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Multiple system atrophy (MSA) is a progressive neurodegenerative disorder characterized by symptoms of autonomic nervous system failure such as fainting spells and bladder control problems, combined with motor control symptoms such as tremor, rigidity, and loss of muscle coordination. MSA affects both men and women primarily in their 50s. Although what causes MSA is unknown, the disorder's symptoms reflect the loss of nerve cells in several different areas in the brain and spinal cord that control the autonomic nervous system and coordinate muscle movements. The loss of nerve cells may be due to the buildup of a protein called alpha-synuclein in the cells that support nerve cells in the brain.
Mutations in the WT1 gene cause Frasier syndrome. The WT1 gene provides instructions for making a protein that regulates the activity of other genes by attaching (binding) to specific regions of DNA. On the basis of this action, the WT1 protein is called a transcription factor. The WT1 protein plays a role in the development of the kidneys and gonads (ovaries in females and testes in males) before birth. The WT1 gene mutations that cause Frasier syndrome lead to the production of a protein with an impaired ability to control gene activity and regulate the development of the kidneys and reproductive organs, resulting in the signs and symptoms of Frasier syndrome. Frasier syndrome has features similar to another condition called Denys-Drash syndrome, which is also caused by mutations in the WT1 gene. Because these two conditions share a genetic cause and have overlapping features, some researchers have suggested that they are part of a spectrum and not two distinct conditions.
Brooke-Spiegler syndrome is a condition involving multiple skin tumors that develop from structures associated with the skin (skin appendages), such as sweat glands and hair follicles. People with Brooke-Spiegler syndrome may develop several types of tumors, including growths called spiradenomas, trichoepitheliomas, and cylindromas. Spiradenomas develop in sweat glands. Trichoepitheliomas arise from hair follicles. The origin of cylindromas has been unclear; while previously thought to derive from sweat glands, they are now generally believed to begin in hair follicles. The tumors associated with Brooke-Spiegler syndrome are generally noncancerous (benign), but occasionally they may become cancerous (malignant). Affected individuals are also at increased risk of developing tumors in tissues other than skin appendages, particularly benign or malignant tumors of the salivary glands. People with Brooke-Spiegler syndrome typically begin developing tumors in early adulthood. The tumors are most often found on the head and neck. They grow larger and increase in number over time. In severe cases, the tumors may get in the way of the eyes, ears, nose, or mouth and affect vision, hearing, or other functions. The tumors can be disfiguring and may contribute to depression or other psychological problems. For reasons that are unclear, females with Brooke-Spiegler syndrome are often more severely affected than males.
Researchers have not found a way to prevent benign prostatic hyperplasia. Men with risk factors for benign prostatic hyperplasia should talk with a health care provider about any lower urinary tract symptoms and the need for regular prostate exams. Men can get early treatment and minimize benign prostatic hyperplasia effects by recognizing lower urinary tract symptoms and identifying an enlarged prostate.
Diagnosis of marine toxin poisoning is generally based on symptoms and a history of recently eating a particular kind of seafood. Laboratory testing for the specific toxin in patient samples is generally not necessary because this requires special techniques and equipment available in only specialized laboratories. If suspect, leftover fish or shellfish are available, they can be tested for the presence of the toxin more easily. Identification of the specific toxin is not usually necessary for treating patients because there is no specific treatment.
Ocular cicatricial pemphigoid (OCP) is a form of mucous membrane pemphigoid (a group of rare, chronic autoimmune disorders) that affects the eyes. In the early stages, people with OCP generally experience chronic or relapsing conjunctivitis that is often characterized by tearing, irritation, burning, and/or mucus drainage. If left untreated, OCP can progress to severe conjunctiva scarring and vision loss. Involvement of other mucosal sites and the skin may also occur in OCP. The exact underlying cause is currently unknown. The treatment of OCP aims to slow disease progression and prevent complications. This usually involves long-term use of medications called immunomodulators which help regulate or normalize the immune system.
Mutations in the OTC gene cause ornithine transcarbamylase deficiency. Ornithine transcarbamylase deficiency belongs to a class of genetic diseases called urea cycle disorders. The urea cycle is a sequence of reactions that occurs in liver cells. It processes excess nitrogen, generated when protein is used by the body, to make a compound called urea that is excreted by the kidneys. In ornithine transcarbamylase deficiency, the enzyme that starts a specific reaction within the urea cycle is damaged or missing. The urea cycle cannot proceed normally, and nitrogen accumulates in the bloodstream in the form of ammonia. Ammonia is especially damaging to the nervous system, so ornithine transcarbamylase deficiency causes neurological problems as well as eventual damage to the liver.
Individuals with Fabry disease often die prematurely of complications from strokes, heart disease, or kidney failure.
How is 17q21.31 microdeletion syndrome diagnosed? 17q21.31 microdeletion syndrome is diagnosed in individuals who have a deletion of 500,000 to 650,000 DNA building blocks (base pairs) at chromosome 17q21.31. The diagnosis can be made by various genetic testing methods, including FISH and array CGH. This condition cannot be diagnosed by traditional chromosome tests (karyotype) that look at chromosome banding patterns under the microscope because the deletion is too small to be detected.
Mutations in the COL6A1, COL6A2, and COL6A3 genes can cause the various forms of collagen VI-related myopathy. These genes each provide instructions for making one component of a protein called type VI collagen. Type VI collagen makes up part of the extracellular matrix that surrounds muscle cells and connective tissue. This matrix is an intricate lattice that forms in the space between cells and provides structural support. The extracellular matrix is necessary for cell stability and growth. Research suggests that type VI collagen helps secure and organize the extracellular matrix by linking the matrix to the cells it surrounds. Mutations in the COL6A1, COL6A2, and COL6A3 genes result in a decrease or lack of type VI collagen or the production of abnormal type VI collagen. While it is difficult to predict which type of mutation will lead to which form of collagen VI-related myopathy, in general, lower amounts of type VI collagen lead to more severe signs and symptoms that begin earlier in life. Changes in type VI collagen structure or production lead to an unstable extracellular matrix that is no longer attached to cells. As a result, the stability of the surrounding muscle cells and connective tissue progressively declines, which leads to the muscle weakness, contractures, and other signs and symptoms of collagen VI-related myopathy.
Is there a medicine that can cure Dowling-Degos disease? There is no cure for Dowling-Degos disease. Many different treatments have been tried for this condition, but none has proven effective in eliminating the symptoms for all patients. Topical retinoic acids, topical steroids, hydroquinone, tretinoin, and systemic retinoids have been used without success. Limited reports indicate at least temporary therapeutic benefit with topical adapalene. Various laser systems (CO2 and erbiumYAG) have also shown some promise. Additional articles that address this topic can be accessed below: Altomare G, Capella GL, Fracchiolla C, Frigerio E. Effectiveness of topical adapalene in Dowling-Degos disease. Dermatology. 1999;198(2):176-7.
