Fibrous Dysplasia
DR KS Dhillon
Introduction
Fibrous dysplasia is a benign bone lesion that is characterized by intramedullary fibro-osseous proliferation secondary to altered osteogenesis (1). It was first introduced by Lichtenstein and Jaffe in 1942 and originally termed Jaffe-Lichtenstein syndrome. Fibrous dysplasia can occur in monostotic form (single bone) or polyostotic form (multiple bones) (1). Fibro-osseous tissue replacement of normal bone can result in complications such as fractures or compression of adjacent soft tissues including neurovascular structures (2). Monostotic fibrous dysplasia is usually an asymptomatic clinical entity. The polyostotic form usually presents in childhood. Presentation in adults is often detected incidentally during imaging for unrelated indications (2). Fibro-osseous replacement of bone in fibrous dysplasia can lead to pathologic fracture, especially in weight-bearing bones or the upper extremities in athletes (3). Malignant transformation is rare. Radiation therapy has been reported as a risk factor (4). McCune-Albright syndrome is a relatively rare condition. It features polyostotic fibrous dysplasia with skin pigmentation lesions and endocrine dysfunction. Mazabraud syndrome is a very rare polyostotic variant. It features coexistent single or multiple intramuscular myxomas (5).
Etiology
Fibrous dysplasia etiology has been linked with a missense mutation in the GNAS1 gene on chromosome 20. Following an activating mutation abnormal proliferation of fibrous tissue ensues (6).
Epidemiology
The incidence of fibrous dysplasia has been estimated at 1 in 5,000 to 10,000 (7). Usually, fibrous dysplasia is first diagnosed in children or young adults. There is no predilection for gender. Fibrous dysplasia constitutes 5% of all benign bone lesions (2). The monostotic form is the most common. It accounts for 75% to 80% of fibrous dysplasia cases (8).
Histopathology
In fibrous dysplasia, there are histologic elements of immature collagen and immature bone trabeculae forming a fibrocellular matrix (9). The trabeculae are not rimmed by osteoblasts secondary to osteoblast maturation arrest. There is abrupt histologic transition from normal to abnormal bone (9).
History and Physical Examination
Patients with monostotic fibrous dysplasia are usually asymptomatic, but they may occasionally present with bone pain. Pathologic fracture with minor trauma can be the first presentation (10). Pregnancy can increase disease activity and increase the risk of pain and pathologic fracture (11).
In patients with asymptomatic osseous involvement history and physical examination may contribute little to disease evaluation. History will address the characteristics of bony protuberance, osseous asymmetry, tenderness, endocrine disturbance, and dermatologic complaints. There may be a family history of bone lesions in hereditary forms of fibrous dysplasia such as cherubism. Malignant transformation is rare. It occurs in less than 1% of the patients (12). A periodic evaluation for aggressive lesion growth should be performed in a patient with known fibrous dysplasia (13). In patients with hyperfunctioning endocrinopathy, McCune-Albright syndrome should be considered.
Physical examination has a minor role in the evaluation of fibrous dysplasia lesions. Focal palpation may increase pain in patients with fractures. Visual inspection for skeletal deformities and asymmetries will show the sites of involvement. Leg length discrepancy may indicate the presence of disease such as the classic shepherd’s crook deformity of the proximal femur (14). Facial involvement can produce orbital asymmetry (15). Other possible face complications include frontal bossing, proptosis, or mandibular enlargement (16).
Deformity commonly occurs in the ribs, long bones, and craniofacial structures. Less often it occurs in the hands, sternum, and spine (17,18). In patients with McCune-Albright syndrome, the physical examination should include an examination of the skin to look for cafe au lait skin pigmentation. Skin acne can be a feature of endocrinopathy (Cushing syndrome) (19). A thorough physical examination to assess the endocrine system should be done. This would include cardiopulmonary, gastrointestinal, and thyroid evaluation (20). Assessment of hearing and vision in the setting of craniofacial manifestation of fibrous dysplasia is also important (2).
