Pancreatic endocrine tumor, also known as pancreatic neuroendocrine tumor (PNET), describes a group of endocrine tumors originating in the pancreas that are usually indolent and benign, but may have the potential to be malignant. They can be functional, exhibiting a hormonal hypersecretion syndrome, but can be non-functional presenting with non-specific symptoms and include insulinoma, glucagonoma, VIPoma, somatostatinoma (SSoma), PPoma and Zollinger-Ellison syndrome (ZES, or gastrinoma) and other ectopic hormone producing tumors (such as GRFoma) (see these terms). Epidemiology Prevalence in the U.S. is estimated at 1/4,000-1/3,300 and 1/37,000 in Japan, but this is likely an underestimate due to a low detection rate. Clinical description PNETs, when functional, usually present in the 5th decade of life as various hypersecretion syndromes. These include insulinoma presenting with hyperinsulinemic hypoglycemia; glucagonoma with necrolytic migratory erythema, diabetes mellitus, and thomboembolisms; VIPoma with watery diarrhea, hypokalemia and or hypo/achlorhydia; SSoma with diabetes mellitus, cholelithiasis, steatorrhea and hypochlorhydria; and ZES with severe peptic ulcer disease.

Endocrine gland neoplasm Specialty Oncology , endocrinology An endocrine gland neoplasm is a neoplasm affecting one or more glands of the endocrine system . Examples include: Adrenal tumor Pituitary adenoma The most common form is thyroid cancer . [1] Condition such as pancreatic cancer or ovarian cancer can be considered endocrine tumors, or classified under other systems. Pinealoma is often grouped with brain tumors because of its location. [ citation needed ] See also [ edit ] Multiple endocrine neoplasia References [ edit ] ^ "Thyroid cancer" . Archived from the original on 2007-12-20 . Retrieved 2007-12-22 . External links [ edit ] Classification D ICD - 10 : C73 - C75 D34 - D35 MeSH : D00470 v t e Overview of tumors , cancer and oncology Conditions Benign tumors Hyperplasia Cyst Pseudocyst Hamartoma Malignant progression Dysplasia Carcinoma in situ Cancer Metastasis Primary tumor Sentinel lymph node Topography Head and neck ( oral , nasopharyngeal ) Digestive system Respiratory system Bone Skin Blood Urogenital Nervous system Endocrine system Histology Carcinoma Sarcoma Blastoma Papilloma Adenoma Other Precancerous condition Paraneoplastic syndrome Staging / grading TNM Ann Arbor Prostate cancer staging Gleason grading system Dukes classification Carcinogenesis Cancer cell Carcinogen Tumor suppressor genes / oncogenes Clonally transmissible cancer Oncovirus Carcinogenic bacteria Misc. Research Index of oncology articles History Cancer pain Cancer and nausea v t e Tumours of endocrine glands Pancreas Pancreatic cancer Pancreatic neuroendocrine tumor α : Glucagonoma β : Insulinoma δ : Somatostatinoma G : Gastrinoma VIPoma Pituitary Pituitary adenoma : Prolactinoma ACTH-secreting pituitary adenoma GH-secreting pituitary adenoma Craniopharyngioma Pituicytoma Thyroid Thyroid cancer (malignant): epithelial-cell carcinoma Papillary Follicular / Hurthle cell Parafollicular cell Medullary Anaplastic Lymphoma Squamous-cell carcinoma Benign Thyroid adenoma Struma ovarii Adrenal tumor Cortex Adrenocortical adenoma Adrenocortical carcinoma Medulla Pheochromocytoma Neuroblastoma Paraganglioma Parathyroid Parathyroid neoplasm Adenoma Carcinoma Pineal gland Pinealoma Pinealoblastoma Pineocytoma MEN 1 2A 2B This article about a neoplasm is a stub .

This subtype is due to a mutation in the APP gene (21q21.2), encoding the beta-amyloid precursor protein.

Etiology HCHWA-D is due to a mutation in the APP gene on chromosome 21q21.2, encoding the beta-amyloid precursor protein. ... Genetic testing reveals a mutation in the APP gene. Differential diagnosis Differential diagnoses include other conditions that could cause intracerebral hemorrhage such as coagulopathies, vasculitis (see these terms), CNS neoplasms, cerebral vascular malformations, ischemic stroke and antecedent trauma.

The Dutch type is the most common, with over 200 affected individuals reported in the scientific literature. Causes Mutations in the APP gene are the most common cause of hereditary cerebral amyloid angiopathy. APP gene mutations cause the Dutch, Italian, Arctic, Iowa, Flemish, and Piedmont types of this condition. ... Familial British and Danish dementia are caused by mutations in the ITM2B gene. The APP gene provides instructions for making a protein called amyloid precursor protein. ... Additionally, the ITM2B protein may be involved in processing the amyloid precursor protein. Mutations in the APP , CST3 , or ITM2B gene lead to the production of proteins that are less stable than normal and that tend to cluster together (aggregate). ... Learn more about the genes associated with Hereditary cerebral amyloid angiopathy APP CST3 ITM2B Inheritance Pattern Hereditary cerebral amyloid angiopathy caused by mutations in the APP , CST3 , or ITM2B gene is inherited in an autosomal dominant pattern , which means one copy of the altered gene in each cell is sufficient to cause the disorder.

