Myoclonus

Myoclonus

A person with a myoclonus following anesthesia
Classification and external resources
Specialty Neurology
ICD-10 G25.3
ICD-9-CM 333.2
DiseasesDB 23053
MeSH D009207

Myoclonus is a brief, involuntary twitching of a muscle or a group of muscles. It describes a medical sign and, generally, is not a diagnosis of a disease. These myoclonic twitches, jerks, or seizures are usually caused by sudden muscle contractions (positive myoclonus) or brief lapses of contraction (negative myoclonus). The most common circumstance under which they occur is while falling asleep (hypnic jerk). Myoclonic jerks occur in healthy persons and are experienced occasionally by everyone. However, when they appear with more persistence and become more widespread they can be a sign of various neurological disorders. Hiccups are a kind of myoclonic jerk specifically affecting the diaphragm. When a spasm is caused by another person it is known as a provoked spasm. Shuddering attacks in babies fall in this category.

Myoclonic jerks may occur alone or in sequence, in a pattern or without pattern. They may occur infrequently or many times each minute. Most often, myoclonus is one of several signs in a wide variety of nervous system disorders such as multiple sclerosis, Parkinson's disease, Alzheimer's disease, Gaucher's Disease, subacute sclerosing panencephalitis, Creutzfeldt-Jakob disease (CJD), serotonin toxicity, some cases of Huntington's disease, some forms of epilepsy, and occasionally in intracranial hypotension. Some researchers indicate that jerks persistently may even cause early tremors.

In almost all instances in which myoclonus is caused by central nervous system disease it is preceded by other symptoms; for instance, in CJD it is generally a late-stage clinical feature that appears after the patient has already started to exhibit gross neurological deficits.

Anatomically, myoclonus may originate from lesions of the cortex, subcortex or spinal cord. The presence of myoclonus above the foramen magnum effectively excludes spinal myoclonus; further localisation relies on further investigation with electromyography (EMG) and electroencephalography (EEG).

Symptoms

Myoclonic seizure can be described as "jumps" or "jolts" experienced in a single extremity or even the entire body. The feeling experienced by the individual is described as uncontrollable jolts common to receiving a mild electric shock.[1] The sudden jerks and twitching of the body can often be so severe that it can cause a small child to fall.

A myoclonic seizure (myo "muscle", clonic "jerk") is a sudden involuntary contraction of muscle groups. The muscle jerks consist of symmetric, mostly generalized jerks, localized in the arms and in the shoulders and also simultaneously with a head nod; both the arms may fling out together and simultaneously a head nod may occur. Symptoms have some variability amongst subjects. Sometimes the entire body may jerk, just like a startle response. As is the case with all generalised seizures, the patient is not conscious during the event but the seizure is so brief that the person appears to remain fully conscious.

In reflex epilepsies, myoclonic seizures can be brought on by flashing lights or other environmental triggers (see photosensitive epilepsy).

Familiar examples of normal myoclonus include hiccups and hypnic jerks that some people experience while drifting off to sleep. Severe cases of pathologic myoclonus can distort movement and severely limit a person's ability to sleep, eat, talk, and walk. Myoclonic jerks commonly occur in individuals with epilepsy.

Types

The most common types of myoclonus include action, cortical reflex, essential, palatal, those seen in the progressive myoclonus epilepsies, reticular reflex, sleep and stimulus-sensitive.

Epilepsy forms

Diaphragmatic flutter

A very rare form includes the diaphragmatic flutter, or the Belly Dancer's Syndrome.[3]:2 It was first described by Antony van Leeuwenhoek in 1723, who suffered from it.[3]:2 The condition characterizes spoken communication that sounds like a short-breathed hiccup. These muscle spasms can recur dozens of times per day. Rate of diaphragmatic contraction ranges between 35 and 480 contractions per minute, with the average rate found to be 150.[3]:3 Studies show that possible causes include disruptions within the central or peripheral nervous systems, anxiety, nutritional disorder, and certain pharmaceuticals. No single treatment has proven effective, though blocking or crushing of the phrenic nerve can provide instantaneous relief when pharmacologic treatment has proven ineffective.[3]:11

Only about 50 people in the world have been diagnosed with diaphragmatic flutter. One notable case is Chaz Moore of Colorado Springs, Colorado, who was interviewed by CNN’s correspondent and medical expert Dr. Sanjay Gupta. The patient had tried several medications, of which only medical marijuana worked.[4][5]

Other forms

Cause

Rarely does myoclonus indicate anything other than arbitrary muscle contraction. Myoclonus may develop in response to infection, hyperosmolar hyperglycemic state, head or spinal cord injury, stroke, stress, brain tumors, kidney or liver failure, lipid storage disease, chemical or drug poisoning, as a side effect of certain drugs (such as tramadol,[8] quinolones, benzodiazepine, gabapentin, sertraline, lamotrigine), or other disorders.

Benign myoclonic movements are commonly seen during the induction of general anesthesia with intravenous medications such as etomidate and propofol. These are postulated to result from decreased inhibitory signaling from cranial neurons. Prolonged oxygen deprivation to the brain, hypoxia, may result in posthypoxic myoclonus. People suffering from benign fasciculation syndrome can often experience myoclonic jerking of limbs, fingers and thumbs.