Evaluation
Imaging plays a main role in the diagnosis and evaluation of the extent of the disease. Radiography should be utilized first in an evaluation of fibrous dysplasia. Imaging such as magnetic resonance imaging (MRI) and computerized tomography (CT) can exclude other bone lesions; evaluate for soft tissue complications occurring from fractures, evaluate craniofacial neurovascular complications, and assess lesions for rare malignant transformation (21). MRI and CT also have a role in the evaluation of thyroid nodules, adrenal hyperplasia, and pituitary tumors (22,23). The bone lesions classically, have an internal ground glass matrix on radiographs and CT. The appearance can vary with lytic and/or sclerotic components, possible bone expansion, and cortical thinning (12). Bowing deformities such as femoral shepherd's crook deformity, limb length discrepancy, and short stature secondary to premature fusion of growth plates can be characterized with imaging (21). Bone scan demonstrating increased Technetium-99m radiotracer uptake can have a role in polyostotic cases to assess the extent of the disease (24). Biopsy with histologic evaluation may be necessary in some cases where imaging features mimic malignant lesions (14).
Management
Patients with monostotic fibrous dysplasia are usually asymptomatic. They can be followed periodically to look for new symptoms and to take radiographs (25). In asymptomatic cases, no treatment is required. Bone pain and disease-associated osteoporosis can be alleviated in adults with bisphosphonates (10). Bisphosphonates inhibit osteoclastic bone resorption and preserve cortical bone mass. Hence they reduce fracture risk (26,27). Surgery may be required in symptomatic fibrous dysplasia treatment.
Surgery for internal fixation is needed in patients with pathologic fractures and for prophylactic internal fixation in lesions weakening weight-bearing bones (14). Surgical interventions may be required for the correction of extremity and spine deformities and for limb length inequality (14). Craniofacial surgery may be required to alleviate nerve compression symptoms (28). During surgery, bone lesion curettage, bone grafting, and insertion of metallic fixation rods, screws, and plates may be required (14).
Differential Diagnosis
Accurate assessment of the cafe au lait skin pigmentation lesions is important in patients with polyostotic McCune-Albright syndrome. The skin lesion borders have been described as serrated. This is in contrast to smooth skin lesion borders seen in neurofibromatosis (11).
Fibrous dysplasia usually has varied imaging presentation and varied osseous sites of involvement. Therefore other bone diseases must be kept in mind. Monostotic radiologic appearance can mimic simple bone cysts, fibroxanthomas, osteoblastomas, giant cell tumors, hemangiomas, osteofibrous dysplasia, and Paget disease. Polyostotic appearance can mimic neurofibromatosis, enchondromatosis, hyperparathyroidism, and eosinophilic granuloma (11,25). Bone location, patient age, presence of ground glass matrix, and non-aggressive appearance are features that favor fibrous dysplasia (11). If malignancy cannot be excluded following clinical and imaging workup, bone biopsy does have a role (14).
Complications
Fibrous dysplasia is usually monostotic and asymptomatic. In patients with severe bone deformity, bowing may result in musculoskeletal dysfunction or acceleration of the development of osteoarthritis (29). Spine lesions can predispose to scoliosis and subsequent functional dysfunction (30). Craniofacial cases can have associated cranial nerve deficits with vision and hearing loss (31,32). In patients with prior history of radiation therapy, malignant transformation to sarcoma can occur although it is rare (33).
Conclusion
Fibrous dysplasia is a benign bone lesion. It is characterized by intramedullary fibro-osseous proliferation secondary to altered osteogenesis. Fibro-osseous tissue replacement of normal bone can result in complications such as fractures or compression of adjacent soft tissues. Patient education regarding the risk of fracture is important (34). In patients with craniofacial disease, the patient should be coached to monitor for evolving cranial nerve deficits including vision and hearing loss. In patients with McCune-Albright syndrome genetic counseling would be required (35). Routine visits to an endocrinologist would also be required to monitor for symptoms of endocrine dysfunction.
Managing fibrous dysplasia involves an interprofessional team approach. Craniofacial involvement should prompt, ophthalmology, neurology, audiology, and possible neurosurgery consultation (3,36). Additional support from physical therapist and psychiatrist in cases of disability or deformity may be needed (3).
