Chondroblastoma

Chondroblastoma is a rare, benign, locally aggressive bone tumor that typically affects the epiphyses or apophyses of long bones. It is thought to arise from an outgrowth of immature cartilage cells (chondroblasts) from secondary ossification centers, originating from the epiphyseal plate or some remnant of it. Chondroblastoma is a rare, benign, locally aggressive bone tumor that typically affects the epiphyses or apophyses of long bones. It is thought to arise from an outgrowth of immature cartilage cells (chondroblasts) from secondary ossification centers, originating from the epiphyseal plate or some remnant of it. Chondroblastoma is very uncommon, accounting for only 1-2% of all bone tumors. It affects mostly children and young adults with most patients being in the second decade of life, or less than 20 years of age. Chondroblastoma shows a predilection towards the male sex, with a ratio of male to female patients of 2:1. The most commonly affected site is the femur, followed by the humerus and tibia. Less commonly affected sites include the talus and calcaneus of the foot and flat bones. The most common symptom is mild to severe pain that is gradually progressive in the affected region and may be initially attributed to a minor injury or sports-related injury. Pain may be present for several weeks, months, or years. Other symptoms in order of most common to least commonly observed include swelling, a limp (when affected bone is in the lower extremity), joint stiffness, and a soft tissue mass. Physical findings include localized tenderness and a decreased range of motion in the involved bone and nearby joint, muscle atrophy, a palpable mass, soft tissue swelling, and joint effusion in the affected area. Less commonly, pathological fractures can be found, especially in cases involving the foot. In cases involving the temporal bone, tinnitus, dizziness, and hearing loss have been reported. In a publication by Turcotte et al. it was found that the average duration of symptoms for patients with chondroblastoma was about 20 months, ranging from 5 weeks to 16 years. Currently, the genetic or environmental factors that predispose an individual for chondroblastoma are not well known or understood. Chondroblastoma affects males more often than females at a ratio of 2:1 in most clinical reports. Furthermore, it is most often observed in young patients that are skeletally immature, with most cases diagnosed in the second decade of life. Approximately 92% of patients presenting with chondroblastoma are younger than 30 years. There is no indication of a racial predilection for chondroblastoma. The etiology of chondroblastoma is uncertain, as there is no specific characteristic abnormality or chromosomal breaking point observed, despite cytogenetic abnormalities being highly specific for some tumors. Romeo et al has noted that chondroblastoma arising in long bones mainly affects the epiphyses, while in other locations it is close to ossification centers. Additionally, rare prevalence of chondroblastoma in intra-membranous ossification suggests a close relationship with growth plate cartilage. In chondroblastoma, growth signaling molecules may be present due to the pre-pubertal signaling network as well as cartilage growth. Sex hormones are thought to be linked to this process because of the spatial relationship of chondroblastoma with the growth plate and its typical occurrence before growth plate fusion. Both Indian Hedgehog/Parathyroid Hormone-related Protein (IHh/PtHrP) and fibroblast growth factor (FGF) signaling pathways, important for development of the epiphyseal growth plate, are active in chondroblastoma leading to greater proliferation among the cells in the proliferating/pre-hypertrophic zone (cellular-rich area) versus the hypertrophic/calcifying zone (matrix-rich area). These findings suggest that chondroblastoma is derived from a mesenchymal cell undergoing chondrogenesis via active growth-plate signaling pathways (see Endochondral ossification). The highly heterogeneous nature of the tumor makes classification particularly difficult especially considering the origins of chondroblastoma. There are two opposing views on the nature of chondroblastoma, one favoring an osseous origin and the other favoring a cartilaginous origin. The work of Aigner et al suggests that chondroblastoma should be reclassified as a bone-forming neoplasm versus a cartilaginous neoplasm due to the presence of osteoid matrix, type I collagen, and absence of true cartilage matrix (collagen II). However, Edel et al found that collagen II, a marker for mature chondrocytes, was expressed in chondroblastoma, supporting the chondroid nature of the neoplasm. The results of Romeo and colleagues favor the view of Edel et al of chondroblastoma being cartilaginous in nature but recognize that any definitive determinations regarding the origin of this neoplasm are not possible because of the plasticity of mesenchymal cells when set into different microenvironments and static approaches used in literature. Romeo et al have observed chondroblastoma neoplasms to be composed of mesenchymal cells that have completed normal chondrogenesis along with the production of osteoid and collagen I that could be the result of transdifferentiation of chondrocytes towards osteoblasts.