Hereditary elliptocytosis

Hereditary elliptocytosis
Hereditary elliptocytosis
Other names	Ovalocytosis, elliptocytes, ovalocytes
	Peripheral blood smear showing an abundant number of elliptocytes
Specialty	Hematology

Last updated March 06, 2024

Hereditary elliptocytosis, also known as ovalocytosis, is an inherited blood disorder in which an abnormally large number of the person's red blood cells are elliptical rather than the typical biconcave disc shape. Such morphologically distinctive erythrocytes are sometimes referred to as elliptocytes or ovalocytes. It is one of many red-cell membrane defects. In its severe forms, this disorder predisposes to haemolytic anaemia. Although pathological in humans, elliptocytosis is normal in camelids.

Presentation

RBCs are elleptical in shape rather than normal biconcave shape. Most cases are asymptomatic with abnormalities in their peripheral blood film.

Pathophysiology

Common hereditary elliptocytosis

A number of genes have been linked to common hereditary elliptocytosis (many involve the same gene as forms of hereditary spherocytosis, or HS):

Type	OMIM	Gene
EL1 or HS5	611804	EPB41
EL2 or HS3	130600	SPTA1
EL3 or HS2	182870	SPTB
EL4 or HS4 or SEO	109270	SLC4A1

These mutations have a common result; they destabilise the cytoskeletal scaffold of cells. This stability is especially important in erythrocytes as they are constantly under the influence of deforming shear forces. As disc-shaped erythrocytes pass through capillaries, which can be 2–3 micrometres wide, they are forced to assume an elliptical shape in order to fit through. Normally, this deformation lasts only as long as a cell is present in a capillary, but in hereditary elliptocytosis the instability of the cytoskeleton means that erythrocytes deformed by passing through a capillary are forever rendered elliptical. These elliptical cells are taken up by the spleen and removed from circulation when they are younger than they would normally be, meaning that the erythrocytes of people with hereditary elliptocytosis have a shorter than average life-span (a normal person's erythrocytes average 120 days or more).

EL2 and EL3: The most common genetic defects (present in two-thirds of all cases of hereditary elliptocytosis) are in genes for the polypeptides α-spectrin or β-spectrin. These two polypeptides combine with one another in vivo to form an αβ heterodimer. These αβ heterodimers then combine to form spectrin tetramers. These spectrin tetramers are among the basic structural subunits of the cytoskeleton of all cells in the body. Although there is much interindividual variability, it is generally true that α-spectrin mutations result in an inability of α-spectrin to interact properly with β-spectrin to form a heterodimer. In contrast, it is generally true that β-spectrin mutations lead to αβ heterodimers being incapable of combining to form spectrin tetramers.^[1] In both cases the end result is a weakness in the cytoskeleton of the cell. Individuals with a single mutation in one of the spectrin genes are usually asymptomatic, but those who are homozygotes or are compound heterozygotes (i.e. they are heterozygous for two different elliptocytosis-causing mutations) have sufficient cell membrane instability to have a clinically significant haemolytic anaemia.^{[ citation needed ]}
EL1: Less common than spectrin mutations are band 4.1 mutations. Spectrin tetramers must bind to actin in order to create a proper cytoskeleton scaffold, and band 4.1 is an important protein involved in the stabilisation of the link between spectrin and actin. Similarly to the spectrin mutations, band 4.1 mutations cause a mild haemolytic anaemia in the heterozygous state, and a severe haemolytic disease in the homozygous state.^{[ citation needed ]}
EL4: Southeast Asian ovalocytosis is associated with the Band 3 protein.^{[ citation needed ]}
Another group of mutations that lead to elliptocytosis are those that cause glycophorin C deficiencies. There are three phenotypes caused by abnormal glycophorin C, these are named Gerbich, Yus and Leach (see glycophorin C for more information). Only the rarest of the three, the Leach phenotype, causes elliptocytosis. Glycophorin C has the function of holding band 4.1 to the cell membrane. It is thought that elliptocytosis in glycophorin C deficiency is actually the consequence of a band 4.1 deficit, as glycophorin C deficient individuals also have reduced intracellular band 4.1 (probably due to the reduced number of binding sites for band 4.1 in the absence of glycoprotein C).^{[ citation needed ]}

