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What is the outlook for Back Pain ?
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Most patients with back pain recover without residual functional loss, but individuals should contact a doctor if there is not a noticeable reduction in pain and inflammation after 72 hours of self-care. Recurring back pain resulting from improper body mechanics or other nontraumatic causes is often preventable. Engaging in exercises that don't jolt or strain the back, maintaining correct posture, and lifting objects properly can help prevent injuries. Many work-related injuries are caused or aggravated by stressors such as heavy lifting, vibration, repetitive motion, and awkward posture. Applying ergonomic principles designing furniture and tools to protect the body from injury at home and in the workplace can greatly reduce the risk of back injury and help maintain a healthy back.
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Back Pain
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what research (or clinical trials) is being done for Back Pain ?
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The National Institute of Neurological Disorders and Stroke (NINDS) and other institutes of the National Institutes of Health (NIH) conduct pain research in laboratories at the NIH and also support pain research through grants to major medical institutions across the country. Currently, researchers are examining the use of different drugs to effectively treat back pain, in particular, chronic pain that has lasted at least 6 months. Other studies are comparing different health care approaches to the management of acute low back pain (standard care versus chiropractic, acupuncture, or massage therapy). These studies are measuring symptom relief, restoration of function, and patient satisfaction. Other research is comparing standard surgical treatments to the most commonly used standard nonsurgical treatments to measure changes in health-related quality of life among patients suffering from spinal stenosis.
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Back Pain
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What is (are) Coma ?
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A coma, sometimes also called persistent vegetative state, is a profound or deep state of unconsciousness. Persistent vegetative state is not brain-death. An individual in a state of coma is alive but unable to move or respond to his or her environment. Coma may occur as a complication of an underlying illness, or as a result of injuries, such as head trauma. . Individuals in such a state have lost their thinking abilities and awareness of their surroundings, but retain non-cognitive function and normal sleep patterns. Even though those in a persistent vegetative state lose their higher brain functions, other key functions such as breathing and circulation remain relatively intact. Spontaneous movements may occur, and the eyes may open in response to external stimuli. Individuals may even occasionally grimace, cry, or laugh. Although individuals in a persistent vegetative state may appear somewhat normal, they do not speak and they are unable to respond to commands.
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Coma
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What are the treatments for Coma ?
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Once an individual is out of immediate danger, the medical care team focuses on preventing infections and maintaining a healthy physical state. This will often include preventing pneumonia and bedsores and providing balanced nutrition. Physical therapy may also be used to prevent contractures (permanent muscular contractions) and deformities of the bones, joints, and muscles that would limit recovery for those who emerge from coma.
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Coma
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What is the outlook for Coma ?
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The outcome for coma and persistent vegetative state depends on the cause, severity, and site of neurological damage. Individuals may emerge from coma with a combination of physical, intellectual, and psychological difficulties that need special attention. Recovery usually occurs gradually, with some acquiring more and more ability to respond. Some individuals never progress beyond very basic responses, but many recover full awareness. Individuals recovering from coma require close medical supervision. A coma rarely lasts more than 2 to 4 weeks. Some patients may regain a degree of awareness after persistent vegetative state. Others may remain in that state for years or even decades. The most common cause of death for someone in a persistent vegetative state is infection, such as pneumonia.
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Coma
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what research (or clinical trials) is being done for Coma ?
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The National Institute of Neurological Disorders and Stroke (NINDS) and other institutes of the National Institutes of Health (NIH) conduct research related to coma in their laboratories at the NIH and also support additional research through grants to major medical institutions across the country. Much of this research focuses on finding better ways to prevent and treat coma.
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Coma
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What is (are) Neuronal Migration Disorders ?
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Neuronal migration disorders (NMDs) are a group of birth defects caused by the abnormal migration of neurons in the developing brain and nervous system. In the developing brain, neurons must migrate from the areas where they are born to the areas where they will settle into their proper neural circuits. Neuronal migration, which occurs as early as the second month of gestation, is controlled by a complex assortment of chemical guides and signals. When these signals are absent or incorrect, neurons do not end up where they belong. This can result in structurally abnormal or missing areas of the brain in the cerebral hemispheres, cerebellum, brainstem, or hippocampus. The structural abnormalities found in NMDs include schizencephaly, porencephaly, lissencephaly, agyria, macrogyria, polymicrogyria, pachygyria, microgyria, micropolygyria, neuronal heterotopias (including band heterotopia), agenesis of the corpus callosum, and agenesis of the cranial nerves. Symptoms vary according to the abnormality, but often feature poor muscle tone and motor function, seizures, developmental delays, impaired cognitive development, failure to grow and thrive, difficulties with feeding, swelling in the extremities, and a smaller than normal head. Most infants with an NMD appear normal, but some disorders have characteristic facial or skull features that can be recognized by a neurologist. Several genetic abnormalities in children with NMDs have been identified. Defects in genes that are involved in neuronal migration have been associated with NMDs, but the role they play in the development of these disorders is not yet well-understood. More than 25 syndromes resulting from abnormal neuronal migration have been described. Among them are syndromes with several different patterns of inheritance; genetic counseling thus differs greatly between syndromes.
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Neuronal Migration Disorders
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What are the treatments for Neuronal Migration Disorders ?
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Treatment is symptomatic, and may include anti-seizure medication and special or supplemental education consisting of physical, occupational, and speech therapies.
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Neuronal Migration Disorders
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What is the outlook for Neuronal Migration Disorders ?
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The prognosis for children with NMDs varies depending on the specific disorder and the degree of brain abnormality and subsequent neurological signs and symptoms.
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Neuronal Migration Disorders
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what research (or clinical trials) is being done for Neuronal Migration Disorders ?
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The NINDS conducts and supports a wide range of studies that explore the complex systems of brain development. These studies include the identification of the mechanism of action of the known causes of NMD as well as studies to identify further causes of disease. NIH-funded researchers work closely with parental support groups to bring research discoveries directly to patients. The knowledge gained from these studies provides the foundation for understanding abnormal development and offers hope for new ways to treat and prevent NMDs.
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Neuronal Migration Disorders
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What are the complications of Neurological Complications of AIDS ?
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AIDS is primarily an immune system disorder caused by the human immunodeficiency virus (HIV), but it can also affect the nervous system. HIV does not appear to directly invade nerve cells but it jeopardizes their health and function, causing symptoms such as confusion, forgetfulness, behavioral changes, headaches, progressive weakness and loss of sensation in the arms and legs, cognitive motor impairment, or damage to the peripheral nerves. Other complications that can occur as a result of HIV infection or the drugs used to treat it include pain, seizures, shingles, spinal cord problems, lack of coordination, difficult or painful swallowing, anxiety disorder, depression, fever, vision loss, gait disorders, destruction of brain tissue, and coma. Other AIDS-related nervous system disorders may be caused by certain cancers or by illnesses that would not otherwise affect people with healthy immune systems.
Among the most common neurological complications are: AIDS dementia complex, causing symptoms such as encephalitis (inflammation of the brain), behavioral changes, and a gradual decline in cognitive function; central nervous system lymphomas, cancerous tumors that either begin in the brain or result from a cancer that has spread from another site in the body; cryptococcal meningitis; cytomegalovirus infections; herpes virus infections; neuropathy; neurosyphilis; progressive multifocal leukoencephalopathy (PML); and psychological and neuropsychiatric disorders.
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Neurological Complications of AIDS
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What are the treatments for Neurological Complications of AIDS ?
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No single treatment can cure the neurological complications of AIDS. Some disorders require aggressive therapy while others are treated symptomatically.
Medicines range from analgesics sold over the counter to antiepileptic drugs, opiates, corticosteroids, and some classes of antidepressants. Other treatments include radiation therapy or chemotherapy to kill or shrink cancerous brain tumors that may be caused by HIV, antifungal or antimalarial drugs to combat certain bacterial infections, and penicillin to treat neurosyphilis. Aggressive antiretroviral therapy is used to treat AIDS dementia complex, PML, and cytomegalovirus encephalitis. HAART, or highly active antiretroviral therapy, combines at least three drugs to reduce the amount of virus circulating in the blood and may also delay the start of some infections.
