Histochemical evidence of the initial chondrogenesis and osteogenesis in the periosteum of a rib fractured model: Implications of osteocyte involvement in periosteal chondrogenesis

Abstract We have examined cellular events at the early stages of periosteal chondrogenesis and osteogenesis induced by bone fracture, using a well‐standardized rib fracture model of the mouse. The initial cellular event was recognized as considerable proliferation in the deeper layer referred to as the “cambium layer” of the periosteum, as evidenced by numerous proliferating cell nuclear antigen‐positive cells. The periosteal cartilage and bone were then regenerated directly from the region of the most‐differentiated cell, i.e., mature osteoblasts of the cambium layer both close to and distant from the fracture site. Therefore, periosteal osteoblasts appeared to have the potential to differentiate into chondrogenic and osteoblastic lineages. CD31‐positive blood vessels were uniformly localized along the periosteum that was regenerating cartilage and bone, being therefore indicative of less influence on the initiation of osteochondrogenesis. In contrast, however, the regenerated periosteal cartilage or bone extended from the cortical bones included dead or living osteocytes, respectively. Empty lacunae and lacunae embedded with amorphous materials were found close to the regenerated cartilage, while intact osteocytes persisted adjacent to the regenerated bone. The embedded lacunae with amorphous materials would render the tissue fluid, nutrients, oxygen, and several secretory factors such as dentin matrix protein‐1 impossible to be delivered to the periosteal osteoblasts that interconnect osteocytes via gap junctions. Our study thus provides two major clues on initial cellular events in response to bone fracture: the potentiality of periosteal osteoblastic differentiation into a chondrogenic lineage, and a putative involvement of osteocytes in periosteal cartilage and bone regeneration. Microsc. Res. Tech. 64:330–342, 2004. © 2004 Wiley‐Liss, Inc.