Inheritance of multiple mutations tends to infer more serious disease. For instance, the most common genotype responsible for HPP occurs when the affected individual inherits an α-spectrin mutation from one parent (i.e. one parent has hereditary elliptocytosis) and the other parent passes on an as-yet-undefined defect that causes the affected individual's cells to preferentially produce the defective α-spectrin rather than normal α-spectrin.

Diagnosis

The diagnosis of hereditary elliptocytosis is usually made by coupling a family history of the condition with an appropriate clinical presentation and confirmation on a blood smear. In general it requires that at least 25% of erythrocytes in the specimen are abnormally elliptical in shape, though the observed percentage of elliptocytes can be 100%. This is in contrast to the rest of the population, in which it is common for up to 15% of erythrocytes to be elliptical.^[2]

If some doubt remains regarding the diagnosis, definitive diagnosis can involve osmotic fragility testing, an autohaemolysis test, and direct protein assaying by gel electrophoresis.^[3]

Treatment

The vast majority of those with hereditary elliptocytosis require no treatment whatsoever. They have a mildly increased risk of developing gallstones, which is treated surgically with a cholecystectomy if pain becomes problematic. This risk is relative to the severity of the disease.^{[ citation needed ]}

Folate helps to reduce the extent of haemolysis in those with significant haemolysis due to hereditary elliptocytosis.^{[ citation needed ]}

Because the spleen breaks down old and worn-out blood cells, those individuals with more severe forms of hereditary elliptocytosis can have splenomegaly. Symptoms of splenomegaly can include:^{[ citation needed ]}

Vague, poorly localised abdominal pain
Fatigue and dyspnoea
Growth failure
Leg ulcers
Gallstones.

Removal of the spleen (splenectomy) is effective in reducing the severity of these complications, but is associated with an increased risk of overwhelming bacterial septicaemia, and is only performed on those with significant complications. Because many neonates with severe elliptocytosis progress to have only a mild disease, and because this age group is particularly susceptible to pneumococcal infections, a splenectomy is only performed on those under 5 years old when it is absolutely necessary.^{[ citation needed ]}

Prognosis

Those with hereditary elliptocytosis have a good prognosis, only those with very severe disease have a shortened life expectancy.^{[ citation needed ]}

Epidemiology

The incidence of hereditary elliptocytosis is hard to determine, as many sufferers of the milder forms of the disorder are asymptomatic and their condition never comes to medical attention.^[4] Around 90% of those with this disorder are thought to fall into the asymptomatic population. It is estimated that its incidence is between 3 and 5 per 10,000 in the United States,^[5] and that those of African and Mediterranean descent are of higher risk. Because it can confer resistance to malaria, some subtypes of hereditary elliptocytosis are significantly more prevalent in regions where malaria is endemic. For example, in equatorial Africa its incidence is estimated at 60-160 per 10,000,^[6] and in Malayan natives its incidence is 1500-2000 per 10,000.^[7] Almost all forms of hereditary elliptocytosis are autosomal dominant, and both sexes are therefore at equal risk of having the condition. The most important exception to this rule of autosomal dominance is for a subtype of hereditary elliptocytosis called hereditary pyropoikilocytosis (HPP), which is autosomal recessive.^[8]

There are three major forms of hereditary elliptocytosis: common hereditary elliptocytosis, spherocytic elliptocytosis and southeast Asian ovalocytosis.

Common hereditary elliptocytosis is the most common form of elliptocytosis, and the form most extensively researched. Even when looking only at this form of elliptocytosis, there is a high degree of variability in the clinical severity of its subtypes. A clinically significant haemolytic anaemia occurs only in 5-10% of sufferers, with a strong bias towards those with more severe subtypes of the disorder.^{[ citation needed ]}

Southeast Asian ovalocytosis and spherocytic elliptocytosis are less common subtypes predominantly affecting those of south-east Asian and European ethnic groups, respectively.

