CASE-CONTROL STUDY OF CHILDHOOD CANCER AND EXPOSURE TO 60-HZ MAGNETIC FIELDS

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American Journal of Epidemiology Vol. 128, No. 1: 21-38
Copyright © 1988 by The Johns Hopkins University School of Hygiene and Public Health

research-article

CASE-CONTROL STUDY OF CHILDHOOD CANCER AND EXPOSURE TO 60-HZ MAGNETIC FIELDS

DAVID A. SAVITZ¹, HOWARD WACHTEL², FRANK A. BARNES², ESTHER M. JOHN¹ and JIRI G. TVRDIK³

¹Department of Epidemiology, School of Public Health, and the Carolina Population Center, University of North Carolina Chapel Hill, NC
²Department of Electrical and Computer Engineering, University of Colorado Boulder, CO
³Council of Energy Resource Tribes Denver, CO

Reprint requests to Dr. David A. Savitz, Department of Epidemiology, Campus Box #7400, Rosenau Hall, School of Public Health, University of North Carolina, Chapel Hill, NC 27599

Concern with health effects of extremely low frequency magneticfields has been raised by epidemiologic studies of childhoodcancer in relation to proximity to electric power distributionlines. This case-control study was designed to assess the relationbetween residential exposure to magnetic fields and the developmentof childhood cancer. Eligible cases consisted of all 356 residentsof the five-county 1970 Denver, Colorado Standard MetropolitanStatistical Area aged 0–14 years who were diagnosed withany form of cancer between 1976 and 1983. Controls were selectedby random digit dialing to approximate the case distributionby age, sex, and telephone exchange area. Exposure was characterizedthrough in-home electric and magnetic field measurements underlow and high power use conditions and wire configuration codes,a surrogate measure of long-term magnetic field levels. Measuredmagnetic fields under low power use conditions had a modestassociation with cancer incidence; a cutoff score of 2.0 milligaussresulted in an odds ratio of 1.4 (95% confidence interval (CI)= 0.6– 2.9) for total cancers and somewhat larger oddsratios (ORs) for leukemias (OR = 1.9), lymphomas (OR = 2.2),and soft tissue sarcomas (OR = 3.3). Neither magnetic fields(OR = 1.0) nor electric fields (OR = 0.9) under high power useconditions were related to total cancers. Wire codes associatedwith higher magnetic fields were more common among case thancontrol homes. The odds ratio to contrast very high and highto very low, low, and buried wire codes was 1.5 (95% Cl = 1.0–2.3)for total cases, with consistency across cancer subgroups exceptfor brain cancer (OR = 2.0) and lymphomas (OR = 0.8). Contrastsof very high to buried wire code homes produced larger, lessprecise odds ratios of 2.3 for total cases, 2.9 for leukemias,and 3.3 for lymphomas. Adjusted estimates for measured fieldsand wire codes did not differ from crude results, indicatingan absence of confounding. Limitations to the study are nonresponse(especially for field measurements), differential mobility ofcases and controls, and a presumably nondifferential exposuremisclassification from the use of imperfect surrogates for long-termmagnetic field exposure history. In spite of these concerns,the results encourage further examination of the carcinogenicpotential from this form of nonionizing radiation.

brain neoplasms; child; electromagnetic fields; leukemia

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