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Amyotrophic Lateral Sclerosis (Lou Gehrig's Disease)
Classification and external resources
File:ALS Coronal.jpg
MRI (parasagittal FLAIR) demonstrates increased T2 signal within the posterior part of the internal capsule and can be tracked to the subcortical white matter of the motor cortex, outlining the corticospinal tract, consistent with the clinical diagnosis of ALS
ICD-10 G12.2
ICD-9 335.20
OMIM 105400
DiseasesDB 29148
MedlinePlus 000688
eMedicine neuro/14 emerg/24 pmr/10
MeSH D000690

Amyotrophic lateral sclerosis (abbreviated ALS, also referred to as Lou Gehrig's disease) is a form of motor neuron disease. ALS is a progressive,[1] fatal, neurodegenerative disease caused by the degeneration of motor neurons, the nerve cells in the central nervous system that control voluntary muscle movement. The condition is often called Lou Gehrig's disease in North America, after the famous New York Yankees baseball player who was diagnosed with the disease in 1939.

Signs and symptoms

The disorder causes muscle weakness and atrophy throughout the body caused by degeneration of the upper and lower motor neurons. Unable to function, the muscles weaken and atrophy. Affected individuals may ultimately lose the ability to initiate and control all voluntary movement, although bladder and bowel sphincters and the muscles responsible for eye movement are usually, but not always, spared.

Cognitive function is generally spared for most patients although some (~5%) also have frontotemporal dementia.[2] A higher proportion of patients (~30-50%) also have more subtle cognitive changes which may go unnoticed but are revealed by detailed neuropsychological testing. Sensory nerves and the autonomic nervous system, which controls functions like sweating, are generally unaffected but may be involved for some patients.

Initial symptoms

The earliest symptoms of ALS are typically obvious weakness and/or muscle atrophy. Other presenting symptoms include muscle fasciculation (twitching), cramping, or stiffness of affected muscles; muscle weakness affecting an arm or a leg; and/or slurred and nasal speech. The parts of the body affected by early symptoms of ALS depend on which motor neurons in the body are damaged first. About 75% of people contracting the disease experience "limb onset" ALS i.e. first symptoms in the arms ("upper limb", not to be confused with "upper motor neuron") or legs ("lower limb", not to be confused with "lower motor neuron"). Patients with the leg onset form may experience awkwardness when walking or running or notice that they are tripping or stumbling, often with a "dropped foot" which drags along the ground. Arm-onset patients may experience difficulty with tasks requiring manual dexterity such as buttoning a shirt, writing, or turning a key in a lock. Occasionally, the symptoms remain confined to one limb for a long period of time or for the whole course of the illness; this is known as monomelic amyotrophy.

About 25% of cases are "bulbar onset" ALS. These patients first notice difficulty speaking clearly or swallowing. Speech may become slurred, nasal in character, or quieter. Other symptoms include difficulty swallowing, and loss of tongue mobility. A smaller proportion of patients experience "respiratory onset" ALS where the intercostal muscles that support breathing are affected first.

Regardless of the part of the body first affected by the disease, muscle weakness and atrophy spread to other parts of the body as the disease progresses. Patients experience increasing difficulty moving, swallowing (dysphagia), and speaking or forming words (dysarthria). Symptoms of upper motor neuron involvement include tight and stiff muscles (spasticity) and exaggerated reflexes (hyperreflexia) including an overactive gag reflex. An abnormal reflex commonly called Babinski's sign (the big toe extends upward and other toes spread out) also indicates upper motor neuron damage. Symptoms of lower motor neuron degeneration include muscle weakness and atrophy, muscle cramps, and fleeting twitches of muscles that can be seen under the skin (fasciculations). Around 15–45% of patients experience pseudobulbar affect, also known as "emotional lability", which consists of uncontrollable laughter, crying or smiling, attributable to degeneration of bulbar upper motor neurons resulting in exaggeration of motor expressions of emotion.

To be diagnosed with ALS, patients must have signs and symptoms of both upper and lower motor neuron damage that cannot be attributed to other causes.