The following categorisation of the disorder demonstrates its heterogeneity:^[9]

Common hereditary elliptocytosis (in approximate order from least severe to most severe)
- With asymptomatic carrier status - individuals have no symptoms of disease and diagnosis is only able to be made on blood film
- With mild disease - individuals have no symptoms, with a mild and compensated haemolytic anaemia
- With sporadic haemolysis - individuals are at risk of haemolysis in the presence of particular comorbidities, including infections, and vitamin B₁₂ deficiency
- With neonatal poikilocytosis - individuals have a symptomatic haemolytic anaemia with poikilocytosis that resolves in the first year of life
- With chronic haemolysis - individual has a moderate to severe symptomatic haemolytic anaemia (this subtype has variable penetrance in some pedigrees)
- With homozygosity or compound heterozygosity - depending on the exact mutations involved, individuals may lie anywhere in the spectrum between having a mild haemolytic anaemia and having a life-threatening haemolytic anaemia with symptoms mimicking those of HPP (see below)
- With pyropoikilocytosis (HPP) - individuals are typically of African descent and have a life-threateningly severe haemolytic anaemia with micropoikilocytosis (small and misshapen erythrocytes) that is compounded by a marked instability of erythrocytes in even mildly elevated temperatures (pyropoikilocytosis is often found in burns victims and is the term is commonly used in reference to such people)
South-east Asian ovalocytosis (SAO) (also called stomatocytic elliptocytosis) - individuals are of South-East Asian descent (typically Malaysian, Indonesian, Melanesian, New Guinean or Filipino, have a mild haemolytic anaemia, and has increased resistance to malaria
Spherocytic elliptocytosis (also called hereditary haemolytic ovalocytosis) - individuals are of European descent and elliptocytes and spherocytes are simultaneously present in their blood

History

Elliptocytosis was first described in 1904,^[10] and was first recognised as a hereditary condition in 1932.^[11] More recently it has become clear that the severity of the condition is highly variable,^[12] and there is much genetic variability amongst those affected.^[13]

Related Research Articles

<span class="mw-page-title-main">Hemolysis</span> Rupturing of red blood cells and release of their contents

Hemolysis or haemolysis, also known by several other names, is the rupturing (lysis) of red blood cells (erythrocytes) and the release of their contents (cytoplasm) into surrounding fluid. Hemolysis may occur in vivo or in vitro.

Hereditary spherocytosis (HS) is a congenital hemolytic disorder wherein a genetic mutation coding for a structural membrane protein phenotype causes the red blood cells to be sphere-shaped (spherocytosis), rather than the normal biconcave disk shape. This abnormal shape interferes with the cells' ability to flex during blood circulation, and also makes them more prone to rupture under osmotic stress, mechanical stress, or both. Cells with the dysfunctional proteins are degraded in the spleen, which leads to a shortage of erythrocytes and results in hemolytic anemia.

Glycophorin C plays a functionally important role in maintaining erythrocyte shape and regulating membrane material properties, possibly through its interaction with protein 4.1. Moreover, it has previously been shown that membranes deficient in protein 4.1 exhibit decreased content of glycophorin C. It is also an integral membrane protein of the erythrocyte and acts as the receptor for the Plasmodium falciparum protein PfEBP-2.

Hemoglobin A (HbA), also known as adult hemoglobin, hemoglobin A1 or α₂β₂, is the most common human hemoglobin tetramer, accounting for over 97% of the total red blood cell hemoglobin. Hemoglobin is an oxygen-binding protein, found in erythrocytes, which transports oxygen from the lungs to the tissues. Hemoglobin A is the most common adult form of hemoglobin and exists as a tetramer containing two alpha subunits and two beta subunits (α2β2). Hemoglobin A2 (HbA2) is a less common adult form of hemoglobin and is composed of two alpha and two delta-globin subunits. This hemoglobin makes up 1-3% of hemoglobin in adults.

