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Multiple congenital exostosis(EXT)

MedGen UID:: 4612
•Concept ID:: C0015306
•: Congenital Abnormality

Synonyms:	EXT; Hereditary multiple exostoses; Hereditary multiple exostosis; Hereditary multiple osteochondromas; MULTIPLE CARTILAGINOUS EXOSTOSES; Multiple exostoses; Multiple osteochondromas
SNOMED CT:	Hereditary multiple exostosis (254044004); Osteochondromatosis syndrome (254044004); Osteochondromatosis (254044004); Diaphyseal aclasia (254044004); Multiple osteochondromatosis (254044004); Multiple exostoses type I (254044004); Multiple congenital exostosis (254044004)
Modes of inheritance:	Autosomal dominant inheritance MedGen UID: 141047 •Concept ID: C0443147 • Intellectual Product Source: Orphanet A mode of inheritance that is observed for traits related to a gene encoded on one of the autosomes (i.e., the human chromosomes 1-22) in which a trait manifests in heterozygotes. In the context of medical genetics, an autosomal dominant disorder is caused when a single copy of the mutant allele is present. Males and females are affected equally, and can both transmit the disorder with a risk of 50% for each child of inheriting the mutant allele. Autosomal dominant inheritance (Orphanet)

Related gene: Gene(s) associated with related conditions. For conditions in a hierarchy, the parent condition will list the genes associated with the children conditions.	EXT2

HPO:	HP:0002762
Monarch Initiative:	MONDO:0005508
OMIM®:	133700; 608177
OMIM® Phenotypic series:	PS133700
Orphanet:	ORPHA321

Disease characteristics

Excerpted from the GeneReview: Hereditary Multiple Osteochondromas

Hereditary multiple osteochondromas (HMO), previously called hereditary multiple exostoses (HME), is characterized by growths of multiple osteochondromas, benign cartilage-capped bone tumors that grow outward from the metaphyses of long bones. Osteochondromas can be associated with a reduction in skeletal growth, bony deformity, restricted joint motion, shortened stature, premature osteoarthrosis, and compression of peripheral nerves. The median age of diagnosis is three years; nearly all affected individuals are diagnosed by age 12 years. The risk for malignant degeneration to osteochondrosarcoma increases with age, although the lifetime risk for malignant degeneration is low (~2%-5%). [from GeneReviews]

Authors:
Wim Wuyts | Gregory A Schmale | Howard A Chansky, et. al. view full author information

Additional description

From MedlinePlus Genetics
Hereditary multiple osteochondromas is a condition in which people develop multiple benign (noncancerous) bone tumors called osteochondromas. The number of osteochondromas and the bones on which they are located vary greatly among affected individuals. The osteochondromas are not present at birth, but approximately 96 percent of affected people develop multiple osteochondromas by the time they are 12 years old. Osteochondromas typically form at the end of long bones and on flat bones such as the hip and shoulder blade.

Multiple osteochondromas can disrupt bone growth and can cause growth disturbances of the arms, hands, and legs, leading to short stature. Often these problems with bone growth do not affect the right and left limb equally, resulting in uneven limb lengths (limb length discrepancy). Bowing of the forearm or ankle and abnormal development of the hip joints (hip dysplasia) caused by osteochondromas can lead to difficulty walking and general discomfort. Multiple osteochondromas may also result in pain, limited range of joint movement, and pressure on nerves, blood vessels, the spinal cord, and tissues surrounding the osteochondromas.

Osteochondromas are typically benign; however, in some instances these tumors become malignant (cancerous). Researchers estimate that people with hereditary multiple osteochondromas have a 1 in 20 to 1 in 200 lifetime risk of developing cancerous osteochondromas (called sarcomas). https://medlineplus.gov/genetics/condition/hereditary-multiple-osteochondromas

Clinical features

From HPO

Chondrosarcoma

MedGen UID:: 3054
•Concept ID:: C0008479
•: Neoplastic Process

A slowly growing malignant neoplasm derived from cartilage cells.

