세 이상이 되어서 보이는 특징이 있다. DSM-IV-TR 진단 기준은 다음과 같다. A. 다른 사람들의 권리를 침해하고 무시하는 패턴이 15세 이후로 전반적으로 나타나며 다음의 특성 중 3개 이상을 충족시킨다. 법에서 정한 사회적 규범을 준수하지 않으며 구속당할만한 행동을 반복함 개인의 이익이나 쾌락을 위한 반복적인 거짓말, 가명 사용 또는 타인을 속이는 사기 행동 충동적이거나 미리 계획을 세우지 못함 빈번한 육체적 싸움이나 폭력에서 드러나는 호전성과 공격성 자신이나 타인의 안전을 무시하는 무모성 꾸준하게 직업 활동을 수행하지 못하거나 채무를 이행하지 못하는 행동으로 나타나는 지속적인 무책임성 타인에게 상처를 입히거나 학대하거나 절도 행위를 하고도 무관심하거나 합리화하는 행동으로 나타나는 자책의 결여 B. 적어도 18세 이상에게 진단한다. C. 15세 이상에 품행 장애를 나타낸 증거가 있어야 한다. D. 반사회적 행동이 조현증 또는 조증 삽화의 경과 중에만 나타나는 것이 아니어야 한다. 경계선 인격장애 경계선 인격장애 문서를 참고하십시오. 경계선 인격장애(Borderline Personality Disorder, BPD)는 기분이나 감정 기복이 심하며 권태, 공허함을 주로 느낀다. 또한 주체성에도 혼란을 가지고 있으며 정서가 강렬하고 쉽게 변화하는 특징이 있다. 그리고 자제력의 상실과 돌발적인 행동으로 인한 문제행동을 자주 보인다. DSM-IV-TR 진단 기준은 다음과 같다. A. 대인관계, 자기상, 정동에서의 불안정성과 심한 충동성이 광범위하게 나타나며 이러한 특징적 양상은 성인기 초기에 시작하여 여러 가지 상황에서 일어난다. 다음 중 5가지 이상의 항목을 충족시킨다. 실제적이거나 가상적인 유기를 피하기 위한 필사적인 노력 : 5번 기준에서 말하는 자살 또는 자해 행위는 포함되지 않는다. 극단적인 이상화와 평가절하가 교차하여 반복되는 불안정하고 강렬한 대인관계 양식 정체감 혼란 : 심각하게 지속적으로 불안정한 자기상 또는 자기 지각 자신에게 손상을 줄 수 있는 충동성이 적어도 2가지 영역에서 나타남 (예 : 낭비, 성관계, 물질 남용, 무모한 운전, 폭식) 반복적인 자살 행동, 자살 시늉, 자살하겠다는 위협, 혹은 자해 행동 현저한 기분 변화에 따른 정동의 불안정성 (예 : 대체로 수 시간 지속되며 드물게는 수일간 지속되기도 하는 간헐적인 심한 불쾌감, 성마름, 불안) 만성적인 공허감 부적절하고 심한 분노, 혹은 분노 조절의 어려움 스트레스에 따른 일시적인 망상적 사고, 혹은 심한 해리 증상 자기애성 인격장애 자기애성 인격장애 문서를 참고하십시오. 자기애성 인격장애(Narcissistic Personality Disorder, NPD)는 자신이 중요하다고 믿으며, 자신의 재능이나 능력을 과대평가한다. 그래서 사람들의 평가절하에 민감하게 반응하며 남들의 평가에 굉장히 집착한다. 심한 경우에는 자기를 향한 공격성을 보이기도 하며 대체로 헌신적이지 못하며 주로 예술가형 사람들에게 나타난다. DSM-IV-TR 진단 기준은 다음과 같다. A. 지나치게 과장된 자존감, 칭찬에 대한 욕구, 그리고 감정이입의 결여와 같은 광범위한 양상이 초기 성인기에 시작되어 다양한 상황에서 다음 중 5개 이상의 항목으로 나타난다. 자신의 중요성에 대해 지나치게 과장된 자존감이 있음 (예 : 자신의 성취나 재능을 과장함, 뒷받침될만한 성취가 없는 상태에서 자신의 뛰어남을 인정받고자 함) 끝없는 성공, 권력, 탁월성, 아름다움, 이상적인 사랑에 대한 공상에 빠진다. 자신이 특별하고 독특해서 다른 특별하거나 상류층인 사람 또는 기관만이 자신을 이해할 수 있거나, 그런 사람들과만 어울려야 한다고 믿는다. 과도한 찬사를 요구한다. 특권의식 즉 특별대우를 받을 것에 대한 불합리한 기대감이나, 그럴만한 이유가 없는데도 특별대우나 복종을 바라는 불합리한 기대감을 가진다. 