Disease progression

Although the sequence of emerging symptoms and the rate of disease progression vary from person to person, eventually most patients are not able to stand or walk, get in or out of bed on their own, or use their hands and arms. Difficulty swallowing and chewing impair the patient's ability to eat normally and increase the risk of choking. Maintaining weight can then become a problem. Because the disease usually does not affect cognitive abilities, patients are aware of their progressive loss of function and may become anxious and depressed. A small percentage of patients go on to develop frontotemporal dementia characterized by profound personality changes; this is more common among those with a family history of dementia. A larger proportion of patients experience mild problems with word-generation, attention, or decision-making. Cognitive function may be affected as part of the disease process or could be related to poor breathing at night (nocturnal hypoventilation). Health care professionals need to explain the course of the disease and describe available treatment options so that patients can make informed decisions in advance.

As the diaphragm and intercostal muscles (rib cage) weaken, forced vital capacity and inspiratory pressure diminish. In bulbar onset ALS, this may occur before significant limb weakness is apparent. Bilevel positive pressure ventilation (frequently referred to by the tradename BiPAP) is frequently used to support breathing, first at night, and later during the daytime as well. It is recommended that long before BiPAP becomes insufficient, patients must decide whether to have a tracheostomy and long term mechanical ventilation. At this point, some patients choose palliative hospice care. Most people with ALS die of respiratory failure or pneumonia. Death usually occurs within two to five years of diagnosis. Although the disease can strike at any age, most people are between forty and seventy years of age when the disease strikes and men are affected slightly more frequently than women. An estimated 5,000 people in the United States are diagnosed with the disease each year.[3] ALS, a progressive disease, leads to death in half of the people diagnosed within three years and ninety percent within six years.

ALS predominantly affects the motor neurons, and in the majority of cases the disease does not impair a patient's mind, personality, intelligence, or memory. Nor does it affect a person's ability to see, smell, taste, hear, or feel touch. Control of eye muscles is the most preserved function, although some patients with an extremely long duration of disease (20+ years) may lose eye control too. Unlike multiple sclerosis, bladder and bowel control are usually preserved in ALS, although as a result of immobility and diet changes, intestinal problems such as constipation can require intensive management.


For patients without a family history of the disease, which includes ~95% of cases, there is no known cause for ALS.

There is a known hereditary factor in familial ALS (FALS), where the condition is known to run in families, although this only accounts for around 5% of all cases. An inherited genetic defect on chromosome 21 (coding for superoxide dismutase) is associated with approximately 20% of familial cases of ALS.[4][5] This mutation is believed to be autosomal dominant. The most common ALS causing SOD1 mutation in North America is A4V, characterized by an exceptionally rapid progression from onset to death. The children of those diagnosed with familial ALS have a higher risk factor for developing the disease; however, those who have close family members who have been diagnosed with sporadic ALS have no greater a risk factor than the general population, suggesting again an environmental or other non-genetic cause.[6]

Some environmental causative factors have been suggested for the increased incidence in the western Pacific. Prolonged exposure to a dietary neurotoxin called BMAA is one suspected risk factor in Guam;[7] this neurotoxin produced by cyanobacteria is one of several possible neurotoxic compounds found in the seed of the cycad Cycas circinalis,[8] a tropical plant found in Guam, which was used in the human food supply during the 1950s and early 1960s.

The very high incidence of the disease among Italian soccer players (more than five times higher than normally expected) has raised the concern of a possible link between the disease and the use of pesticides on the soccer fields (several of which have been linked to neuronal toxicity).[9][10]

According to the ALS Association, military veterans are at an increased risk of contracting ALS (again, possibly implying a link to neurotoxic chemical exposure). In its report ALS in the Military,[11] the group pointed to an almost 60% greater chance of the disease in military veterans than the general population. For Gulf War veterans, the chance is seen as twice that of veterans not deployed to the Persian Gulf in a joint study by the Veterans Affairs Administration and the DOD, another epidemiologic association suggesting a link to toxic exposure.[12][13][14]