<span class="mw-page-title-main">Sideroblastic anemia</span> Medical condition

Sideroblastic anemia, or sideroachrestic anemia, is a form of anemia in which the bone marrow produces ringed sideroblasts rather than healthy red blood cells (erythrocytes). In sideroblastic anemia, the body has iron available but cannot incorporate it into hemoglobin, which red blood cells need in order to transport oxygen efficiently. The disorder may be caused either by a genetic disorder or indirectly as part of myelodysplastic syndrome, which can develop into hematological malignancies.

Spectrin is a cytoskeletal protein that lines the intracellular side of the plasma membrane in eukaryotic cells. Spectrin forms pentagonal or hexagonal arrangements, forming a scaffold and playing an important role in maintenance of plasma membrane integrity and cytoskeletal structure. The hexagonal arrangements are formed by tetramers of spectrin subunits associating with short actin filaments at either end of the tetramer. These short actin filaments act as junctional complexes allowing the formation of the hexagonal mesh. The protein is named spectrin since it was first isolated as a major protein component of human red blood cells which had been treated with mild detergents; the detergents lysed the cells and the hemoglobin and other cytoplasmic components were washed out. In the light microscope the basic shape of the red blood cell could still be seen as the spectrin-containing submembranous cytoskeleton preserved the shape of the cell in outline. This became known as a red blood cell "ghost" (spectre), and so the major protein of the ghost was named spectrin.

Southeast Asian ovalocytosis is a blood disorder that is similar to, but distinct from hereditary elliptocytosis. It is common in some communities in Malaysia and Papua New Guinea, as it confers some resistance to cerebral Falciparum Malaria.

<span class="mw-page-title-main">Hereditary stomatocytosis</span> Medical condition

Hereditary stomatocytosis describes a number of inherited, mostly autosomal dominant human conditions which affect the red blood cell and create the appearance of a slit-like area of central pallor (stomatocyte) among erythrocytes on peripheral blood smear. The erythrocytes' cell membranes may abnormally 'leak' sodium and/or potassium ions, causing abnormalities in cell volume. Hereditary stomatocytosis should be distinguished from acquired causes of stomatocytosis, including dilantin toxicity and alcoholism, as well as artifact from the process of preparing peripheral blood smears.

Hereditary pyropoikilocytosis (HPP) is an autosomal recessive form of hemolytic anemia characterized by an abnormal sensitivity of red blood cells to heat and erythrocyte morphology similar to that seen in thermal burns or from prolonged exposure of a healthy patient's blood sample to high ambient temperatures. Patients with HPP tend to experience severe hemolysis and anemia in infancy that gradually improves, evolving toward typical elliptocytosis later in life. However, the hemolysis can lead to rapid sequestration and destruction of red cells. Splenectomy is curative when this occurs.

Triosephosphate isomerase deficiency is a rare autosomal recessive metabolic disorder which was initially described in 1965.

Protein 4.1,, is a protein associated with the cytoskeleton that in humans is encoded by the EPB41 gene. Protein 4.1 is a major structural element of the erythrocyte membrane skeleton. It plays a key role in regulating membrane physical properties of mechanical stability and deformability by stabilizing spectrin-actin interaction. Protein 4.1 interacts with spectrin and short actin filaments to form the erythrocyte membrane skeleton. Mutations of spectrin and protein 4.1 are associated with elliptocytosis or spherocytosis and anemia of varying severity.

Erythrocyte membrane protein band 4.2 is a protein that in humans is encoded by the EPB42 gene. It is part of the red blood cell cytoskeleton.

<span class="mw-page-title-main">Aldolase A deficiency</span> Medical condition

Aldolase A deficiency is an autosomal recessive metabolic disorder resulting in a deficiency of the enzyme aldolase A; the enzyme is found predominantly in red blood cells and muscle tissue. The deficiency may lead to hemolytic anaemia as well as myopathy associated with exercise intolerance and rhabdomyolysis in some cases.

Spectrin alpha chain, erythrocyte is a protein that in humans is encoded by the SPTA1 gene.