Studies have shown that most people with prediabetes develop type 2 diabetes within a few years, unless they change their lifestyle. Most people with prediabetes dont have any symptoms. Your doctor can test your blood to find out if your blood glucose levels are higher than normal. Losing weightat least 5 to 10 percent of your starting weightcan prevent or delay diabetes or even reverse prediabetes. Thats 10 to 20 pounds for someone who weighs 200 pounds. You can lose weight by cutting the amount of calories and fat you consume and by being physically active at least 30 to 60 minutes every day. Physical activity also helps your body use the hormone insulin properly. Your body needs insulin to use glucose for energy. Medicine can help control the amount of glucose in your blood. Ask your doctor if medicine to control glucose is right for you. Learn more about prediabetes here.
This condition is inherited in an autosomal recessive pattern, which means both copies of the gene in each cell have mutations. The parents of an individual with an autosomal recessive condition each carry one copy of the mutated gene, but they typically do not show signs and symptoms of the condition.
How can I find additional comprehensive information on the treatment of Wolman disease? You can find relevant journal articles on Wolman syndrome and its treatment through a service called PubMed, a searchable database of medical literature. Information on finding an article and its title, authors, and publishing details is listed here. Some articles are available as a complete document, while information on other studies is available as a summary abstract. To obtain the full article, contact a medical/university library (or your local library for interlibrary loan), or order it online using the following link. Using "Wolman syndrome[ti] treatment" as your search term should locate articles. To narrow your search, click on the Limits tab under the search box and specify your criteria for locating more relevant articles. Click here to view a search. http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed The National Library of Medicine (NLM) Web site has a page for locating libraries in your area that can provide direct access to these journals (print or online). The Web page also describes how you can get these articles through interlibrary loan and Loansome Doc (an NLM document-ordering service). You can access this page at the following link http://nnlm.gov/members/. You can also contact the NLM toll-free at 888-346-3656 to locate libraries in your area.
The most common treatment for learning disabilities is special education. Specially trained educators may perform a diagnostic educational evaluation assessing the child's academic and intellectual potential and level of academic performance. Once the evaluation is complete, the basic approach is to teach learning skills by building on the child's abilities and strengths while correcting and compensating for disabilities and weaknesses. Other professionals such as speech and language therapists also may be involved. Some medications may be effective in helping the child learn by enhancing attention and concentration. Psychological therapies may also be used.
What are the signs and symptoms of High molecular weight kininogen deficiency? The Human Phenotype Ontology provides the following list of signs and symptoms for High molecular weight kininogen deficiency. If the information is available, the table below includes how often the symptom is seen in people with this condition. You can use the MedlinePlus Medical Dictionary to look up the definitions for these medical terms. Signs and Symptoms Approximate number of patients (when available) Autosomal recessive inheritance - Prolonged partial thromboplastin time - Reduced kininogen activity - The Human Phenotype Ontology (HPO) has collected information on how often a sign or symptom occurs in a condition. Much of this information comes from Orphanet, a European rare disease database. The frequency of a sign or symptom is usually listed as a rough estimate of the percentage of patients who have that feature. The frequency may also be listed as a fraction. The first number of the fraction is how many people had the symptom, and the second number is the total number of people who were examined in one study. For example, a frequency of 25/25 means that in a study of 25 people all patients were found to have that symptom. Because these frequencies are based on a specific study, the fractions may be different if another group of patients are examined. Sometimes, no information on frequency is available. In these cases, the sign or symptom may be rare or common.
SOX2 anophthalmia syndrome is inherited in an autosomal dominant pattern, which means one copy of the altered gene in each cell is sufficient to cause the disorder. Most cases result from new mutations in the SOX2 gene and occur in people with no history of the disorder in their family. In a small number of cases, people with SOX2 anophthalmia syndrome have inherited the altered gene from an unaffected parent who has a SOX2 mutation only in their sperm or egg cells. This phenomenon is called germline mosaicism.
Summary : Screenings are tests that look for diseases before you have symptoms. Screening tests can find diseases early, when they're easier to treat. You can get some screenings in your doctor's office. Others need special equipment, so you may need to go to a different office or clinic. Some conditions that doctors commonly screen for include - Breast cancer and cervical cancer in women - Colorectal cancer - Diabetes - High blood pressure - High cholesterol - Osteoporosis - Overweight and obesity - Prostate cancer in men Which tests you need depends on your age, your sex, your family history, and whether you have risk factors for certain diseases. After a screening test, ask when you will get the results and whom to talk to about them. Agency for Healthcare Research and Quality
How might a sacrococcygeal teratoma be treated? The treatment for sacrococcygeal teratoma (SCT) typically involves surgery to remove the tumor. Surgery occurs either in the prenatal period or shortly after delivery. The timing is dependent on the size of the tumor and the associated symptoms. To learn more about both prenatal and postnatal surgery for SCT, visit the following links from The Children's Hospital of Philadelphia (CHOP) http://www.chop.edu/treatments/fetal-surgery-sacrococcygeal-teratoma-sct/about#.VqGW_PkrJD8 http://www.chop.edu/treatments/postnatal-surgery-sacrococcygeal-teratoma-sct#.VqGX7vkrJD8
Hypotrichosis-lymphedema-telangiectasia syndrome (HLTS) is a rare condition that, as the name suggests, is associated with sparse hair (hypotrichosis), lymphedema, and telangiectasia, particularly on the palms of the hands. Symptoms usually begin at birth or in early childhood and become worse over time. HLTS is thought to be caused by changes (mutations) in the SOX18 gene. It can follow both an autosomal dominant or an autosomal recessive pattern of inheritance, depending on the affected family. There is currently no cure for the condition. Treatment is based on the signs and symptoms present in each person.
These resources address the diagnosis or management of Fuchs endothelial dystrophy: - Duke Eye Center: Corneal Disease - Genetic Testing Registry: Corneal dystrophy, Fuchs endothelial 1 - Genetic Testing Registry: Corneal dystrophy, Fuchs endothelial, 2 - Genetic Testing Registry: Corneal dystrophy, Fuchs endothelial, 3 - Genetic Testing Registry: Corneal dystrophy, Fuchs endothelial, 4 - Genetic Testing Registry: Corneal dystrophy, Fuchs endothelial, 5 - Genetic Testing Registry: Corneal dystrophy, Fuchs endothelial, 6 - Genetic Testing Registry: Corneal dystrophy, Fuchs endothelial, 7 - MedlinePlus Encyclopedia: Fuchs Dystrophy These resources from MedlinePlus offer information about the diagnosis and management of various health conditions: - Diagnostic Tests - Drug Therapy - Surgery and Rehabilitation - Genetic Counseling - Palliative Care
The prevalence of Pelizaeus-Merzbacher disease is estimated to be 1 in 200,000 to 500,000 males in the United States. This condition rarely affects females.
