Amelioration of oxygen‐induced osteoporosis in the in vitro fetal rat tibia with a capacitively coupled electrical field

Abstract

Near-term fetal rat tibiae were grown in M.E.M. Eagle/NCTC 135/15% newborn calf serum in 5% carbon dioxide and 5, 10, 21, 35, 60, and 90% oxygen for 3, 7, 10, and 14 days. Linear growth of the explants, as measured from macrophotographs of the explants at day zero and each of the days above, was greastest in the lower oxygen concentrations and least in the days above, was greastest in the lower oxygen concentration and least in the higher oxygen concentrations. Breaking strengths of the tibial diaphyses were signigicantly reduced in those explants grown in 60 and 90% oxygen. When the fetal rat tibiae were grown in 60% oxygen for 7 days and were subjected to a capacitively coupled electrical signal (sine wave, 60 kHz, 10 V peak-to-peak output signal; current density and field in the culture dish calculated to be 5.2 μA/ cm² and 0.32 mV/cm, respectively), the breaking strengths and middiaphyseal widths were statistically significantly greater than control tibiae grown in 60% oxygen alone. It is concluded that an appropriate capacitively coupled elecmalian long bone model.