Biological responses to electromagnetic fields 1

Electrification in developed countries has progressively increased the mean level of extremely low‐frequency electromagnetic fields (ELF‐EMFs) to which populations are exposed; these humanmade fields are substantially above the naturally occurring ambient electric and magnetic fields of ~10‐3 Vm‐1 and ~10‐13 T, respectively. Several epidemiological studies have concluded that ELF‐EMFs may be linked to an increased risk of cancer, particularly childhood leukemia. These observations have been reinforced by cellular studies reporting EMF‐induced effects on biological systems, most notably on the activity of components of the pathways that regulate cell proliferation. However, the limited number of attempts to directly replicate these experimental findings have been almost uniformly unsuccessful, and no EMF‐induced biological response has yet been replicated in independent laboratories. Many of the most well‐defined effects have come from gene expression studies; several attempts have been made recently to repeat these key findings. This review analyses these studies and summarizes other reports of major cellular responses to EMFs and the published attempts at replication. The opening sections discuss quantitative aspects of exposure to EMFs and the incidence of cancers that have been correlated with such fields. The concluding section considers the problems that confront research in this area and suggests feasible strategies.—Lacy‐hulbert, A., Metcalfe, J. C., Hesketh, R. Biological responses to electromagnetic fields. FASEB J. 12, 395–420 (1998)

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