Frequently Asked Questions (FAQs) Cystic echinococcosis (CE) disease results from being infected with the larval stage of Echinococcus granulosus, a tiny tapeworm (~2-7 millimeters in length) found in dogs (definitive host), sheep, cattle, goats, foxes, and pigs, amongst others (intermediate hosts). Most infections in humans are asymptomatic, but CE, also known as hydatid disease, causes slowly enlarging masses, most commonly in the liver and the lungs. Treatment can involve both medication and surgery. More on: Cystic Echinococcosis (CE) FAQs Alveolar echinococcosis (AE) disease results from being infected with the larval stage of Echinococcus multilocularis, a tiny tapeworm (~1-4 millimeters in length) found in foxes, coyotes, dogs, and cats (definitive hosts). Although human cases are rare, infection in humans causes parasitic tumors to form in the liver, and, less commonly, the lungs, brain, and other organs. If left untreated, infection with AE can be fatal. More on: Alveolar Echinococcosis (AE) FAQs
ACD/MPV can be caused by mutations in the FOXF1 gene. The protein produced from the FOXF1 gene is a transcription factor, which means that it attaches (binds) to specific regions of DNA and helps control the activity of many other genes. The FOXF1 protein is important in development of the lungs and their blood vessels. The FOXF1 protein is also involved in the development of the gastrointestinal tract. Mutations in the FOXF1 gene that cause ACD/MPV result in an inactive protein that cannot regulate development, leading to abnormal formation of the pulmonary blood vessels and gastrointestinal tract. ACD/MPV can also be caused by a deletion of genetic material on the long arm of chromosome 16 in a region known as 16q24.1. This region includes several genes, including the FOXF1 gene. Deletion of one copy of the FOXF1 gene in each cell reduces the production of the FOXF1 protein. A shortage of FOXF1 protein affects the development of pulmonary blood vessels and causes the main features of ACD/MPV. Researchers suggest that the loss of other genes in this region probably causes the additional abnormalities, such as heart defects, seen in some infants with this disorder. Like FOXF1, these genes also provide instructions for making transcription factors that regulate development of various body systems before birth. In about 60 percent of affected infants, the genetic cause of ACD/MPV is unknown.
These resources address the diagnosis or management of Carney complex: - Gene Review: Gene Review: Carney Complex - Genetic Testing Registry: Carney complex - Genetic Testing Registry: Carney complex, type 1 - Genetic Testing Registry: Carney complex, type 2 - MedlinePlus Encyclopedia: Atrial Myxoma - MedlinePlus Encyclopedia: Pituitary Tumor These resources from MedlinePlus offer information about the diagnosis and management of various health conditions: - Diagnostic Tests - Drug Therapy - Surgery and Rehabilitation - Genetic Counseling - Palliative Care
- Viral hepatitis is inflammation of the liver caused by the hepatitis A, B, C, D, or E viruses. - Depending on the type of virus, viral hepatitis is spread through contaminated food or water, contact with infected blood, sexual contact with an infected person, or from mother to child during childbirth. - Vaccines offer protection from hepatitis A and hepatitis B. - No vaccines are available for hepatitis C, D, and E. Reducing exposure to the viruses offers the best protection. - Hepatitis A and E usually resolve on their own. Hepatitis B, C, and D can be chronic and serious. Drugs are available to treat chronic hepatitis.
Brugada syndrome is a condition that causes a disruption of the heart's normal rhythm. Specifically, this disorder can lead to irregular heartbeats in the heart's lower chambers (ventricles), which is an abnormality called ventricular arrhythmia. If untreated, the irregular heartbeats can cause fainting (syncope), seizures, difficulty breathing, or sudden death. These complications typically occur when an affected person is resting or asleep. Brugada syndrome usually becomes apparent in adulthood, although it can develop any time throughout life. Signs and symptoms related to arrhythmias, including sudden death, can occur from early infancy to late adulthood. Sudden death typically occurs around age 40. This condition may explain some cases of sudden infant death syndrome (SIDS), which is a major cause of death in babies younger than 1 year. SIDS is characterized by sudden and unexplained death, usually during sleep. Sudden unexplained nocturnal death syndrome (SUNDS) is a condition characterized by unexpected cardiac arrest in young adults, usually at night during sleep. This condition was originally described in Southeast Asian populations, where it is a major cause of death. Researchers have determined that SUNDS and Brugada syndrome are the same disorder.
The activity of the TPMT enzyme is inherited in a pattern described as autosomal codominant. Codominance means that two different versions of the gene are active (expressed), and both versions influence the genetic trait. The TPMT gene can be classified as either low-activity or high-activity. When the gene is altered in a way that impairs the activity of the TPMT enzyme, it is described as low-activity. When the gene is unaltered and TPMT activity is normal, it is described as high-activity. Because two copies of the gene are present in each cell, each person can have two low-activity copies, one low-activity copy and one high-activity copy, or two high-activity copies. People with two low-activity copies of the TPMT gene in each cell have TPMT deficiency and are at the greatest risk of developing hematopoietic toxicity when treated with thiopurine drugs unless they are given much less than the usual dose. People with one high-activity copy and one low-activity copy have moderately reduced enzyme activity and are also at increased risk of this complication unless given a significantly lower dose of the drug. People with two high-activity copies have normal TPMT activity and do not have an increased risk of hematopoietic toxicity with thiopurine drug treatment.
These resources address the diagnosis or management of 9q22.3 microdeletion: - Gene Review: Gene Review: 9q22.3 Microdeletion - Gene Review: Gene Review: Nevoid Basal Cell Carcinoma Syndrome - Genetic Testing Registry: Gorlin syndrome - MedlinePlus Encyclopedia: Basal Cell Nevus Syndrome These resources from MedlinePlus offer information about the diagnosis and management of various health conditions: - Diagnostic Tests - Drug Therapy - Surgery and Rehabilitation - Genetic Counseling - Palliative Care
The NINDS supports and conducts neurogenetic research which focuses on identifying and studying the genes involved in normal brain development. The knowledge gained from these fundamental studies provides the foundation for understanding how this process can go awry and, thus, may eventually give clues to understanding disorders such as SOD.
How might cerebellar degeneration be treated? There is currently no cure for hereditary forms of cerebellar degeneration. In these cases, treatment is usually supportive and based on the signs and symptoms present in each person. For example, a variety of drugs may be used to treat gait abnormalities. Physical therapy can strengthen muscles, while special devices or appliances can assist in walking and other activities of daily life. In acquired (non-genetic and non-inherited) forms of cerebellar degeneration, some signs and symptoms may be reversible with treatment of the underlying cause. For example, paraneoplastic cerebellar degeneration may improve after successful treatment of the underlying cancer. For alcoholic/nutritional cerebellar degeneration, symptoms are often relieved with discontinuation of alcohol abuse, a normal diet and dietary supplementation with thiamine and other B vitamins.
Your spinal cord is a bundle of nerves that runs down the middle of your back. It carries signals back and forth between your body and your brain. A spinal cord injury disrupts the signals. Spinal cord injuries usually begin with a blow that fractures or dislocates your vertebrae, the bone disks that make up your spine. Most injuries don't cut through your spinal cord. Instead, they cause damage when pieces of vertebrae tear into cord tissue or press down on the nerve parts that carry signals. Spinal cord injuries can be complete or incomplete. With a complete spinal cord injury, the cord can't send signals below the level of the injury. As a result, you are paralyzed below the injury. With an incomplete injury, you have some movement and sensation below the injury. A spinal cord injury is a medical emergency. Immediate treatment can reduce long-term effects. Treatments may include medicines, braces or traction to stabilize the spine, and surgery. Later treatment usually includes medicines and rehabilitation therapy. Mobility aids and assistive devices may help you to get around and do some daily tasks. NIH: National Institute of Neurological Disorders and Stroke
Henoch-Schonlein purpura (HSP) is a disease that involves purple spots on the skin (purpura), joint pain, digestive problems, and glomerulonephritis (a type of kidney disorder). While the cause of this condition is not fully understood, it may develop as an immune response to an infection. HSP is usually seen in children, but it may affect people of any age. Most cases go away on their own without treatment. For those cases which require treatment, the main goal is to relieve symptoms such as joint pain, abdominal pain, or swelling. In many cases, over-the-counter medicines can be used. In some patients with severe arthritis, prednisone, a steroid medicine, may be prescribed.