This subtype is due to a mutation in the APP gene (21q21.2), encoding the beta-amyloid precursor protein.

This subtype is due to a mutation in the APP gene (21q21.2), encoding the beta-amyloid precursor protein.

This subtype is due to a mutation in the APP gene (21q21.2), encoding the beta-amyloid precursor protein.

This subtype is due to a mutation in the APP gene (21q21.2), encoding the beta-amyloid precursor protein.

Inclusion body myositis (IBM) is a slowly progressive degenerative inflammatory disorder of skeletal muscles characterized by late onset weakness of specific muscles and distinctive histopathological features. Epidemiology IBM has a highly variable prevalence according to geographic, ethnic and age criteria. Prevalence in the general population ranges from 1:1,000,000 to 1:14,000 but a three-fold increase is observed when considering only a population over 50 years. Underdiagnosis may be an explanation for the high ethno-geographic variation. Male-to-female ratio is 2:1 on average (0.5 to 6.5:1). Clinical description IBM onset is over 50 years but may also occur earlier, in the 5th decade.

Inflammatory muscle disease in older adults This article needs additional citations for verification . Please help improve this article by adding citations to reliable sources . Unsourced material may be challenged and removed. Find sources: "Inclusion body myositis" – news · newspapers · books · scholar · JSTOR ( September 2009 ) ( Learn how and when to remove this template message ) Inclusion body myositis Other names sIBM Specialty Rheumatology Inclusion body myositis ( IBM ) ( / m aɪ oʊ ˈ s aɪ t ɪ s / ) (sometimes called sporadic inclusion body myositis , sIBM ) is the most common inflammatory muscle disease in older adults. [1] The disease is characterized by slowly progressive weakness and wasting of both proximal muscles (closest to the body's midline) and distal muscles (the limbs), most apparent in the finger flexors and knee extensors . [2] IBM is often confused with an entirely different class of diseases, called hereditary inclusion body myopathies (hIBM). [3] [4] The "M" in hIBM is an abbreviation for "myopathy" while the "M" in IBM is an abbreviation for "myositis". These diseases should not be confused with each other. In IBM, two processes appear to occur in the muscles in parallel, one autoimmune and the other degenerative. Inflammation is evident from the invasion of muscle fibers by immune cells .

Idiopathic inflammatory myopathy is a group of disorders characterized by inflammation of the muscles used for movement (skeletal muscles). Idiopathic inflammatory myopathy usually appears in adults between ages 40 and 60 or in children between ages 5 and 15, though it can occur at any age. The primary symptom of idiopathic inflammatory myopathy is muscle weakness, which develops gradually over a period of weeks to months or even years. Other symptoms include joint pain and general tiredness (fatigue). There are several forms of idiopathic inflammatory myopathy, including polymyositis, dermatomyositis, and sporadic inclusion body myositis. Polymyositis and dermatomyositis involve weakness of the muscles closest to the center of the body (proximal muscles), such as the muscles of the hips and thighs, upper arms, and neck.

Inclusion body myositis (IBM) is a progressive muscle disorder characterized by muscle inflammation, weakness, and atrophy (wasting). It is a type of inflammatory myopathy . IBM develops in adulthood, usually after age 50. The symptoms and rate of progression vary from person to person. The most common symptoms include progressive weakness of the legs, arms, fingers, and wrists. Some people also have weakness of the facial muscles (especially muscles controlling eye closure), or difficulty swallowing (dysphagia). Muscle cramping and pain are uncommon, but have been reported in some people.

Acquired angioedema (AAE) is a rare disorder that causes recurrent episodes of swelling (edema) of the face or body, lasting several days. People with AAE may have swelling of the face, lips, tongue, limbs, or genitals. People with AAE can have edema of the lining of the digestive tract, which can cause abdominal pain and nausea, as well as edema of the upper airway, which can be life-threatening. Swelling episodes may have various triggers, such as mild trauma (such as dental work), viral illness, cold exposure, pregnancy, certain foods, or emotional stress. The frequency of episodes is unpredictable and can vary widely. There are two forms of AAE.

A rare disease characterized by the occurrence of transitory and recurrent subcutaneous and/or submucosal edemas resulting in swelling and/or abdominal pain due to an acquired C1 inhibitor (C1-INH) deficiency. Epidemiology Prevalence is unknown. Clinical description Onset most commonly occurs after 50 years of age. Patients present with white, circumscribed nonpruritic edemas that remain for a period of 48 to 72 hours and recur with variable frequency. The edemas may involve the digestive tract resulting in a clinical picture similar to that seen in intestinal occlusion syndrome, sometimes associated with ascites and hypovolemic shock. Laryngeal edema can be life-threatening with a risk of death of 25% in the absence of appropriate treatment.

