In July 2017, a clinical Center specialized in rare diseases was funded in our major University Hospital(1). As defined by the European Union Regulation on Orphan Medicinal Products (1999), in European countries a disease is defined as rare when it affects fewer than 2000 people(2). Even if a small number of people are affected by a single rare condition, rare diseases are not rare, at least in aggregate: there are between 5,000 and 8,000 rare diseases(3). These pathologies are often serious, chronic, with a progressive and worsening course, and may be life-threatening. Rare diseases are also known as “orphan” diseases because the diagnosis is often very difficult or misinterpreted(4). Indeed, the presenting signs and symptoms of rare diseases could be very different for individual patients and often mimic other pathologies. The diagnosis is often missed or frustratingly slow, thereby worsening the patients’ physical and social status.
Indeed, it is well known that an early diagnosis of a disease may improve the prognosis and overall quality of life due to timely and appropriate therapies. Diagnostic imaging is usually performed and could be the most important diagnostic tool for several rare diseases. Medical imaging is crucial not only for the diagnosis, but also for therapy monitoring and even outcome prediction. Recent advances in several medical imaging techniques, such as magnetic resonance imaging (MRI), computed tomography (CT) and ultrasound (US), guarantee significant improvement in diagnosis due to improved sensitivity and tissue characterization. Most data provided by diagnostic imaging can also be immediately shared and transmitted by the radiologist to the referring physicians(5).
Rare diseases can involve all systems and organs, including the musculoskeletal system. Unfortunately, even in highly specialized environments with cutting edge resources such as genetics, many patients remain undiagnosed despite extensive medical evaluation. According to a recent study reported in the New England Journal of Medicine, the Undiagnosed Diseases Network yielded a rate of diagnosis of 35%(6). Therefore, the purpose of the present study was to assess when medical imaging plays the primary role in the diagnosis of rare musculoskeletal diseases with an emphasis on ultrasound.
The Center included an alphabetical database of 621 main rare diseases (with the main name as well as alternative names), based on the available data in the medical literature, to help patients with orphan diseases find detailed information about their conditions(1).
From September 2017 to January 2018 one junior radiologist under senior supervision (F.R. and A.T.) evaluated one by one all the 621 pathologies from the list to assess when radiology had a primary role in the diagnostic pathway. PubMed, Cochrane library, Medline (Ovid) and Orphanet databases were searched using appropriate keywords and following a strict scientific method. Different sources of information were compared. Rare diseases involving the musculoskeletal system were selected and classified based on age groups (adults, children, both adults and children) and etiologic sub-types. Further subdivision was made according to imaging modalities: magnetic resonance imaging (MRI), computerized tomography (CT), ultrasound (US), positron emission tomography (PET) and X-ray. The analysis was repeated twice to increase accuracy. A second senior radiologist (A.T.), official consultant of the Center, independently checked the list for consistency. Any discrepancies were resolved through discussion, until consensus was reached. To summarize the basic features of the obtained data, descriptive analysis was performed. Relevant US findings helpful for clinicians are systematically reported.
The first part of the research involved a selection of rare diseases that could be diagnosed with an imaging approach. Musculoskeletal pathologies were selected and a subdivision into categories was performed for each abnormality (Tab. 1).
