Abstract
There were 44 freshly excised adult rat femora subjected to mechanical deformation in a 4-point bending jig while the load/deformation curves and the electrical potentials generated were recorded simultaneously. Serial testing was repeated after storage of specimens up to 30 days at 25°C and −15°, and after heating for 1 h at 70°, 80°, and 85°C. The amplitude of the potential decreased shortly after the femora had been excised until, by 4–7 days, it reached a plateau which was 10–20% of the initial value. In some cases polarity reversal occurred. These changes were not prevented by freezing or drying nor were they accompanied by increased stiffness. It is presumed that they are related to more subtle changes in the mechanical properties of bone or to alterations inthe generating or conducting mechanisms. Heating caused a significant increase in potential without a change in the waveform. A corresponding increase in the deformation occurred due to sofening of the bone which could, in itself, be responsible for the increased potential without a basic alteration in the transducer mechanism.
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References
Anderson, J. C., Eriksson, C.: Piezoelectric properties of dry and wet bone. Nature (Lond.)227, 491–492 (1970)
Bassett, C. A. L.: Electrical effects in bone. Sci. Amer.213, 18–25 (1965)
Bassett, C. A. L., Becker, R. O.: Generation of electric potentials by bone in response to mechanical stress. Science127, 1063–1064 (1962)
Bonar, L. C., Glimcher, M. J.: Thermal denaturation of mineralized and demineralized bone collagens. J. Ultrastruct. Res.32, 545–548 (1970)
Cochran, G. V. B., Pawluck, R. J., Bassett, C. A. L.: Electromechanical characteristics of bone under physiologic moisture conditions. Clin. Orthop.58, 249–270 (1968)
Dwyer, N. St. J. P., Matthews, B.: The electrical repsonse to stress in dried, recently excised, and living bone. Injury1, 279–286 (1970)
Fukada, E., Yasuda, I.: On the piezoelectric effect in bone. J. Phys. Soc., Japan12, 1158–1162 (1957)
Shamos, M. H.: Physical basis for bioelectric effects in mineralized tissues. Clin. Orthop.35, 177–188 (1964)
Steinberg, M. E., Bosch, A., Schwan, a. J., Jr., Glazer, R. M.: Electrical potentials in stressed bone. Clin. Orthop.61, 294–299 (1968)
Steinberg, M. E., Busenkell, G. L., Black, J., Korostoff, E.: Stress-induced potentials in moist bonein vitro. J. Bone Jt. Surg. A56, 704–713 (1974)
Steinberg, M. E., Wert, R. E., Korostoff, E., Black, J.: Deformation potentials in whole bone. J. surg. Res.14, 254–259 (1973)
Winston, P. W., Bates, D. H.: Saturated solutions for the control of humidity in biological research. Ecology41, 232–237 (1960)
Yasuda, I.: J. Jap. Orthop. Surg. Soc.28, 268 (1954)
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Steinberg, M.E., Finnegan, W.J., Labosky, D.A. et al. Temporal and thermal effects on deformation potentials in bone. Calc. Tis Res. 21, 135–144 (1976). https://doi.org/10.1007/BF02547390
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DOI: https://doi.org/10.1007/BF02547390