Acquired C1 esterase inhibitor deficiency Other names Acquired angioedema Specialty Hematology Acquired C1 esterase inhibitor deficiency presents with symptoms indistinguishable from hereditary angioedema , but generally with onset after the fourth decade of life. [1] : 153 C4 levels are low and C3 levels are normal. [2] See also [ edit ] Hereditary Angioedema Wheal response Urticaria Skin lesion List of cutaneous conditions References [ edit ] ^ James, William; Berger, Timothy; Elston, Dirk (2005). Andrews' Diseases of the Skin: Clinical Dermatology . (10th ed.). Saunders. ISBN 0-7216-2921-0 . ^ Markovic SN, Inwards DJ, Frigas EA, Phyliky RP (January 2000). "Acquired C1 esterase inhibitor deficiency". Ann. Intern. Med . 132 (2): 144–50. doi : 10.7326/0003-4819-132-2-200001180-00009 . PMID 10644276 . External links [ edit ] Classification D ICD - 10 : D84.1 ( ILDS D84.112) MeSH : C538173 External resources eMedicine : article/104888 v t e Lymphoid and complement disorders causing immunodeficiency Primary Antibody / humoral ( B ) Hypogammaglobulinemia X-linked agammaglobulinemia Transient hypogammaglobulinemia of infancy Dysgammaglobulinemia IgA deficiency IgG deficiency IgM deficiency Hyper IgM syndrome ( 1 2 3 4 5 ) Wiskott–Aldrich syndrome Hyper-IgE syndrome Other Common variable immunodeficiency ICF syndrome T cell deficiency ( T ) thymic hypoplasia : hypoparathyroid ( Di George's syndrome ) euparathyroid ( Nezelof syndrome Ataxia–telangiectasia ) peripheral: Purine nucleoside phosphorylase deficiency Hyper IgM syndrome ( 1 ) Severe combined (B+T) x-linked: X-SCID autosomal: Adenosine deaminase deficiency Omenn syndrome ZAP70 deficiency Bare lymphocyte syndrome Acquired HIV/AIDS Leukopenia : Lymphocytopenia Idiopathic CD4+ lymphocytopenia Complement deficiency C1-inhibitor ( Angioedema / Hereditary angioedema ) Complement 2 deficiency / Complement 4 deficiency MBL deficiency Properdin deficiency Complement 3 deficiency Terminal complement pathway deficiency Paroxysmal nocturnal hemoglobinuria Complement receptor deficiency This cutaneous condition article is a stub .

Overview Neuroendocrine tumors are cancers that begin in specialized cells called neuroendocrine cells. Neuroendocrine cells have traits similar to those of nerve cells and hormone-producing cells. Neuroendocrine tumors are rare and can occur anywhere in the body. Most neuroendocrine tumors occur in the lungs, appendix, small intestine, rectum and pancreas. There are many types of neuroendocrine tumors. Some grow slowly and some grow very quickly. Some neuroendocrine tumors produce excess hormones (functional neuroendocrine tumors).

Human disease Orthostatic intolerance ( OI ) is the development of symptoms when standing upright which are relieved when reclining . [1] There are many types of orthostatic intolerance. OI can be a subcategory of dysautonomia , a disorder of the autonomic nervous system [2] occurring when an individual stands up. [3] There is a substantial overlap between syndromes of orthostatic intolerance on the one hand, and either chronic fatigue syndrome (CFS) or fibromyalgia (FM) on the other. [4] It affects more women than men (female-to-male ratio is at least 4:1), usually under the age of 35. [5] Orthostatic intolerance occurs in humans because standing upright is a fundamental stressor and requires rapid and effective circulatory and neurologic compensations to maintain blood pressure , cerebral blood flow , and consciousness . When a human stands, approximately 750 mL of thoracic blood is abruptly translocated downward. People who suffer from OI lack the basic mechanisms to compensate for this deficit. [1] Changes in heart rate , blood pressure, and cerebral blood flow that produce OI may be caused by abnormalities in the interactions between blood volume control, the cardiovascular system , the nervous system and circulation control system . [6] Contents 1 Signs and symptoms 1.1 Acute OI 1.2 Chronic OI 2 Causes 3 Diagnosis 4 Management 5 Notable case 6 See also 7 References 8 External links Signs and symptoms [ edit ] Orthostatic intolerance is divided, roughly based on patient history, in two variants: acute and chronic . Acute OI [ edit ] Patients who suffer from acute OI usually manifest the disorder by a temporary loss of consciousness and posture , with rapid recovery (simple faints , or syncope ), as well as remaining conscious during their loss of posture.

