The number of events that can lead to the development of PSH symptoms is many. The exact pathways or causes for the development of the syndrome are not known. Traumatic brain injury, hypoxia, stroke, anti-NMDA receptor encephalitis (although further associations are being explored), injury of the spinal cord, and many other forms of brain injury can cause onset of PSH. Even more obscure diseases such as intracranial tuberculoma have been seen to cause onset of paroxysmal sympathetic hyperactivity. It is observed that these injuries lead to the development of PSH or are seen in conjunction with PSH, but the pathophysiology behind these diseases and the syndrome is not well understood.

Patients who develop PSH after traumatic injury have longer hospitalization and longer durations in intensive care in cases where ICU treatment is necessary. Patients often are more vulnerable to infections and spend longer times on ventilators, which can lead to an increased risk of various lung diseases. PSH does not affect mortality rate, but it increases the amount of time it takes a patient to recover from injury, compared to patients with similar injuries who do not develop PSH episodes. It often takes patients who develop PSH longer to reach similar levels of the brain activity seen in patients who do not develop PSH, although PSH patients do eventually reach these same levels.

It has been mapped to chromosome 2q31-36.

It has been associated with PNKD.

The prognosis is best when identified early and treated aggressively. In these cases NMS is not usually fatal. In previous studies the mortality rates from NMS have ranged from 20%–38%; however, in the last two decades, mortality rates have fallen below 10% due to early recognition and improved management. Re-introduction to the drug that originally caused NMS to develop may also trigger a recurrence, although in most cases it does not.

Memory impairment is a consistent feature of recovery from NMS, and usually temporary, though in some cases, may become persistent.

While not the same in all people, there are several common triggers that can precipitate an attack:

- Moderate to high consumption of stimulants, such as alcohol, caffeine, or nicotine.

- Low amounts of energy due to hunger, lack of sleep, illness, or physical fatigue.

- Moderate to high presence of stress.

- Menstruation and ovulation.

All PD associated subtypes have genetic contributions and are likely to run in a families genetic history due to dominant allele mutations. Mutations of identified genes have been leading areas of research in the study and treatment of paroxysmal dyskinesia. PKD, PNKD, and PED are classified as separate subtypes because they all have different presentations of symptoms, but also, because they are believed to have different pathologies.

Interestingly, studies on diseases that are similar in nature to PD have revealed insights into the causes of movement disorders. Hypnogenic paroxysmal dyskinesia is a form of epilepsy affecting the frontal lobe. Single genes have been identified on chromosomes 15, 20, and 21, which contribute to the pathology of these epilepsy disorders. Utilizing new knowledge about pathologies of related and similar disease can shed insight on the causal relationships in paroxysmal dyskinesia.

In most cases, PED is familial, but can also be sporadic. In familial cases, pedigrees examined have shown PED to be an autosomal-dominant inheritance trait. PED also has been associated with Parkinson's disease, epilepsy and migraines, although the exact relationship between these is unknown.

A suspected contributor to familial PED is a mutation in the GLUT1 gene, SLC2A1, which codes for the transporter GLUT1, a protein responsible for glucose entry across the blood–brain barrier. It is not thought that the mutation causes a complete loss of function of the protein but rather only slightly reduces the transporter's activity. In a study of PED patients, a median CSF/blood glucose ratio of .52 compared to a normal .60 was found. In addition, reduced glucose uptake by mutated transporters compared with wild-type in Xenopus oocytes confirmed a pathogenic role of these mutations.

Another recent study was performed to continue to look at the possible connection between PED and mutations on the SLC2A1 gene which codes for the GLUT1 transporter. While PED can occur in isolation it was also noted that it occurs in association with epilepsy as well. In this study the genetics of a five-generation family with history of PED and epilepsy were evaluated. From the results it was noted that most of the mutations were due to frameshift and missense mutations. When looking at homologous GLUT1 transporters in other species it was noted that serine (position 95), valine (position 140), and asparagine (position 317) were highly conserved and therefore mutations in these residues would most likely be pathogenic. Therefore, these are areas of interest when looking at what could lead to PED.All mutations that were observed appeared to only affect the ability of GLUT1 to transport glucose and not the ability for it to be inserted in the membrane. The observed maximum transport velocity of glucose was reduced anywhere from 3 to 10 fold.