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Neurological Complications of AIDS
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What is the outlook for Neurological Complications of AIDS ?
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The overall prognosis for individuals with AIDS in recent years has improved significantly because of new drugs and treatments. AIDS clinicians often fail to recognize neurological complications of AIDS. Those who suspect they are having neurological complications should be sure to discuss these with their doctor.
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Neurological Complications of AIDS
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what research (or clinical trials) is being done for Neurological Complications of AIDS ?
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Within the Federal government, the National Institute of Neurological Disorders and Stroke (NINDS), one part of the National Institutes of Health (NIH), supports research on the neurological consequences of AIDS. The NINDS works closely with its sister agency, the National Institute of Allergy and Infectious Diseases (NIAID), which has primary responsibility for research related to HIV and AIDS.
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Neurological Complications of AIDS
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What is (are) Familial Periodic Paralyses ?
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Familial periodic paralyses are a group of inherited neurological disorders caused by mutations in genes that regulate sodium and calcium channels in nerve cells. They are characterized by episodes in which the affected muscles become slack, weak, and unable to contract. Between attacks, the affected muscles usually work as normal.
The two most common types of periodic paralyses are: Hypokalemic periodic paralysis is characterized by a fall in potassium levels in the blood. In individuals with this mutation attacks often begin in adolescence and are triggered by strenuous exercise, high carbohydrate meals, or by injection of insulin, glucose, or epinephrine. Weakness may be mild and limited to certain muscle groups, or more severe and affect the arms and legs. Attacks may last for a few hours or persist for several days. Some patients may develop chronic muscle weakness later in life. Hyperkalemic periodic paralysis is characterized by a rise in potassium levels in the blood. Attacks often begin in infancy or early childhood and are precipitated by rest after exercise or by fasting. Attacks are usually shorter, more frequent, and less severe than the hypokalemic form. Muscle spasms are common.
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Familial Periodic Paralyses
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What are the treatments for Familial Periodic Paralyses ?
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Treatment of the periodic paralyses focuses on preventing further attacks and relieving acute symptoms. Avoiding carbohydrate-rich meals and strenuous exercise, and taking acetazolamide daily may prevent hypokalemic attacks. Attacks can be managed by drinking a potassium chloride oral solution. Eating carbohydrate-rich, low-potassium foods, and avoiding strenuous exercise and fasting, can help prevent hyperkalemic attacks. Dichorphenamide may prevent attacks.
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Familial Periodic Paralyses
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What is the outlook for Familial Periodic Paralyses ?
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The prognosis for the familial periodic paralyses varies. Chronic attacks may result in progressive weakness that persists between attacks. Some cases respond well to treatment, which can prevent or reverse progressive muscle weakness.
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Familial Periodic Paralyses
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what research (or clinical trials) is being done for Familial Periodic Paralyses ?
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The NINDS conducts and supports research on neuromuscular disorders such as the familial periodic paralyses. These studies are aimed at increasing knowledge about these disorders and finding ways to prevent, treat, and cure them.
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Familial Periodic Paralyses
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What is (are) Central Pain Syndrome ?
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Central pain syndrome is a neurological condition caused by damage to or dysfunction of the central nervous system (CNS), which includes the brain, brainstem, and spinal cord. This syndrome can be caused by stroke, multiple sclerosis, tumors, epilepsy, brain or spinal cord trauma, or Parkinson's disease. The character of the pain associated with this syndrome differs widely among individuals partly because of the variety of potential causes. Central pain syndrome may affect a large portion of the body or may be more restricted to specific areas, such as hands or feet. The extent of pain is usually related to the cause of the CNS injury or damage. Pain is typically constant, may be moderate to severe in intensity, and is often made worse by touch, movement, emotions, and temperature changes, usually cold temperatures. Individuals experience one or more types of pain sensations, the most prominent being burning. Mingled with the burning may be sensations of "pins and needles;" pressing, lacerating, or aching pain; and brief, intolerable bursts of sharp pain similar to the pain caused by a dental probe on an exposed nerve. Individuals may have numbness in the areas affected by the pain. The burning and loss of touch sensations are usually most severe on the distant parts of the body, such as the feet or hands. Central pain syndrome often begins shortly after the causative injury or damage, but may be delayed by months or even years, especially if it is related to post-stroke pain.
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Central Pain Syndrome
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What are the treatments for Central Pain Syndrome ?
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Pain medications often provide some reduction of pain, but not complete relief of pain, for those affected by central pain syndrome. Tricyclic antidepressants such as nortriptyline or anticonvulsants such as neurontin (gabapentin) can be useful. Lowering stress levels appears to reduce pain.
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Central Pain Syndrome
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What is the outlook for Central Pain Syndrome ?
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Central pain syndrome is not a fatal disorder, but the syndrome causes disabling chronic pain and suffering among the majority of individuals who have it.
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Central Pain Syndrome
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what research (or clinical trials) is being done for Central Pain Syndrome ?
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The NINDS vigorously pursues a research program seeking new treatments for chronic pain and nervous system damage. The goals of this research are to develop ways to more effectively treat and potentially reverse debilitating conditions such as central pain syndrome.
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Central Pain Syndrome
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What is (are) Progressive Multifocal Leukoencephalopathy ?
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Progressive multifocal leukoencephalopathy (PML) is a disease of the white matter of the brain, caused by a virus infection that targets cells that make myelin--the material that insulates nerve cells (neurons). Polyomavirus JC (often called JC virus) is carried by a majority of people and is harmless except among those with lowered immune defenses. The disease is rare and occurs in patients undergoing chronic corticosteroid or immunosuppressive therapy for organ transplant, or individuals with cancer (such as Hodgkins disease or lymphoma). Individuals with autoimmune conditions such as multiple sclerosis, rheumatoid arthritis, and systemic lupus erythematosis -- some of whom are treated with biological therapies that allow JC virus reactivation -- are at risk for PML as well. PML is most common among individuals with HIV-1 infection / acquired immune deficiency syndrome (AIDS). Studies estimate that prior to effective antiretroviral therapy, as many as 5 percent of persons infected with HIV-1 eventually develop PML that is an AIDS-defining illness. However, current HIV therapy using antiretroviral drugs (ART), which effectively restores immune system function, allows as many as half of all HIV-PML patients to survive, although they may sometimes have an inflammatory reaction in the regions of the brain affected by PML. The symptoms of PML are diverse, since they are related to the location and amount of damage in the brain, and may evolve over the course of several weeks to months The most prominent symptoms are clumsiness; progressive weakness; and visual, speech, and sometimes personality changes. The progression of deficits leads to life-threatening disability and (frequently) death. A diagnosis of PML can be made following brain biopsy or by combining observations of a progressive course of the disease, consistent white matter lesions visible on a magnetic resonance imaging (MRI) scan, and the detection of the JC virus in spinal fluid.
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Progressive Multifocal Leukoencephalopathy
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What are the treatments for Progressive Multifocal Leukoencephalopathy ?
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Currently, the best available therapy is reversal of the immune-deficient state, since there are no effective drugs that block virus infection without toxicity. Reversal may be achieved by using plasma exchange to accelerate the removal of the therapeutic agents that put patients at risk for PML. In the case of HIV-associated PML, immediately beginning anti-retroviral therapy will benefit most individuals. Several new drugs that laboratory tests found effective against infection are being used in PML patients with special permission of the U.S. Food and Drug Administration. Hexadecyloxypropyl-Cidofovir (CMX001) is currently being studied as a treatment option for JVC because of its ability to suppress JVC by inhibiting viral DNA replication.
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Progressive Multifocal Leukoencephalopathy
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What is the outlook for Progressive Multifocal Leukoencephalopathy ?
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In general, PML has a mortality rate of 30-50 percent in the first few months following diagnosis but depends on the severity of the underlying disease and treatment received. Those who survive PML can be left with severe neurological disabilities.
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Progressive Multifocal Leukoencephalopathy
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what research (or clinical trials) is being done for Progressive Multifocal Leukoencephalopathy ?
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The National Institute of Neurological Disorders and Stroke (NINDS) and other institutes of the National Institutes of Health (NIH) conduct research related to PML in laboratories at the NIH, and support additional research through grants to majorresearch institutions across the country. Much of this research focuses on finding better ways to prevent, treat, and ultimately cure disorders such as PML.
