Potassium ion influx measurements on cultured Chinese hamster cells exposed to 60‐Hertz electromagnetic fields

Abstract

Potassium ion influx was measured by monitoring ⁴²KCI uptake by Chinese hamster ovary (CHO) cells grown in suspension culture and exposed in the culture medium to 60–Hz electromagnetic fields up to 2.85 V/m. In the presence of the field CHO cells exhibited two components of uptake, the same as previously observed for those grown under normal conditions; both these components of influx were decreased when compared to sham‐exposed cells. Although decreases were consistently observed in exposed cells when plotted as log_c of uptake, the differences between the means of the calculated fluxes of exposed and sham‐exposed cells were quite small (on the order of 4–7%). When standard deviations were calculated, there was no significant difference between these means; however, when time‐paired uptake data were analyzed, the differences were found to be statistically significant. Cells exposed only to the magnetic field exhibited similar small decreases in influx rates when compared to sham‐exposed cells, suggesting that the reduction in K⁺ uptake could be attributed to the magnetic field. Additionally, intracellular K⁺ levels were measured over a prolonged exposure period (96 h), and no apparent differences in intracellular K⁺ levels were observed between field‐exposed and shamexposed cultures. These results indicate that high‐strength electric fields have a small effect on the rate of transport of potassium ions but no effect on long‐term maintenance of intracellular K⁺.