A study was performed to determine if the mutation known for the PNKD locus on chromosome 2q33-35 was the cause of PED. In addition, other loci were observed such as the familial hemiplegic migraine (FHM) locus on chromosome 19p, or the familial infantile convulsions and paroxysmal choreoathetosis (ICCA). All three of these suspected regions were found to not contain any mutations, and were therefore ruled out as possible candidates for a cause of PED.

Pooled data suggest the incidence of NMS is between 0.2%–3.23%. However, more physician awareness coupled with increased use of atypical anti-psychotics have likely reduced the prevalence of NMS. Additionally, young males are particularly susceptible and the male:female ratio has been reported to be as high as 2:1.

There are very few reported cases of PED, there are approximately 20 reported sporadic cases of PED and 9 PED families but there is some dispute on the exact number of cases. In addition it appears that PED becomes less severe with aging. Prior to onset of a PED episode some patients reported onset of symptoms including sweating, pallor, and hyperventilation. In brain scans it was observed that patients suffering form frequent PEDs there was increased metabolism in the putamen of the brain and decreased metabolism in the frontal lobe. Another study using subtraction single photon emission computed tomographic (SPECT) imaging technique which was coregistered with an MRI on a patient presented with PED symptoms showed increased cerebral perfusion in the primary somatosensory cortex area, and a mild increase in the region of the primary motor cortex and cerebellum. While all these correlations are not fully understand as to what exactly is happening in the brain it provides areas of interest to study further to hopefully understand PED more fully.

Paroxysmal Dyskinesia is not a fatal disease. Life can be extremely difficult with this disease depending on the severity. The prognosis of PD is extremely difficult to determine because the disease varies from person to person. The attacks for PKD can be reduced and managed with proper anticonvulsants, but there is no particular end in sight for any of the PD diseases. PKD has been described to cease for some patients after the age of 20, and two patients have reported to have a family history of the disease where PKD went into complete remission after the age of 23. With PNKD and PED, at this time, there is no proper way to determine an accurate prognosis.

PEPD is an extremely rare disorder with only 15 known affected families. There are some cases, however, of individuals originally diagnosed with epilepsy who are later determined to have PEPD. This suggests that rates of PEPD may be higher than currently believed.

The cause of benign paroxysmal torticollis in infants is thought to be migrainous. More than 50% of infants have a family history of migraine in first degree relatives. The cause is likely to be genetic.

Hemiplegic attacks can be brought on by particular triggers, and management of AHC often centers around avoiding common or known triggers. While triggers vary greatly from person to person, there are also some common ones which are prevalent in many patients. Common triggers include temperature changes, water exposure, bright lights, certain foods, emotional stress, and physical activity. While avoiding triggers may help, it cannot prevent all hemiplegic episodes because many occur without being triggered. Because attacks and other associated symptoms end with sleep, various sedatives can be used to help patients sleep.

The cause of AHC is unknown. It was initially thought to be a form of complicated migraine because of strong family histories of migraine reported in AHC cases. AHC has also been considered to be a movement disorder or a form of epilepsy. Suggested causes have included channelopathy, mitochondrial dysfunction, and cerebrovascular dysfunction. The disorder most closely related to AHC is familial hemiplegic migraine, and this was recently discovered to be caused by a mutation in a gene for calcium channel receptors. It is suspected that AHC may be caused by a similar channelopathy, and this is a current area of investigation into the cause of AHC. An association with "ATP1A2" mutation has been found in some patients, but other studies have found no mutations and thus a lack of evidence that mutations which cause AHC are in the same genes as mutations which cause familial hemiplegic migraine.