A 2010 study has raised questions about the diagnosis of ALS in some veterans and athletes, suggesting that repeated concussions may cause a chronic traumatic encephalopathy that mimics ALS; this might explain the higher rate of ALS diagnoses in those populations.[unreliable medical source?][15]


The defining feature of ALS is the death of both upper and lower motor neurons in the motor cortex of the brain, the brain stem, and the spinal cord. Prior to their destruction, motor neurons develop proteinaceous inclusions in their cell bodies and axons. These inclusions often contain ubiquitin, and generally incorporate one of the ALS-associated proteins: SOD1, TAR DNA binding protein (TDP-43, or TARDBP), or FUS. Interestingly, these inclusions do not stain with the dyes Congo Red or Thioflavin S, and are therefore non-amyloid aggregates.[16][17] This is in contrast to the aggregates and plaques seen in many other neurodegenerative diseases of protein aggregation, including Alzheimer's disease, Parkinson's disease, Huntington's disease, and prion diseases.


The cause of ALS is not known, though an important step toward determining the cause came in 1993 when scientists discovered that mutations in the gene that produces the Cu/Zn superoxide dismutase (SOD1) enzyme were associated with some cases (approximately 20%) of familial ALS. This enzyme is a powerful antioxidant that protects the body from damage caused by superoxide, a toxic free radical generated in the mitochondria. Free radicals are highly reactive molecules produced by cells during normal metabolism again largely by the mitochondria. Free radicals can accumulate and cause damage to both mitochondrial and nuclear DNA and proteins within cells. To date, over 110 different mutations in SOD1 have been linked with the disease, some of which have a very long clinical course (e.g. H46R), while others, such as A4V, being exceptionally aggressive. Evidence suggests that failure of defenses against oxidative stress up-regulates programmed cell death (apoptosis), among many other possible consequences. Although it is not yet clear how the SOD1 gene mutation leads to motor neuron degeneration, researchers have theorized that an accumulation of free radicals may result from the faulty functioning of this gene. Current research, however, indicates that motor neuron death is not likely a result of lost or compromised dismutase activity, suggesting mutant SOD1 induces toxicity in some other way (a gain of function).[18][19]

Studies involving transgenic mice have yielded several theories about the role of SOD1 in mutant SOD1 familial amyotrophic lateral sclerosis. Mice lacking the SOD1 gene entirely do not customarily develop ALS, although they do exhibit an acceleration of age-related muscle atrophy (sarcopenia) and a shortened lifespan (see article on superoxide dismutase). This indicates that the toxic properties of the mutant SOD1 are a result of a gain in function rather than a loss of normal function. In addition, aggregation of proteins has been found to be a common pathological feature of both familial and sporadic ALS (see article on proteopathy). Interestingly, in mutant SOD1 mice (most commonly, the G93A mutant), aggregates (misfolded protein accumulations) of mutant SOD1 were found only in diseased tissues, and greater amounts were detected during motor neuron degeneration.[20] It is speculated that aggregate accumulation of mutant SOD1 plays a role in disrupting cellular functions by damaging mitochondria, proteasomes, protein folding chaperones, or other proteins.[21] Any such disruption, if proven, would lend significant credibility to the theory that aggregates are involved in mutant SOD1 toxicity. Critics have noted that in humans, SOD1 mutations cause only 2% or so of overall cases and the etiological mechanisms may be distinct from those responsible for the sporadic form of the disease. To date, the ALS-SOD1 mice remain the best model of the disease for preclinical studies but it is hoped that more useful models will be developed.

Other factors

Studies also have focused on the role of glutamate in motor neuron degeneration. Glutamate is one of the chemical messengers or neurotransmitters in the brain. Scientists have found that, compared to healthy people, ALS patients have higher levels of glutamate in the serum and spinal fluid.[5] Riluzole is currently the only FDA approved drug for ALS and targets glutamate transporters. It only has a modest effect on survival, however, suggesting that excess glutamate is not the sole cause of the disease.


