Figure 1
Chest conventional radiography
Large chest wall mass in the left hemithorax, with underlying rib destruction.
A large calcified mass of the chest wall in a young adolescent
SectionPaediatric radiology
Case TypeClinical Cases
AuthorsRiccardo La Macchia, Mehrak Anooshiravani
Connected authors
14 years, female
Clinical History
A 14-year-old girl presented with left shoulder pain mainly during gym lessons. She consulted a pediatrician after having pain for 6 weeks. Clinical examination suggested a thoracic mass for which a chest X-ray was performed.
Imaging Findings
The chest X-ray showed a large calcified mass of the left upper hemithorax with underlying rib destruction. The subsequent enhanced CT revealed a large calcified heterogeneous contrast-enhancing mass surrounding the region of the 3rd left rib, which seemed osteolytic, associated with an osteolytic lesion of the third dorsal vertebrae and invasion of the spinal canal. The mass seemed to spare the axillary and subclavian vessels and was supplied by an enlarged left mammary artery. A few suspected lung metastases were also detected.
MRI showed abnormal signal intensity of the left side of the 3rd dorsal vertebral body and pedicle with intraspinal extension of the mass and displacement of the spinal cord to the right. The spinal cord showed no signal abnormality.
Biopsy of the mass revealed rib osteosarcoma. Chemotherapy was then started, according to AOST-0031 protocol (high-dose methotrexate, cisplatin and doxorubicin), followed by surgery.
MRI showed abnormal signal intensity of the left side of the 3rd dorsal vertebral body and pedicle with intraspinal extension of the mass and displacement of the spinal cord to the right. The spinal cord showed no signal abnormality.
Biopsy of the mass revealed rib osteosarcoma. Chemotherapy was then started, according to AOST-0031 protocol (high-dose methotrexate, cisplatin and doxorubicin), followed by surgery.
Discussion
Osteosarcoma is defined as a primary aggressive malignant neoplasm arising from primitive transformed cells of mesenchymal origin that exhibit osteoblastic differentiation and produce malignant osteoid[1, 2, 3].
Primary osteosarcoma (as opposed to the secondary type presenting in old age) is the most common histological form of primary malignancy in adolescents. It typically originates in the metaphyseal areas of the long bones (femur, tibia and humerus). Only 3% of primary osteosarcomas involve the chest wall[4] and 34% of these rare cases occur in the ribs[5]. The first differential diagnosis for the paediatric population in this location is Ewing sarcoma, which presents no osteoid matrix as opposed to osteosarcoma.
Pathological fractures and metastatic dissemination, usually in the lungs, are the most frequent complications of osteosarcoma.
Characteristic X-ray features of osteosarcoma are lytic and sclerotic lesions, a wide zone of transition, a permeative or moth-eaten appearance, sun-burst reaction, periosteal lifting with formation of Codman's triangles in the long bones, and new bone formation in the soft tissues.
CT delineates the extraosseous and intraosseous extent of the tumour and is used to detect distant metastatic disease. The main advantage of CT is its ability to show small areas of osteoid matrix, in predominantly lytic lesions, that cannot be detected with conventional radiography or MR imaging, allowing to make a radiological differential diagnosis with tumours that most commonly affect the chest wall, such as Ewing sarcoma[6].
MRI is the most accurate tool for determining the limits of tumour within and outside the bone and it is used for local staging prior to treatment. MRI is superior to CT in the assessment of tumour extension into the spinal canal and epidural space and is crucial for surgical planning[7, 8]. Given the ability to detect necrotic areas, enhanced sequences are used in association with diffusion to judge chemotherapy response correlating with the degree of histological necrosis.
Whole body MRI as well as PET-CT are increasingly used for staging and detecting systemic dissemination of the tumour, local recurrence, and metastases after treatment.
Chemotherapy usually precedes surgery that consists of en bloc resection of the lesion, often with amputation.
The most important predictors of the outcome and survival rates are metastatic spread at the time of diagnosis, margins of resection, and the histological degree of necrosis following induction chemotherapy; a rate of more than 90% being considered as a good response to chemotherapy[9].
Primary osteosarcoma (as opposed to the secondary type presenting in old age) is the most common histological form of primary malignancy in adolescents. It typically originates in the metaphyseal areas of the long bones (femur, tibia and humerus). Only 3% of primary osteosarcomas involve the chest wall[4] and 34% of these rare cases occur in the ribs[5]. The first differential diagnosis for the paediatric population in this location is Ewing sarcoma, which presents no osteoid matrix as opposed to osteosarcoma.
Pathological fractures and metastatic dissemination, usually in the lungs, are the most frequent complications of osteosarcoma.