Because alternating hemiplegia of childhood is so rare, there is no increased risk of AHC for the children of siblings of someone with AHC, but it is believed to be autosomal dominant, by which a person with AHC has a 50% change of passing the disorder on to their children. AHC is questionably a progressive disease, because cognitive abilities do appear to decline over time. This cannot be completely determined however, because the mechanism of AHC's progression is unknown. It is likely that it is caused by a generalized cellular dysfunction caused by a mitochondrial disorder. However, studies involving mechanisms of AHC have been inconclusive. Experts currently researching this disorder believe that the cause of AHC is a mutated ion channel. This would make the cause difficult to find because one disrupted channel may be represented differently in different tissues. This mutation is suspected because the most closely related disease, FHM, is also caused by a mutated ion channel. A small number of genes which were suspected to carry a mutation for AHC have been screened for sodium channel protein mutations, ATP pump mutations, and excitatory amino acid transmitter mutations. None of these have yet been successful in determining the underlying cause of AHC.

One large study has identified the gene ATP1A3 as the likely genetic cause of this disorder. This gene is located on the long arm of chromosome 19 (19q13.31).

Paroxysmal hypertension is episodic and volatile high blood pressure, which may be due to stress of any sort, or from a pheochromocytoma, a type of tumor involving the adrenal medulla. Patients with paroxysmal hypertension who test negative for pheochromocytoma are said to be suffering from a clinical entity called "pseudopheochromocytoma." This disorder is due to episodic dopamine discharge and has been observed predominantly in hypertensive women, that had episodes that shared similar characteristics of pheochromocytoma but testing proved negative and had ruled out the tumor. In patients with pseudopheochromocytoma dopamine was found to be significantly increased post-paroxysm. The paroxysm is said to be similar to the hypertensive episodes described by Page. These episodes commonly occur after diencephalic stimulation. Therefore, pseudopheochromocytoma, shares many characteristics of "Page's syndrome."

Pseudopheochromocytoma, colloquially known as page's syndrome, is caused predominantly by episodic dopamine discharge, stressors including pain or anxiety, or possibly repressed emotions caused by prior emotional trauma and commonly, a repressive way of coping emotionally. Therefore, treatment of pseudopheochromocytoma is aimed at psychological support and intervention with antidepressants, but also treatment with alpha and then beta blockers in resistant cases.

The mechanism of action of benign paroxysmal torticollis is not yet understood. It has been suggested that unilateral vestibular dysfunction or vascular disturbance in the brain stem may be responsible for the condition.

Paroxysmal kinesigenic dyskinesia has been shown to be inherited in an autosomal dominant fashion. In 2011, the PRRT2 gene on chromosome 16 was identified as the cause of the disease. The researchers looked at the genetics of eight families with strong histories of PKD. They employed whole genome sequencing, along with Sanger sequencing to identify the gene that was mutated in these families. The mutations in this gene included a nonsense mutation identified in the genome of one family and an insertion mutation identified in the genome of another family. The researchers then confirmed this gene as the cause of PKD when it was not mutated in the genome of 1000 control patients. Researchers found PRRT2 mutations in 10 of 29 sporadic cases affected with PKD, thus suggests PRRT2 is the gene mutated in a subset of PKD and PKD is genetically heterogeneous. The mechanism of how PRRT2 causes PKD still requires further investigation. However, researchers suggest it may have to do with PRRT2's expression in the basal ganglia, and the expression of an associated protein, SNAP25, in the basal ganglia as well.