Not to be confused with Pott disease . Condition in which a change from lying to standing causes an abnormally large increase in heart rate Postural orthostatic tachycardia syndrome Other names Postural tachycardia syndrome (POTS) Specialty Cardiology , Neurology Symptoms More often with standing: lightheadedness , trouble thinking , tachycardia , weakness, [1] palpitations , heat intolerance , acrocyanosis Usual onset Most common (modal) age of onset is 14 years [2] Duration > 6 months [3] Causes Antibodies against the Alpha 1 adrenergic receptor [4] [5] [6] Risk factors Family history [1] Diagnostic method An increase in heart rate by 30 beats/min with standing [1] Differential diagnosis Dehydration , heart problems, adrenal insufficiency , epilepsy , parkinson disease [7] Treatment Avoiding factors that bring on symptoms, increasing dietary salt and water, compression stockings , exercise, medications [1] Medication Beta blockers , Ivabradine , midodrine , and fludrocortisone . [1] Prognosis ~90% improve with treatment, [8] 25% of patients unable to work [9] Frequency ~ 500,000 (US) [7] Postural orthostatic tachycardia syndrome ( POTS ) is a condition in which a change from lying to standing causes an abnormally large (or higher than normal) increase in heart beat rate . [1] This occurs with symptoms that may include lightheadedness , trouble thinking, blurred vision , or weakness. [1] Other commonly associated conditions include Ehlers–Danlos syndrome , mast cell activation syndrome , irritable bowel syndrome , insomnia , chronic headaches , chronic fatigue syndrome , and fibromyalgia . [1] Contents 1 Causation 2 Signs and symptoms 2.1 Brain fog 3 Causes 3.1 Autoimmunity 3.2 Secondary 4 COVID-19 5 Diagnosis 5.1 Diagnostic criteria 5.2 Autoantibodies against G-protein coupled receptor 5.3 Orthostatic intolerance 5.4 Differential diagnoses 6 Treatment 6.1 Medication 7 Prognosis 8 Epidemiology 9 History 10 Notable cases 11 References 12 Further reading 13 External links Causation [ edit ] The causes of POTS are varied. [10] Often, it begins after a viral infection, surgery, or pregnancy. [8] Risk factors include a family history of the condition. [1] Diagnosis in adults is based on an increase in heart rate of more than 30 beats per minute within ten minutes of standing up that is accompanied by symptoms. [1] Low blood pressure with standing , however, does not occur. [1] Other conditions which can cause similar symptoms, such as dehydration , heart problems, adrenal insufficiency , epilepsy , and parkinson disease , must not be present. [7] Treatment may include avoiding factors that bring on symptoms, increasing dietary salt and water, small and frequent meals, [11] avoidance of immobilization, [11] compression stockings , exercise program, and medications. [12] [13] [1] [14] Medications used may include beta blockers , [15] pyridostigmine , [16] midodrine [17] or fludrocortisone . [1] More than 50% of people whose condition was triggered by a viral infection get better within five years. [8] About 80% have symptomatic improvement with treatment, but 25 percent of patients are still unable to work. [9] [8] Retrospective studies has shown that five years after diagnosis 19% had a full resolution of symptom. [18] It is estimated that 500,000 people are affected in the United States. [19] The average age of onset is 20 years old, and it occurs about five times more frequently in females. [1] Signs and symptoms [ edit ] In adults the primary symptom is an increase in heart rate of more than 30 beats per minute within ten minutes of standing up. [1] [20] The resulting heart rate is typically more than 120 beats per minute. [1] For people aged between 12 and 19, the minimum increase for diagnosis is 40 beats per minute. [21] This symptom is known as orthostatic (upright) tachycardia (fast heart rate). It occurs without any coinciding drop in blood pressure, as that would indicate orthostatic hypotension . [20] Certain medications to treat POTS may cause orthostatic hypotension. It is accompanied by other features of orthostatic intolerance —symptoms that develop in an upright position and are relieved by reclining. [20] These orthostatic symptoms include palpitations , light-headedness , chest discomfort, shortness of breath , [20] nausea, weakness or "heaviness" in the lower legs, blurred vision , and cognitive difficulties. [1] Symptoms may be exacerbated with prolonged sitting, prolonged standing, alcohol, heat, exercise, or eating a large meal. [ citation needed ] In up to one third of people with POTS, [1] fainting occurs in response to postural changes or exercise. [22] Migraine -like headaches are common, sometimes with symptoms worsening in an upright position ( orthostatic headache ). [22] 40-50% of patients with POTS develop acrocyanosis of extremities, a reddish-purple color in the legs and/or hands when they stand (indicative of blood pooling). [23] [22] [24] 48% of people with POTS report chronic fatigue and 32% report sleep disturbances . [25] [26] [27] [28] Others exhibit only the cardinal symptom of orthostatic tachycardia. [22] Additional symptoms are varied, and may include excessive sweating, a lack of sweating, heat intolerance, digestive issues such as bloating, nausea, indigestion, constipation, and diarrhea, a flu-like feeling, coat-hanger pain, forgetfulness, brain fog, and presyncope . [29] Brain fog [ edit ] One of the most disabling and prevalent symptoms in POTS is " brain fog ", [30] a term used by patient to describe the cognitive difficulties they experience. In one survey of 138 POTS patients, brain fog was defined as “forgetful” (91%), “difficulty thinking” (89%), and “difficulty focusing” (88%). Other common description was "Difficulty processing what others say" (80%), Confusion (71%), Lost (64 %), and "Thoughts moving too quickly" (40%) [31] The same survey described the most common triggers of brain fog to be fatigue (91%), lack of sleep (90%), prolonged standing (87%) and dehydration (86%). [ citation needed ] Neuropsychological testing has shown that a POTS-patient has reduced attention (Ruff 2&7 speed and WAIS-III digits forward), short-term memory ( WAIS-III digits back), cognitive processing speed ( Symbol digits modalities test ) and executive function ( Stroop word color and trails B ). [32] [33] [34] A potential cause for brain fog is a decrease in cerebral blood flow (CBF), especially in upright position. [35] [36] [37] Another theory is that interoception of excessive autonomic activity causes interoceptive prediction errors (PE) to occur. [38] A prediction error is the mismatch between a prior expectation and reality. [39] This would cause anxiety which then overwhelms the consciousness of pots-patient causing cognitive-affective symptoms.

