Throughout life, human bone is renewed continuously in a tightly controlled sequence of resorption and formation. This process of bone remodeling is remarkable because it involves cells from different lineages, collaborating in so-called basic multicellular units (BMUs) within small spatial and temporal boundaries. Moreover, the newly formed (secondary) osteons are aligned to the dominant load direction and have a density related to its magnitude, thus creating a globally optimized mechanical structure. Although the existence of BMUs is amply described, the cellular mechanisms driving bone remodeling-particularly the alignment process-are poorly understood. In this study we present a theory that explains bone remodelling as a self-organizing process of mechanical adaptation.
The intracellular localization of calcium in the saccus vasculosus of the rainbow trout, Salmo gairdneri Richardson, was studied by means of ultracytochemical and X-ray microanalytical techniques. Using a variant of the glutaraldehyde/potassium pyroantimonate-osmium tetroxide method, Ca was detected in mitochondria, smooth endoplasmic reticulum and primary vesicles of coronet cells, and in mitochondria and smooth endoplasmic reticulum of tanycytes. Mitochondria and smooth endoplasmic reticulum in both cell types are considered as general Ca-stores. The primary vesicles in the ciliary globules of coronet cells are viewed as additional Ca-reservoirs. Possible roles of these Ca-stores in the regulation of transport activities of coronet cells in the homeostasis of the CSF are discussed.
Mechanical stimulation by intermittent compressive force (ICF) stimulates bone formation and inhibits bone resorption in cultured fetal mouse bone. Fetal bone tissue can produce autocrine factors that stimulate bone cell replication and matrix formation, and paracrine factors that increase the formation of osteoclast precursor-like cells from bone marrow. In the present study, we have tested whether ICF affects the production of such local factors in fetal mouse calvariae. Calvariae were cultured for 4 days in the presence and absence of ICF (130 mbar, 0.3 Hz). Conditioned medium was collected daily and pooled. We found that conditioned medium from ICF-exposed cultures stimulated [3H]-TdR incorporation into DNA, and [3H]-proline incorporation into collagenase digestible protein but not into non-collagen protein in fresh calvarial cultures. Treatment with conditioned medium from ICF-exposed cultures had earlier effects on [3H]-TdR and [3H]-proline incorporation than direct treatment with ICF. Conditioned medium from ICF-exposed cultures decreased the number of osteoclast precursor-like cells in bone marrow cultures stained for tartrate-resistant acid phosphatase. We conclude that ICF stimulates the release (activity) of an autocrine growth-factor from bone. In addition, ICF can stimulate the release (activity) of a paracrine factor, inhibiting the growth and/or differentiation of osteoclast precursor-like cells. These data suggest that mechanical forces may modulate skeletal (re)modeling by affecting the production of local growth factors.
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