Paroxysmal kinesigenic choreathetosis (PKC) also called paroxysmal kinesigenic dyskinesia (PKD) is a hyperkinetic movement disorder characterized by attacks of involuntary movements, which are triggered by sudden voluntary movements. The number of attacks can increase during puberty and decrease in a person's 20s to 30s. Involuntary movements can take many forms such as ballism, chorea or dystonia and usually only affect one side of the body or one limb in particular. This rare disorder only affects about 1 in 150,000 people with PKD accounting for 86.8% of all the types of paroxysmal dyskinesias and occurs more often in males than females. There are two types of PKD, primary and secondary. Primary PKD can be further broken down into familial and sporadic. Familial PKD, which means the individual has a family history of the disorder, is more common, but sporadic cases are also seen. Secondary PKD can be caused by many other medical conditions such as multiple sclerosis (MS), stroke, pseudohypoparathyroidism, hypocalcemia, hypoglycemia, hyperglycemia, central nervous system trauma, or peripheral nervous system trauma. PKD has also been linked with infantile convulsions and choreoathetosis (ICCA) syndrome, in which patients have afebrile seizures during infancy (benign familial infantile epilepsy) and then develop paroxysmal choreoathetosis later in life. This phenomenon is actually quite common, with about 42% of individuals with PKD reporting a history of afebrile seizures as a child.

Episodic ataxia (EA) is an autosomal dominant disorder characterized by sporadic bouts of ataxia (severe discoordination) with or without myokymia (continuous muscle movement). There are seven types recognised but the majority are due to two recognized entities. Ataxia can be provoked by stress, startle, or heavy exertion such as exercise. Symptoms can first appear in infancy. There are at least 6 loci for EA, of which 4 are known genes. Some patients with EA also have migraine or progressive cerebellar degenerative disorders, symptomatic of either familial hemiplegic migraine or spinocerebellar ataxia. Some patients respond to acetazolamide though others do not.

Autistic catatonia is a rare type of disorder that affects roughly 10 percent of all adults with autism spectrum disorder. Most of them are not severely affected but a few exhibit stupor and severe excitement, which is the most extreme form of the disorder. Full expression of excitement could be a sign of comorbid Bipolar disorder but more research is needed.

More than 40 symptoms has been identified to be a result of the disorder, but some of the symptoms overlap with those of autism spectrum disorder, making diagnosing difficult even for a seasoned professional. In a few cases stupor and hyperactivity can continue for weeks or even months.

During the excitement phase individuals show combativeness and can have delusions and hallucinations and can also pose a danger to themselves or others and can make marked destruction of property..In the later stages of medium and even more in the severe and if left untreatead lethal state they will also experience autonomic instability! (Behav Sci (Basel). 2015 Dec; 5(4): 576–588.

Published online 2015 Dec 9. doi: 10.3390/bs5040576

Childhood schizophrenia increases the risk for autistic catatonia later in life dramatically. There seems to be a common font of brain pathology for psychosis, catatonia and autism.

Treatment consists of high-dose lorazepam or in some cases ECT. The response to the treatment is usually good, especially if detected early

The various symptoms of EA are caused by dysfunction of differing areas. Ataxia, the most common symptom, is due to misfiring of Purkinje cells in the cerebellum. This is either due to direct malfunction of these cells, such as in EA2, or improper regulation of these cells, such as in EA1. Seizures are likely due to altered firing of hippocampal neurons (KCNA1 null mice have seizures for this reason).

Possible causes include:

- Syncope (fainting)

- Reflex anoxic seizures

- Breath-holding spells of childhood

- Hypoglycaemia

- Cataplexy

- Hyperekplexia, also called startle syndrome

- Migraine

- Narcolepsy

- Non-epileptic myoclonus

- Opsoclonus

- Parasomnias, including night terrors

- Paroxysmal kinesigenic dyskinesia

- Repetitive or ritualistic behaviours

- Tics

- AADC Deficiency

Non-epileptic seizures are paroxysmal events that mimic an epileptic seizure but do not involve abnormal, rhythmic discharges of cortical neurons. They are caused by either physiological or psychological conditions. The latter is discussed more fully in psychogenic non-epileptic seizures.

[Please could somebody add an actual description of what happens when somebody has a seizure or 'paroxysmal event'?!]

The cause of autonomic dysreflexia itself can be life-threatening, and must also be completely investigated and treated appropriately to prevent unnecessary morbidity and mortality.

The Consortium for Spinal Cord Medicine has developed evidence-based clinical practice guidelines for the management of autonomic dysreflexia in adults, children, and pregnant women. There is also a consumer version of this guideline.