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Progressive Multifocal Leukoencephalopathy
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What is (are) Creutzfeldt-Jakob Disease ?
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Creutzfeldt-Jakob disease (CJD) is a rare, degenerative,fatal brain disorder. Typically, onset of symptoms occurs at about age 60. There are three major categories of CJD: sporadic (the most common form, in which people do not have any risk factors for the disease); hereditary (in which the person has a family member with the disease and tests positive for a genetic mutation), and acquired (in which the disease is transmitted by exposure to brain and nervous system tissue, usually through certain medical procedures. A form called variant CJD can be acquired by eating meat from cattle affected by a disease similar to CJD, called bovine spongiform encephalopathy (commonly called mad cow disease). Symptoms of CJD include problems with muscular coordination, personality changes including progressive and severe mental impairment, impaired vision that may lead to blindness, and involuntary muscle jerks called myoclonus. People eventually lose the ability to move and speak and enter a coma. Tests that help in the diagnosis of CJD include electroencephalography (which measures brain waves), detection of certain proteins in the fluid that surrounds the brain and spinal cord, and magnetic resonance imaging.. The first concern is to rule out treatable forms of dementia such as encephalitis or chronic meningitis. The only way to confirm a diagnosis of CJD is by brain biopsy or autopsy. In a brain biopsy, a neurosurgeon removes a small piece of tissue from the person's brain so that it can be examined by a neurologist. Because a correct diagnosis of CJD does not help the individual, a brain biopsy is discouraged unless it is need to rule out a treatable disorder. .
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Creutzfeldt-Jakob Disease
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What are the treatments for Creutzfeldt-Jakob Disease ?
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There is no treatment that can cure or control CJD, although studies of a variety of drugs are now in progress. Current treatment is aimed at alleviating symptoms and making the person as comfortable as possible. Opiate drugs can help relieve pain, and the drugs clonazepam and sodium valproate may help relieve involuntary muscle jerks.Intravenous fluids and artificial feeding may be needed in later stages of the disease.
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Creutzfeldt-Jakob Disease
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What is the outlook for Creutzfeldt-Jakob Disease ?
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About 70 percent of individuals die within one year. In the early stages of disease, people may have failing memory, behavioral changes, lack of coordination and visual disturbances. As the illness progresses, mental deterioration becomes pronounced and involuntary movements, blindness, weakness of extremities, and coma may occur.
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Creutzfeldt-Jakob Disease
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what research (or clinical trials) is being done for Creutzfeldt-Jakob Disease ?
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The mission of the National Institute of Neurological Disorders and Stroke (NINDS) is to seek fundamental knowledge about the brain and nervous system, and to use that knowledge to reduce the burden of neurological disease. The leading scientific theory at this time maintains that CJD is caused by a type of protein called a prion. The harmless and the infectious forms of the prion protein are nearly identical, but the infectious form takes a different folded shape than the normal protein. Researchers are trying to discover factors that influence prion infectivity and how the disorder damages the brain. Using rodent models of the disease and brain tissue from autopsies, researchers are also trying to develop improved diagnostic tests for CJD and to learn what changes ultimately kill the neurons so that effective treatments can be developed.
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Creutzfeldt-Jakob Disease
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What is (are) Giant Axonal Neuropathy ?
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Giant axonal neuropathy (GAN) is a rare inherited genetic disorder that affects both the central and peripheral nervous systems. The majority of children with GAN will begin to show symptoms of the disease sometime before five years of age. Signs of GAN usually begin in the peripheral nervous system, which controls movement and sensation in the arms, legs, and other parts of the body. The typical symptoms of GAN are clumsiness and muscle weakness that progresses from a waddling gait to a pronounced difficulty in walking. Additional symptoms include numbness or lack of feeling in the arms and legs, seizures, nystagmus (rapid back and forth movement of the eyes), and impaired cognitive development. A characteristic sign of the disease is dull, tightly curled hair that is markedly different from the parents in color and texture.
Researchers have discovered more than 20 different mutations associated with GAN in a gene, GAN1, which makes a protein called gigaxonin. These mutations disrupt the regulation or production of gigaxonin in the nervous system. As a result, axons, which are the long tails of neurons that allow them to communicate with other nerve cells, swell up with tangled filaments and become abnormally large. Eventually these axons deteriorate and cause problems with movement and sensation since neurons are no longer able to communicate with each other.
Doctors diagnose GAN by using several tests, including one that measures nerve conduction velocity, a brain MRI, and a peripheral nerve biopsy (in which a bit of tissue from a peripheral nerve is removed and examined to look for swollen axons). A definitive diagnosis using genetic testing is available on a research basis only.
GAN is inherited in an autosomal recessive pattern, which means that both parents of a child with GAN have to carry a copy of the mutated gene. Parents, typically, will show no signs of the disease.
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Giant Axonal Neuropathy
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What are the treatments for Giant Axonal Neuropathy ?
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Treatment is symptomatic. Children with GAN and their families usually work with a medical team that includes a pediatric neurologist, orthopedic surgeon, physiotherapist, psychologist, and speech and occupational therapists. The major goals of treatment are to maximize intellectual and physical development and minimize their deterioration as time passes. Many children with GAN begin with normal intellectual development and are able to attend a regular school program. Children should be monitored at least once a year to assess their intellectual abilities and to look for the presence of neurological deterioration.
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Giant Axonal Neuropathy
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What is the outlook for Giant Axonal Neuropathy ?
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GAN generally progresses slowly as neurons degenerate and die. Most children have problems with walking in the early stages of the disorder. Later they may lose sensation, coordination, strength, and reflexes in their arms and legs. As time goes on, the brain and spinal cord may become involved, causing a gradual decline in mental function, loss of control of body movement, and seizures. Most children become wheelchair dependent in the second decade of life. Some children may survive into early adulthood.
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Giant Axonal Neuropathy
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what research (or clinical trials) is being done for Giant Axonal Neuropathy ?
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The National Institute of Neurological Disorders and Stroke (NINDS) supports research related to GAN through grants to major medical institutions across the country. Much of this research focuses on finding better ways to prevent, treat, and ultimately cure inherited neurological disorders such as GAN.
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Giant Axonal Neuropathy
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What is (are) SUNCT Headache ?
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SUNCT-Short-lasting, Unilateral, Neuralgiform headache attacks with Conjunctival injection and Tearing-is a rare form of headache that is most common in men after age 50. The disorder is marked by bursts of moderate to severe burning, piercing, or throbbing pain, usually on one side of the head and around the eye or temple. The pain usually peaks within seconds of onset and may follow a pattern of increasing and decreasing intensity. Attacks typically occur in daytime hours and last from 5 seconds to 4 minutes per episode. Individuals generally have five to six attacks per hour.
Autonomic nervous system responses include watery eyes, reddish or bloodshot eyes caused by dilation of blood vessels (conjunctival injection), nasal congestion, runny nose, sweaty forehead, swelling of the eyelids, and increased pressure within the eye on the affected side of head. Systolic blood pressure may rise during the attacks. Movement of the neck may trigger these headaches. SUNCT may be a form of trigeminal neuralgia and is considered one of the trigeminal autonomic cephalgias, or TACs.
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SUNCT Headache
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What are the treatments for SUNCT Headache ?
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These headaches are generally non-responsive to usual treatment for other short-lasting headaches. Corticosteroids and the anti-epileptic drugs gabapentin, lamotrigine, and carbamazepine may help relieve some symptoms in some patients. Studies have shown that injections of glycerol to block nerve signaling along the trigeminal nerve may provide temporary relief in some severe cases, but the headaches recurred in about 40 percent of individuals studied.
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SUNCT Headache
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What is the outlook for SUNCT Headache ?
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There is no cure for these headaches. The disorder is not fatal but can cause considerable discomfort.
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SUNCT Headache
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what research (or clinical trials) is being done for SUNCT Headache ?
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The NINDS conducts a wide range of research on headache disorders. This research aims to discover ways to better diagnose, treat, and ultimately, prevent these disorders.
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SUNCT Headache
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What is (are) Neurotoxicity ?