No test can provide a definite diagnosis of ALS, although the presence of upper and lower motor neuron signs in a single limb is strongly suggestive. Instead, the diagnosis of ALS is primarily based on the symptoms and signs the physician observes in the patient and a series of tests to rule out other diseases. Physicians obtain the patient's full medical history and usually conduct a neurologic examination at regular intervals to assess whether symptoms such as muscle weakness, atrophy of muscles, hyperreflexia, and spasticity are getting progressively worse.

File:ALS cross.jpg

MRI (axial FLAIR) demonstrates increased T2 signal within the posterior part of the internal capsule, consistent with the clinical diagnosis of ALS.

Because symptoms of ALS can be similar to those of a wide variety of other, more treatable diseases or disorders, appropriate tests must be conducted to exclude the possibility of other conditions. One of these tests is electromyography (EMG), a special recording technique that detects electrical activity in muscles. Certain EMG findings can support the diagnosis of ALS. Another common test measures nerve conduction velocity (NCV). Specific abnormalities in the NCV results may suggest, for example, that the patient has a form of peripheral neuropathy (damage to peripheral nerves) or myopathy (muscle disease) rather than ALS. The physician may order magnetic resonance imaging (MRI), a noninvasive procedure that uses a magnetic field and radio waves to take detailed images of the brain and spinal cord. Although these MRI scans are often normal in patients with ALS, they can reveal evidence of other problems that may be causing the symptoms, such as a spinal cord tumor, multiple sclerosis, a herniated disk in the neck, syringomyelia, or cervical spondylosis.

Based on the patient's symptoms and findings from the examination and from these tests, the physician may order tests on blood and urine samples to eliminate the possibility of other diseases as well as routine laboratory tests. In some cases, for example, if a physician suspects that the patient may have a myopathy rather than ALS, a muscle biopsy may be performed.

Infectious diseases such as human immunodeficiency virus (HIV), human T-cell leukaemia virus (HTLV), Lyme disease,[22] syphilis[23] and tick-borne encephalitis[24] viruses can in some cases cause ALS-like symptoms. Neurological disorders such as multiple sclerosis, post-polio syndrome, multifocal motor neuropathy, CIDP, and spinal muscular atrophy can also mimic certain facets of the disease and should be considered by physicians attempting to make a diagnosis.

Because of the prognosis carried by this diagnosis and the variety of diseases or disorders that can resemble ALS in the early stages of the disease, patients should always obtain a second neurological opinion.


Slowing progression

The Food and Drug Administration (FDA) has approved only one drug treatment for the disease: Riluzole (Rilutek). Riluzole is believed to reduce damage to motor neurons by decreasing the release of glutamate via activation of glutamate transporters. In addition, the drug may offer other neuroprotective effects, by means of sodium and calcium channel blockades,[25] inhibition of protein kinase C,[26] and the promotion of NMDA (N-methyl d-aspartate) receptor antagonism.[25][27] Clinical trials with ALS patients showed that Riluzole lengthens survival by several months, and may have a greater survival benefit for those with a bulbar onset. The drug also extends the time before a patient needs ventilation support. Riluzole does not reverse the damage already done to motor neurons, and patients taking the drug must be monitored for liver damage (occurring in ~10% of patients taking the drug) and other possible side effects. Although only a modest first step, Riluzole offers hope that the progression of ALS may one day be slowed by new medications or a combination of drugs.


Other treatments for ALS are designed to relieve symptoms and improve the quality of life for patients. This supportive care is best provided by multidisciplinary teams of health care professionals such as physicians; pharmacists; physical, occupational, and speech therapists; nutritionists; social workers; and home care and hospice nurses. Working with patients and caregivers, these teams can design an individualized plan of medical and physical therapy and provide special equipment aimed at keeping patients as mobile and comfortable as possible.

Physicians can prescribe medications to help reduce fatigue, ease muscle cramps, control spasticity, and reduce excess saliva and phlegm. Drugs also are available to help patients with pain, depression, sleep disturbances, and constipation. Pharmacists can advise on best use of medications. This is particularly helpful with regards to patients with dysphagia, which many ALS patients experience. They would also monitor a patient's medications to reduce risk of drug interactions.