See: Feature record | Search on this feature

Genu valgum

MedGen UID:: 154364
•Concept ID:: C0576093
•: Anatomical Abnormality

The legs angle inward, such that the knees are close together and the ankles far apart.

See: Feature record | Search on this feature

Short metacarpal

MedGen UID:: 323064
•Concept ID:: C1837084
•: Anatomical Abnormality

Diminished length of one or more metacarpal bones in relation to the others of the same hand or to the contralateral metacarpal.

See: Feature record | Search on this feature

Madelung-like forearm deformities

MedGen UID:: 342004
•Concept ID:: C1851419
•: Finding

See: Feature record | Search on this feature

Coxa vara

MedGen UID:: 1790477
•Concept ID:: C5551440
•: Anatomical Abnormality

Coxa vara includes all forms of decrease of the femoral neck shaft angle (the angle between the neck and the shaft of the femur) to less than 120 degrees.

See: Feature record | Search on this feature

Short stature

MedGen UID:: 87607
•Concept ID:: C0349588
•: Finding

A height below that which is expected according to age and gender norms. Although there is no universally accepted definition of short stature, many refer to "short stature" as height more than 2 standard deviations below the mean for age and gender (or below the 3rd percentile for age and gender dependent norms).

See: Feature record | Search on this feature

Cervical myelopathy

MedGen UID:: 57691
•Concept ID:: C0149645
•: Disease or Syndrome

See: Feature record | Search on this feature

Peripheral nerve compression

MedGen UID:: 343565
•Concept ID:: C1851414
•: Finding

See: Feature record | Search on this feature

Multiple congenital exostosis

MedGen UID:: 4612
•Concept ID:: C0015306
•: Congenital Abnormality

See: Feature record | Search on this feature

Rib exostoses

MedGen UID:: 322689
•Concept ID:: C1835579
•: Finding

Multiple circumscribed bony excrescences located in the ribs.

See: Feature record | Search on this feature

Pelvic bone exostoses

MedGen UID:: 335004
•Concept ID:: C1844689
•: Neoplastic Process

A benign growth the projects outward from the bone surface of the pelvis. Exostoses are capped by cartilage, and arise from a bone that develops from cartilage.

See: Feature record | Search on this feature

Scapular exostoses

MedGen UID:: 377019
•Concept ID:: C1851415
•: Neoplastic Process

The presence of multiple exostoses on the scapula. An exostosis is a benign growth the projects outward from the bone surface. It is capped by cartilage.

See: Feature record | Search on this feature

Protuberances at ends of long bones

MedGen UID:: 342003
•Concept ID:: C1851418
•: Finding

The presence of multiple protuberances (bulges, or knobs) at the ends of the long bones.

See: Feature record | Search on this feature

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Abnormality of limbs
Abnormality of the musculoskeletal system
Abnormality of the nervous system
- Cervical myelopathy
- Peripheral nerve compression
Growth abnormality
- Short stature
Neoplasm
- Chondrosarcoma

Term Hierarchy

GTR
MeSH

CClinical test, RResearch test, OOMIM, GGeneReviews, VClinVar

CROGVMultiple congenital exostosis
- CROGVExostoses, multiple, type 2
- CROGVExostoses, multiple, type III

Congenital disorder of glycosylation-related bone disorder
- Multiple congenital exostosis

Conditions with this feature

Multiple congenital exostosis

MedGen UID:: 4612
•Concept ID:: C0015306
•: Congenital Abnormality

See: Condition Record

Leri-Weill dyschondrosteosis

MedGen UID:: 75562
•Concept ID:: C0265309
•: Disease or Syndrome

The phenotypic spectrum of SHOX deficiency disorders, caused by haploinsufficiency of the short stature homeobox-containing gene (SHOX), ranges from Leri-Weill dyschondrosteosis (LWD) at the severe end of the spectrum to nonspecific short stature at the mild end of the spectrum. In adults with SHOX deficiency, the proportion of LWD versus short stature without features of LWD is not well defined. In LWD the classic clinical triad is short stature, mesomelia, and Madelung deformity. Mesomelia, in which the middle portion of a limb is shortened in relation to the proximal portion, can be evident first in school-aged children and increases with age in frequency and severity. Madelung deformity (abnormal alignment of the radius, ulna, and carpal bones at the wrist) typically develops in mid-to-late childhood and is more common and severe in females. The phenotype of short stature caused by SHOX deficiency in the absence of mesomelia and Madelung deformity (called SHOX-deficient short stature in this GeneReview) is highly variable, even within the same family.