Hyperferritinemia-cataract syndrome is caused by mutations in the FTL gene. This gene provides instructions for making the ferritin light chain, which is one part (subunit) of the protein ferritin. Ferritin is made up of 24 subunits formed into a hollow spherical molecule. The 24 subunits consist of varying numbers of the ferritin light chain and another subunit called the ferritin heavy chain, which is produced from another gene. The proportion of the two subunits varies in different tissues. Ferritin stores and releases iron in cells. Each ferritin molecule can hold as many as 4,500 iron atoms inside its spherical structure. This storage capacity allows ferritin to regulate the amount of iron in cells and tissues. The mutations that cause hyperferritinemia-cataract syndrome are found in a segment of the gene called the iron responsive element (IRE). The IRE normally can attach (bind) to a protein called the iron regulatory protein (IRP). When this binding occurs, the activity (expression) of the FTL gene is stopped to prevent too much ferritin light chain from being produced. This normally occurs when iron levels are low, because under those circumstances less ferritin is needed to store the iron. Mutations in the IRE segment of the FTL gene prevent it from binding with IRP, interfering with the mechanism by which ferritin production is matched to iron levels and resulting in excess ferritin being formed.
How might scapuloperoneal myopathy be treated? There is no standard course of treatment for scapuloperoneal myopathy. Some patients may benefit from physical therapy or other therapeutic exercises.
The prognosis for individuals with BSS varies depending on the cause of the disorder.
What causes hairy tongue? The exact cause is unknown; however, smoking, alcohol, dehydration, use of antibiotics, low saliva production, trigeminal neuralgia, poor oral hygiene and cranial radiation therapy have shown to bring about hairy tongue.
Summary : A healthy diet helps children grow and learn. It also helps prevent obesity and weight-related diseases, such as diabetes. To give your child a nutritious diet - Make half of what is on your child's plate fruits and vegetables - Choose healthy sources of protein, such as lean meat, nuts, and eggs - Serve whole-grain breads and cereals because they are high in fiber. Reduce refined grains. - Broil, grill, or steam foods instead of frying them - Limit fast food and junk food - Offer water or milk instead of sugary fruit drinks and sodas Learn about your children's nutrient requirements. Some of them, such as the requirements for iron and calcium, change as your child ages. NIH: National Institute of Diabetes and Digestive and Kidney Diseases
Preventing pulmonary embolism (PE) begins with preventing deep vein thrombosis (DVT). Knowing whether you're at risk for DVT and taking steps to lower your risk are important. Exercise your lower leg muscles if you're sitting for a long time while traveling. Get out of bed and move around as soon as you're able after having surgery or being ill. The sooner you move around, the better your chance is of avoiding a blood clot. Take medicines to prevent clots after some types of surgery (as your doctor prescribes). Follow up with your doctor. If you've already had DVT or PE, you can take more steps to prevent new blood clots from forming. Visit your doctor for regular checkups. Also, use compression stockings to prevent chronic (ongoing) swelling in your legs from DVT (as your doctor advises). Contact your doctor right away if you have any signs or symptoms of DVT or PE.
Chorea-acanthocytosis is one of a group of conditions called the neuroacanthocytoses that involve neurological problems and abnormal red blood cells. The condition is characterized by involuntary jerking movements (chorea), abnormal star-shaped red blood cells (acanthocytosis), and involuntary tensing of various muscles (dystonia), such as those in the limbs, face, mouth, tongue, and throat. Chorea-acanthocytosis is caused by mutations in the VPS13A gene and is inherited in an autosomal recessive manner. There are currently no treatments to prevent or slow the progression of chorea-acanthocytosis; treatment is symptomatic and supportive.
How might Mantle cell lympoma be treated? Various treatmentsare currently available for Mantle cell lymphomas. Rare cases of early stage mantle cell lymphomas may be treated with radiation therapy. For more advance stagestreatment includes chemotherapy, immunotherapy, bone marrow transplant, and medication.
These resources address the diagnosis or management of facioscapulohumeral muscular dystrophy: - Gene Review: Gene Review: Facioscapulohumeral Muscular Dystrophy - Genetic Testing Registry: Facioscapulohumeral muscular dystrophy - Genetic Testing Registry: Facioscapulohumeral muscular dystrophy 2 - MedlinePlus Encyclopedia: Facioscapulohumeral Muscular Dystrophy These resources from MedlinePlus offer information about the diagnosis and management of various health conditions: - Diagnostic Tests - Drug Therapy - Surgery and Rehabilitation - Genetic Counseling - Palliative Care
Severe intellectual disability-progressive spastic diplegia syndrome is a rare condition that has been described in a few people with severe intellectual disability . Other signs and symptoms include progressive microcephaly (very small head); ataxia (lack of coordination); spasticity; and/or skin, hair and mild facial anomalies. It is caused by changes (mutations) in the CTNNB1 gene and it is inherited in an autosomal dominant fashion. Treatment is based on the signs and symptoms present in each person.
SOX2 anophthalmia syndrome is estimated to affect 1 in 250,000 individuals. About 10 percent to 15 percent of people with anophthalmia in both eyes have SOX2 anophthalmia syndrome.
Tay-Sachs disease is a rare, inherited disorder. It causes too much of a fatty substance to build up in the brain. This buildup destroys nerve cells, causing mental and physical problems. Infants with Tay-Sachs disease appear to develop normally for the first few months of life. Then mental and physical abilities decline. The child becomes blind, deaf, and unable to swallow. Muscles begin to waste away and paralysis sets in. Even with the best of care, children with Tay-Sachs disease usually die by age 4. The cause is a gene mutation which is most common in Eastern European Ashkenazi Jews. To get the disease, both parents must have the gene. If they do, there is a 25% chance of the child having the disease. A blood test and prenatal tests can check for the gene or the disease. There is no cure. Medicines and good nutrition can help some symptoms. Some children need feeding tubes. NIH: National Institute of Neurological Disorders and Stroke
WaterhouseFriderichsen syndrome is adrenal gland failure due to bleeding into the adrenal gland. It is usually caused by severe meningococcal infection or other severe, bacterial infection. Symptoms include acute adrenal gland insufficiency, and profound shock. Most patients with this condition are children, although adults may rarely be affected. It is deadly if not treated immediately.