Spectrin beta chain, erythrocyte is a protein that in humans is encoded by the SPTB gene.

Glycophorin B (MNS blood group) (gene designation GYPB) also known as sialoglycoprotein delta and SS-active sialoglycoprotein is a protein which in humans is encoded by the GYPB gene. GYPB has also recently been designated CD235b (cluster of differentiation 235b).

Congenital hemolytic anemia (CHA) is a diverse group of rare hereditary conditions marked by decreased life expectancy and premature removal of erythrocytes from blood flow. Defects in erythrocyte membrane proteins and red cell enzyme metabolism, as well as changes at the level of erythrocyte precursors, lead to impaired bone marrow erythropoiesis. CAH is distinguished by variable anemia, chronic extravascular hemolysis, decreased erythrocyte life span, splenomegaly, jaundice, biliary lithiasis, and iron overload. Immune-mediated mechanisms may play a role in the pathogenesis of these uncommon diseases, despite the paucity of data regarding the immune system's involvement in CHAs.

Human genetic resistance to malaria refers to inherited changes in the DNA of humans which increase resistance to malaria and result in increased survival of individuals with those genetic changes. The existence of these genotypes is likely due to evolutionary pressure exerted by parasites of the genus Plasmodium which cause malaria. Since malaria infects red blood cells, these genetic changes are most common alterations to molecules essential for red blood cell function, such as hemoglobin or other cellular proteins or enzymes of red blood cells. These alterations generally protect red blood cells from invasion by Plasmodium parasites or replication of parasites within the red blood cell.

Hemoglobin O-Arab or Haemoglobin O-Arab is a rare alternation of Hemoglobin or Haemoglobin, characterised with the presence of β^121Glu → Lys. Mutations of heterozygotes for Hb O-Arab have been reported in Saudi Arabia, North Africa, Sudan, the Mediterranean and the United States. Diagnosis of Hb O-Arab requires liquid chromatography on both cellulose acetate and citrate agar, due to co-migrating with Hb C at alkaline pH. When combined with Hemoglobin S it causes a severe form of Sickle cell disease known as Hemoglobin S/O-Arab. Detection of Hb O-Arab can be carried out with a blood test, identifying the carries of hemoglobinopathies, so as to inform patients their chances of producing an affected child and ensure appropriate guidance is given.

Hyperbilirubinemia is a clinical condition describing an elevation of blood bilirubin level due to the inability to properly metabolise or excrete bilirubin, a product of erythrocytes breakdown. In severe cases, it is manifested as jaundice, the yellowing of tissues like skin and the sclera when excess bilirubin deposits in them. The US records 52,500 jaundice patients annually. By definition, bilirubin concentration of greater than 3 mg/ml is considered hyperbilirubinemia, following which jaundice progressively develops and becomes apparent when plasma levels reach 20 mg/ml. Rather than a disease itself, hyperbilirubinemia is indicative of multifactorial underlying disorders that trace back to deviations from regular bilirubin metabolism. Diagnosis of hyperbilirubinemia depends on physical examination, urinalysis, serum tests, medical history and imaging to identify the cause. Genetic diseases, alcohol, pregnancy and hepatitis viruses affect the likelihood of hyperbilirubinemia. Causes of hyperbilirubinemia mainly arise from the liver. These include haemolytic anaemias, enzymatic disorders, liver damage and gallstones. Hyperbilirubinemia itself is often benign. Only in extreme cases does kernicterus, a type of brain injury, occur. Therapy for adult hyperbilirubinemia targets the underlying diseases but patients with jaundice often have poor outcomes.