Disease name | Diagnostic Modality | Patients’ age | Etiology |
---|---|---|---|
1. Achondroplasia | prenatal US, X-ray | Childhood | Genetic (autosomal dominant)(10) |
2. Algodystrophy | X-rays, CT, MRI | All ages | Multifactorial |
3. Buschke-Ollendorff syndrome | CT, X-ray | All ages | Genetic (autosomal dominant) |
4. Claude Bernard Horner | CT, MRI | All ages | Multifactorial |
5. CREST Syndrome | CT, X-ray | Adulthood | Multifactorial |
6. Diffuse cutaneous systemic sclerosis | X-ray, CT | Adulthood | Multifactorial |
7. Emery-Dreifuss muscular dystrophy | US, MRI | Childhood | Genetic (autosomal dominant or autosomal recessive or X-linked recessive)(11) |
8. Ewing sarcoma | X-ray, CT, MRI | Childhood | Unknown |
9. Fibrodysplasia ossificans progressiva | X-ray, CT | Childhood | Genetic (autosomal dominant) |
10. Fibrous dysplasia | X-ray, CT | Childhood | Multifactorial |
11. Focal myositis | MRI | Adulthood | Unknown |
12. Gorham-Stout syndrome | CT, MRI, X-rays | All ages | Unknown |
13. Inclusion body myositis | MRI | Adulthood | Unknown |
14. Kienbok disease | X-ray, CT, MRI | All ages | Unknown |
15. Klippel-Trenaunay-Weber syndrome | X-ray, CT, MRI | Childhood | Unknown |
16. Larsen syndrome | X-ray | Childhood | Genetic (autosomal dominant) |
17. Léri-Weill dyschondrosteosis | X-ray, CT | Childhood | Genetic (autosomal dominant) |
18. Maffucci syndrome | X-ray, CT | Childhood | Unknown |
19. McCune Albright syndrome | X-ray | Childhood | Genetic |
20. Meralgia paresthetica | MRI, US | Adulthood | Multifactorial(12) |
21. Multifocal motor neuropathy | MRI | Adulthood | Unknown |
22. Multiple osteochondromas | X-ray, CT | Childhood | Genetic (autosomal dominant) |
23. Nager syndrome | X-ray, prenatal US | Childhood | Genetic(13) |
24. Nasu-Hakola disease | MRI, X-ray, CT | All ages | Genetic (autosomal recessive) |
25. Neuralgic amyotrophy | MRI, US | Adulthood | Unknown(14,15) |
26. Neurofibromatosis type 1 | MRI | Childhood | Genetic (autosomal dominant) |
27. Osteogenesis imperfecta | MRI, X-ray, CT | All ages | Genetic (autosomal dominant or recessive) |
28. Osteopetrosis | MRI, X-ray, CT | All ages | Genetic (autosomal dominant or recessive or X-linked recessive) |
29. Paget disease | MRI | Adulthood | Unknown |
30. Peripheral neuropathy | MRI, US | All ages | Multifactorial(16) |
31. Psuedoachondroplasia | X-ray | Childhood | Genetic (autosomal dominant) |
32. Pudendal neuralgia | MRI, US | Adulthood | Multifactorial(17) |
33. SAPHO syndrome | X-ray, CT, MRI | All ages | Multifactorial |
34. Soft tissue tumor | PET, MRI, CT, US | All ages | Multifactorial(18) |
35. Tarlov cysts | MRI, CT | Adulthood | Multifactorial |
36. Tietze syndrome | X-ray, MRI, US | All ages | Unknown(19) |
US – ultrasound, MRI – magnetic resonance imaging, CT – computed tomography, PET – positron emission tomography
A total of 101/621 (16%) rare diseases can be diagnosed for the first time with medical imaging.
A total of 36/101 (36%) rare diseases involve the musculoskeletal system, including the peripheral nervous system (
Rare musculoskeletal diseases were subdivided according to the age of the affected population: 14/36 (39%) pediatric diseases, 10/36 (28%) adulthood diseases, 12/36 (33%) conditions affecting all ages. From the etiopathological point of view, the causes vary and are dominated by genetic (
A total of 23/36 (64%) of the selected rare diseases could be diagnosed with MRI, 19/36 (53%) with CT, 23/36 (64%) with X-ray exams, 9/36 (25%) with an US scan, and 1/36 (3%) with PET.
Table 2 presents the main US findings and the role of US in nine rare conditions where ultrasonography may have an important contribution to diagnosis and even treatment. These nine conditions are: achondroplasia, Emery-Dreifuss muscular dystrophy, meralgia paresthetica (Fig. 1 A, B), Nager syndrome, neuralgic amyotrophy, peripheral neuropathy (Fig. 2), pudendal neuralgia (Fig. 3), soft tissue tumor (Fig. 4), and Tietze syndrome.