These resources address the diagnosis or management of Andermann syndrome: - Gene Review: Gene Review: Hereditary Motor and Sensory Neuropathy with Agenesis of the Corpus Callosum - Genetic Testing Registry: Andermann syndrome These resources from MedlinePlus offer information about the diagnosis and management of various health conditions: - Diagnostic Tests - Drug Therapy - Surgery and Rehabilitation - Genetic Counseling - Palliative Care
What are the signs and symptoms of Laurence Prosser Rocker syndrome? The Human Phenotype Ontology provides the following list of signs and symptoms for Laurence Prosser Rocker syndrome. If the information is available, the table below includes how often the symptom is seen in people with this condition. You can use the MedlinePlus Medical Dictionary to look up the definitions for these medical terms. Signs and Symptoms Approximate number of patients (when available) Aganglionic megacolon - Autosomal recessive inheritance - Polysyndactyly of hallux - Preaxial foot polydactyly - Ventricular septal defect - The Human Phenotype Ontology (HPO) has collected information on how often a sign or symptom occurs in a condition. Much of this information comes from Orphanet, a European rare disease database. The frequency of a sign or symptom is usually listed as a rough estimate of the percentage of patients who have that feature. The frequency may also be listed as a fraction. The first number of the fraction is how many people had the symptom, and the second number is the total number of people who were examined in one study. For example, a frequency of 25/25 means that in a study of 25 people all patients were found to have that symptom. Because these frequencies are based on a specific study, the fractions may be different if another group of patients are examined. Sometimes, no information on frequency is available. In these cases, the sign or symptom may be rare or common.
Androgen insensitivity syndrome is a condition that affects sexual development before birth and during puberty. People with this condition are genetically male, with one X chromosome and one Y chromosome in each cell. Because their bodies are unable to respond to certain male sex hormones (called androgens), they may have some physical traits of a woman. Androgen insensitivity syndrome is caused by mutations in the AR gene and is inherited in an X-linked recessive pattern.
Mutations in or near the SOX9 gene cause campomelic dysplasia. This gene provides instructions for making a protein that plays a critical role in the formation of many different tissues and organs during embryonic development. The SOX9 protein regulates the activity of other genes, especially those that are important for development of the skeleton and reproductive organs. Most cases of campomelic dysplasia are caused by mutations within the SOX9 gene. These mutations prevent the production of the SOX9 protein or result in a protein with impaired function. About 5 percent of cases are caused by chromosome abnormalities that occur near the SOX9 gene; these cases tend to be milder than those caused by mutations within the SOX9 gene. The chromosome abnormalities disrupt regions of DNA that normally regulate the activity of the SOX9 gene. All of these genetic changes prevent the SOX9 protein from properly controlling the genes essential for normal development of the skeleton, reproductive system, and other parts of the body. Abnormal development of these structures causes the signs and symptoms of campomelic dysplasia.
What causes 17q23.2q23.2 microdeletion syndrome? The syndrome is caused by an interstitial deletion (a deletion that does not involve the ends of a chromosome) encompassing bands 23.1 to 23.2 on the long (q) arm of chromosome 17. Two transcription factors, TBX2 and TBX4, which belong to a family of genes implicated in a variety of developmental pathways including those of heart and limbs, are found within this 2.2Mb region. This suggests that they may play a part in the symptoms seen in this condition.
This condition is inherited in an autosomal recessive pattern, which means both copies of the gene in each cell have mutations. The parents of an individual with an autosomal recessive condition each carry one copy of the mutated gene, but they typically do not show signs and symptoms of the condition.
The course of Ohtahara syndrome is severely progressive. Seizures become more frequent, accompanied by delays in physical and cognitive development.Some children will die in infancy; others will survive but be profoundly handicapped. As they grow, some children will progress into other epileptic disorders such as West syndrome and Lennox-Gestaut syndrome.
What causes primary melanoma of the small intestine? The cause of primary melanoma of the small intestine is currently unknown. Theories include that the cancer originated from a undetectable primary tumor that spontaneously (naturally) regressed on its own; that the cancer originated from a primary tumor that is so small it can not be detected using standard clinical and laboratory investigations; lastly, because melanocytes are not normally found in the stomach, a final theory is that the melanocytes are in the stomach because early melanocyte cells lost their way during the development of the baby in the womb, and that these misplaced cells later became cancerous.
What are the signs and symptoms of Schistosomiasis? The Human Phenotype Ontology provides the following list of signs and symptoms for Schistosomiasis. If the information is available, the table below includes how often the symptom is seen in people with this condition. You can use the MedlinePlus Medical Dictionary to look up the definitions for these medical terms. Signs and Symptoms Approximate number of patients (when available) Abnormality of the immune system - Autosomal dominant inheritance - The Human Phenotype Ontology (HPO) has collected information on how often a sign or symptom occurs in a condition. Much of this information comes from Orphanet, a European rare disease database. The frequency of a sign or symptom is usually listed as a rough estimate of the percentage of patients who have that feature. The frequency may also be listed as a fraction. The first number of the fraction is how many people had the symptom, and the second number is the total number of people who were examined in one study. For example, a frequency of 25/25 means that in a study of 25 people all patients were found to have that symptom. Because these frequencies are based on a specific study, the fractions may be different if another group of patients are examined. Sometimes, no information on frequency is available. In these cases, the sign or symptom may be rare or common.
What causes human T-cell leukemia virus, type 2? Human T-cell leukemia virus, type 2 (HTLV-2) occurs when a person is infected by the human T-cell leukemia retrovirus. HTLV-2 is spread by blood transfusions, sexual contact and sharing needles. It can also be spread from mother to child during birth or breast-feeding. It is unclear why some people with HTLV-2 may develop neurological problems and other medical conditions, while others remain asymptomatic (show no signs or symptoms) their entire lives.
Amblyopia, or "lazy eye," is the most common cause of visual impairment in children. It happens when an eye fails to work properly with the brain. The eye may look normal, but the brain favors the other eye. In some cases, it can affect both eyes. Causes include - Strabismus - a disorder in which the two eyes don't line up in the same direction - Refractive error in an eye - when one eye cannot focus as well as the other, because of a problem with its shape. This includes nearsightedness, farsightedness, and astigmatism. - Cataract - a clouding in the lens of the eye It can be hard to diagnose amblyopia. It is often found during a routine vision exam. Treatment for amblyopia forces the child to use the eye with weaker vision. There are two common ways to do this. One is to have the child wear a patch over the good eye for several hours each day, over a number of weeks to months. The other is with eye drops that temporarily blur vision. Each day, the child gets a drop of a drug called atropine in the stronger eye. It is also sometimes necessary to treat the underlying cause. This could include glasses or surgery. NIH: National Eye Institute
Singleton Merten syndrome is an extremely rare, multisystem disorder. The major characteristics are tooth abnormalities (dental dysplasia); calcifications in the aorta and certain valves of the heart (i.e., aortic and mitral valves); and progressive thinning and loss of protein of the bones (osteoporosis), especially the upper and back portions of the skull. Other physical findings may include generalized muscle weakness; progressive muscle atrophy; growth delay; delays in motor development; skin conditions; and/or malformation of the hips and/or feet. It appears to occur sporadically (in individuals with no history of the condition in their family) but in some cases, autosomal dominant inheritance has been suggested. Treatment is typically directed toward the specific symptoms that are present in each individual.
The exact prevalence of progressive supranuclear palsy is unknown. It may affect about 6 in 100,000 people worldwide.