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Neurotoxicity occurs when the exposure to natural or manmade toxic substances (neurotoxicants) alters the normal activity of the nervous system. This can eventually disrupt or even kill neurons, key cells that transmit and process signals in the brain and other parts of the nervous system. Neurotoxicity can result from exposure to substances used in chemotherapy, radiation treatment, drug therapies, and organ transplants, as well as exposure to heavy metals such as lead and mercury, certain foods and food additives, pesticides, industrial and/or cleaning solvents, cosmetics, and some naturally occurring substances. Symptoms may appear immediately after exposure or be delayed. They may include limb weakness or numbness; loss of memory, vision, and/or intellect; headache; cognitive and behavioral problems; and sexual dysfunction. Individuals with certain disorders may be especially vulnerable to neurotoxicants.
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Neurotoxicity
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What are the treatments for Neurotoxicity ?
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Treatment involves eliminating or reducing exposure to the toxic substance, followed by symptomatic and supportive therapy.
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Neurotoxicity
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What is the outlook for Neurotoxicity ?
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The prognosis depends upon the length and degree of exposure and the severity of neurological injury. In some instances, exposure to neurotoxicants can be fatal. In others, patients may survive but not fully recover. In other situations, many individuals recover completely after treatment.
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Neurotoxicity
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what research (or clinical trials) is being done for Neurotoxicity ?
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The NINDS supports research on disorders of the brain and nervous system such as neurotoxicity, aimed at learning more about these disorders and finding ways to prevent and treat them. Scientists are investigating the role occupational or environmental toxicants have on progressive neurodegenerative disorders such as Parkinson's disease, amyotrophic lateral sclerosis, multiple sclerosis, and dementia. Also being studied are the mechanisms that trigger neuroimmune responses in the central nervous system and the possibility that some brain disorders in children may occur when environmental triggers interact with genes.
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Neurotoxicity
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What is (are) Spinal Cord Injury ?
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A spinal cord injury usually begins with a sudden, traumatic blow to the spine that fractures or dislocates vertebrae. The damage begins at the moment of injury when displaced bone fragments, disc material, or ligaments bruise or tear into spinal cord tissue. Most injuries to the spinal cord don't completely sever it. Instead, an injury is more likely to cause fractures and compression of the vertebrae, which then crush and destroy axons -- extensions of nerve cells that carry signals up and down the spinal cord between the brain and the rest of the body. An injury to the spinal cord can damage a few, many, or almost all of these axons. Some injuries will allow almost complete recovery. Others will result in complete paralysis.
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Spinal Cord Injury
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What are the treatments for Spinal Cord Injury ?
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Improved emergency care for people with spinal cord injuries and aggressive treatment and rehabilitation can minimize damage to the nervous system and even restore limited abilities. Respiratory complications are often an indication of the severity of spinal cord injury About one-third of those with injury to the neck area will need help with breathing and require respiratory support. The steroid drug methylprednisolone appears to reduce the damage to nerve cells if it is given within the first 8 hours after injury. Rehabilitation programs combine physical therapies with skill-building activities and counseling to provide social and emotional support.Electrical simulation of nerves by neural prosthetic devices may restore specific functions, including bladder, breathing, cough, and arm or leg movements, though eligibility for use of these devices depends on the level and type of the spinal cord injury.
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Spinal Cord Injury
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What is the outlook for Spinal Cord Injury ?
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Spinal cord injuries are classified as either complete or incomplete. An incomplete injury means that the ability of the spinal cord to convey messages to or from the brain is not completely lost. People with incomplete injuries retain some motor or sensory function below the injury. A complete injury is indicated by a total lack of sensory and motor function below the level of injury. People who survive a spinal cord injury will most likely have medical complications such as chronic pain and bladder and bowel dysfunction, along with an increased susceptibility to respiratory and heart problems. Successful recovery depends upon how well these chronic conditions are handled day to day.
Surgery to relieve compression of the spinal tissue by surrounding bones broken or dislocated by the injury is often necessary, through timing of such surgery may vary widely. A recent prospective multicenter trial called STASCIS is exploring whether performing decompression surgery early (less than 24 hours following injury) can improve outcomes for patients with bone fragments or other tissues pressing on the spinal cord.
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Spinal Cord Injury
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what research (or clinical trials) is being done for Spinal Cord Injury ?
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The National Institute of Neurological Disorders and Stroke (NINDS) conducts spinal cord research in its laboratories at the National Institutes of Health (NIH) and also supports additional research through grants to major research institutions across the country. Advances in research are giving doctors and patients hope that repairing injured spinal cords is a reachable goal. Advances in basic research are also being matched by progress in clinical research, especially in understanding the kinds of physical rehabilitation that work best to restore function. Some of the more promising rehabilitation techniques are helping spinal cord injury patients become more mobile.
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Spinal Cord Injury
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What is (are) Ataxia Telangiectasia ?
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Ataxia-telangiectasia is a rare, childhood neurological disorder that causes degeneration in the part of the brain that controls motor movements and speech. The first signs of the disease are unsteady walking and slurred speech, usually occurring during the first five years of life. Telangiectasias (tiny, red "spider" veins), which appear in the corners of the eyes or on the surface of the ears and cheeks, are characteristic of the disease, but are not always present and generally do not appear in the first years of life. About 35 percent of those with A-T develop cancer, most frequently acute lymphocytic leukemia or lymphoma. The most unusual symptom is an acute sensitivity to ionizing radiation, such as X-rays or gamma rays. Many individuals with A-T have a weakened immune system, making them susceptible to recurrent respiratory infections. Other features of the disease may include mild diabetes mellitus, premature graying of the hair, difficulty swallowing, and delayed physical and sexual development. Children with A-T usually have normal or above normal intelligence.
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Ataxia Telangiectasia
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What are the treatments for Ataxia Telangiectasia ?
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There is no cure for A-T and, currently, no way to slow the progression of the disease. Treatment is symptomatic and supportive. Physical and occupational therapy help to maintain flexibility. Speech therapy is important, teaching children to control air flow to the vocal cords. Gamma-globulin injections may be useful if immunoglobulin levels are sufficiently reduced to weaken the immune system. High-dose vitamin regimens and antioxidants such as alpha lipoic acid also may also be used.
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Ataxia Telangiectasia
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What is the outlook for Ataxia Telangiectasia ?
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Average lifespan has been improving for years, for unknown reasons, and varies with the severity of the underlying mutations, ATM (ataxia-telangiectasia mutated) protein levels, and residual ATM kinase activity. Some individuals with later onset of disease and slower progression survive into their 50s.
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Ataxia Telangiectasia
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what research (or clinical trials) is being done for Ataxia Telangiectasia ?
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NINDS-supported researchers discovered the gene responsible for A-T, known as ATM (ataxia-telangiectasia mutated) in 1995. This gene makes a protein that activates many (probably more than 700) other proteins that control cell cycle, DNA repair, and cell death. Without it, cells are unable to activate the cellular checkpoints that protect against the damage of ionizing radiation and other agents that can harm DNA. In addition to supporting basic research on A-T, NINDS also funds research aimed at A-T drug development, including development of animal models, gene and stem-cell based therapies, and high-throughput drug screens. The NINDS also leads a trans-NIH A-T Working Group whose members include NINDS, NHLBI, NIEHS, NCI, NEI, NIGMS, NHGRI, NIA, NIAID, NICHD, and ORD.
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Ataxia Telangiectasia
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What is (are) Central Pontine Myelinolysis ?
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Central pontine myelinolysis (CPM) is a neurological disorder that most frequently occurs after too rapid medical correction of sodium deficiency (hyponatremia). The rapid rise in sodium concentration is accompanied by the movement of small molecules and pulls water from brain cells. Through a mechanism that is only partly understood, the shift in water and brain molecules leads to the destruction of myelin, a substance that surrounds and protects nerve fibers. Nerve cells (neurons) can also be damaged. Certain areas of the brain are particularly susceptible to myelinolysis, especially the part of the brain stem called the pons. Some individuals will also have damage in other areas of the brain, which is called extrapontine myelinolysis (EPM). Experts estimate that 10 percent of those with CPM will also have areas of EPM.