Physical therapy and special equipment such as assistive technology can enhance patients' independence and safety throughout the course of ALS. Gentle, low-impact aerobic exercise such as walking, swimming, and stationary bicycling can strengthen unaffected muscles, improve cardiovascular health, and help patients fight fatigue and depression. Range of motion and stretching exercises can help prevent painful spasticity and shortening (contracture) of muscles. Physical therapists can recommend exercises that provide these benefits without overworking muscles. Physiotherapists can suggest devices such as ramps, braces, walkers, and wheelchairs that help patients remain mobile. Occupational therapists can provide or recommend equipment and adaptations to enable people to retain as much independence in activities of daily living as possible.

ALS patients who have difficulty speaking may benefit from working with a speech-language pathologist. These health professionals can teach patients adaptive strategies such as techniques to help them speak louder and more clearly. As ALS progresses, speech-language pathologists can recommend the use of augmentative and alternative communication such as voice amplifiers, speech-generating devices (or voice output communication devices) and/or low tech communication techniques such as alphabet boards or yes/no signals. These methods and devices help patients communicate when they can no longer speak or produce vocal sounds. With the help of occupational Therapists, speech-generating devices can be activated by switches or mouse emulation techniques controlled by small physical movements of, for example, the head, finger or eyes.

Patients and caregivers can learn from speech-language pathologists and nutritionists how to plan and prepare numerous small meals throughout the day that provide enough calories, fiber, and fluid and how to avoid foods that are difficult to swallow. Patients may begin using suction devices to remove excess fluids or saliva and prevent choking. When patients can no longer get enough nourishment from eating, doctors may advise inserting a feeding tube into the stomach. The use of a feeding tube also reduces the risk of choking and pneumonia that can result from inhaling liquids into the lungs. The tube is not painful and does not prevent patients from eating food orally if they wish.

When the muscles that assist in breathing weaken, use of ventilatory assistance (intermittent positive pressure ventilation (IPPV), bilevel positive airway pressure (BIPAP), or biphasic cuirass ventilation (BCV)) may be used to aid breathing. Such devices artificially inflate the patient's lungs from various external sources that are applied directly to the face or body. When muscles are no longer able to maintain oxygen and carbon dioxide levels, these devices may be used full-time. BCV has the added advantage of being able to assist in clearing secretions by using high-frequency oscillations followed by several positive expiratory breaths.[28] Patients may eventually consider forms of mechanical ventilation (respirators) in which a machine inflates and deflates the lungs. To be effective, this may require a tube that passes from the nose or mouth to the windpipe (trachea) and for long-term use, an operation such as a tracheostomy, in which a plastic breathing tube is inserted directly in the patient's windpipe through an opening in the neck.

Patients and their families should consider several factors when deciding whether and when to use one of these options. Ventilation devices differ in their effect on the patient's quality of life and in cost. Although ventilation support can ease problems with breathing and prolong survival, it does not affect the progression of ALS. Patients need to be fully informed about these considerations and the long-term effects of life without movement before they make decisions about ventilation support. Some patients under long-term tracheostomy intermittent positive pressure ventilation with deflated cuffs or cuffless tracheostomy tubes (leak ventilation) are able to speak, provided their bulbar muscles are strong enough. This technique preserves speech in some patients with long-term mechanical ventilation.

Social workers and home care and hospice nurses help patients, families, and caregivers with the medical, emotional, and financial challenges of coping with ALS, particularly during the final stages of the disease. Social workers provide support such as assistance in obtaining financial aid, arranging durable power of attorney, preparing a living will, and finding support groups for patients and caregivers. Home nurses are available not only to provide medical care but also to teach caregivers about tasks such as maintaining respirators, giving feedings, and moving patients to avoid painful skin problems and contractures. Home hospice nurses work in consultation with physicians to ensure proper medication, pain control, and other care affecting the quality of life of patients who wish to remain at home. The home hospice team can also counsel patients and caregivers about end-of-life issues.

Researchers have stated that "ALS patients have a chronically deficient intake of energy and recommended augmentation of energy intake."[29] Both animal [30] and human research [29][31] suggest that ALS patients should be encouraged to consume as many calories as possible and not to restrict their calorie intake.