See: Condition Record

Potocki-Shaffer syndrome

MedGen UID:: 318657
•Concept ID:: C1832588
•: Disease or Syndrome

Potocki-Shaffer syndrome is a rare contiguous gene deletion syndrome due to haploinsufficiency of the 11p12-p11.2 region and is characterized by craniofacial abnormalities, developmental delay, intellectual disability, multiple exostoses (168500), and biparietal foramina (609597) (summary by Swarr et al., 2010).

See: Condition Record

Multiple exostoses with spastic tetraparesis

MedGen UID:: 371889
•Concept ID:: C1834724
•: Disease or Syndrome

See: Condition Record

Exostoses, multiple, type III

MedGen UID:: 333090
•Concept ID:: C1838420
•: Disease or Syndrome

See: Condition Record

Exostoses, multiple, type 2

MedGen UID:: 377018
•Concept ID:: C1851413
•: Disease or Syndrome

See: Condition Record

Exostoses-anetodermia-brachydactyly type E syndrome

MedGen UID:: 338695
•Concept ID:: C1851428
•: Disease or Syndrome

An association reported in a single kindred characterized by the variable presence of the following features: anetodermia (macular atrophy of the skin), multiple exostoses, and brachydactyly type E. There have been no further descriptions in the literature since 1985.

See: Condition Record

Polyposis, intestinal, with multiple exostoses

MedGen UID:: 401357
•Concept ID:: C1868005
•: Neoplastic Process

See: Condition Record

Wilms tumor, aniridia, genitourinary anomalies, intellectual disability, and obesity syndrome

MedGen UID:: 382718
•Concept ID:: C2675904
•: Disease or Syndrome

For a detailed discussion of the WAGR syndrome, see 194072. In a subgroup of individuals with the WAGR syndrome, obesity develops. The phenotype in this subset is associated with haploinsufficiency for the BDNF gene.

See: Condition Record

Exostoses, multiple, type 2

Exostoses, multiple, type III

Exostoses-anetodermia-brachydactyly type E syndrome

Leri-Weill dyschondrosteosis

Multiple congenital exostosis

Multiple exostoses with spastic tetraparesis

Polyposis, intestinal, with multiple exostoses

Potocki-Shaffer syndrome

Wilms tumor, aniridia, genitourinary anomalies, intellectual disability, and obesity syndrome

Professional guidelines

PubMed

Clinical and Functional Outcomes of Ulnar Lengthening in the Treatment of Masada Type I Forearm Deformities in Hereditary Multiple Osteochondromas.

Baghdadi S, Arabi H, Farhoud A, Moharrami A, Baghdadi T
J Hand Surg Am 2020 Sep;45(9):876.e1-876.e7. Epub 2020 Apr 3 doi: 10.1016/j.jhsa.2020.02.010. PMID: 32253060

A genotype-phenotype study of hereditary multiple exostoses in forty-six Chinese patients.

Li Y, Wang J, Wang Z, Tang J, Yu T
BMC Med Genet 2017 Nov 10;18(1):126. doi: 10.1186/s12881-017-0488-2. PMID: 29126381 Free PMC Article

Clinical outcome and genotype in patients with hereditary multiple exostoses.

Jäger M, Westhoff B, Portier S, Leube B, Hardt K, Royer-Pokora B, Gossheger G, Krauspe R
J Orthop Res 2007 Dec;25(12):1541-51. doi: 10.1002/jor.20479. PMID: 17676624

See all (21)

Recent clinical studies

Etiology

Total hip arthroplasty in hereditary multiple exostosis patients: literature review and evaluation of 10 cases.