The initial symptoms of myelinolysis, which begin to appear 2 to 3 days after hyponatremia is corrected, include a depressed level of awareness, difficulty speaking (dysarthria or mutism), and difficulty swallowing (dysphagia). Additional symptoms often arise over the next 1-2 weeks, including impaired thinking, weakness or paralysis in the arms and legs, stiffness, impaired sensation, and difficulty with coordination. At its most severe, myelinolysis can lead to coma, locked-in syndrome (which is the complete paralysis of all of the voluntary muscles in the body except for those that control the eyes), and death.
Although many affected people improve over weeks to months, some have permanent disability. Some also develop new symptoms later, including behavioral or intellectual impairment or movement disorders like parkinsonism or tremor.
Anyone, including adults and children, who undergoes a rapid rise in serum sodium is at risk for myelinolysis. Some individuals who are particularly vulnerable are those with chronic alcoholism and those who have had a liver transplant. Myelinolysis has occurred in individuals undergoing renal dialysis, burn victims, people with HIV-AIDS, people over-using water loss pills (diuretics), and women with eating disorders such as anorexia or bulimia. The risk for CPM is greater if the serum (blood) sodium was low for at least 2 days before correction.
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Central Pontine Myelinolysis
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What are the treatments for Central Pontine Myelinolysis ?
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The ideal treatment for myelinolysis is to prevent the disorder by identifying individuals at risk and following careful guidelines for evaluation and correction of hyponatremia. These guidelines aim to safely restore the serum sodium level, while protecting the brain. For those who have hyponatremia for at least 2 days, or for whom the duration is not known, the rate of rise in the serum sodium concentration should be kept below 10 mmol/L during any 24-hour period, if possible.
For those who develop myelinolysis, treatment is supportive. Some physicians have tried to treat myelinolysis with steroid medication or other experimental therapies, but none has been proven effective. Individuals are likely to require extensive and prolonged physical therapy and rehabilitation. Those individuals who develop parkinsonian symptoms may respond to the dopaminergic drugs that work for individuals with Parkinsons disease.
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Central Pontine Myelinolysis
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What is the outlook for Central Pontine Myelinolysis ?
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The prognosis for myelinolysis varies. Some individuals die and others recover completely. Although the disorder was originally considered to have a mortality rate of 50 percent or more, improved imaging techniques and early diagnosis have led to a better prognosis for many people. Most individuals improve gradually, but still continue to have challenges with speech, walking, emotional ups and downs, and forgetfulness.
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Central Pontine Myelinolysis
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what research (or clinical trials) is being done for Central Pontine Myelinolysis ?
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The mission of the National Institute of Neurological Disorders and Stroke (NINDS) is to seek fundamental knowledge of the brain and nervous system and to use that knowledge to reduce the burden of neurological disease. The NINDS is a component of the National Institutes of Health, the leading supporter of biomedical research in the world.
The NINDS conducts and supports research to better understand conditions that affect the protective myelin coating around nerve fibers and ways to prevent and treat the destruction of myelin. Scientists hope to develop drugs that can prevent brain cells from dying or help them produce new myelin. Research funded by the NIH's National Institute of Diabetes and Digestive and Kidney Diseases aims to understand the biological mechanisms involved in water balance in the body.
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Central Pontine Myelinolysis
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What is (are) Cerebro-Oculo-Facio-Skeletal Syndrome (COFS) ?
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Cerebro-oculo-facio-skeletal syndrome (COFS) is a pediatric, genetic, degenerative disorder that involves the brain and the spinal cord. It is characterized by craniofacial and skeletal abnormalities, severely reduced muscle tone, and impairment of reflexes. Symptoms may include large, low-set ears, small eyes, microcephaly (abnormal smallness of the head), micrognathia (abnormal smallness of the jaws), clenched fists, wide-set nipples, vision impairments, involuntary eye movements, and impaired cognitive development, which can be moderate or severe. Respiratory infections are frequent. COFS is diagnosed at birth. Ultrasound technology can detect fetuses with COFS at an early stage of pregnancy, as the fetus moves very little, and some of the abnormalities result, in part, from lack of movement.
A small number of individuals with COFS have a mutation in the "ERCC6" gene and are more appropriately diagnosed as having Cockayne Syndrome Type II. Other individuals with COFS may have defects in the xeroderma pigmentosum genes "XPG" or "XPD." Still others who are diagnosed with COFS have no identifiable genetic defect and are presumably affected because of mutations in a distinct, as-yet-unknown gene.
NOTE: This disorder is not the same as Cohen's syndrome (cerebral obesity ocular skeletal syndrome).
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Cerebro-Oculo-Facio-Skeletal Syndrome (COFS)
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What are the treatments for Cerebro-Oculo-Facio-Skeletal Syndrome (COFS) ?
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Treatment is supportive and symptomatic. Individuals with the disorder often require tube feeding. Because COFS is genetic, genetic counseling is available.
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Cerebro-Oculo-Facio-Skeletal Syndrome (COFS)
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What is the outlook for Cerebro-Oculo-Facio-Skeletal Syndrome (COFS) ?
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COFS is a fatal disease. Most children do not live beyond five years.
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Cerebro-Oculo-Facio-Skeletal Syndrome (COFS)
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what research (or clinical trials) is being done for Cerebro-Oculo-Facio-Skeletal Syndrome (COFS) ?
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The NINDS supports research on genetic disorders such as COFS. The goals of this research include finding ways to prevent, treat, and cure these disorders.
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Cerebro-Oculo-Facio-Skeletal Syndrome (COFS)
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What is (are) Shingles ?
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Shingles (herpes zoster) is an outbreak of rash or blisters on the skin that is caused by the same virus that causes chickenpox the varicella-zoster virus. The first sign of shingles is often burning or tingling pain (which can be severe), or sometimes numbness or itch,generally on one side of the body. After several days or a week, a rash of fluid-filled blisters, similar to chickenpox, appears in one area on one side of the body. Shingles pain can be mild or intense. Some people have mostly itching; some feel pain from the gentlest touch or breeze. The most common location for shingles is a band, called a dermatome, spanning one side of the trunk around the waistline. Anyone who has had chickenpox is at risk for shingles. Scientists think that some of the virus particles from the original exposure to the varicella-zoster virus,leave the skin blisters and move into the nervous system. When the varicella-zoster virus reactivates, the virus moves back down the long nerve fibers that extend from the sensory cell bodies to the skin. The viruses multiply, the tell-tale rash erupts, and the person now has shingles.
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Shingles
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What are the treatments for Shingles ?
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The severity and duration of an attack of shingles can be significantly reduced by immediate treatment with antiviral drugs, which include acyclovir, valcyclovir, or famcyclovir. Antiviral drugs may also help stave off the painful after-effects of shingles known as postherpetic neuralgia. Other treatments for postherpetic neuralgia include steroids, antidepressants, anticonvulsants (including pregabalin and gabapentin enacarbil), and topical agents. The varicella zoster virus vaccine (Zostavax) has been approved by teh food and Drug Administration for adults age 50 and older. Researchers found that giving older adults the vaccine reduced the expected number of later cases of shingles by half. And in people who still got the disease despite immunization, the severity and complications of shingles were dramatically reduced. The shingles vaccine is a preventive therapy and not a treatment for those who already have shingles or long-lasting nerve pain (postherpetic neuralgia).
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Shingles
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What is the outlook for Shingles ?
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For most healthy people who receive treatment soon after the outbreak of blisters, the lesions heal, the pain subsides within 3 to 5 weeks, and the blisters often leave no scars. However, shingles is a serious threat in immunosuppressed individuals for example, those with HIV infection or who are receiving cancer treatments that can weaken their immune systems. People who receive organ transplants are also vulnerable to shingles because they are given drugs that suppress the immune system.
A person with a shingles rash can pass the virus to someone, usually a child, who has never had chickenpox, but the child will develop chickenpox, not shingles. A person with chickenpox cannot give shingles to someone else. Shingles comes from the virus hiding inside the person's body, not from an outside source.
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Shingles
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what research (or clinical trials) is being done for Shingles ?