Many ALS patients use complementary and alternative medicines in an attempt to slow their disease. This may include popular vitamin supplements such as Vitamin C, high doses of vitamins and nutrients ("mega-dosing"), traditional Chinese medicine, or other forms of therapy such as acupuncture, reiki, or massage. To date there have been no studies demonstrating that such treatment approaches have an effect on the progression of the disease. Given the lack of therapeutic options, people with ALS can be vulnerable to snake oil scams involving complicated medical terminology or potentially exciting technologies such as stem cell transplantation. Practitioners of these scams promise amazing results but carry out little or no real follow up or study of the patients they have treated in order to prove their assertions. The risks of false hope, financial harm, and potentially medically harm, are a threat to the wellbeing of ALS patients and their families.


Eventually most people with ALS are not able to stand or walk, get in or out of bed on their own, use their hands and arms, or communicate. In later stages of the disease, individuals have difficulty breathing as the muscles of the respiratory system weaken. Although ventilation support can ease problems with breathing and prolong survival, it does not affect the progression of ALS. Most people with ALS die from respiratory failure, usually within three to five years from the onset of symptoms. However, about 10–20 percent[32] of those individuals with ALS survive 10 or more years.


ALS is one of the most common neuromuscular diseases worldwide, and people of all races and ethnic backgrounds are affected. One or two out of 100,000 people develop ALS each year.[33] ALS most commonly strikes people between 40 and 60 years of age, but younger and older people can also develop the disease. Men are affected slightly more often than women.

"Familial ALS" accounts for approximately 5%–10% of all ALS cases and is caused by genetic factors. Of these, approximately 1 in 10 is linked to a mutation in copper/zinc superoxide dismutase (SOD1), an enzyme responsible for scavenging free radicals. A recent study has identified a gene called FUS ("Fused in Sarcoma", ALS6) as being responsible for 1 in 20 cases of fALS.[34][35]

Although the incidence of ALS is thought to be regionally uniform, there are three regions in the West Pacific where there has in the past been an elevated occurrence of ALS. This seems to be declining in recent decades. The largest is the area of Guam inhabited by the Chamorro people, who have historically had a high incidence (as much as 143 cases per 100,000 people per year) of a condition called Lytico-Bodig disease which is a combination of ALS, Parkinsonism, and dementia.[36] Two more areas of increased incidence are the Kii peninsula of Japan and West Papua.[37][38]

Although there have been reports of several "clusters" including three American football players from the San Francisco 49ers, more than fifty football players in Italy,[9] three football-playing friends in the south of England,[39] and reports of conjugal (husband and wife) cases in the south of France,[40][41][42][43][44] these are statistically plausible chance events. Although many authors consider ALS to be caused by a combination of genetic and environmental risk factors, so far the latter have not been firmly identified, other than a higher risk with increasing age.

In 2010, a VA study found that head trauma can produce symptoms that resemble ALS but that are actually chronic traumatic encephalopathy (CTE). Postmortem brain studies conducted on two American football players showed evidence of CTE, rather than ALS[45]


Amyotrophic comes from the Greek language: A- means "no", myo refers to "muscle", and trophic means "nourishment"; amyotrophic therefore means "no muscle nourishment," which describes the characteristic atrophication of the sufferer's disused muscle tissue. Lateral identifies the areas in a person's spinal cord where portions of the nerve cells that are affected are located. As this area degenerates it leads to scarring or hardening ("sclerosis") in the region.


Year Event
1850 English scientist Augustus Waller describes the appearance of shriveled nerve fibers
1869 French doctor Jean-Martin Charcot first describes ALS in scientific literature[46]
1881 "On Amyotrophic Lateral Sclerosis" is translated into English and published in a three-volume edition of Lectures on the Diseases of the Nervous System
1939 ALS becomes a cause célèbre in the United States when baseball legend Lou Gehrig's career—and, two years later, his life—are ended by the disease. He gives his farewell speech on July 4.
1950s ALS epidemic occurs among the Chamorro people on Guam
1991 Researchers link chromosome 21 to FALS (Familial ALS)
1993 SOD1 gene on chromosome 21 found to play a role in some cases of FALS
1996 Rilutek becomes the first FDA-approved drug for ALS
1998 The El Escorial criteria is developed as the standard for classifying ALS patient in clinical research