This condition is inherited in an autosomal recessive pattern, which means both copies of the gene in each cell have mutations. The parents of an individual with an autosomal recessive condition each carry one copy of the mutated gene, but they typically do not show signs and symptoms of the condition.
These resources address the diagnosis or management of cap myopathy: - Genetic Testing Registry: TPM2-related cap myopathy - Genetic Testing Registry: cap myopathy These resources from MedlinePlus offer information about the diagnosis and management of various health conditions: - Diagnostic Tests - Drug Therapy - Surgery and Rehabilitation - Genetic Counseling - Palliative Care
North American Indian childhood cirrhosis has been found only in children of Ojibway-Cree descent in the Abitibi region of northwestern Quebec, Canada. At least 30 affected individuals from this population have been reported.
What treatment is available for orofaciodigital syndrome type 2? Treatment is dependent on the symptoms. For example, reconstructive surgery might be performed to correct oral, facial, and/or finger and toe abnormalities.
These resources address the diagnosis or management of spastic paraplegia type 11: - Gene Review: Gene Review: Spastic Paraplegia 11 - Genetic Testing Registry: Spastic paraplegia 11, autosomal recessive - Spastic Paraplegia Foundation, Inc.: Treatments and Therapies These resources from MedlinePlus offer information about the diagnosis and management of various health conditions: - Diagnostic Tests - Drug Therapy - Surgery and Rehabilitation - Genetic Counseling - Palliative Care
Mutations in the TSC1 gene or, more commonly, the TSC2 gene, cause LAM. The TSC1 and TSC2 genes provide instructions for making the proteins hamartin and tuberin, respectively. Within cells, these two proteins likely help regulate cell growth and size. The proteins act as tumor suppressors, which normally prevent cells from growing and dividing too fast or in an uncontrolled way. When both copies of the TSC1 gene are mutated in a particular cell, that cell cannot produce any functional hamartin; cells with two altered copies of the TSC2 gene are unable to produce any functional tuberin. The loss of these proteins allows the cell to grow and divide in an uncontrolled way, resulting in the tumors and cysts associated with LAM. It is not well understood why LAM occurs predominantly in women. Researchers believe that the female sex hormone estrogen may be involved in the development of the disorder.
Summary : Today, children in the United States routinely get vaccines that protect them from more than a dozen diseases such as measles, polio, tetanus, diphtheria, and pertussis (whooping cough). Most of these diseases are now at their lowest levels in history, thanks to years of immunization. Children must get at least some vaccines before they may attend school. Vaccines help make you immune to serious diseases without getting sick first. Without a vaccine, you must actually get a disease in order to become immune to the germ that causes it. Vaccines work best when they are given at certain ages. For example, children don't receive measles vaccine until they are at least one year old. If it is given earlier it might not work as well. The Centers for Disease Control and Prevention publishes a schedule for childhood vaccines. Although some of the vaccines you receive as a child provide protection for many years, adults need immunizations too. Centers for Disease Control and Prevention
Fragile XE syndrome is estimated to affect 1 in 25,000 to 100,000 newborn males. Only a small number of affected females have been described in the medical literature. Because mildly affected individuals may never be diagnosed, it is thought that the condition may be more common than reported.
Signs of uterine sarcoma include abnormal bleeding. Abnormal bleeding from the vagina and other signs and symptoms may be caused by uterine sarcoma or by other conditions. Check with your doctor if you have any of the following: - Bleeding that is not part of menstrual periods. - Bleeding after menopause. - A mass in the vagina. - Pain or a feeling of fullness in the abdomen. - Frequent urination.
Mutations in the ANTXR2 gene (also known as the CMG2 gene) cause infantile systemic hyalinosis. The ANTXR2 gene provides instructions for making a protein involved in the formation of tiny blood vessels (capillaries). Researchers believe that the ANTXR2 protein is also important for maintaining the structure of basement membranes, which are thin, sheet-like structures that separate and support cells in many tissues. The signs and symptoms of infantile systemic hyalinosis are caused by the accumulation of a hyaline substance in different parts of the body. The nature of this substance is not well known, but it is likely made up of protein and sugar molecules. Researchers suspect that mutations in the ANTXR2 gene disrupt the formation of basement membranes, allowing the hyaline substance to leak through and build up in various body tissues.
Are basilar migraines inherited? In most cases, basilar migraines are not inherited. However, the susceptibility to basilar migraines may rarely be caused by a change (mutation) in the ATP1A2 gene or CACNA1A gene. In these cases, they are inherited in an autosomal dominant manner. This means that to be affected, a person only needs a mutation in one copy of the responsible gene in each cell. In some cases, an affected person inherits the mutation from an affected parent. Other cases may result from new (de novo) mutations in the gene. These cases occur in people with no history of the disorder in their family. A person with one of these mutations has a 50% chance with each pregnancy of passing along the altered gene to his or her child.
Muenke syndrome occurs in about 1 in 30,000 newborns. This condition accounts for an estimated 8 percent of all cases of craniosynostosis.
What causes Floating-Harbor syndrome? The exact cause of Floating-Harbor syndrome is not known. Autosomal dominant inheritance has been suggested.
Candida is the scientific name for yeast. It is a fungus that lives almost everywhere, including in your body. Usually, your immune system keeps yeast under control. If you are sick or taking antibiotics, it can multiply and cause an infection. Yeast infections affect different parts of the body in different ways: - Thrush is a yeast infection that causes white patches in your mouth - Candida esophagitis is thrush that spreads to your esophagus, the tube that takes food from your mouth to your stomach. It can make it hard or painful to swallow. - Women can get vaginal yeast infections, causing itchiness, pain and discharge - Yeast infections of the skin cause itching and rashes - Yeast infections in your bloodstream can be life-threatening Antifungal medicines get rid of yeast infections in most people. If you have a weak immune system, treatment might be more difficult.
These resources address the diagnosis or management of juvenile polyposis syndrome: - Gene Review: Gene Review: Juvenile Polyposis Syndrome - Genetic Testing Registry: Juvenile polyposis syndrome - MedlinePlus Encyclopedia: Colorectal Polyps These resources from MedlinePlus offer information about the diagnosis and management of various health conditions: - Diagnostic Tests - Drug Therapy - Surgery and Rehabilitation - Genetic Counseling - Palliative Care
Summary : Circumcision is the removal of the foreskin, which is the skin that covers the tip of the penis. In the United States, it is often done before a new baby leaves the hospital. There are medical benefits and risks to circumcision. Possible benefits include a lower risk of urinary tract infections, penile cancer and sexually transmitted diseases. The risks include pain and a low risk of bleeding or infection. The American Academy of Pediatrics (AAP) found that the medical benefits of circumcision outweigh the risks. They recommend that parents make this decision in consultation with their pediatrician. Parents need to decide what is best for their sons, based on their religious, cultural and personal preferences.
Hypochondrogenesis is one of the most severe conditions in a spectrum of disorders caused by mutations in the COL2A1 gene. This gene provides instructions for making a protein that forms type II collagen. This type of collagen is found mostly in the clear gel that fills the eyeball (the vitreous) and in cartilage. Cartilage is a tough, flexible tissue that makes up much of the skeleton during early development. Most cartilage is later converted to bone, except for the cartilage that continues to cover and protect the ends of bones and is present in the nose and external ears. Type II collagen is essential for the normal development of bones and other connective tissues that form the body's supportive framework. Mutations in the COL2A1 gene interfere with the assembly of type II collagen molecules, which prevents bones and other connective tissues from developing properly.