A number sign (#) is used with this entry because of evidence that orthostatic intolerance is caused by heterozygous mutation in the gene encoding the norepinephrine transporter (SLC6A2; 163970) on chromosome 16q12. One such family has been reported. Clinical Features Orthostatic intolerance is a syndrome characterized by adrenergic symptoms that occur when an upright posture is assumed: the heart rate increases by at least 30 beats per minute, without orthostatic hypotension (Jacob et al., 1997). Most patients with orthostatic intolerance are women between the ages of 20 and 50 years (Low et al., 1995). This syndrome, first described by Da Costa (1871), has been called soldiers heart (Fraser and Wilson, 1918), neurocirculatory asthenia (Wooley, 1976), and mitral valve prolapse syndrome (Boudoulas et al., 1980). It is similar in many respects to chronic fatigue syndrome (Schondorf and Freeman, 1999).

For a general phenotypic description and a discussion of genetic heterogeneity of Alzheimer disease, see 104300. Mapping Liu et al. (2007) conducted a genome screen of 103 patients with late-onset AD who were ascertained as part of the Genetic Research in Isolated Populations (GRIP) program that was conducted in an isolated population from the southwestern area of the Netherlands. Genealogic information resulted in an extremely large and complex pedigree of 4,645 members. The pedigree was split into 35 subpedigrees to reduce the computational burden of linkage analysis. The strongest evidence for linkage, hlod = 5.20 at marker D1S498, was obtained at chromosome 1q21 (AD13).

There are three subtypes of early-onset familial AD which are each associated with changes (mutations) in unique genes: (1) Alzheimer disease, type 1 is caused by mutations in the APP gene (2) Alzheimer disease, type 3 is caused by mutations in the PSEN1 gene (3) Alzheimer disease, type 4 is caused by mutations in the PSEN2 gene.

For a general phenotypic description and a discussion of genetic heterogeneity of Alzheimer disease (AD), see 104300. Mapping By genomewide linkage analysis of 466 families with late-onset AD, including 730 affected sib pairs, Pericak-Vance et al. (2000) identified a candidate disease locus on chromosome 9p22.1 (nonparametric maximum lod score of 2.97 at marker D9S741). Analysis of a subset of 199 families in which there was at least 1 autopsy-confirmed AD case yielded a higher lod score of 4.31 at the same marker. Scott et al. (2003) reexamined 437 white AD families included in the original report by Pericak-Vance et al. (2000) by considering age of onset as a covariate. Ordered-subsets analysis included continuous covariates in linkage analysis by rank ordering families by a covariate and summing lod scores.

In HEK293 cells with an AD-associated APP mutation (104760.0008), overexpression of SORCS1 resulted in a significant decrease in amyloid-beta-40 and -beta-42 secretion, whereas suppression of SORCS1 in HEK293 cells increased beta-amyloid-40 levels. The findings indicated that SORCS1 can influence APP processing, and Reitz et al. (2011) suggested that variation in the SORCS1 gene may be associated with risk of LOAD. ... The findings indicated a role for calcium signaling in APP (104760) processing and suggested that variations in the CALHM1 gene may influence susceptibility to late-onset AD.