대인관계가 착취적이다. 즉, 자신의 목적을 달성하기 위해 다른 사람들을 이용한다. 공감 능력이 결여되어 있다. 즉 타인의 감정이나 욕구를 인정하거나 자신의 감정 또는 욕구와 같은 선상에서 보려 하지 않는다. 종종 타인들을 시기하거나, 타인들이 자신을 시기하고 있다고 믿는다. 거만하고 방자한 행동이나 태도를 보인다. 연극성 인격장애 연극성 인격장애 문서를 참고하십시오. 연극성 인격장애(Histrionic Personality Disorder, HPD)는 정체성의 혼란을 가지며 행동이 매우 극적이며 주의를 끄는 행동을 많이 한다. 또, 감정적인 표현이나 피상적인 묘사나 부사를 남발하는 등 언어 사용에 특징이 있다. DSM-IV-TR 진단 기준은 다음과 같다. A. 과도한 정서성과 주목에 대한 추구의 만연한 패턴이 성인기 초기에 시작하여 다양한 맥락에서 나타난다. 다음 중 5가지 이상의 항목을 충족시킨다. 자신이 중심적인 관심의 대상이 아닌 상황에서 불편해한다. 다른 사람과의 상호작용이 종종 부적절한 성적 유혹이나 도발적인 행동으로 이어진다. 감정이 빨리 변하며 감정 표현이 피상적이다. 신체의 매력을 이용하여 관심을 끌려고 한다. 과도하게 인상주의적이면서 세부적인 것은 결여된 언어 양식을 보인다. 자기 극화, 연극성, 그리고 과장된 정서 표현을 드러낸다. 피암시성이 강하다. 즉, 다른 사람이나 환경에 쉽게 영향을 받는다. 관계를 실제보다 더 친밀한 것으로 받아들인다. C군(Cluster C), 불안형 회피성 인격장애 회피성 인격장애 문서를 참고하십시오. 회피성 인격장애(Avoidant Personality Disorder, AvPD)를 가진 사람들은 거절에 대해서 매우 예민하며, 이로 인해 사회적 상황에서의 억제를 보여 남들에게 은둔형으로 보인다. 그리고 내향성과 불안한 증세는 그들을 더욱 은둔형으로 보이게 한다. 또한 자존심이 낮으며 사회공포증도 많이 나타난다. DSM-IV-TR에선 일반화된 유형의 사회공포증을 진단할 땐 회피성 성격 장애를 진단하는 것을 반드시 고려하라고 되어 있다. DSM-IV-TR진단 기준은 다음과 같다. A. 사회활동의 제한, 부적절감, 그리고 부정적 평가에 대한 과민성과 같은 광범위한 양상이 초기 성인기에 시작되어 다양한 상황에서 다음 중 4가지 이상의 항목으로 나타난다. 비판, 비난 또는 거절이 두려워 중요한 대인 접촉을 포함한 직업 활동을 회피한다. 자신을 좋아한다는 확신이 없으면 다른 사람들과의 관계에 관여하지 않으려 한다. 창피를 당하거나 조롱을 받을까 두려워 친밀한 관계를 갖지 않으려 한다. 사회적 상황에서 비판을 받거나 거절당하는 것에 집착한다. 부적절감 때문에 새로운 대인관계적 상황에서는 억제되어 있다. 자신을 사회적으로 어리석고 개인적으로 매력이 없으며 다른 사람에 비하여 열등한 것으로 여긴다. 당황하게 될까봐 개인적 위험을 감수하거나 새로운 활동에 참가하는 것을 지나치게 주저한다. 의존성 인격장애 의존성 인격장애 문서를 참고하십시오. 의존성 인격장애(Dependent Personality Disorder, DPD)는 내향성과 불안한 증세라는 면에선 회피성 성격 장애와 비슷하지만, 이들은 자신의 모든 행동과 결정을 다른 사람에게 맡기는 모습을 보인다. 자신의 행동을 자신이 책임져야 하는 상황이 오는 것을 두려워하며, 타인의 보살핌을 얻기 위해서는 어떤 일이라도 자처해서 하는 모습을 보인다. DSM - 4 - TR 진단 기준은 다음과 같다. A. 보살핌을 받으려는 과도하고 만연된 욕구로 인해서 복종적이고 매달리는 행동과 분리에 대한 두려움이 나타나며, 성인 초기에 시작되고 다양한 상황에서 나타나며 다음 중 5개 이상의 항목을 충족시킨다. 다른 사람으로부터 과도한 정도의 조언이나 확신이 없이는 매일매일의 결정을 내리기가 어렵다. 자기 인생의 매우 중요한 영역까지도 대신 책임져줄 수 있는 타인을 필요로 한다. 