Name of rare diseases according to orphanet database | Main US findings and US role | Genetic mutation |
---|---|---|
Achondroplasia and Nager syndorme | Early onset hydrocephalus, enlarged cerebellum and cisterna magna, and hydrancephaly on prenatal ultrasound | FGFR3 and SF3B4 |
Emery-Dreifuss | US identifies muscle fatty infiltration US assesses Achilles tendon | X (Xq28) |
Muscular dystrophy and neuralgic amyotrophy | US identifies muscle fatty infiltration. Homogenously increased muscle echo intensity with attenuation of the US signal. Inflammatory myopathies can show homogenously increased echogenicity. Denervation can show “moth-eaten,” atrophic muscles with fasciculation | Various |
|
Increased caliber of lateral femoral cutaneous nerve. |
None, it is an entrapment syndrome |
Peripheral neuropathy and pudendal neuralgia | Increased caliber of the nerve. |
NA |
Soft Tissue Tumor | Lump detection |
Depends on tumor sub-type |
Tietze syndrome | Swelling of the costochondral joints and calcifications Corticosteroids injection | Unknown |
A wide range of rare conditions involve the musculoskeletal system. Rare musculoskeletal diseases can arise from genetic problems in the muscles themselves, like Duchenne muscular dystrophy, while other involve the nerves (e.g. Charcot-Marie-Tooth disease) or the bones (e.g. osteogenesis imperfecta). The absence of diagnosis represents an unmet medical need. Despite innovations in the clinical management of more common diseases, up to a quarter of patients diagnosed with a rare disease can have a diagnostic delay of between 5–30 years and 95 % of rare diseases are still without specific treatments(5). The diagnosis of a rare musculoskeletal disease can be relatively rapid or slow. Some types manifest early in life with obvious and severe symptoms, while other emerge later. Patients with mild diseases might not notice any symptoms until later childhood or adulthood, delaying the diagnosis. Even if most rare conditions have congenital causes, medical imaging plays an important and primary role in the diagnostic pathway. Indeed, although the progress of molecular genetics has improved, the selection of patients to undergo expensive genetic tests is often based on clinical imaging data. To the best of our knowledge, an evaluation of the role of radiology in the diagnosis of rare musculoskeletal diseases is missing in the literature. Groft underlined the growing interest in rare diseases with the expanding role and outreach activities of patient advocacy groups that have increased public awareness and legislative interest in rare diseases(10).
In the present paper, we identified several conditions where medical imaging generally plays a crucial role in the diagnosis. In particular, we identified nine conditions where US is crucial. Prenatal ultrasound is crucial to suspect the diagnosis before birth in acondorplasia and its variants, early onset hydrocephalus, enlarged cerebellum and cisterna magna, and hydrancephaly(11). Nager syndrome, acrofacial dysostosis and temporomandibular joint disorders could be assessed with US as complementary tests(3). In the case of Emery-Drayfus sindrome, which is present in the Orphanet database, US could be used to assess skeletal muscle and soft-tissue disorders, especially at the level of the Achilles tendons(12). US is also helpful in muscular dystrophyes; indeed it is the only technique able to show fasciluations. In addition, ultrasound can identify abnormal echo intensity and size. US can be used to evaluate multiple muscles to guide not only the electrodiagnostic examination but also muscle biopsy if needed. Most muscular dystrophies show increased muscle echo intensity due to increased intramuscular fat and fibrosis(13). Homogenously increased echogenicity is typical of inflammatory myopathies, but there is lack of signal attenuation in the first phases of muscular dystrophies. In denervation, typical “moth-eaten,” atrophic muscles with fasciculations are seen(13). The use of US to assess muscles in older and obese patients is limited. In general, muscle US yields sensitivities and specificities of 67% to 100% for detecting neuromuscular disorders in children(13).
Meralgia paresthetica is the entrapment of the lateral femoral cutaneous nerve at the inguinal ligament. At US, the nerve appears hypoechoic and swollen at the inguinal ligament(14). US is helpful not only to confirm the entrapment, but is able to identify the underlying cause and guides interventional therapeutic procedure(14–16). Medical literature is full of papers dealing with peripheral nerve ultrasound for both diagnosis and treatment(8,17–20). We briefly underline that peripheral nerve US is an increasingly popular topic, with potential to detect abnormalities of the peripheral nerves even with quantitative measurements describing the internal fascicular echotexture. US can be also used to introduce the use of US as a possible quantitative imaging biomarker(19) by calculating quantitative parameters such as fascicular ratio or nerve density(19–21). The role of US in patients with a soft-tissue mass is related to lump detection, characterization, follow-up and biopsy when necessary(22). In the Tietze syndrome, an uncommon disease of unknown etiology that manifests with pain and tenderness of the parasternal joints, US can detect swelling of the costochondral joints, calcifications and guide corticosteroid injection(23).
In conclusion, medical imaging plays a primary role in the diagnosis of musculoskeletal rare diseases and should be considered as an important step in the diagnostic pathway. The presented data shows that musculoskeletal imaging could help diagnose specific rare musculoskeletal diseases, including peripheral neuropathies. Incentives for the development of preventive and validated diagnostic techniques are necessary and strongly recommended.