For a phenotypic description and a discussion of genetic heterogeneity of Alzheimer disease (AD), see 104300. Mapping In a late-onset form of familial Alzheimer disease (AD), Pericak-Vance et al. (1997) identified linkage to a locus on chromosome 12. From a series of multiplex families affected with late-onset AD (at least 60 years) ascertained during the previous 14 years and for which DNA had been obtained, Pericak-Vance et al. (1997) selected a subset of 16 families (with 52 AD patients) to use for a genomewide screen. A second subset of 38 families (with 89 AD patients) was used for a follow-up analysis. Linkage analysis was performed using both genetic model-dependent (lod score) and model-independent methods.

Clinical Features Leuba et al. (2000) described a Swiss family whose members presented with standard clinical and neuropathologic features of Alzheimer disease (104300) and, in particular, severe neurofibrillary tangle degeneration present in the hippocampus and in several cortical areas, together with a large number of beta-amyloid deposits and senile plaques. The brain pathology of 5 deceased members of this family, from 2 generations, represented a coexisting beta-amyloid and prion protein (PrP; 176640) pathology. Frequent beta-amyloid-positive senile plaques were observed, together with senile plaques stained by the monoclonal antibody against PrP(106-126). In all 5 cases, the cerebral cortex showed spongiform changes, mainly in the superficial layers, with some degree of gliosis. Successive sections showed that both beta-amyloid- and PrP-positive senile plaques were deposited in all layers of the frontal and temporal cortex.

Within this candidate region, 1 gene of particular interest was that encoding cystatin-3 (CST3; 604312), because it is known to be an amyloidogenic protein and is codeposited with the amyloid-beta precursor protein (APP; 104760) in amyloid plaques in the brain of AD patients. Using a covariate-based linkage method, Olson et al. (2001) showed that the APP region on chromosome 21q21 is strongly linked to AD-affected sib pairs of the oldest current age (i.e., age either at last exam or at death) who lacked E4 alleles at the apolipoprotein E (APOE; 107741) locus. ... Two-locus analysis provided evidence of strong epistasis between 20p and the APP region, limited to the oldest age group and to those lacking E4 alleles at the APOE locus.

Onset was early in 4 other families tested; 2 had chromosome 21 APP (104760) mutations and 2 showed linkage to chromosome 14, thus representing AD1 (104300) and AD3 (607822), respectively.

Etiology EOAD is the consequence of either PSEN1 mutations (69%), APP mutations (13%), or APP duplication (7,5%), and exceptionally of PSEN2 mutations (2%).

A number sign (#) is used with this entry because Alzheimer disease-4 (AD4) is caused by heterozygous mutation in the presenilin-2 gene (PSEN2; 600759) on chromosome 1q42. For a phenotypic description and a discussion of genetic heterogeneity of Alzheimer disease, see 104300. Clinical Features Bird et al. (1988) described 5 German kindreds with an autosomal dominant early-onset form of Alzheimer disease. All families were descendants of a group of immigrants, known as the Volga Germans, who came to the United States between 1870 and 1920. Their ancestors had moved from Germany to the southern Volga region of Russia in the 1760s.

There are three subtypes of early-onset familial AD which are each associated with changes (mutations) in unique genes: (1) Alzheimer disease, type 1 is caused by mutations in the APP gene (2) Alzheimer disease, type 3 is caused by mutations in the PSEN1 gene (3) Alzheimer disease, type 4 is caused by mutations in the PSEN2 gene.

For a general phenotypic description and a discussion of genetic heterogeneity of Alzheimer disease, see 104300. Mapping Liu et al. (2007) conducted a genome screen of 103 patients with late-onset AD who were ascertained as part of the Genetic Research in Isolated Populations (GRIP) program that was conducted in an isolated population from the southwestern area of the Netherlands. Genealogic information resulted in an extremely large and complex pedigree of 4,645 members. The pedigree was split into 35 subpedigrees to reduce the computational burden of linkage analysis. They found significant evidence of linkage of AD to 3q22-q24 (AD15), in a region of 18 cM from D3S3514 to D3S3626 that reached a maximum hlod of 4.44 at marker D3S1579.

For a general phenotypic description and a discussion of genetic heterogeneity of Alzheimer disease, see 104300. Mapping In a genome screen of individuals from an isolated population from the southwestern area of the Netherlands, ascertained as part of the Genetic Research in Isolated Populations (GRIP) program, Liu et al. (2007) found the strongest evidence of linkage for chromosome 1q21 (AD13; 611152). Approximately 30 cM upstream of this locus, at 1q25, another peak (AD14) was found (hlod = 4.0 at marker D1S218). Liu et al. (2007) noted that these 2 loci were in a linkage region spanning 1q21-q31 identified by Zubenko et al. (1998), Hiltunen et al. (2001), Myers et al. (2002), and Blacker et al. (2003). Haplotype analysis showed that the 2 linkage peaks on chromosome 1q21 and 1q25 are explained by different haplotypes, of 15 cM and 21 cM, respectively, segregating in different families.