References

↑ McMullin MF (1999). "The molecular basis of disorders of the red cell membrane". J. Clin. Pathol. 52 (4): 245–8. doi:10.1136/jcp.52.4.245. PMC 501324 . PMID 10474512.
↑ Gerard M. Doherty (2010). Current Diagnosis & Treatment - Surgery (13th ed.). McGraw Hill Professional. pp. 204–5. ISBN 978-0-07-163515-8 . Retrieved 5 May 2011.
↑ Robert S. Hillman; Kenneth A. Ault; Henry M. Rinder (2005). Hematology in clinical practice: a guide to diagnosis and management (4th ed.). McGraw-Hill Professional. p. 147. ISBN 978-0-07-144035-6 . Retrieved 5 May 2011.
↑ Kim, D (24 May 2006). "Elliptocytosis, Hereditary". Medscape. WebMD LLC. Retrieved 12 August 2013.
↑ Bannerman, Rm; Renwick, Jh (July 1962). "The hereditary elliptocytoses: clinical and linkage data". Annals of Human Genetics. 26 (1): 23–38. doi:10.1111/j.1469-1809.1962.tb01306.x. ISSN 0003-4800. PMID 13864689. S2CID 40636103.
↑ Hoffman, R; Benz, E; Shattil, S; Furie, B; Cohen, H (2005). Hoffman Hematology: Basic Principles and Practice (4th ed.). Philadelphia: Churchill Livingstone. ISBN 978-0-443-06628-3.
↑ Cattani, Ja; Gibson, Fd; Alpers, Mp; Crane, Gg (1987). "Hereditary ovalocytosis and reduced susceptibility to malaria in Papua New Guinea" (Free full text). Transactions of the Royal Society of Tropical Medicine and Hygiene. 81 (5): 705–9. doi:10.1016/0035-9203(87)90001-0. ISSN 0035-9203. PMID 3329776.
↑ Kutlar, A (22 October 2013). "Hereditary Pyropoikilocytosis". Medscape. WebMD LLC. Retrieved 29 January 2015.
↑ Coetzer T, Lawler J, Prchal JT, Palek J (1 September 1987). "Molecular determinants of clinical expression of hereditary elliptocytosis and pyropoikilocytosis". Blood . 70 (3): 766–72. doi: 10.1182/blood.V70.3.766.766 . PMID 3620700.
↑ Dresbach M (1904). "Elliptical human red corpuscles". Science . 19 (481): 469–470. Bibcode:1904Sci....19..469D. doi:10.1126/science.19.481.469. PMID 17730874.
↑ Hunter, WC (1932). "Further study of a white family showing elliptical erythrocytes". Ann Intern Med . 6 (6): 775–781. doi:10.7326/0003-4819-6-6-775.
↑ Gallagher, Pg (2005). "Red Cell Membrane Disorders". Hematology. 2005 (1): 13–8. doi: 10.1182/asheducation-2005.1.13 . PMID 16304353.
↑ Tse, Wt; Lux, Se (January 1999). "Red blood cell membrane disorders". British Journal of Haematology. 104 (1): 2–13. doi: 10.1111/j.1365-2141.1999.01130.x . ISSN 0007-1048. PMID 10027705.

External links

Hereditary Elliptocytosis Archived 2012-12-11 at archive.today Image of hereditary elliptocytosis
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[1] McMullin MF (1999). "The molecular basis of disorders of the red cell membrane". J. Clin. Pathol. 52 (4): 245–8. doi:10.1136/jcp.52.4.245. PMC 501324 . PMID 10474512.

[Doherty2010-2] Gerard M. Doherty (2010). Current Diagnosis & Treatment - Surgery (13th ed.). McGraw Hill Professional. pp. 204–5. ISBN 978-0-07-163515-8 . Retrieved 5 May 2011.

[HillmanAult2005-3] Robert S. Hillman; Kenneth A. Ault; Henry M. Rinder (2005). Hematology in clinical practice: a guide to diagnosis and management (4th ed.). McGraw-Hill Professional. p. 147. ISBN 978-0-07-144035-6 . Retrieved 5 May 2011.

[4] Kim, D (24 May 2006). "Elliptocytosis, Hereditary". Medscape. WebMD LLC. Retrieved 12 August 2013.