References
Schoenau E, Rauch F. Fibrous dysplasia. Horm Res. 2002;57 Suppl 2:79-82.
DiCaprio MR, Enneking WF. Fibrous dysplasia. Pathophysiology, evaluation, and treatment. J Bone Joint Surg Am. 2005 Aug;87(8):1848-64.
Leet AI, Collins MT. Current approach to fibrous dysplasia of bone and McCune-Albright syndrome. J Child Orthop. 2007 Mar;1(1):3-17.
Hansen MR, Moffat JC. Osteosarcoma of the Skull Base after Radiation Therapy in a Patient with McCune-Albright Syndrome: Case Report. Skull Base.
Munksgaard PS, Salkus G, Iyer VV, Fisker RV. Mazabraud's syndrome: case report and literature review. Acta Radiol Short Rep. 2013;2(4):2047981613492532.
Robinson C, Collins MT, Boyce AM. Fibrous Dysplasia/McCune-Albright Syndrome: Clinical and Translational Perspectives. Curr Osteoporos Rep. 2016 Oct;14(5):178-86.
Pai B, Ferdinand D. Fibrous dysplasia causing safeguarding concerns. Arch Dis Child. 2013 Dec;98(12):1003.
Riddle ND, Bui MM. Fibrous dysplasia. Arch Pathol Lab Med. 2013 Jan;137(1):134-8.
Riminucci M, Liu B, Corsi A, Shenker A, Spiegel AM, Robey PG, Bianco P. The histopathology of fibrous dysplasia of bone in patients with activating mutations of the Gs alpha gene: site-specific patterns and recurrent histological hallmarks. J Pathol. 1999 Jan;187(2):249-58.
Chapurlat RD, Gensburger D, Jimenez-Andrade JM, Ghilardi JR, Kelly M, Mantyh P. Pathophysiology and medical treatment of pain in fibrous dysplasia of bone. Orphanet J Rare Dis. 2012 May 24;7 Suppl 1(Suppl 1):S3.
Kransdorf MJ, Moser RP, Gilkey FW. Fibrous dysplasia. Radiographics. 1990 May;10(3):519-37.
Adetayo OA, Salcedo SE, Borad V, Richards SS, Workman AD, Ray AO. Fibrous dysplasia: an overview of disease process, indications for surgical management, and a case report. Eplasty. 2015;15:e6.
Ruggieri P, Sim FH, Bond JR, Unni KK. Malignancies in fibrous dysplasia. Cancer. 1994 Mar 01;73(5):1411-24.
Stanton RP, Ippolito E, Springfield D, Lindaman L, Wientroub S, Leet A. The surgical management of fibrous dysplasia of bone. Orphanet J Rare Dis. 2012 May 24;7 Suppl 1(Suppl 1):S1.
Gupta S, Jain S, Newaskar V, Ali M. Craniofacial fibrous dysplasia with facial asymmetry, canted occlusion and open bite: a case report with 2 years follow-up. J Contemp Dent Pract. 2014 Sep 01;15(5):636-45.
Sandhu SV, Sandhu JS, Sabharwal A. Clinicoradiologic perspective of a severe case of polyostotic fibrous dysplasia. J Oral Maxillofac Pathol. 2012 May;16(2):301-5.
Zorzin L, Palmieri G, Marrese C, Spagnoli LG. Polyostotic fibrous dysplasia involving the sternum. Clin Rheumatol. 1988 Mar;7(1):107-9.
Batista KT, Araújo HJ, Schwartzman UP. Monostotic fibrous dysplasia of the metacarpal: a case report. Rev Bras Ortop. 2016 Nov-Dec;51(6):730-734.
Dean L. McCune-Albright Syndrome. In: Pratt VM, Scott SA, Pirmohamed M, Esquivel B, Kattman BL, Malheiro AJ, editors. Medical Genetics Summaries [Internet]. National Center for Biotechnology Information (US); Bethesda (MD): Mar 8, 2012.
Francis GL, Waguespack SG, Bauer AJ, Angelos P, Benvenga S, Cerutti JM, Dinauer CA, Hamilton J, Hay ID, Luster M, Parisi MT, Rachmiel M, Thompson GB, Yamashita S., American Thyroid Association Guidelines Task Force. Management Guidelines for Children with Thyroid Nodules and Differentiated Thyroid Cancer. Thyroid. 2015 Jul;25(7):716-59.