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The mission of the National Institute of Neurological Disorders and Stroke (NINDS) is to seek fundamental knowledge of the brain and nervous system and to use that knowledge to reduce the burden of neurological disease. The NINDS supports research on viral proteins and virus defense mechanisms in neurons to understand why the varicella-zoster virus establishes latency uniquely in neurons and not in other cell types. Other studies focus on how VZV travels along sensory nerve fibers, or axons, and its role in latency and viral reactivation. Scientists also hope to identify molecular mechanisms that regulate the expression of latent viral genes, which may lead to targeted therapy to prevent reactivation. Other studies hope to better understand cellular changes that lead to persistent pain.
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Shingles
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What is (are) Prosopagnosia ?
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Prosopagnosia is a neurological disorder characterized by the inability to recognize faces. Prosopagnosia is also known as face blindness or facial agnosia. The term prosopagnosia comes from the Greek words for face and lack of knowledge. Depending upon the degree of impairment, some people with prosopagnosia may only have difficulty recognizing a familiar face; others will be unable to discriminate between unknown faces, while still others may not even be able to distinguish a face as being different from an object. Some people with the disorder are unable to recognize their own face. Prosopagnosia is not related to memory dysfunction, memory loss, impaired vision, or learning disabilities. Prosopagnosia is thought to be the result of abnormalities, damage, or impairment in the right fusiform gyrus, a fold in the brain that appears to coordinate the neural systems that control facial perception and memory. Prosopagnosia can result from stroke, traumatic brain injury, or certain neurodegenerative diseases. In some cases it is a congenital disorder, present at birth in the absence of any brain damage. Congenital prosopagnosia appears to run in families, which makes it likely to be the result of a genetic mutation or deletion. Some degree of prosopagnosia is often present in children with autism and Aspergers syndrome, and may be the cause of their impaired social development.
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Prosopagnosia
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What are the treatments for Prosopagnosia ?
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The focus of any treatment should be to help the individual with prosopagnosia develop compensatory strategies. Adults who have the condition as a result of stroke or brain trauma can be retrained to use other clues to identify individuals.
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Prosopagnosia
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What is the outlook for Prosopagnosia ?
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Prosopagnosia can be socially crippling. Individuals with the disorder often have difficulty recognizing family members and close friends. They often use other ways to identify people, such as relying on voice, clothing, or unique physical attributes, but these are not as effective as recognizing a face. Children with congenital prosopagnosia are born with the disability and have never had a time when they could recognize faces. Greater awareness of autism, and the autism spectrum disorders, which involve communication impairments such as prosopagnosia, is likely to make the disorder less overlooked in the future.
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Prosopagnosia
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what research (or clinical trials) is being done for Prosopagnosia ?
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The National Institute of Neurological Disorders and Stroke (NINDS) conducts research related to prosopagnosia in its laboratories at the National Institutes of Health (NIH), and also supports additional research through grants to major medical institutions across the country. Much of this research focuses on finding better ways to prevent, treat, and ultimately cure disorders, such as prosopagnosia.
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Prosopagnosia
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What is (are) Shaken Baby Syndrome ?
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Shaken baby syndrome is a type of inflicted traumatic brain injury that happens when a baby is violently shaken. A baby has weak neck muscles and a large, heavy head. Shaking makes the fragile brain bounce back and forth inside the skull and causes bruising, swelling, and bleeding, which can lead to permanent, severe brain damage or death. The characteristic injuries of shaken baby syndrome are subdural hemorrhages (bleeding in the brain), retinal hemorrhages (bleeding in the retina), damage to the spinal cord and neck, and fractures of the ribs and bones. These injuries may not be immediately noticeable. Symptoms of shaken baby syndrome include extreme irritability, lethargy, poor feeding, breathing problems, convulsions, vomiting, and pale or bluish skin. Shaken baby injuries usually occur in children younger than 2 years old, but may be seen in children up to the age of 5.
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Shaken Baby Syndrome
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What are the treatments for Shaken Baby Syndrome ?
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Emergency treatment for a baby who has been shaken usually includes life-sustaining measures such as respiratory support and surgery to stop internal bleeding and bleeding in the brain. Doctors may use brain scans, such as MRI and CT, to make a more definite diagnosis.
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Shaken Baby Syndrome
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What is the outlook for Shaken Baby Syndrome ?
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In comparison with accidental traumatic brain injury in infants, shaken baby injuries have a much worse prognosis. Damage to the retina of the eye can cause blindness. The majority of infants who survive severe shaking will have some form of neurological or mental disability, such as cerebral palsy or cognitive impairment, which may not be fully apparent before 6 years of age. Children with shaken baby syndrome may require lifelong medical care.
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Shaken Baby Syndrome
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what research (or clinical trials) is being done for Shaken Baby Syndrome ?
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The National Institute of Neurological Disorders and Stroke (NINDS), and other institutes of the National Institutes of Health (NIH), conduct research related to shaken baby syndrome in laboratories at the NIH and also support additional research through grants to major medical institutions across the country. Much of this research focuses on finding better ways to treat and heal medical conditions such as shaken baby syndrome.
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Shaken Baby Syndrome
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What is (are) Gaucher Disease ?
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Gaucher disease is one of the inherited metabolic disorders known as lipid storage diseases. Lipids are fatty materials that include oils, fatty acids, waxes, and steroids (such as cholesterol and estrogen). Gaucher disease is caused by a deficiency of the enzyme glucocerebrosidase. Fatty materials can accumulate in the brain, spleen, liver, lungs, bone marrow, and kidneys. Symptoms may begin in early life or adulthood and include skeletal disorders and bone lesions that may cause pain and fractures, enlarged spleen and liver, liver malfunction, anemia, and yellow spots in the eyes. There are three common clinical subtypes of Gaucher disease. The first category, called type 1 (or nonneuropathic), typically does not affect the brain. Symptoms may begin early in life or in adulthood. People in this group usually bruise easily due to low blood platelets and experience fatigue due to anemia They also may have an enlarged liver and spleen. Many individuals with a mild form of the disorder may not show any symptoms. In type 2 Gaucher disease (acute infantile neuropathic Gaucher disease), symptoms usually begin by 3 months of age and include extensive brain damage, seizures, spasticity, poor ability to suck and swallow, and enlarged liver and spleen. Affecetd children usually die before 2 years of age. In the third category, called type 3 (or chronic neuropathic Gaucher disease), signs of brain involvement such as seizures gradually become apparent. Major symptoms also include skeletal irregularities, eye movement disorders, cognitive deficit, poor coordination, enlarged liver and spleen, respiratory problems, and blood disorders.
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Gaucher Disease
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What are the treatments for Gaucher Disease ?
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Enzyme replacement therapy is available for most people with types 1 and 3 Gaucher disease. Given intravenously every two weeks, this therapy decreases liver and spleen size, reduces skeletal abnormalities, and reverses other symptoms of the disorder. The U.S. Food and Drug Administration has approved eligustat tartrate for Gaucher treatment, which works by administering small molecules that reduce the action of the enzyme that catalyzes glucose to ceramide. Surgery to remove the whole or part of the spleen may be required on rare occasions, and blood transfusions may benefit some anemic individuals. Other individuals may require joint replacement surgery to improve mobility and quality of life. There is no effective treatment for severe brain damage that may occur in persons with types 2 and 3 Gaucher disease.
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Gaucher Disease
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What is the outlook for Gaucher Disease ?
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Enzyme replacement therapy is very beneficial for type 1 and most type 3 individuals with this condition. Successful bone marrow transplantation can reverse the non-neurological effects of the disease, but the procedure carries a high risk and is rarely performed in individuals with Gaucher disease.
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Gaucher Disease
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what research (or clinical trials) is being done for Gaucher Disease ?
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The mission of the National Institute of Neurological Disorders and Stroke (NINDS), a part of the National Institutes of Health), is to seek fundamental knowledge about the brain and nervous system and to use that knowledge to reduce the burden of neurological disease. The NINDS supports research to find ways to treat and prevent lipid storage disorders such as Gaucher disease. For example, researchers hope to identify biomarkers (signs that may indicate risk of a disease and improve diagnosis) for Gaucher disease and other lipid storage diseases; and identify genetic, biochemical, and clinical factors that are associated with disease severity in individuals with Gaucher disease.Additional research is looking at the increased buildup of the protein alpha-synuclein, which is seen in Gaucher disease, Parkinson's disease, and Lewy Body Dementia. Using different models of glucoserebrosidase deficiency, scientists hope to learn how this deficiency impairs the breakdown of lysosomal proteins, including the breakdown of alpha-synuclein.