For a phenotypic description and a discussion of genetic heterogeneity of Alzheimer disease (AD), see 104300. Mapping Giedraitis et al. (2006) conducted a genome scan with 369 microsatellite markers in 12 extended families collected in Sweden. Age at disease onset ranged from 53 to 78 years, but in 10 of the families there was at least 1 member with age at onset of less than 65 years. Mutations in known early-onset Alzheimer disease susceptibility genes were excluded. All persons were genotyped for APOE (107741), but no clear linkage with the E4 allele was observed.

In 2 Belgian families with early-onset autosomal dominant AD, Van Broeckhoven et al. (1987) excluded linkage to the APP locus on chromosome 21q. One pedigree contained 36 patients in 6 generations, and the second had 22 patients spanning 5 generations.

For a phenotypic description and a discussion of genetic heterogeneity of Alzheimer disease (AD), see 104300. Mapping In an extended multiplex family, ascertained in a population-based study of early-onset AD in the northern Netherlands, Rademakers et al. (2005) obtained conclusive evidence of linkage of AD with a candidate region of 19.7 cM at 7q36. They identified a shared haplotype at 7q36 between the index family and 3 of 6 multiplex AD-affected families from the same geographic region, which was indicative of a founder effect and defined a priority region of 9.3 cM. Mutation analysis of coding exons of 29 candidate genes identified only an exonic silent mutation in the PAXIP1 gene (608254), 38030G-C in the exon 10 genomic sequence, which affected codon 626. It remained to be determined whether PAXIP1 has a functional role in the expression of AD in the index family or whether another mutation at this locus explained the observed linkage and sharing.

For a phenotypic description and a discussion of genetic heterogeneity of Alzheimer disease (AD), see 104300. Mapping In a systematic survey of the human genome in patients with AD, Zubenko et al. (1998) identified D10S1423, located at 10p13, as a candidate susceptibility locus. The allelic associations in this survey were observed in independent samples of autopsied AD cases and controls from geographically disparate sites (Boston and Pittsburgh). Majores et al. (2000) replicated these findings by identifying an association of the D10S1423 234-bp allele with AD in an ethnically homogeneous group of 397 German AD cases and controls. Zubenko et al. (2001) described a prospective, longitudinal, double-blind assessment of the age-specific risk of AD encountered by 325 asymptomatic first-degree relatives of AD probands who carried the D10S1423 234-bp allele, the APOE E4 allele (107741), or both, after 11.5 years of systematic follow-up.

Hepatic lipase deficiency is a rare condition that is characterized by increased levels of certain fats (known as triglycerides and cholesterol ) in the blood. Affected people may also have increased levels of high-density lipoproteins (HDLs) and decreased levels of low-density lipoproteins (LDLs), which are two molecules that help transport fats throughout the body. Hepatic lipase deficiency may be associated with an increased risk of developing atherosclerosis and/or heart disease ; however, additional research is needed on the long-term outlook of people with this condition. Hepatic lipase deficiency is caused by changes (mutations) in the LIPC gene and is inherited in an autosomal recessive manner. Treatment is based on the signs and symptoms present in each person.

Hepatic lipase deficiency is a disorder that affects the body's ability to break down fats (lipids). People with this disorder have increased amounts of certain fats, known as triglycerides and cholesterol, in the blood. These individuals also have increased amounts of molecules known as high-density lipoproteins (HDLs) and decreased amounts of molecules called low-density lipoproteins (LDL). These molecules transport triglycerides and cholesterol throughout the body. In people with hepatic lipase deficiency, the LDL molecules are often abnormally large.

Description Hepatic lipase deficiency is characterized by premature atherosclerosis, elevated total cholesterol, triglycerides (TG), and very low density lipoprotein (VLDL), as well as TG-rich low density lipoprotein (LDL) and HDL subfractions (summary by Hegele et al., 1991).

. ^ Rigby HB, Dugger BN, Hentz JG, Adler CH, Beach TG, Shill HA, et al. (March 2015). "Clinical Features of Patients with Concomitant Parkinson's Disease and Progressive Supranuclear Palsy Pathology" . ... S2CID 20622672 . ^ Dugger BN, Adler CH, Shill HA, Caviness J, Jacobson S, Driver-Dunckley E, Beach TG, et al. (Arizona Parkinson's Disease Consortium) (May 2014).

A number sign (#) is used with this entry because of evidence that a form of atypical supranuclear palsy is caused by mutation in the microtubule-associated protein tau gene (MAPT; 157140). Clinical Features Mata et al. (1983) described 2 brothers and a sister with a 'new' Parkinson-dementia syndrome. The disorder, characterized also by ophthalmoparesis and pyramidal signs, came on in the third decade and progressed for several years. Kyphoscoliosis was present in all 3 sibs. Examination of the brain in the sister, who died at age 31 years, showed neurofibrillary degeneration of the hippocampus, basal ganglia and brainstem nuclei. The parents were not related. The authors suggested that the disorder most closely resembled the Parkinson-dementia complex of Guam (105500) but could be distinguished by the lack of Chamorro descent (a dubious argument) and the earlier age of onset.