지지와 승인을 상실할까봐 두려워하여 타인의 의견에 반대하지 못한다. (주의 : 보복에 대한 현실적인 두려움은 포함되지 않는다) 스스로 어떤 일을 시작하거나 수행하기 어렵다. 동기나 활력이 부족해서가 아니라 자신의 판단과 능력에 대한 자신이 없기 때문이다. 타인의 보살핌과 지지를 받기 위하여 불쾌한 행동까지도 자청해서 한다. 스스로 잘해나갈 수 없다는 과도한 두려움으로 인해 혼자 있으면 불편한 감정이나 무력감을 느낀다. 어떤 친밀한 관계가 끝났을 때 보살핌과 지지를 얻기 위해 곧바로 또 다른 관계를 찾는다. 스스로 자신을 돌봐야 하는 상황에 처할지도 모른다는 두려움에 비현실적으로 집착한다. 강박성 인격장애 강박성 인격장애 문서를 참고하십시오. 강박성 인격장애(Obsessive Compulsive Personality Disorder, OCPD)는 세부 사항에 지나치게 집착하는 모습을 보이며, 주어진 일을 제대로 수행할 수 있을지에 대해서 자신과 타인을 지나치게 불신하는 경향을 보인다. 강박 장애와는 달리 그 심상이 자기에게 불쾌하게 느껴지지 않으며 대상이 한 범위로 한정되어 있지도 않다. DSM-IV-TR 진단 기준은 다음과 같다. A. 융통성, 개방성, 효율성의 상실이라는 대가를 치르면서까지 정리정돈에 몰두하고, 완벽주의적이며, 마음을 통제하고 대인관계를 통제하려고 노력하는 전반적인 행동 양식이 나타난다. 성인기 초기에 시작되며 여러 다양한 상황에서 이러한 특징들이 나타난다. 다음 가운데 4개 이상의 항목을 충족시킨다. 사소한 세부사항, 규칙, 목록, 순서, 시간 계획이나 형식에 집착하여 일의 큰 흐름을 잃고 만다. 완벽주의로 인하여 일을 완수하는 데 방해를 받는다. (예 : 자신의 지나치게 엄격한 기준에 맞지 않기 때문에 계획을 완수하지 못한다) 여가 활동과 우정을 나눌 시간을 배제하면서까지 지나치게 일과 생산성에 몰두한다. 일에 대한 몰두가 명백한 경제적 필요 때문으로는 설명되지 않는다. 도덕, 윤리, 또는 가치 문제에서 문화적 또는 종교적 배경으로 설명되지 않을 정도로 지나치게 양심적이고 고지식하며 융통성이 없다. 감상적인 가치조차 없을 때라도 닳아빠지거나 무가치한 물건을 버리지 못한다. 타인이 자신의 방식을 그대로 따르지 않을 경우에 타인에게 일을 맡기거나 같이 일하는 것을 꺼려한다. 자신과 타인 모두에게 돈을 쓰는 데 인색하다. 돈은 미래의 재난에 대비하여 축적해야 하는 것으로 생각한다. 경직성과 완고함을 보인다. 기타 혼재성 인격장애(Mixed personality disorders)는 여러 인격장애의 특성을 보이지만, 보다 특정한 진단을 붙일 만한 뚜렷한 증상이 없는 경우를 말한다. 치료 인격장애의 치료는 보통 어렵지만, 증상이 호전되지 않는 것은 아니다. 하지만 급작스러운 호전 또한 기대할 수 없다.[6] 일부 전문가들은 정신분석적 접근을 고려하지 않고 인지행동주의적 접근에서의 사회기술훈련으로 보다 유용한 결과를 보여준다는 것을 언급한 바 있다.[9] 마샤 리네한(Marsha Linehan)은 변증법적 행동치료(dialectical behavior therapy, DBT)를 제안하고 이를 시행한 바 있다. 같이 보기 망상 피해망상 부정망상 관계망상 빙의망상 과대망상 추적망상 조현증(정신분열병) - 편집성 인격장애(PPD)와 유사하나, 환청과 환각 등이 추가로 동반된다 불안 불안 장애 가정폭력(DV) 아동학대 동물학대 변증법적 행동치료 각주 Steven K. Huprich 2010, 18쪽. (NCBI-Actas Esp Psiquiatr. 