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Gaucher Disease
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What is (are) Moyamoya Disease ?
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Moyamoya disease is a rare, progressive cerebrovascular disorder caused by blocked arteries at the base of the brain in an area called the basal ganglia. The name moyamoya means puff of smoke in Japanese and describes the look of the tangle of tiny vessels formed to compensate for the blockage. Moyamoya disease was first described in Japan in the 1960s and it has since been found in individuals in the other countries around the world; its incidence is higher in Asian countries than in Europe or North America. The disease primarily affects children, but it can also occur in adults. In children, the first symptom of Moyamoya disease is often stroke, or recurrent transient ischemic attacks (TIA, commonly referred to as mini-strokes), frequently accompanied by muscular weakness or paralysis affecting one side of the body, or seizures. Adults may also experience these symptoms that arise from blocked arteries, but more often experience a hemorrhagic stroke due to bleeding into the brain from the abnormal brain vessels. Individuals with this disorder may have disturbed consciousness, problems with speaking and understanding speech, sensory and cognitive impairments, involuntary movements, and vision problems.About one in 10 individuals with Moyamoya disease has a close relative who is also affected; in these cases researchers think that Moyamoya disease is the result of inherited genetic abnormalities.Studies that look for the abnormal gene(s) may help reveal the biomechanisms that cause the disorder.
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Moyamoya Disease
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What are the treatments for Moyamoya Disease ?
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There are several types of surgery that can restore blood flow (revascularization) to the brain by opening narrowed blood vessels or by bypassing blocked arteries. Children usually respond better to revascularization surgery than adults, but the majority of individuals have no further strokes or related problems after surgery.
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Moyamoya Disease
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What is the outlook for Moyamoya Disease ?
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Without surgery, the majority of individuals with Moyamoya disease will experience mental decline and multiple strokes because of the progressive narrowing of arteries.Without treatment,Moyamoya diseasecan be fatal as the result ofintracerebral hemorrhage (bleeding within the brain).
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Moyamoya Disease
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what research (or clinical trials) is being done for Moyamoya Disease ?
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The mission of the National Institute of Neurological Disorders and Stroke (NINDS) is to seek fundamental knowledge about the brain and nervous system and to use that knowledge to reduce the burden of neurological disease. The NINDS conducts and supports neurological research aimed at understanding why diseases develop in the brain, and that focus on finding ways to prevent, treat, or cure them.Anti-angiogenic therapy uses drugs that either activate and promote cell growth or directly block the growing blood vessel cells. NINDS-funded researchers are testing the anti-angiogenic drug Apo-Timop, part of a class of drugs called beta-blockers, which may lead to the development of new anti-angiogenics for people with vascular malformations. In other research, Other NINDS-funded research hopes to improve the understanding of this disease by determining whether infections injure blood vessels and thereby predispose children to stroke. It will also determine causes of recurrence, a crucial step toward developing ways to prevent repeated strokes in children.
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Moyamoya Disease
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What is (are) Dyslexia ?
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Dyslexia is a brain-based type of learning disability that specifically impairs a person's ability to read. These individuals typically read at levels significantly lower than expected despite having normal intelligence. Although the disorder varies from person to person, common characteristics among people with dyslexia are difficulty with phonological processing (the manipulation of sounds), spelling, and/or rapid visual-verbal responding. In individuals with adult onset of dyslexia, it usually occurs as a result of brain injury or in the context of dementia; this contrasts with individuals with dyslexia who simply were never identified as children or adolescents. Dyslexia can be inherited in some families, and recent studies have identified a number of genes that may predispose an individual to developing dyslexia.
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Dyslexia
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What are the treatments for Dyslexia ?
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The main focus of treatment should be on the specific learning problems of affected individuals. The usual course is to modify teaching methods and the educational environment to meet the specific needs of the individual with dyslexia.
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Dyslexia
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What is the outlook for Dyslexia ?
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For those with dyslexia, the prognosis is mixed. The disability affects such a wide range of people and produces such different symptoms and varying degrees of severity that predictions are hard to make. The prognosis is generally good, however, for individuals whose dyslexia is identified early, who have supportive family and friends and a strong self-image, and who are involved in a proper remediation program.
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Dyslexia
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what research (or clinical trials) is being done for Dyslexia ?
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The National Institute of Neurological Disorders and Stroke (NINDS) and other institutes of the National Institutes of Health (NIH) support dyslexia research through grants to major research institutions across the country. Current research avenues focus on developing techniques to diagnose and treat dyslexia and other learning disabilities, increasing the understanding of the biological and possible genetic bases of learning disabilities, and exploring the relationship between neurophysiological processes and cognitive functions with regard to reading ability.
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Dyslexia
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What is (are) Lesch-Nyhan Syndrome ?
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Lesch-Nyhan syndrome (LNS) is a rare, inherited disorder caused by a deficiency of the enzyme hypoxanthine-guanine phosphoribosyltransferase (HPRT). LNS is an X-linked recessive disease-- the gene is carried by the mother and passed on to her son. LNS is present at birth in baby boys. The lack of HPRT causes a build-up of uric acid in all body fluids, and leads to symptoms such as severe gout, poor muscle control, and moderate retardation, which appear in the first year of life. A striking feature of LNS is self-mutilating behaviors characterized by lip and finger biting that begin in the second year of life. Abnormally high uric acid levels can cause sodium urate crystals to form in the joints, kidneys, central nervous system, and other tissues of the body, leading to gout-like swelling in the joints and severe kidney problems. Neurological symptoms include facial grimacing, involuntary writhing, and repetitive movements of the arms and legs similar to those seen in Huntingtons disease. Because a lack of HPRT causes the body to poorly utilize vitamin B12, some boys may develop a rare disorder called megaloblastic anemia.
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Lesch-Nyhan Syndrome
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What are the treatments for Lesch-Nyhan Syndrome ?
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Treatment for LNS is symptomatic. Gout can be treated with allopurinol to control excessive amounts of uric acid. Kidney stones may be treated with lithotripsy, a technique for breaking up kidney stones using shock waves or laser beams. There is no standard treatment for the neurological symptoms of LNS. Some may be relieved with the drugs carbidopa/levodopa, diazepam, phenobarbital, or haloperidol.
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Lesch-Nyhan Syndrome
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What is the outlook for Lesch-Nyhan Syndrome ?
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The prognosis for individuals with LNS is poor. Death is usually due to renal failure in the first or second decade of life.
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Lesch-Nyhan Syndrome
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what research (or clinical trials) is being done for Lesch-Nyhan Syndrome ?
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The gene associated with LNS is known. The NINDS supports and conducts research on genetic disorders such as LNS in an effort to find ways to prevent and treat these disorders.
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Lesch-Nyhan Syndrome
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What is (are) Hereditary Spastic Paraplegia ?
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Hereditary spastic paraplegia (HSP), also called familial spastic paraparesis (FSP), refers to a group of inherited disorders that are characterized by progressive weakness and spasticity (stiffness) of the legs. Early in the disease course, there may be mild gait difficulties and stiffness. These symptoms typically slowly progress so that eventually individuals with HSP may require the assistance of a cane, walker, or wheelchair. Though the primary features of "pure" HSP are progressive lower limb spasticity and weakness, complicated forms may be accompanied by other symptoms. These additional symptoms include impaired vision due to cataracts and problems with the optic nerve and retina of the eye, ataxia (lack of muscle coordination), epilepsy, cognitive impairment, peripheral neuropathy, and deafness. The diagnosis of HSP is primarily by neurological examination and testing to rule out other disorders. Brain MRI abnormalities, such as a thin corpus callosum, may be seen in some of the complicated forms of HSP. Several genetic mutations have been identified which underlie various forms of HSP, and specialized genetic testing and diagnosis are available at some medical centers. HSP has several forms of inheritance. Not all children in a family will necessarily develop symptoms, although they may be carriers of the abnormal gene. Symptoms may begin in childhood or adulthood, depending on the particular HSP gene involved.
