Cancer and Power Lines

APR 01, 1994

Do the all‐pervasive low‐frequency electromagnetic fields of modern life threaten our health? Most probably not, judging from comparisons with the natural fields present in the environment and in our bodies.

DOI: 10.1063/1.881417

William R. Bennett

Epidemiologists in Denver, Los Angeles and Sweden are asking us to believe that magnetic fields of 2 milligauss from power distribution lines are a serious cause of childhood leukemia. What started as a series of sensational articles in The New Yorker magazine by Paul Brodeur (later collected into a book), bringing the earliest of these studies to the attention of the general public, has turned into a new growth industry. Several government agencies, not to mention the private electric power industry, have already sponsored multimillion‐dollar studies of the problem; a number of small companies selling 60‐Hz gaussmeters have sprung into existence and are doing a land‐office business; and the public concern over this issue has become a bonanza to groups of people doing epidemiological and biological research on the effects of electromagnetic fields. Hastily contrived legislation in a number of states has legalized the status quo for fields from power lines, and the threat of still more ill‐thought‐out legislation is on the horizon—mandating, for example, warning labels on toaster ovens and television sets similar to those now found on cigarettes.

This article is only available in PDF format

References

1. N. Wertheimer, E. Leeper, Am. J. Epidemiol. 109, 273 (1979). https://doi.org/AJEPAS
D. A. Savitz et al., Am. J. Epidemiol. 131, 763 (1990). https://doi.org/AJEPAS
S. J. London et al., Am. J. Epidemiol. 134, 923 (1991). https://doi.org/AJEPAS
L. Tomenius, Bioelectromagnetics 7, 191 (1986).
M. Fechting, A. Ahlbom, Magnetic Fields and Cancer in People Residing near Swedish High‐Voltage Power Lines, IMM report 8/92, Karolinska Inst., Stockholm, Sweden (1992).
G. Floderus et al. Occupational Exposure to Electromagnetic Fields in Relation to Leukemia and Brain Tumors: A Case Control Study, Natl. Inst. Occupational Health, Solna, Sweden (1992).
2. P. Brodeur, Currents of Death, Simon and Schuster, New York (1989).
See also P. Brodeur, The New Yorker, 7 December 1992, p. 86. But also see E. R. Adair, “Currents of Death Rectified: A Paper Commissioned by the IEEE‐USA Committee on Man and Radiation in Response to the Book by Paul Brodeur,” IEEE‐USA, New York (1991).
3. J. G. Davis et al., Science 260, 13 (1993). https://doi.org/SCIEAS
C. Pool, D. Trichopoulos, Cancer Causes Control 2, 267 (1991).
D. Trichopoulos, in Health Effects of Low‐Frequency Electromagnetic Fields, Oak Ridge Associated Universities, Oak Ridge, Tenn., (1992)
p. VI.
4. W. R. Bennett Jr, Health and Low Frequency Electromagnetic Fields, Yale U.P., New Haven, Conn. (1994).
5. R. K. Adair, Bioelectromagnetics 14, 1 (1993).
6. J. L. Kirschvink, J. Exp. Biol. 92, 333 (1981).https://doi.org/JEBIAM
7. CRC Handbook of Biological Ef fects of Electromagnetic Fields, C. Polk, E. Rostow, eds., Chemical Rubber P., Boca Raton, Fla. (1986).
8. C. A. L. Bassett, N. Calo, J. Kort, Clin. Orthop. Related Res. 154, 136 (1981).
R. A. Luben, C. D. Cain, M. C.‐Y. Chen, D. M. Rosen, W. R. Adey, Proc. Natl. Acad. Sci. USA 79, 4180 (1982). https://doi.org/PNASA6
R. K. Aaron, D. M. Ciombor, G. Jolly, J. Bone Mineral Res. 4, 227 (1989).
9. H. P. Schwan, Ann. Biomed. Eng. 16, 245 (1988).https://doi.org/ABMECF
10. F. N. Netterer et al., in Heart, F. F. Yonkman, ed., CIBA, Summit, N.J. (1978), pp. 15, 48. R. Plonsey, Bioelectric Phenomena, McGraw‐Hill, New York (1969).
11. J. B. Johnson, Phys. Rev. 32, 97 (1928).https://doi.org/PHRVAO
12. H. Nyquist, Phys. Rev. 32, 110 (1928).https://doi.org/PHRVAO
13. See, for example, W. R. Bennett, Electrical Noise, McGraw‐Hill, New York (1960).
14. R. K. Adair, Phys. Rev. A 43, 1039 (1991).https://doi.org/PLRAAN
15. J. C. Weaver, R. D. Astumian, Bioelectromagnetics Suppl. 1, 119 (1992).
16. W. R. Loewenstein, Ann. N. Y. Acad. Sci. 137, 441 (1966). https://doi.org/ANYAA9
M. V. L. Bennett, M. E. Spira, G. O. Pappas, Dev. Biol. 29, 419 (1972). https://doi.org/DEBIAO
J. Neyton, A. Trautmann, Nature 317, 331 (1985).https://doi.org/NATUAS
17. K. R. Foster, H. P. Schwan, CRC Crit. Rev. Biomed. Eng. 17, 25 (1989).
18. C. F. Blackman et al., Radiation Res. 92, 510 (1982). https://doi.org/RAREAE
C. F. Blackman et al., Bioelectromagnetics 6, 1 (1985);
C. F. Blackman, 9, 215 (1988)
C. F. Blackman, 11, 159 (1990).
19. A. R. Liboff et al., J. Bioelectricity 8, 12 (1987).
B. R. McCleod et al., J. Bioelectricity 6, 1 (1987).
B. R. McCleod, S. D. Smith, A. R. Liboff, J. Bioelectricity 6, 153 (1987).
S. D. Smith et al., Bioelectromagnetics 8, 215 (1987).
A. R. Liboff, B. R. McCleod, S. D. Smith, U.S. patent 5 077 934, 7 January 1992.
20. V. V. Lednev, Bioelectromagnetics 12, 71 (1991).
21. R. K. Adair, Bioelectromagnetics 13, 231 (1992).
22. L. A. Couton, A. T. Barker, Phys. Med. Biol. 38, 347 (1993).https://doi.org/PHMBA7

More about the Authors

William R. Bennett. Yale University.