Abstract
Objectives: Development a giant cell tumor model arising from the mutated mesenchymal cells present in its stroma. This establishes the pathogenic mechanism of giant cell tumor, and allows the evaluation of the possible role of biphosphonates and retinoic acid in medical therapy of giant cell tumor of bone.
Introduction: In previous studies our group has shown that mesenchymal stroma contains mesenchymal cells capable of recruiting osteoclasts, and lacking capacity to undergo osteoblastic differentiation. These cells represent the actual neoplastic component of the tumor. In the current study, an attempt was made to establish a giant cell tumor in an animal model by injection of these cells.
Methods: 6 Balb/C named mice were used. The mice were kept in a laminar flow hood and injected when they were 4 weeks old. The injection was in an intra-osseous location into the distal femur. The cell inoculum consisted of 1 million stromal cells. The cells were derived from a grade III giant cell tumor occurring in the hip joint of a 30 years old woman. The mice were kept for 2 months and than sacrificed.
Results: A lytic lesion similar to that occurring in humans developed. The tumor consisted of stromal cells with interspersed osteoclasts. These were identified as being of host origin by mice-specific monoclonal antibodies. The tumor penetrated the cortex but did not infiltrate the articular cartilage. Metastases were not observed.
Discussion: Giant cell tumor of bone is typified by osteolytic bone destruction mediated by osteoclasts. In previous studies, our group has shown that the proliferation rate of the stromal component correlates closely with prognosis and grade of the tumor. The stromal component was shown to consist of pre-osteoblasts that fail to differentiate into osteoblasts, but instead recruit giant cells (osteoclasts), mediating bone destruction. Addition of retinoic acid in culture induces osteoblastogenesis cells by blocking AP-1. The current study confirms in an animal model that indeed the stromal cells are capable of osteoclast recruitment and bone destruction. This animal model might allow development of medical remedies to this tumor.
The abstracts were prepared by Orah Naor. Correspondence should be addressed to him at the Israel Orthopaedic Association, PO Box 7845, Haifa 31074, Israel.