You can't prevent primary, or inherited, hemochromatosis. However, not everyone who inherits hemochromatosis genes develops symptoms or complications of the disease. In those who do, treatments can keep the disease from getting worse. Treatments include therapeutic phlebotomy, iron chelation therapy, dietary changes, and other treatments. For more information, go to "How Is Hemochromatosis Treated?" People who have hemochromatosis (or a family history of it) and are planning to have children may want to consider genetic testing and counseling. Testing will help show whether one or both parents have faulty HFE genes. A genetic counselor also can help figure out the likelihood of the parents passing the faulty genes on to their children.
Worldwide, tyrosinemia type I affects about 1 in 100,000 individuals. This type is more common in Norway where 1 in 60,000 to 74,000 individuals are affected. Tyrosinemia type I is even more common in Quebec, Canada where it occurs in about 1 in 16,000 individuals. In the Saguenay-Lac St. Jean region of Quebec, tyrosinemia type I affects 1 in 1,846 people. Tyrosinemia type II occurs in fewer than 1 in 250,000 individuals worldwide. Tyrosinemia type III is very rare; only a few cases have been reported.
These resources address the diagnosis or management of Swyer syndrome: - Gene Review: Gene Review: 46,XY Disorder of Sex Development and 46,XY Complete Gonadal Dysgenesis - Genetic Testing Registry: Pure gonadal dysgenesis 46,XY - MedlinePlus Encyclopedia: Intersex - University College London Hospitals: Disorders of Sexual Development These resources from MedlinePlus offer information about the diagnosis and management of various health conditions: - Diagnostic Tests - Drug Therapy - Surgery and Rehabilitation - Genetic Counseling - Palliative Care
Mutations in the ACSF3 gene cause CMAMMA. This gene provides instructions for making an enzyme that plays a role in the formation (synthesis) of fatty acids. Fatty acids are building blocks used to make fats (lipids). The ACSF3 enzyme performs a chemical reaction that converts malonic acid to malonyl-CoA, which is the first step of fatty acid synthesis in cellular structures called mitochondria. Based on this activity, the enzyme is classified as a malonyl-CoA synthetase. The ACSF3 enzyme also converts methylmalonic acid to methylmalonyl-CoA, making it a methylmalonyl-CoA synthetase as well. The effects of ACSF3 gene mutations are unknown. Researchers suspect that the mutations lead to altered enzymes that have little or no function. Because the enzyme cannot convert malonic and methylmalonic acids, they build up in the body. Damage to organs and tissues caused by accumulation of these acids may be responsible for the signs and symptoms of CMAMMA, although the mechanisms are unclear.
Treatment for Graves disease can sometimes affect pregnancy. After treatment with surgery or radioactive iodine, TSI antibodies can still be present in the blood, even when thyroid levels are normal. If a pregnant woman has received either of these treatments prior to becoming pregnant, the antibodies she produces may travel across the placenta to the babys bloodstream and stimulate the fetal thyroid. A pregnant woman who has been treated with surgery or radioactive iodine should inform her health care provider so her baby can be monitored for thyroid-related problems later in the pregnancy. Pregnant women may safely be treated with anti-thyroid medications. For more information about pregnancy and anti-thyroid medications, see Medications under the section titled How is Graves disease treated?More information about pregnancy and thyroid disease is provided in the NIDDK health topic, Pregnancy and Thyroid Disease.
This condition is inherited in an autosomal recessive pattern, which means both copies of the gene in each cell have mutations. The parents of an individual with an autosomal recessive condition each carry one copy of the mutated gene, but they typically do not show signs and symptoms of the condition.
This condition is inherited in an autosomal dominant pattern, which means one copy of the altered gene in each cell can be sufficient to cause the disorder. Some people who inherit the altered gene never develop the condition, a situation known as reduced penetrance.
How might Filippi syndrome be treated? The treatment of Filippi syndrome is directed toward the specific symptoms that are apparent in each individual. Treatment may require the coordinated efforts of a team of medical professionals who may need to systematically and comprehensively plan an affected child's treatment. These professionals may include pediatricians; physicians who specialize in disorders of the skeleton, joints, muscles, and related tissues (orthopedists); and/or other health care professionals. In some affected individuals, treatment may include surgical repair of certain skeletal or other abnormalities associated with the disorder. The surgical procedures performed will depend upon the severity of the abnormalities, their associated symptoms, and other factors.
These resources address the diagnosis or management of Gorlin syndrome: - Gene Review: Gene Review: Nevoid Basal Cell Carcinoma Syndrome - Genetic Testing Registry: Gorlin syndrome - MedlinePlus Encyclopedia: Basal Cell Nevus Syndrome These resources from MedlinePlus offer information about the diagnosis and management of various health conditions: - Diagnostic Tests - Drug Therapy - Surgery and Rehabilitation - Genetic Counseling - Palliative Care
What are the signs and symptoms of Ichthyosis prematurity syndrome? The Human Phenotype Ontology provides the following list of signs and symptoms for Ichthyosis prematurity syndrome. If the information is available, the table below includes how often the symptom is seen in people with this condition. You can use the MedlinePlus Medical Dictionary to look up the definitions for these medical terms. Signs and Symptoms Approximate number of patients (when available) Ichthyosis 90% Premature birth 90% The Human Phenotype Ontology (HPO) has collected information on how often a sign or symptom occurs in a condition. Much of this information comes from Orphanet, a European rare disease database. The frequency of a sign or symptom is usually listed as a rough estimate of the percentage of patients who have that feature. The frequency may also be listed as a fraction. The first number of the fraction is how many people had the symptom, and the second number is the total number of people who were examined in one study. For example, a frequency of 25/25 means that in a study of 25 people all patients were found to have that symptom. Because these frequencies are based on a specific study, the fractions may be different if another group of patients are examined. Sometimes, no information on frequency is available. In these cases, the sign or symptom may be rare or common.
Best disease is inherited in an autosomal dominant pattern, which means one copy of the altered gene in each cell is sufficient to cause the disorder. In most cases, an affected person has one parent with the condition. The inheritance pattern of adult-onset vitelliform macular dystrophy is uncertain. Some studies have suggested that this disorder may be inherited in an autosomal dominant pattern. It is difficult to be sure, however, because many affected people have no history of the disorder in their family, and only a small number of affected families have been reported.
Hepatic veno-occlusive disease with immunodeficiency (also called VODI) is a hereditary disorder of the liver and immune system. Its signs and symptoms appear after the first few months of life. Hepatic veno-occlusive disease is a condition that blocks (occludes) small veins in the liver, disrupting blood flow in this organ. This condition can lead to enlargement of the liver (hepatomegaly), a buildup of scar tissue (hepatic fibrosis), and liver failure. Children with VODI are prone to recurrent infections caused by certain bacteria, viruses, and fungi. The organisms that cause infection in people with this disorder are described as opportunistic because they ordinarily do not cause illness in healthy people. These infections are usually serious and may be life-threatening. In most people with VODI, infections occur before hepatic veno-occlusive disease becomes evident. Many people with VODI live only into childhood, although some affected individuals have lived to early adulthood.