A number of clinical trials are underway globally for ALS; a comprehensive listing of trials in the US can be found at

KNS-760704 is under clinical investigation in ALS patients. It is hoped that the drug will have a neuroprotective effect. It is one enantiomer of pramipexole, which is approved for the treatment of Parkinson's disease and restless legs syndrome.[47] The single-enantiomer preparation is essentially inactive at dopamine receptors, is not dose limited by the potent dopaminergic properties of pramipexole.[48] Results of a Phase II clinical trial conducted by Knopp Neurosciences and involving 102 patients were reported in 2010; the trial found a dose-dependent slowing in loss of function.[49]

Olesoxime (TRO19622) is being tested in a phase 3 clinical study, as part of the MitoTarget Project.[50] The molecule has a cholesterol-like structure and displays strong neuroprotective properties, and it should be as effective as a cocktail of three neurotrophic factors in keeping motor neurons alive in culture. The ongoing clinical study aims to test efficacy, safety, tolerability and plasma levels in patients with ALS, to see whether a single daily dose of two capsules – under certain circumstances – can improve survival and symptoms of ALS patients. The trial started in May 2009, all the patients are recruited and results are expected in the last quarter of 2011. The study is taking place in France, Belgium, Germany, the UK and Spain.

The new discovery of RNAi has some promise in treating ALS. In recent studies, RNAi has been used in lab rats to shut off specific genes that lead to ALS. Cytrx Corporation has sponsored ALS research using RNAi gene silencing technology targeted at the mutant SOD1 gene.[51] Cytrx's orally-administered drug Arimoclomol is currently in clinical evaluation as a therapeutic treatment for ALS.

Insulin-like growth factor 1 has also been studied as treatment for ALS. Cephalon and Chiron conducted two pivotal clinical studies of IGF-1 for ALS, and although one study demonstrated efficacy, the second was equivocal, and the product has never been approved by the FDA. In January 2007, the Italian Ministry of Health has requested INSMED corporation's drug, IPLEX, which is a recombinant IGF-1 with Binding Protein 3(IGF1BP3) to be used in a clinical trial for ALS patients in Italy.

Ultra-high-dose vitamin B12 analog Methylcobalamin by intravenous injection, which has a protective effect on cultured cortical neurons against glutamate-induced cytotoxicity, is being studied in Japan. Ultra-high-dose methylcobalamin slows down the progressive reduction of the CMAP (compound muscle action potential) amplitudes in ALS.[52]

See also


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Further reading

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Template:Diseases of the nervous system

ar:التصلب العضلي الجانبي bg:Амиотрофична латерална склероза ca:Esclerosi lateral amiotròfica cs:Amyotrofická laterální skleróza da:Amyotrofisk lateral sklerose de:Amyotrophe Lateralsklerose es:Esclerosis lateral amiotrófica eo:Amiotrofa lateralsklerozo fa:اسکلروز جانبی آمیوتروفیک fr:Sclérose latérale amyotrophique ko:근위축성 측색 경화증 hr:Amiotrofična lateralna skleroza id:Sklerosis lateral amiotrofik it:Sclerosi laterale amiotrofica he:ALS ka:ამიოტროფული გვერდითი სკლეროზი mk:Амиотрофична латерална склероза nl:Amyotrofe laterale sclerose ja:筋萎縮性側索硬化症 no:Amyotrofisk lateralsklerose pl:Stwardnienie zanikowe boczne pt:Esclerose lateral amiotrófica ru:Боковой амиотрофический склероз simple:Amyotrophic lateral sclerosis sr:Amiotrofična lateralna skleroza sh:Amiotrofična lateralna skleroza fi:ALS-tauti sv:Amyotrofisk lateralskleros ta:அமையோட்ரோபிக் லேட்டரல் ஸ்க்லெரோசிஸ் tr:Amyotrofik lateral skleroz zh:肌肉萎縮性側索硬化症

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