[5] Bannerman, Rm; Renwick, Jh (July 1962). "The hereditary elliptocytoses: clinical and linkage data". Annals of Human Genetics. 26 (1): 23–38. doi:10.1111/j.1469-1809.1962.tb01306.x. ISSN 0003-4800. PMID 13864689. S2CID 40636103.

[hoffman-6] Hoffman, R; Benz, E; Shattil, S; Furie, B; Cohen, H (2005). Hoffman Hematology: Basic Principles and Practice (4th ed.). Philadelphia: Churchill Livingstone. ISBN 978-0-443-06628-3.

[7] Cattani, Ja; Gibson, Fd; Alpers, Mp; Crane, Gg (1987). "Hereditary ovalocytosis and reduced susceptibility to malaria in Papua New Guinea" (Free full text). Transactions of the Royal Society of Tropical Medicine and Hygiene. 81 (5): 705–9. doi:10.1016/0035-9203(87)90001-0. ISSN 0035-9203. PMID 3329776.

[8] Kutlar, A (22 October 2013). "Hereditary Pyropoikilocytosis". Medscape. WebMD LLC. Retrieved 29 January 2015.

[9] Coetzer T, Lawler J, Prchal JT, Palek J (1 September 1987). "Molecular determinants of clinical expression of hereditary elliptocytosis and pyropoikilocytosis". Blood . 70 (3): 766–72. doi: 10.1182/blood.V70.3.766.766 . PMID 3620700.

[10] Dresbach M (1904). "Elliptical human red corpuscles". Science . 19 (481): 469–470. Bibcode:1904Sci....19..469D. doi:10.1126/science.19.481.469. PMID 17730874.

[11] Hunter, WC (1932). "Further study of a white family showing elliptical erythrocytes". Ann Intern Med . 6 (6): 775–781. doi:10.7326/0003-4819-6-6-775.

[12] Gallagher, Pg (2005). "Red Cell Membrane Disorders". Hematology. 2005 (1): 13–8. doi: 10.1182/asheducation-2005.1.13 . PMID 16304353.

[13] Tse, Wt; Lux, Se (January 1999). "Red blood cell membrane disorders". British Journal of Haematology. 104 (1): 2–13. doi: 10.1111/j.1365-2141.1999.01130.x . ISSN 0007-1048. PMID 10027705.

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Classification	D ICD-10 : D58.1 ICD-9-CM : 282.1 OMIM : 611804 MeSH : D004612 DiseasesDB : 4172
External resources	MedlinePlus : 000563 eMedicine : ped/987 med/648

v t e Genetic disorder, membrane: Solute carrier disorders
1-10	SLC1A3 Episodic ataxia 6 SLC2A1 De Vivo disease SLC2A2 Fanconi-Bickel syndrome SLC2A5 Fructose malabsorption SLC2A10 Arterial tortuosity syndrome SLC3A1 Cystinuria SLC4A1 Hereditary spherocytosis 4/Hereditary elliptocytosis 4 SLC4A11 Congenital endothelial dystrophy type 2 Fuchs' dystrophy 4 SLC5A1 Glucose-galactose malabsorption SLC5A2 Renal glycosuria SLC5A5 Thyroid dyshormonogenesis type 1 SLC6A19 Hartnup disease SLC7A7 Lysinuric protein intolerance SLC7A9 Cystinuria
11-20	SLC11A1 Crohn's disease SLC12A3 Gitelman syndrome SLC16A1 HHF7 SLC16A2 Allan–Herndon–Dudley syndrome SLC17A3 Von Gierke's disease, GSD-Ic SLC17A5 Salla disease SLC17A8 DFNA25
21-40	SLC26A2 Multiple epiphyseal dysplasia 4 Achondrogenesis type 1B Recessive multiple epiphyseal dysplasia Atelosteogenesis, type II Diastrophic dysplasia SLC26A4 Pendred syndrome SLC35C1 CDOG 2C SLC37A4 Von Gierke's disease, GSD-Ib SLC39A4 Acrodermatitis enteropathica SLC40A1 African iron overload
51-60	SLC54A1 (Mitochondrial pyruvate carrier deficiency)
see also solute carrier family