Myoclonus can occur by itself, but most often as one of several symptoms associated with a variety of nervous system disorders, including multiple sclerosis, Parkinson's disease, Alzheimer's disease, Opsoclonus Myoclonus, Creutzfeldt-Jakob disease, Lyme Disease and lupus. Myoclonic jerks commonly occur in persons with epilepsy, a disorder in which the electrical activity in the brain becomes disordered leading to seizures. It is also found in MERRF (Myoclonic Epilepsy with Ragged Red Fibers), a rare mitochondrial encephalomyopathy. Myoclonus can be a coexisting condition with Tourette syndrome.

Jerks of muscle groups, much of the body, or a series in rapid succession, which results in the person jerking bolt upright from a more relaxed sitting position is sometimes seen in ambulatory patients being treated with high doses of morphine, hydromorphine, and similar drugs, and is possibly a sign of high and/or rapidly increasing serum levels of these drugs. Myoclonic jerks caused by other opioids, such as tramadol and pethidine, may be less benign. Medications unrelated to opioids, such as anticholinergics, are known to cause myoclonic jerks.

Pathophysiology

Most myoclonus is caused by a disturbance of the central nervous system. Some are from peripheral nervous system injury. Studies suggest several locations in the brain are involved in myoclonus. One is in the brainstem, close to structures that are responsible for the startle response, an automatic reaction to an unexpected stimulus involving rapid muscle contraction.

The specific mechanisms underlying myoclonus are not yet fully understood. Scientists believe that some types of stimulus-sensitive myoclonus may involve overexcitability of the parts of the brain that control movement. These parts are interconnected in a series of feedback loops called motor pathways. These pathways facilitate and modulate communication between the brain and muscles. Key elements of this communication are chemicals known as neurotransmitters, which carry messages from one nerve cell, or neuron, to another. Neurotransmitters are released by neurons and attach themselves to receptors on parts of neighboring cells. Some neurotransmitters may make the receiving cell more sensitive, while others tend to make the receiving cell less sensitive. Laboratory studies suggest that an imbalance between these chemicals may underlie myoclonus.

Some researchers speculate that abnormalities or deficiencies in the receptors for certain neurotransmitters may contribute to some forms of myoclonus. Receptors that appear to be related to myoclonus include those for two important inhibitory neurotransmitters: serotonin, which constricts blood vessels and brings on sleep, and gamma-aminobutyric acid (GABA), which helps the brain maintain muscle control. Other receptors with links to myoclonus include those for benzodiazepines, drugs that induce sleep, and for glycine, an inhibitory neurotransmitter that is important for the control of motor and sensory functions in the spinal cord. More research is needed to determine how these receptor abnormalities cause or contribute to myoclonus.

Treatment

Concerning more serious afflictions, the complex origins of myoclonus may be treated with multiple drugs, which have a limited effect individually, but greater when combined with others that act on different brain pathways or mechanisms. Treatment is most effective when the underlying cause is known, and can be treated as such. Some drugs being studied in different combinations include clonazepam, sodium valproate, piracetam, and primidone. Hormonal therapy may improve responses to antimyoclonic drugs in some people.

Some studies have shown that doses of 5-hydroxytryptophan (5-HTP) leads to improvement in patients with some types of action myoclonus and PME. These differences in the effect of 5-HTP on patients with myoclonus have not yet been explained.

Many of the drugs used for myoclonus, such as barbiturates, phenytoin and primidone, are also used to treat epilepsy. Barbiturates slow down the central nervous system and cause tranquilizing or antiseizure effects. Phenytoin and primidone are effective antiepileptics drugs, although phenytoin can cause liver failure or have other harmful long-term effects in patients with PME. Sodium valproate is an alternative therapy for myoclonus and can be used either alone or in combination with clonazepam. Some people have adverse reactions to clonazepam and/or sodium volproate.

When patients are taking multiple medications, the discontinuation of drugs suspected of causing myoclonus and treatment of metabolic derangements may resolve some cases of myoclonus.[9] When pharmacological treatment is indicated anticonvulsants are the main line of treatment. Paradoxical reactions to treatment are notable. Drugs which most people respond to may in other individuals worsen their symptoms. Sometimes this leads to the mistake of increasing the dose, rather than decreasing or stopping the drug.[10] Treatment of myoclonus focuses on medications that may help reduce symptoms. Drugs used include sodium valproate, clonazepam, the anticonvulsant levetiracetam, and piracetam.[9] Dosages of clonazepam usually are increased gradually until the patient improves or side effects become harmful. Drowsiness and loss of coordination are common side effects. The beneficial effects of clonazepam may diminish over time if the patient develops a tolerance to the drug.