Characteristic X-ray features of osteosarcoma are lytic and sclerotic lesions, a wide zone of transition, a permeative or moth-eaten appearance, sun-burst reaction, periosteal lifting with formation of Codman's triangles in the long bones, and new bone formation in the soft tissues.
CT delineates the extraosseous and intraosseous extent of the tumour and is used to detect distant metastatic disease. The main advantage of CT is its ability to show small areas of osteoid matrix, in predominantly lytic lesions, that cannot be detected with conventional radiography or MR imaging, allowing to make a radiological differential diagnosis with tumours that most commonly affect the chest wall, such as Ewing sarcoma[6].
MRI is the most accurate tool for determining the limits of tumour within and outside the bone and it is used for local staging prior to treatment. MRI is superior to CT in the assessment of tumour extension into the spinal canal and epidural space and is crucial for surgical planning[7, 8]. Given the ability to detect necrotic areas, enhanced sequences are used in association with diffusion to judge chemotherapy response correlating with the degree of histological necrosis.
Whole body MRI as well as PET-CT are increasingly used for staging and detecting systemic dissemination of the tumour, local recurrence, and metastases after treatment.
Chemotherapy usually precedes surgery that consists of en bloc resection of the lesion, often with amputation.
The most important predictors of the outcome and survival rates are metastatic spread at the time of diagnosis, margins of resection, and the histological degree of necrosis following induction chemotherapy; a rate of more than 90% being considered as a good response to chemotherapy[9].
Differential Diagnosis List
Rib osteosarcoma
Ewing sarcoma and primitive neuroectodermal tumors
Telangiectatic osteosarcoma
Intraosseous hemangioma
Final Diagnosis
Rib osteosarcoma
References
[1] Rosenberg AE. Robins and cotran (2010) pathologic basis of disease. 8th ed. Philadelphia: WB Saunders Bone, joints and soft tissue tumors; pp. 1203–56.
[2] Fletcher CDM, Bridge JA, Hogendoorn PCW, Mertens F (2013) World Health Organization, classification of tumours: Pathology and genetics of tumors of soft tissue and bone. Lyon: IARC Press
[3] Wold LE, Adler CP, Sim FH, Unni KK (2003) Atlas of orthopaedic pathology. 2nd ed. Philadelphia-London: Saunders pp. 179–85
[4] Burt M, Fulton M, Wessner-Dunlap S, Karpeh M, Huvos AG, Bains MS, et al. (1992) Primary bony and cartilaginous sarcomas of chest wall: results of therapy. Ann Thorac Surg 54:226-32. (PMID: 1637209)
[5] Meyers PA, Gorlick R. (1997) Osteosarcoma. Pediatr Clin North Am 44:973-89 (PMID: 9286295)
[6] Murphey MD, Robbin MR, Mcrae GA et-al. The many faces of osteosarcoma. Radiographics 17 (5): 1205-31. (PMID: 9308111)
[7] Sundaram M, McGuire MH, Herbold DR (1987) Magnetic resonance imaging of osteosarcoma. Skeletal Radiol 16(1):23-9 (PMID: 3469764)
[8] Green R, Saifuddin A, Cannon S. (1996) Pictorial review: imaging of primary osteosarcoma of the spine. Clinical Radiology 51: 325-329 (PMID: 8641093)
[9] Picci P, Sangiorgi L, Rougraff BT et-al. (1995) Relationship of chemotherapy-induced necrosis and surgical margins to local recurrence in osteosarcoma. J. Clin. Oncol 12 (12): 2699-705. (PMID: 7989947)
Case information
| URL: | https://eurorad.org/case/14453 |
| DOI: | 10.1594/EURORAD/CASE.14453 |
| ISSN: | 1563-4086 |
License
This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.
Figure 2
Contrast enhanced chest CT scan
An enhanced CT examination of the chest showing a large heterogenously solid mass arising from the skeletal chest wall with lytic destruction of the rib and coarse calcifications.
Figure 3
Spinal canal axial T2 MRI sequence
T2 MRI sequence shows spinal canal and left transverse foramen of D3 invasion, without abnormal signal nor invasion of the spine.
Chest conventional radiography
Large chest wall mass in the left hemithorax, with underlying rib destruction.
Département of Radiology, HUG, Geneva, Switzerland
Département of Radiology, HUG, Geneva, Switzerland
Contrast enhanced chest CT scan
An enhanced CT examination of the chest showing a large heterogenously solid mass arising from the skeletal chest wall with lytic destruction of the rib and coarse calcifications.
Department of radiology, HUG, Geneva,Switzerland.
Department of radiology, HUG, Geneva,Switzerland.
Spinal canal axial T2 MRI sequence
T2 MRI sequence shows spinal canal and left transverse foramen of D3 invasion, without abnormal signal nor invasion of the spine.
Department of radiology, HUG, Geneva,Switzerland
Department of radiology, HUG, Geneva,Switzerland