2015 Sep;43(5):177-86. Epub 2015 Sep 1. The hybrid model for the classification of personality disorders in DSM-5: a critical analysis. Esbec E, Echeburúa E.)https://www.ncbi.nlm.nih.gov/pubmed/26320896 (APA,View and Comment on Recently Proposed Changes to DSM–5)https://www.psychiatry.org/psychiatrists/practice/dsm/proposed-changes (APA-Updates to DSM–5 Criteria, Text and ICD-10 Codes-Changes to ICD-10-CM Codes for DSM-5 Diagnoses)https://www.psychiatry.org/psychiatrists/practice/dsm/updates-to-dsm-5 Steven K. Huprich 2010, 21쪽. Steven K. Huprich 2010, 20쪽. Steven K. Huprich 2010, 19쪽. Steven K. Huprich 2010, 8-9쪽. (APA psycnet - Beck, Aaron T. Freeman, Arthur M. Citation ,Beck, A. T., & Freeman, A. M. (1990). Cognitive therapy of personality disorders. Guilford Press.) https://psycnet.apa.org/record/1990-98221-000 참고 문헌 Steven K. Huprich (2010). 《성격장애 로샤평가》. 학지사. ISBN 9788963302669. (Dialectical Behavior Therapy for Patients with Borderline Personality Disorder and Drug‐Dependence Marsha M. Linehan Ph.D. Henry Schmidt III M.A. Linda A. Dimeff Ph.D. J. Christopher Craft B.S. Jonathan Kanter M.A. Katherine A. Comtois Ph.D. First published:18 February 2010 https://doi.org/10.1080/105504999305686Citations: 525)https://onlinelibrary.wiley.com/doi/abs/10.1080/105504999305686 (Dialectical behavior therapy for binge eating disorder. Journal ArticleDatabase: APA PsycArticles Telch, Christy F. Agras, W. Stewart Linehan, Marsha M. 2001 Dialectical behavior therapy for binge eating disorder. Journal of Consulting and Clinical Psychology, 69(6), 1061–1065. https://doi.org/10.1037/0022-006X.69.6.1061) https://psycnet.apa.org/record/2001-05666-020 외부 링크 분류 D ICD-10: F60ICD-9-CM: 301.9MeSH: D010554질병DB: 9889SNOMED CT: 33449004 외부 자원 메드라인플러스: 000939EMedicine: article/294307 전거 통제 위키데이터에서 편집하기 일반 게마인자메 노름다타이 (독일) 국립도서관 미국 분류: 인격장애성격행동과학심리학 포털 이 문서는 2021년 11월 24일 (수) 15:48에 마지막으로 편집되었습니다. 모든 문서는 크리에이티브 커먼즈 저작자표시-동일조건변경허락 3.0에 따라 사용할 수 있으며, 추가적인 조건이 적용될 수 있습니다. 자세한 내용은 이용 약관을 참고하십시오. 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