Ostetto F, Lana D, Tuzzato G, Staals E, Donati DM, Bianchi G
Hip Int 2023 Mar;33(2):161-168. Epub 2021 Jun 16 doi: 10.1177/11207000211025051. PMID: 34134547

Update on the imaging features of the enchondromatosis syndromes.

Sharif B, Lindsay D, Saifuddin A
Skeletal Radiol 2022 Apr;51(4):747-762. Epub 2021 Jul 24 doi: 10.1007/s00256-021-03870-0. PMID: 34302201

Multiple hereditary exostoses and enchondromatosis.

Jurik AG
Best Pract Res Clin Rheumatol 2020 Jun;34(3):101505. Epub 2020 Apr 4 doi: 10.1016/j.berh.2020.101505. PMID: 32253147

Whole-body MRI of bone marrow: A review.

Hynes JP, Hughes N, Cunningham P, Kavanagh EC, Eustace SJ
J Magn Reson Imaging 2019 Dec;50(6):1687-1701. Epub 2019 Apr 23 doi: 10.1002/jmri.26759. PMID: 31016800

The etiology of osteosarcoma.

Ottaviani G, Jaffe N
Cancer Treat Res 2009;152:15-32. doi: 10.1007/978-1-4419-0284-9_2. PMID: 20213384

See all (218)

Diagnosis

An update on the imaging of diaphyseal aclasis.

Ellatif M, Sharif B, Lindsay D, Pollock R, Saifuddin A
Skeletal Radiol 2021 Oct;50(10):1941-1962. Epub 2021 Apr 1 doi: 10.1007/s00256-021-03770-3. PMID: 33791832

Brachymetacarpia and Brachymetatarsia in Patients with Multiple Hereditary Exostosis.

Cho YJ, Lee JY, Lee WG, Jung ST
Clin Orthop Surg 2020 Dec;12(4):549-553. Epub 2020 Nov 18 doi: 10.4055/cios19121. PMID: 33274034 Free PMC Article

Multiple Hereditary Exostoses.

DuBose CO
Radiol Technol 2016 Jan-Feb;87(3):305-21. quiz 322-5. PMID: 26721841

Hereditary multiple exostosis.

Ryckx A, Somers JF, Allaert L
Acta Orthop Belg 2013 Dec;79(6):597-607. PMID: 24563962

Multiple osteochondromas.

Bovée JV
Orphanet J Rare Dis 2008 Feb 13;3:3. doi: 10.1186/1750-1172-3-3. PMID: 18271966 Free PMC Article

See all (350)

Therapy

Total hip arthroplasty in hereditary multiple exostosis patients: literature review and evaluation of 10 cases.

Ostetto F, Lana D, Tuzzato G, Staals E, Donati DM, Bianchi G
Hip Int 2023 Mar;33(2):161-168. Epub 2021 Jun 16 doi: 10.1177/11207000211025051. PMID: 34134547

Bone development and remodeling in metabolic disorders.

Serra-Vinardell J, Roca-Ayats N, De-Ugarte L, Vilageliu L, Balcells S, Grinberg D
J Inherit Metab Dis 2020 Jan;43(1):133-144. Epub 2019 Apr 29 doi: 10.1002/jimd.12097. PMID: 30942483

Retinoid roles and action in skeletal development and growth provide the rationale for an ongoing heterotopic ossification prevention trial.

Pacifici M
Bone 2018 Apr;109:267-275. Epub 2017 Aug 19 doi: 10.1016/j.bone.2017.08.010. PMID: 28826842 Free PMC Article

The etiology of osteosarcoma.

Ottaviani G, Jaffe N
Cancer Treat Res 2009;152:15-32. doi: 10.1007/978-1-4419-0284-9_2. PMID: 20213384

Osteosarcoma and other bone cancers.

Himelstein BP
Curr Opin Oncol 1998 Jul;10(4):326-33. doi: 10.1097/00001622-199807000-00009. PMID: 9702400

See all (41)

Prognosis

Forearm deformity in multiple hereditary exostosis. Radiologic predictors of radial head dislocation.