Fitzpatrick KA, Taljanovic MS, Speer DP, Graham AR, Jacobson JA, Barnes GR, Hunter TB. Imaging findings of fibrous dysplasia with histopathologic and intraoperative correlation. AJR Am J Roentgenol. 2004 Jun;182(6):1389-98.
O'Laughlin RL, Selinger SE, Moriarty PE. Pituitary adenoma in McCune-Albright syndrome: MR demonstration. J Comput Assist Tomogr. 1989 Jul-Aug;13(4):685-8.
Kirk JM, Brain CE, Carson DJ, Hyde JC, Grant DB. Cushing's syndrome caused by nodular adrenal hyperplasia in children with McCune-Albright syndrome. J Pediatr. 1999 Jun;134(6):789-92.
Zhibin Y, Quanyong L, Libo C, Jun Z, Hankui L, Jifang Z, Ruisen Z. The role of radionuclide bone scintigraphy in fibrous dysplasia of bone. Clin Nucl Med. 2004 Mar;29(3):177-80.
Bousson V, Rey-Jouvin C, Laredo JD, Le Merrer M, Martin-Duverneuil N, Feydy A, Aubert S, Chapurlat R, Orcel P. Fibrous dysplasia and McCune-Albright syndrome: imaging for positive and differential diagnoses, prognosis, and follow-up guidelines. Eur J Radiol. 2014 Oct;83(10):1828-42.
Shahnazari M, Yao W, Dai W, Wang B, Ionova-Martin SS, Ritchie RO, Heeren D, Burghardt AJ, Nicolella DP, Kimiecik MG, Lane NE. Higher doses of bisphosphonates further improve bone mass, architecture, and strength but not the tissue material properties in aged rats. Bone. 2010 May;46(5):1267-74.
Zacharin M, O'Sullivan M. Intravenous pamidronate treatment of polyostotic fibrous dysplasia associated with the McCune Albright syndrome. J Pediatr. 2000 Sep;137(3):403-9.
Tan YC, Yu CC, Chang CN, Ma L, Chen YR. Optic nerve compression in craniofacial fibrous dysplasia: the role and indications for decompression. Plast Reconstr Surg. 2007 Dec;120(7):1957-1962.
Kushare IV, Colo D, Bakhshi H, Dormans JP. Fibrous dysplasia of the proximal femur: surgical management options and outcomes. J Child Orthop. 2014 Dec;8(6):505-11. 30.
Mancini F, Corsi A, De Maio F, Riminucci M, Ippolito E. Scoliosis and spine involvement in fibrous dysplasia of bone. Eur Spine J. 2009 Feb;18(2):196-202.
Michael CB, Lee AG, Patrinely JR, Stal S, Blacklock JB. Visual loss associated with fibrous dysplasia of the anterior skull base. Case report and review of the literature. J Neurosurg. 2000 Feb;92(2):350-4.
Boyce AM, Brewer C, DeKlotz TR, Zalewski CK, King KA, Collins MT, Kim HJ. Association of Hearing Loss and Otologic Outcomes With Fibrous Dysplasia. JAMA Otolaryngol Head Neck Surg. 2018 Feb 01;144(2):102-107.
Qu N, Yao W, Cui X, Zhang H. Malignant transformation in monostotic fibrous dysplasia: clinical features, imaging features, outcomes in 10 patients, and review. Medicine (Baltimore). 2015 Jan;94(3):e369.
Han I, Choi ES, Kim HS. Monostotic fibrous dysplasia of the proximal femur: natural history and predisposing factors for disease progression. Bone Joint J. 2014 May;96-B(5):673-6.
Dumitrescu CE, Collins MT. McCune-Albright syndrome. Orphanet J Rare Dis. 2008 May 19;3:12. [PMC free article] [PubMed]
Bowers CA, Taussky P, Couldwell WT. Surgical treatment of craniofacial fibrous dysplasia in adults. Neurosurg Rev. 2014 Jan;37(1):47-53.