Overview Progressive supranuclear palsy is an uncommon brain disorder that causes serious problems with walking, balance and eye movements, and later with swallowing. The disorder results from deterioration of cells in areas of your brain that control body movement, coordination, thinking and other important functions. Progressive supranuclear palsy is also called Steele-Richardson-Olszewski syndrome. Progressive supranuclear palsy worsens over time and can lead to life-threatening complications, such as pneumonia and swallowing problems. There's no cure for progressive supranuclear palsy, so treatment focuses on managing the signs and symptoms.

A rare late-onset neurodegenerative disease characterized by supranuclear gaze palsy, postural instability, progressive rigidity, and mild dementia. Epidemiology Prevalence is conservatively estimated at about 1/16,600. Clinical description PSP usually manifests during the sixth or seventh decade of life. Five clinical variants have been described with clinicopathological correlations: Classical PSP (Richardson's syndrome), and four atypical variants of PSP including PSP-Parkinsonism (PSP-P), PSP-Pure akinesia with gait freezing (PSP-PAGF), PSP-corticobasal syndrome (PSP-CBS), and PSP-progressive non fluent aphasia (PSP-PNFA) (see these terms). Richardson's syndrome is the most common clinical variant and manifests with a lurching gait, falls due to postural instability, cognitive impairment and slowing of vertical saccadic eye movements.

For a phenotypic description and a discussion of genetic heterogeneity of progressive supranuclear palsy (PSP), see PSNP1 (601104). Mapping Using a pooling-based genomewide association study of more than 500,000 SNPs in 288 patients with PSP and 344 age- and sex-matched controls, Melquist et al. (2007) identified candidate SNPs with large differences in allelic frequency by ranking all SNPs by their probe-intensity difference between cohorts. The MAPT H1 haplotype (see 157140) was strongly detected by this approach as was a second major locus (PSNP3) on chromosome 11p12-p11 that showed evidence of association at allelic (p less than 0.001), genotypic (p less than 0.001), and haplotypic (p less than 0.0001) levels and was narrowed to a single haplotype block containing the DNA damage-binding protein-2 (DDB2; 600811) and lysosomal acid phosphatase-2 (ACP2; 171650) genes. Since DNA damage and lysosomal dysfunction have been implicated in aging and neurodegenerative processes, Melquist et al. (2007) considered both genes to be viable candidates for conferring risk of disease.

For a phenotypic description and a discussion of genetic heterogeneity of progressive supranuclear palsy (PSP), see PSNP1 (601104). Clinical Features De Yebenes et al. (1995) studied a 5-generation Spanish family in which progressive supranuclear palsy was transmitted as an autosomal dominant trait. The proband had the classic presentation of this disorder beginning with axial rigidity, slowness of movement, and gait difficulty. Over the course of 2 years he progressed to complete vertical gaze palsy, axial dystonia, and retrocollis, as well as generalized severe akinesia. Postmortem examination demonstrated neuronal loss and atrophy of the brainstem, cerebellum, and diencephalon.

Progressive supranuclear palsy (PSP) is a degenerative neurologic disease due to damage to nerve cells in the brain. Signs and symptoms vary but may include loss of balance; blurring of vision; problems controlling eye movement; changes in mood, behavior and judgment; cognitive decline; and slowing and slurred speech. PSP is often misdiagnosed as Parkinson disease due to similar symptoms. Onset is usually after age 60 but may occur earlier. Most cases of PSP appear to be sporadic , but familial cases have been reported. Some cases have been found to be caused by a mutation in the MAPT gene, and other genetic factors are being studied.

Classical progressive supranuclear palsy, also known as Richardson's syndrome, is the most common clinical variant of progressive supranuclear palsy (PSP; see this term), a rare late-onset neurodegenerative disease characterized by postural instability, progressive rigidity, supranuclear gaze palsy and mild dementia. Epidemiology The prevalence is conservatively estimated at about 1/16,600. Clinical description PSP usually manifests during the sixth or seventh decade of life with postural instability and falls, slowing of vertical saccadic eye movements and cognitive slowing. Progressively patients develop other eye abnormalities (dry and red eyes, blurred vision, spontaneous involuntary eyelid closure, photophobia), a dysexecutive cognitive syndrome with impulsivity, problems in speech (slow speech) and a supranuclear gaze palsy and difficulties in swallowing. The disease is characterized neuropathologically by gliosis with astrocytic plaques, accumulation of tau-immunoreactive neurofibrillary tangles and neuronal loss in specific brain areas, especially in the subthalamic nucleus and the substantia nigra.