Prediction of Bone Cell Probability Distribution in Weak Electromagnetic Fields
Abstract
Electromagnetic field (EMF) effects on the cell
membrane level, general and specific gene expression and signal
pathways of bone cells have been examined in numerous studies.
These studies were conducted on bioprocesses such as cell
proliferation, cell cycle regulation, cell differentiation, and
metabolism. Genotoxic effects and apoptosis were observed during
in vitro experiments. However, several observations after EMF
exposure have been irreproducible and contradictory with other
studies. Especially, statistic insignificance of EMF effects in
bioprocesses occurred when comparing the exposure group with the
control. Corresponding to the inconsistent observations, the
types of EMF apparatus in vitro are various in parameters. In
this thesis, the biological effects of EMFs on osteoblasts and
osteoclasts were examined in the exposure of the static magnetic
field (SMF) and pulsed electromagnetic field (PEMF). At the
preliminary study, the nonlinear dose-response relationship was
observed between the intensity of EMF exposure and cell
proliferation of osteoblasts. A hypothesis was proposed for
seeking the interpretation of nonlinearity by the principle of
interference on cell probability. Several frameworks were
formulated for building a theoretical structure of the
hypothesis. The verification of the hypothesis was rooted in
experimental designs. Two gradients of SMFs were applied to
osteoblastic Saos-2 cells, and the biological data represented
the interference on cell probability. The interference was also
found in the cell probability of osteoblasts when they were
affected by PEMFs. The similar results were reproduced at the
co-culture of osteoblasts and osteoclasts in SMFs and PEMFs,
which resulted in a unique entanglement of cells.
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