In forms of myoclonus where only a single area is affected, and even in a few other various forms, Botox injections (OnabotulinumtoxinA) may be helpful. The chemical messenger responsible for triggering the involuntary muscle contractions is blocked by the Botulinum toxins of the Botox.[11]

Surgery is also a viable option for treatment if the symptoms are caused by a tumor or lesion in the brain or spinal cord. Surgery may also correct symptoms in those where myoclonus affects parts of the face or ear. While DBS is still being studied for use with myoclonus, Deep Brain Stimulation has also been tried in those with this and other movement disorders.[12]

Prognosis

The effects of myoclonus in an individual can vary depending on the form and the overall health of the individual. In severe cases, particularly those indicating an underlying disorder in the brain or nerves, movement can be extremely distorted and limit ability to normally function, such as in eating, talking, and walking. In these cases, treatment that is usually effective, such as clonazepam and sodium valproate, may instead cause adverse reaction to the drug, including increased tolerance and a greater need for increase in dosage. However, the prognosis for more simple forms of myoclonus in otherwise healthy individuals may be neutral, as the disease may cause few to no difficulties. Other times the disease starts simply, in one region of the body, and then spreads.[13]

Research

Research on myoclonus is supported through the National Institute of Neurological Disorders and Stroke (NINDS). The primary focus of research is on the role of neurotransmitters and receptors involved in the disease. Identifying whether or not abnormalities in these pathways cause myoclonus may help in efforts to develop drug treatments and diagnostic tests. Determining the extent that genetics play in these abnormalities may lead to potential treatments for their reversal, potentially correcting the loss of inhibition while enhancing mechanisms in the body that would compensate for their effects.[14]

Etymology and pronunciation

The word myoclonus uses combining forms of myo- and clonus, indicating muscle contraction dysfunction. It is pronounced /ˌmˈɒklənəs/[15] or /ˌməˈklnəs, ˌm-/[16]. The prevalence of the variants shows division between American English and British English. The variant stressing the -oc- syllable is the only pronunciation given in a half dozen major American dictionaries (medical and general). The variant stressing the -clo- syllable is given in the British English module of Oxford Dictionaries online[17] but not in the American English module.

See also

References

  1. "Myoclonic Seizures". DooseSyndrome.org. Doose Syndrome Epilepsy Alliance. Retrieved 1 May 2015.
  2. Lava, Neil. "What is Juvenile Myonclonic Epilepsy". WebMD Medical Reference. Atlanta, Georgia: WebMD. Treatment of Juvenile Myoclonic Epilepsy. Retrieved 30 April 2015.
  3. 1 2 3 4 Patterson, Victoria (9 November 2011). Belly Dancer’s Syndrome: Causes, Clinical Presentations, and Treatment Options (PDF) (Senior Research Project). assisted by Powers, EJ. Chesterfield, Missouri: Logan University. Retrieved 1 September 2015.
  4. Thursday 23 February 2012 (2012-02-23). "The Story Of Chaz Moore". The Daily Smoker. Retrieved 2014-02-28.
  5. "CNN Medical Correspondent Apologizes for Doubting Medical Marijuana". Marijuanadoctors.com. Retrieved 2014-02-28.
  6. Lance, JW. "Action Myoclonus, Ramsay Hunt Syndrome, and Other Cerebellar Myoclonic Syndromes." National Center for Biotechnology Information. U.S. National Library of Medicine, n.d. Web. 01 May 2015. http://www.ncbi.nlm.nih.gov/pubmed/3080851.
  7. Brown P, Thompson PD, Rothwell JC, Day BL, Marsden CD. Axial myoclonus of propriospinal origin. Brain 1991; 114:197–214.
  8. 1 2 Van Zandijcke, M. (Jun 2003). "Treatment of myoclonus.". Acta Neurol Belg 103 (2): 66–70. PMID 12891998.
  9. Andrade, DM.; Hamani, C.; Minassian, BA. (Jul 2009). "Treatment options for epileptic myoclonus and epilepsy syndromes associated with myoclonus.". Expert Opin Pharmacother 10 (10): 1549–60. doi:10.1517/14656560903025189. PMID 19527185.
  10. "Myoclonus Treatments and Drugs." Mayo Clinic.org. Mayo Clinic, n.d. Web. 01 May 2015. <http://www.mayoclinic.org/diseases-conditions/myoclonus/basics/treatment/con-20027364>
  11. "NINDS Myoclonus Information Page." Ninds.nih.gov. National Institute of Neurological Disorders and Stroke, n.d. Web. 01 May 2015. <http://www.ninds.nih.gov/disorders/myoclonus/myoclonus.htm>.
  12. "NINDS Myoclonus Information Page." Ninds.nih.gov. National Institute of Neurological Disorders and Stroke, n.d. Web. 01 May 2015. <http://www.ninds.nih.gov/disorders/myoclonus/myoclonus.htm>.
  13. "NINDS Myoclonus Information Page." Ninds.nih.gov. National Institute of Neurological Disorders and Stroke, n.d. .
  14. "Myoclonus". Merriam-Webster Dictionary.
  15. "Myoclonus". Oxford Dictionaries. Oxford University Press. Retrieved 2016-01-20.
  16. Oxford Dictionaries, Oxford Dictionaries Online, Oxford University Press.

External links

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