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Hereditary Spastic Paraplegia
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What are the treatments for Hereditary Spastic Paraplegia ?
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There are no specific treatments to prevent, slow, or reverse HSP. Symptomatic treatments used for spasticity, such as muscle relaxants, are sometimes helpful. Regular physical therapy is important for muscle strength and to preserve range of motion.
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Hereditary Spastic Paraplegia
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What is the outlook for Hereditary Spastic Paraplegia ?
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The prognosis for individuals with HSP varies Some individuals are very disabled and others have only mild disability. The majority of individuals with uncomplicated HSP have a normal life expectancy.
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Hereditary Spastic Paraplegia
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what research (or clinical trials) is being done for Hereditary Spastic Paraplegia ?
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The NINDS supports research on genetic disorders such as HSP. More than 30 genes that are responsible for several forms of HSP have been identified, and many more will likely be identified in the future. These genes generally encode proteins that normally help maintain the function of axons in the spinal cord. Understanding how mutations of these genes cause HSP should lead to ways to prevent, treat, and cure HSP.
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Hereditary Spastic Paraplegia
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What is (are) Tethered Spinal Cord Syndrome ?
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Tethered spinal cord syndrome is a neurological disorder caused by tissue attachments that limit the movement of the spinal cord within the spinal column. Attachments may occur congenitally at the base of the spinal cord (conus medullaris) or they may develop near the site of an injury to the spinal cord. These attachments cause an abnormal stretching of the spinal cord. The course of the disorder is progressive. In children, symptoms may include lesions, hairy patches, dimples, or fatty tumors on the lower back; foot and spinal deformities; weakness in the legs; low back pain; scoliosis; and incontinence. This type of tethered spinal cord syndrome appears to be the result of improper growth of the neural tube during fetal development, and is closely linked to spina bifida. Tethered spinal cord syndrome may go undiagnosed until adulthood, when pain, sensory and motor problems, and loss of bowel and bladder control emerge. This delayed presentation of symptoms is related to the degree of strain placed on the spinal cord over time and may be exacerbated during sports or pregnancy, or may be due to narrowing of the spinal column (stenosis) with age. Tethering may also develop after spinal cord injury and scar tissue can block the flow of fluids around the spinal cord. Fluid pressure may cause cysts to form in the spinal cord, a condition called syringomyelia. This can lead to additional loss of movement, feeling or the onset of pain or autonomic symptoms.
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Tethered Spinal Cord Syndrome
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What are the treatments for Tethered Spinal Cord Syndrome ?
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MRI imaging is often used to evaluate individuals with these symptoms, and can be used to diagnose the location of the tethering, lower than normal position of the conus medullaris, or presence of a tumor or fatty mass (lipoma). In children, early surgery is recommended to prevent further neurological deterioration. Regular follow-up is important: retethering may occur in some individuals during periods of rapid growth and may be seen between five to nine years of age. If surgery is not advisable, spinal cord nerve roots may be cut to relieve pain. In adults, surgery to free (detether) the spinal cord can reduce the size and further development of cysts in the cord and may restore some function or alleviate other symptoms. Other treatment is symptomatic and supportive.
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Tethered Spinal Cord Syndrome
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What is the outlook for Tethered Spinal Cord Syndrome ?
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With treatment, individuals with tethered spinal cord syndrome have a normal life expectancy. However, some neurological and motor impairments may not be fully correctable. Surgery soon after symptoms emerge appears to improve chances for recovery and can prevent further functional decline.
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Tethered Spinal Cord Syndrome
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what research (or clinical trials) is being done for Tethered Spinal Cord Syndrome ?
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The NINDS conducts and supports research on disorders of the spinal cord. The goals of this research are to find ways to prevent, treat, and cure these disorders.
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Tethered Spinal Cord Syndrome
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What is (are) Peripheral Neuropathy ?
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Peripheral neuropathy describes damage to the peripheral nervous system, which transmits information from the brain and spinal cord to every other part of the body.
More than 100 types of peripheral neuropathy have been identified, each with its own characteristic set of symptoms, pattern of development, and prognosis. Impaired function and symptoms depend on the type of nerves -- motor, sensory, or autonomic -- that are damaged. Some people may experience temporary numbness, tingling, and pricking sensations, sensitivity to touch, or muscle weakness. Others may suffer more extreme symptoms, including burning pain (especially at night), muscle wasting, paralysis, or organ or gland dysfunction. Peripheral neuropathy may be either inherited or acquired. Causes of acquired peripheral neuropathy include physical injury (trauma) to a nerve, tumors, toxins, autoimmune responses, nutritional deficiencies, alcoholism, medical procedures, and vascular and metabolic disorders. Acquired peripheral neuropathies are caused by systemic disease, trauma from external agents, or infections or autoimmune disorders affecting nerve tissue. Inherited forms of peripheral neuropathy are caused by inborn mistakes in the genetic code or by new genetic mutations.
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Peripheral Neuropathy
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What are the treatments for Peripheral Neuropathy ?
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No medical treatments exist that can cure inherited peripheral neuropathy. However, there are therapies for many other forms. In general, adopting healthy habits -- such as maintaining optimal weight, avoiding exposure to toxins, following a physician-supervised exercise program, eating a balanced diet, correcting vitamin deficiencies, and limiting or avoiding alcohol consumption -- can reduce the physical and emotional effects of peripheral neuropathy. Systemic diseases frequently require more complex treatments.
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Peripheral Neuropathy
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What is the outlook for Peripheral Neuropathy ?
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In acute neuropathies, such as Guillain-Barr syndrome, symptoms appear suddenly, progress rapidly, and resolve slowly as damaged nerves heal. In chronic forms, symptoms begin subtly and progress slowly. Some people may have periods of relief followed by relapse. Others may reach a plateau stage where symptoms stay the same for many months or years. Some chronic neuropathies worsen over time, but very few forms prove fatal unless complicated by other diseases. Occasionally the neuropathy is a symptom of another disorder.
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Peripheral Neuropathy
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what research (or clinical trials) is being done for Peripheral Neuropathy ?
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The National Institute of Neurological Disorders and Stroke (NINDS) and other institutes of the National Institutes of Health (NIH) conduct research related to peripheral neuropathies in laboratories at the NIH and also support additional research through grants to major medical institutions across the country. Current research projects funded by the NINDS involve investigations of genetic factors associated with hereditary neuropathies, studies of biological mechanisms involved in diabetes-associated neuropathies, and investigations exploring how the immune system contributes to peripheral nerve damage. Neuropathic pain is a primary target of NINDS-sponsored studies aimed at developing more effective therapies for symptoms of peripheral neuropathy. Some scientists hope to identify substances that will block the brain chemicals that generate pain signals, while others are investigating the pathways by which pain signals reach the brain.
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Peripheral Neuropathy
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What is (are) Paroxysmal Hemicrania ?
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Paroxysmal hemicrania is a rare form of headache that usually begins in adulthood. Patients experience severe throbbing, claw-like, or boring pain usually on one side of the face; in, around, or behind the eye; and occasionally reaching to the back of the neck. This pain may be accompanied by red and tearing eyes, a drooping or swollen eyelid on the affected side of the face, and nasal congestion. Patients may also feel dull pain, soreness, or tenderness between attacks. Attacks of paroxysmal hemicrania typically occur from 5 to 40 times per day and last 2 to 30 minutes. The disorder has two forms: chronic, in which patients experience attacks on a daily basis for a year or more, and episodic, in which the headaches may remit for months or years. Certain movements of the head or neck or external pressure to the neck may trigger these headaches in some patients. The disorder is more common in women than in men.
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Paroxysmal Hemicrania
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What are the treatments for Paroxysmal Hemicrania ?
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The nonsteroidal anti-inflammatory drug (NSAID) indomethacin often provides complete relief from symptoms. Other less effective NSAIDs, calcium-channel blocking drugs (such as verapamil), and corticosteroids may be used to treat the disorder. Patients with both paroxysmal hemicrania and trigeminal neuralgia (a condition of the 5th cranial nerve that causes sudden, severe pain typically felt on one side of the jaw or cheek) should receive treatment for each disorder.
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Paroxysmal Hemicrania
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