Bom F, Barbier O, Libouton X, Docquier PL
Orthop Traumatol Surg Res 2023 Sep;109(5):103445. Epub 2022 Oct 18 doi: 10.1016/j.otsr.2022.103445. PMID: 36270444

Clinical differences between central and peripheral chondrosarcomas.

Laitinen MK, Evans S, Stevenson J, Sumathi V, Kask G, Jeys LM, Parry MC
Bone Joint J 2021 May;103-B(5):984-990. doi: 10.1302/0301-620X.103B5.BJJ-2020-1082.R2. PMID: 33934657

Syringomyelia in hereditary multiple exostosis.

Legare JM, Modaff P, Iskandar BJ, Pauli RM
Am J Med Genet A 2016 Nov;170(11):2956-2959. Epub 2016 Aug 2 doi: 10.1002/ajmg.a.37854. PMID: 27480811

The role of microRNAs in the biology of rare diseases.

Salvatore M, Magrelli A, Taruscio D
Int J Mol Sci 2011;12(10):6733-42. Epub 2011 Oct 11 doi: 10.3390/ijms12106733. PMID: 22072915 Free PMC Article

Multiple osteochondromas.

Bovée JV
Orphanet J Rare Dis 2008 Feb 13;3:3. doi: 10.1186/1750-1172-3-3. PMID: 18271966 Free PMC Article

See all (130)

Clinical prediction guides

Total hip arthroplasty in hereditary multiple exostosis patients: literature review and evaluation of 10 cases.

Ostetto F, Lana D, Tuzzato G, Staals E, Donati DM, Bianchi G
Hip Int 2023 Mar;33(2):161-168. Epub 2021 Jun 16 doi: 10.1177/11207000211025051. PMID: 34134547

Clinical and Genetic Analysis of Multiple Osteochondromas in A Cohort of Argentine Patients.

Caino S, Cubilla MA, Alba R, Obregón MG, Fano V, Gómez A, Zecchini L, Lapunzina P, Aza-Carmona M, Heath KE, Asteggiano CG
Genes (Basel) 2022 Nov 7;13(11) doi: 10.3390/genes13112063. PMID: 36360300 Free PMC Article

Clinical survey of a pedigree with hereditary multiple exostoses and identification of EXT‑2 gene deletion mutation.

Wang W, Yang M, Shen Y, Chen K, Wu D, Yang C, Bai J, He D, Gao J
Mol Med Rep 2022 Apr;25(4) Epub 2022 Feb 25 doi: 10.3892/mmr.2022.12657. PMID: 35211766 Free PMC Article

Brachymetacarpia and Brachymetatarsia in Patients with Multiple Hereditary Exostosis.

Cho YJ, Lee JY, Lee WG, Jung ST
Clin Orthop Surg 2020 Dec;12(4):549-553. Epub 2020 Nov 18 doi: 10.4055/cios19121. PMID: 33274034 Free PMC Article

The etiology of osteosarcoma.

Ottaviani G, Jaffe N
Cancer Treat Res 2009;152:15-32. doi: 10.1007/978-1-4419-0284-9_2. PMID: 20213384

See all (158)

Recent systematic reviews

Clinical overview and outcome of the Stuve-Wiedemann syndrome: a systematic review.

Warnier H, Barrea C, Bethlen S, Schrouff I, Harvengt J
Orphanet J Rare Dis 2022 Apr 23;17(1):174. doi: 10.1186/s13023-022-02323-8. PMID: 35461249 Free PMC Article

Multiple cartilaginous exostoses and development of chondrosarcomas--a systematic review.

Sonne-Holm E, Wong C, Sonne-Holm S
Dan Med J 2014 Sep;61(9):A4895. PMID: 25186537

See all (2)

MedGen

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Multiple congenital exostosis(EXT)

Disease characteristics

Additional description

Clinical features

Term Hierarchy

Conditions with this feature

Professional guidelines

PubMed

Recent clinical studies

Etiology

Diagnosis

Therapy

Prognosis

Clinical prediction guides

Recent systematic reviews

Supplemental Content

Table of contents

Genetic Testing Registry

Clinical resources

Practice guidelines

Consumer resources

Reviews

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