Hypothesis: the risk of childhood leukemia is related to combinations of power-frequency and static magnetic fields.

We present a hypothesis that the risk of childhood leukemia is related to exposure to specific combinations of static and extremely-low-frequency (ELF) magnetic fields. Laboratory data from calcium efflux and diatom mobility experiments were used with the gyromagnetic equation to predict combinations of 60 Hz and static magnetic fields hypothesized to enhance leukemia risk. The laboratory data predicted 19 bands of the static field magnitude with a bandwidth of 9.1 microT that, together with 60 Hz magnetic fields, are expected to have biological activity. We then assessed the association between this exposure metric and childhood leukemia using data from a case-control study in Los Angeles County. ELF and static magnetic fields were measured in the bedrooms of 124 cases determined from a tumor registry and 99 controls drawn from friends and random digit dialing. Among these subjects, 26 cases and 20 controls were exposed to static magnetic fields lying in the predicted bands of biological activity centered at 38.0 microT and 50.6 microT. Although no association was found for childhood leukemia in relation to measured ELF or static magnetic fields alone, an increasing trend of leukemia risk with measured ELF fields was found for subjects within these static field bands (P for trend = 0.041). The odds ratio (OR) was 3.3 [95% confidence interval (CI) = 0.4-30.5] for subjects exposed to static fields within the derived bands and to ELF magnetic field above 0.30 microT (compared to subjects exposed to static fields outside the bands and ELF magnetic fields below 0.07 microT). When the 60 Hz magnetic fields were assessed according to the Wertheimer-Leeper code for wiring configurations, leukemia risks were again greater with the hypothesized exposure conditions (OR = 9.2 for very high current configurations within the static field bands; 95% CI = 1.3-64.6). Although the risk estimates are based on limited magnetic field measurements for a small number of subjects, these findings suggest that the risk of childhood leukemia may be related to the combined effects of the static and ELF magnetic fields. Further tests of the hypothesis are proposed.

[1]  C. Blackman,et al.  Clarification and application of an ion parametric resonance model for magnetic field interactions with biological systems. , 1994, Bioelectromagnetics.

[2]  Adair,et al.  Constraints on biological effects of weak extremely-low-frequency electromagnetic fields. , 1991, Physical review. A, Atomic, molecular, and optical physics.

[3]  H. Wachtel,et al.  Case-control study of childhood cancer and exposure to 60-Hz magnetic fields. , 1988, American journal of epidemiology.

[4]  T. Litovitz,et al.  Amplitude windows and transiently augmented transcription from exposure to electromagnetic fields. , 1990, Bioelectromagnetics.

[5]  J. R. Thomas,et al.  Low-intensity magnetic fields alter operant behavior in rats. , 1986, Bioelectromagnetics.

[6]  Durward D. Skiles,et al.  The Geomagnetic Field Its Nature, History, and Biological Relevance , 1985 .

[7]  D. Edmonds Larmor precession as a mechanism for the detection of static and alternating magnetic fields , 1993 .

[8]  N. Wertheimer,et al.  Electrical wiring configurations and childhood cancer. , 1979, American journal of epidemiology.

[9]  D A Savitz,et al.  Repeatability of measurements of residential magnetic fields and wire codes. , 1993, Bioelectromagnetics.

[10]  K. Cooksey,et al.  Calcium cyclotron resonance and diatom mobility. , 1987, Bioelectromagnetics.

[11]  N. Wertheimer,et al.  Adult cancer related to electrical wires near the home. , 1982, International journal of epidemiology.

[12]  J. A. Reese,et al.  Evaluation of changes in diatom mobility after exposure to 16-Hz electromagnetic fields. , 1991, Bioelectromagnetics.

[13]  R. Adair Criticism of Lednev's mechanism for the influence of weak magnetic fields on biological systems. , 1992, Bioelectromagnetics.

[14]  J. Kirschvink,et al.  Comment on "Constraints on biological effects of weak extremely-low-frequency electromagnetic fields" , 1992, Physical review. A, Atomic, molecular, and optical physics.

[15]  V. Lednev,et al.  Possible mechanism for the influence of weak magnetic fields on biological systems. , 1991, Bioelectromagnetics.

[16]  N. Breslow,et al.  Statistical methods in cancer research. Vol. 1. The analysis of case-control studies. , 1981 .

[17]  B. Mcleod,et al.  Dynamic characteristics of membrane ions in multifield configurations of low-frequency electromagnetic radiation. , 1986, Bioelectromagnetics.

[18]  A. V. Prasad,et al.  Failure to reproduce increased calcium uptake in human lymphocytes at purported cyclotron resonance exposure conditions , 1991, Radiation and environmental biophysics.

[19]  M Feychting,et al.  Magnetic fields and cancer in children residing near Swedish high-voltage power lines. , 1993, American journal of epidemiology.

[20]  C. Blackman,et al.  A scheme for incorporating DC magnetic fields into epidemiological studies of EMF exposure. , 1993, Bioelectromagnetics.

[21]  D. House,et al.  Importance of alignment between local DC magnetic field and an oscillating magnetic field in responses of brain tissue in vitro and in vivo. , 1990, Bioelectromagnetics.

[22]  R. Liburdy,et al.  Time‐varying and static magnetic fields act in combination to alter calcium signal transduction in the lymphocyte , 1992, FEBS letters.

[23]  D C Thomas,et al.  Exposure to residential electric and magnetic fields and risk of childhood leukemia. , 1991, American journal of epidemiology.

[24]  D. House,et al.  Influence of electromagnetic fields on the efflux of calcium ions from brain tissue in vitro: a three-model analysis consistent with the frequency response up to 510 Hz. , 1988, Bioelectromagnetics.

[25]  Adair Reply to "Comment on 'Constraints on biological effects of weak extremely-low-frequency electromagnetic fields' " , 1992, Physical review. A, Atomic, molecular, and optical physics.

[26]  L. S. Kinney,et al.  Effects of ELF fields on calcium-ion efflux from brain tissue in vitro. , 1982, Radiation research.

[27]  J. Swanson Measurements of static magnetic fields in homes in the UK and their implication for epidemiological studies of exposure to alternating magnetic fields , 1994 .

[28]  A. Liboff,et al.  Kinetics of channelized membrane ions in magnetic fields. , 1988, Bioelectromagnetics.

[29]  D. House,et al.  A role for the magnetic field in the radiation-induced efflux of calcium ions from brain tissue in vitro. , 1985, Bioelectromagnetics.

[30]  R. Spiegel,et al.  Effect of ambient levels of power-line-frequency electric fields on a developing vertebrate. , 1988, Bioelectromagnetics.