Hereditary multiple exostoses (HME), also known as hereditary multiple osteochondromas (HMO), is a rare autosomal dominant skeletal disorder characterized by the development of multiple cartilage-capped bony growths called osteochondromas. These benign tumors usually arise near the growth plates of long bones during childhood and adolescence.

Although osteochondromas are benign, HME can lead to skeletal deformities, chronic pain, restricted joint movement, limb-length discrepancies, and, in rare cases, malignant transformation into chondrosarcoma.

This article provides an evidence-based medical overview of hereditary multiple exostoses, including causes, symptoms, diagnosis, treatment, prognosis, and recent research developments.

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What is Hereditary Multiple Exostoses?

Hereditary multiple exostoses is a genetic disorder affecting bone growth. Patients develop multiple osteochondromas, which are abnormal bony projections covered with cartilage.

These growths commonly occur in:

• Femur
• Tibia
• Humerus
• Forearm bones
• Pelvis
• Ribs
• Scapula

The condition typically presents in early childhood, with most patients diagnosed before age 12.

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Epidemiology of HME

HME is considered a rare disease with an estimated prevalence of approximately 1 in 50,000 individuals worldwide. Males are slightly more frequently affected than females.

The disorder demonstrates high penetrance, meaning most individuals carrying the pathogenic mutation eventually develop clinical manifestations.

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Causes and Genetics of Hereditary Multiple Exostoses

EXT1 and EXT2 Gene Mutations

Most cases of hereditary multiple exostoses are caused by mutations in the EXT1 and EXT2 genes.

These genes are responsible for producing enzymes involved in heparan sulfate synthesis, an essential component in cartilage growth and skeletal development.

The disease follows an autosomal dominant inheritance pattern, meaning:

• One mutated copy of the gene is sufficient to cause disease
• Each child of an affected parent has a 50% chance of inheriting the condition

Research shows:

• EXT1 mutations are often associated with more severe disease
• EXT2 mutations may produce milder phenotypes

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Pathophysiology

The defective EXT genes impair normal heparan sulfate biosynthesis. This disrupts signaling pathways involved in chondrocyte proliferation and growth plate organization.

As a result, cartilage cells grow abnormally outward from the metaphysis of bones, forming osteochondromas.

See Also: Bone Formation & Development

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Symptoms of Hereditary Multiple Exostoses

Clinical manifestations vary considerably between individuals.

Common Symptoms

Multiple Bone Growths

Patients develop hard, palpable masses near joints and long bones.

Skeletal Deformities

Common deformities include:

• Bowing of the forearm
• Short stature
• Knee valgus deformity
• Limb-length discrepancies
• Coxa valga

Pain

Pain may result from:

• Mechanical irritation
• Compression of surrounding tissues
• Bursa formation
• Joint dysfunction

Restricted Movement

Large osteochondromas may limit joint mobility and impair physical activity.

Neurovascular Compression

Some lesions compress nerves or blood vessels, causing:

• Numbness
• Tingling
• Weakness
• Vascular insufficiency

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Complications of HME

Malignant Transformation

The most serious complication is transformation into secondary peripheral chondrosarcoma.

Warning signs include:

• Sudden enlargement of a lesion after skeletal maturity
• Increasing pain
• Thickened cartilage cap
• Neurological symptoms

The estimated lifetime risk of malignant transformation ranges from approximately 1% to 5%.

Orthopedic Complications

Patients may develop:

• Premature osteoarthritis
• Fractures
• Spinal cord compression
• Chronic disability

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Diagnosis of Hereditary Multiple Exostoses

Clinical Evaluation

Diagnosis begins with:

• Family history
• Physical examination
• Assessment of skeletal deformities

Imaging Studies

X-rays

Radiographs remain the primary imaging modality and reveal characteristic osteochondromas near growth plates.

MRI

MRI is useful for:

• Evaluating cartilage cap thickness
• Detecting malignant transformation
• Assessing neurovascular involvement

CT Scan

CT imaging helps evaluate complex anatomical regions such as the pelvis or spine.

Genetic Testing

Molecular testing can identify pathogenic variants in:

• EXT1
• EXT2

Genetic testing confirms diagnosis and supports family counseling.

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Differential Diagnosis

Conditions that may resemble HME include:

• Solitary osteochondroma
• Metachondromatosis
• Ollier disease
• Langer-Giedion syndrome
• Trevor disease

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Treatment of Hereditary Multiple Exostoses

There is currently no cure for HME. Treatment focuses on symptom management and complication prevention.

Conservative Management

Mild cases may only require:

• Observation
• Periodic imaging
• Physical therapy
• Pain management

Surgical Treatment

Surgery may be indicated for:

• Painful lesions
• Functional impairment
• Neurovascular compression
• Severe deformity
• Suspicion of malignancy

Procedures include:

• Osteochondroma excision
• Corrective osteotomy
• Limb-length correction

Long-Term Monitoring

Regular follow-up is essential to monitor:

• Skeletal development
• Tumor growth
• Malignant transformation

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Prognosis

Most patients with hereditary multiple exostoses maintain a normal lifespan. However, quality of life may be affected by chronic pain, repeated surgeries, and skeletal deformities.

Early diagnosis and multidisciplinary management significantly improve functional outcomes.

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Genetic Counseling

Because HME is inherited in an autosomal dominant pattern, genetic counseling is strongly recommended for affected families.

Prenatal and preimplantation genetic testing may be considered in some cases.

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Recent Research and Future Therapies

Current research focuses on:

• Molecular pathways involving heparan sulfate synthesis
• Targeted therapies for abnormal cartilage growth
• Improved genetic diagnostics
• Novel treatments to prevent osteochondroma formation

Experimental therapies are under investigation but are not yet clinically available.

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Conclusion

Hereditary multiple exostoses is a rare genetic skeletal disorder characterized by multiple osteochondromas and progressive orthopedic complications. Mutations in EXT1 and EXT2 disrupt normal bone growth and lead to abnormal cartilage proliferation.

Early recognition, regular monitoring, imaging studies, and individualized orthopedic care are essential for optimal outcomes. Although no definitive cure exists, advances in molecular genetics continue to improve understanding and management of this complex disorder.

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Frequently Asked Questions (FAQs)

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References & More

1. Sefcik R, Earl D, Thorpe S. Hereditary Multiple Osteochondromas. 2000 Aug 3 [Updated 2026 Jan 29]. In: Adam MP, Bick S, Mirzaa GM, et al., editors. GeneReviews® [Internet]. Seattle (WA): University of Washington, Seattle; 1993-2026. Available from: https://www.ncbi.nlm.nih.gov/books/NBK1235/
2. Rueda-de-Eusebio A, Gomez-Pena S, Moreno-Casado MJ, Marquina G, Arrazola J, Crespo-Rodríguez AM. Hereditary multiple exostoses: an educational review. Insights Imaging. 2025 Feb 21;16(1):46. doi: 10.1186/s13244-025-01899-6. PMID: 39982564; PMCID: PMC11845651. Pubmed
3. Beltrami G, Ristori G, Scoccianti G, Tamburini A, Capanna R. Hereditary Multiple Exostoses: a review of clinical appearance and metabolic pattern. Clin Cases Miner Bone Metab. 2016 May-Aug;13(2):110-118. doi: 10.11138/ccmbm/2016.13.2.110. Epub 2016 Oct 5. PMID: 27920806; PMCID: PMC5119707. Pubmed