Differential development of the distal and proximal femoral epiphysis and physis in mice

HA Cole, M Yuasa, G Hawley, JMM Cates, JS Nyman… - Bone, 2013 - Elsevier
HA Cole, M Yuasa, G Hawley, JMM Cates, JS Nyman, JG Schoenecker
Bone, 2013Elsevier
Many pathologic conditions of hip development result from aberrant vascularity with
subsequent effects on physeal resorption and epiphyseal fusion. To elucidate the
mechanisms of these developmental disorders, researchers have mainly focused on larger
mammals as they have been well characterized and are known to provide a model similar to
humans in which a secondary ossification center is formed through an independent blood
supply followed by physeal resorption. Murine models of hip development, however, have …
Many pathologic conditions of hip development result from aberrant vascularity with subsequent effects on physeal resorption and epiphyseal fusion. To elucidate the mechanisms of these developmental disorders, researchers have mainly focused on larger mammals as they have been well characterized and are known to provide a model similar to humans in which a secondary ossification center is formed through an independent blood supply followed by physeal resorption. Murine models of hip development, however, have never been characterized as it was previously assumed that all physes in rodents never resorb and therefore not suitable as a model of the human condition. The purpose of this study was to determine if murine hip development was comparable to humans as laboratory mice provide an ideal model in which genetic knockouts are readily available with a short developmental time span. Here we show for the first time the unique developmental patterns of the murine hip in which a secondary ossification center never develops. Instead, the epiphysis undergoes a prolonged phase of mineralization through chondrocyte, not osteoblast, dependent mechanisms. After skeletal growth, transphyseal vessels develop from the metaphysis resulting in resorption of the physis, ossification of the mineralized cartilage of the epiphysis, and epiphyseal fusion. Although the development of the murine hip is markedly different from that in humans, we believe that these findings have direct implications for studying the vascularity of developing bone, particularly during physeal resorption, chondrocyte-mediated mineralization and more importantly, developmental diseases of the human physis and epiphysis.
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