How is osteogenesis imperfecta type 6 inherited? Osteogenesis imperfecta type 6 has an autosomal recessive pattern of inheritance. Autosomal recessive inheritance means that two copies of the gene in each cell are altered. The parents of a child with an autosomal recessive disorder typically are not affected, but each carry one copy of the altered gene (they are referred to as carriers). When two carriers for an autosomal recessive condition have children, each child has a 25% (1 in 4) risk to have the condition, a 50% (1 in 2) risk to be a carrier, and a 25% chance to not have the condition and not be a carrier. The children of an individual with an autosomal recessive type of OI are always carriers for a disease-causing mutation.
Rabson-Mendenhall syndrome results from mutations in the INSR gene. This gene provides instructions for making a protein called an insulin receptor, which is found in many types of cells. Insulin receptors are embedded in the outer membrane surrounding the cell, where they attach (bind) to insulin circulating in the bloodstream. This binding triggers signaling pathways that influence many cell functions. The INSR gene mutations that cause Rabson-Mendenhall syndrome reduce the number of insulin receptors that reach the cell membrane or diminish the function of these receptors. Although insulin is present in the bloodstream, without enough functional receptors it is less able to exert its effects on cells and tissues. This severe resistance to the effects of insulin impairs blood sugar regulation and affects many aspects of development in people with Rabson-Mendenhall syndrome.
The National Institute of Neurological Disorders and Stroke (NINDS), and other institutes of the National Institutes of Health (NIH), conduct research related to FTD in laboratories at the NIH, and also support additional research through grants to major medical institutions across the country.
What are the signs and symptoms of Accessory deep peroneal nerve? The Human Phenotype Ontology provides the following list of signs and symptoms for Accessory deep peroneal nerve. If the information is available, the table below includes how often the symptom is seen in people with this condition. You can use the MedlinePlus Medical Dictionary to look up the definitions for these medical terms. Signs and Symptoms Approximate number of patients (when available) Abnormality of the nervous system - Autosomal dominant inheritance - The Human Phenotype Ontology (HPO) has collected information on how often a sign or symptom occurs in a condition. Much of this information comes from Orphanet, a European rare disease database. The frequency of a sign or symptom is usually listed as a rough estimate of the percentage of patients who have that feature. The frequency may also be listed as a fraction. The first number of the fraction is how many people had the symptom, and the second number is the total number of people who were examined in one study. For example, a frequency of 25/25 means that in a study of 25 people all patients were found to have that symptom. Because these frequencies are based on a specific study, the fractions may be different if another group of patients are examined. Sometimes, no information on frequency is available. In these cases, the sign or symptom may be rare or common.
How might abetalipoproteinemia be treated? A nutritionist or other qualified medical professional should be consulted for specific dietary instruction in people with abetalipoproteinemia. Treatment involves very large doses of vitamin E, as well as large doses of vitamin supplements containing other fat-soluble vitamins (vitamin A, vitamin D, and vitamin K). Linoleic acid supplements are also recommended. Several diet changes and/or restrictions are also needed to prevent stomach problems. A low-fat diet may help with digestive symptoms; medium chain triglycerides may be used (under supervision of a specialist) as a source of fat in the diet. Management in adults typically focuses on specific complications associated with the disorder, and depends on the signs and symptoms present. Affected people may need consultations with several other types of specialists, including a lipidologist, gastroenterologist, hepatologist, ophthalmologist, and neurologist.
Often, no symptoms appear during the early stages of diabetes retina problems. As retina problems worsen, your symptoms might include - blurry or double vision - rings, flashing lights, or blank spots in your vision - dark or floating spots in your vision - pain or pressure in one or both of your eyes - trouble seeing things out of the corners of your eyes
How might hydranencephaly be treated? Unfortunately, there is no definitive treatment for hydranencephaly. Management of the condition typically focuses on the specific signs and symptoms present in the affected individual and is mostly supportive. Hydrocephalus (the buildup of too much cerebral spinal fluid in the brain) may be treated with a shunt (a surgically implanted tube that helps to drain fluid from the brain).
Dentatorubral-pallidoluysian atrophy (DRPLA) is a progressive brain disorder that causes involuntary movements; mental and emotional problems; and a decline in thinking ability. The average age of onset of DRPLA is 30 years, but the condition can appear anytime from infancy to mid-adulthood. Specific signs and symptoms may differ among affected individuals and sometimes affects children and adults differently. DRPLA is caused by a mutation in the ATN1 gene and is inherited in an autosomal dominant manner. Treatment is symptomatic and supportive.
Hyperkalemic periodic paralysis is a genetic condition that causes episodes of extreme muscle weakness, usually beginning in infancy or early childhood. Most often, these episodes involve a temporary inability to move muscles in the arms and legs. Episodes tend to increase in frequency until about age 25, after which they may occur less frequently. Factors that can trigger attacks include rest after exercise, potassium-rich foods, stress, fatigue, and long periods without food. Muscle strength improves between attacks, although many affected people continue to experience mild stiffness, particularly in muscles of the face and hands. This condition is caused by mutations in the SCN4A gene and is inherited in an autosomal dominant fashion.
How might wandering spleen be treated? Because wandering spleen can cause life-threatening complications (such as splenic infarction, portal hypertension, and hemorrhage), surgery to remove the spleen is the preferred treatment method for patients. Laparoscopic splenectomy is the typical method used for spleen removal. Splenopexy (surgically fixing the floating spleen) is associated with a high risk of recurrence and complications and is not the preferred treatment choice.
These resources address the diagnosis or management of NARP: - Gene Review: Gene Review: Mitochondrial DNA-Associated Leigh Syndrome and NARP - Gene Review: Gene Review: Mitochondrial Disorders Overview - Genetic Testing Registry: Neuropathy ataxia retinitis pigmentosa syndrome - MedlinePlus Encyclopedia: Retinitis pigmentosa These resources from MedlinePlus offer information about the diagnosis and management of various health conditions: - Diagnostic Tests - Drug Therapy - Surgery and Rehabilitation - Genetic Counseling - Palliative Care
Mutations in the CTSD gene cause congenital NCL. The CTSD gene provides instructions for making an enzyme called cathepsin D. Cathepsin D is one of a family of cathepsin proteins that act as proteases, which modify proteins by cutting them apart. Cathepsin D is found in many types of cells and is active in lysosomes, which are compartments within cells that digest and recycle different types of molecules. By cutting proteins apart, cathepsin D can break proteins down, turn on (activate) proteins, and regulate self-destruction of the cell (apoptosis). CTSD gene mutations that cause congenital NCL lead to a complete lack of cathepsin D enzyme activity. As a result, proteins and other materials are not broken down properly. In the lysosomes, these materials accumulate into fatty substances called lipopigments. These accumulations occur in cells throughout the body, but neurons are likely particularly vulnerable to damage caused by the abnormal cell materials and the loss of cathepsin D function. Early and widespread cell death in congenital NCL leads to severe signs and symptoms and death in infancy.