Nonlinear response of the immune system to power-frequency magnetic fields

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Nonlinear response of the immune system to power-frequency magnetic fields

Andrew A. Marino¹, R. Michael Wolcott², Robert Chervenak², Frances Jourd'Heuil², Erik Nilsen¹^,³, and Clifton Frilot II⁴

Departments of ¹ Orthopaedic Surgery and ² Microbiology and Immunology, Louisiana State University Health Sciences Center, Shreveport 71130; and ³ College of Engineering Sciences and ⁴ Department of Bioengineering, Louisiana Tech University, Ruston, Louisiana 71272

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Studies of the effects of power-frequency electromagnetic fields (EMFs) on the immune and other body systems produced positiveand negative results, and this pattern was usually interpretedto indicate the absence of real effects. However, if the biologicaleffects of EMFs were governed by nonlinear laws, deterministicresponses to fields could occur that were both real and inconsistent,thereby leading to both types of results. The hypothesis of realinconsistent effects due to EMFs was tested by exposing mice to1 G, 60 Hz for 1-105 days and observing the effect on 20 immuneparameters, using flow cytometry and functional assays. The datawere evaluated by means of a novel statistical procedure thatavoided averaging away oppositely directed changes in differentanimals, which we perceived to be the problem in some of the earlierEMF studies. The reliability of the procedure was shown usingappropriate controls. In three independent experiments involvingexposure for 21 or more days, the field altered lymphoid phenotypeeven though the changes in individual immune parameters were inconsistent.When the data were evaluated using traditional linear statisticalmethods, no significant difference in any immune parameter wasfound. We were able to mimic the results by sampling from knownchaotic systems, suggesting that deterministic chaos could explainthe effect of fields on the immune system. We conclude that exposureto power-frequency fields produced changes in the immune systemthat were both real andinconsistent.

chaos; electromagnetic fields; powerlines

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

WHETHER ELECTROMAGNETIC FIELDS (EMFs) from electrical transmission and distribution systems constitute a health hazard hasbeen disputed since the issue first became prominent (18). Epidemiologicalstudies implicated EMFs in many different diseases (23, 27,29, 32), but theoretical approaches failed to unambiguouslyrationalize any correlations (1, 11, 31), and laboratorybioassay studies aimed at understanding the range and potentialseriousness of EMF-induced bioeffects seemed always to resultin inconsistency. EMFs altered the immune system in some studies(22), but not in others (15). EMFs affected the rate of releaseof Ca²⁺ from brain tissue (6), but others were unable to reproducethe effect (3). EMFs caused skeletal growth abnormalities inchicks (9), but the same model system in the hands of otherinvestigators yielded negative results (14). Sometimes EMFsaffected growth rate of animals (19), but not in other cases(24). EMFs affected transcription (10) or not (26) in seeminglyidentical experiments performed by different investigators. EMFstudies were similarly inconsistent in other areas, includingeffects on melatonin levels, stress reactions, behavior, and cellgrowth. Whether the result of any particular EMF experiment wouldbe positive or negative was, and continues to be,unpredictable.

Committees of experts assumed that only consistent data could evidence an interaction between fields and tissue and, findingno such data, concluded there were no real EMF bioeffects andtherefore no reasonable possibility of health risks due to EMFexposure (2, 4, 30). It occurred to us, however, thatthe assumption was dubious, because nonlinear chaotic systemscan be both deterministic and unpredictable (13, 25, 28).We previously presented indirect experimental evidence suggestingthat the effects of long-term exposure to 60-Hz EMFs on the growthrate of mice were consistent with the theory of deterministicchaos (16, 19, 20).

Our goal here was to show directly that exposure to power-frequency EMFs could cause biological effects that were both realand inconsistent. We chose lymphoid phenotype as the endpointbecause earlier work suggested that the immune system was a keymechanism linking field exposure and disease (17).

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Experimental Design

In most previous EMF bioeffects studies, it was assumed that any response of an animal to the field would be linear and thatinteranimal measurement differences were due solely to stochasticprocesses. This assumption was sometimes made explicitly but moreoften was manifested by the choice of the statistical procedureemployed to evaluate the data. In such a model, which we shallrefer to as a linear stochastic model, a true response must beconsistent from animal to animal. If it were the case, for example,that the field produced an increase in a parameter in one animaland a decrease or no change in a second animal, that result wouldviolate either the assumption that the response was caused bythe field or the assumption that the animals wereidentical.

In our concept of the link between EMF exposure and changes in the immune system, we assumed that if immune parameters weremeasured as a time series in each of a group of animals, the responseof a given parameter could be an increase, decrease, or no change,depending on the animal. More particularly, the evolution of thetime series could appear random but still contain a deterministiccomponent due to the EMF. We chose parameters that could be measuredin the same animal only once. Consequently, to test our hypothesis,we compared the average response of a group of exposed animalswith that from a separate control group. We recognized that themean of a large sample of exposed mice that each exhibited theputative inconsistent response would be similar to that of thecontrols even though, hypothetically, the field produced a deterministicresponse in some or even most of the exposed animals. In otherwords, in our conceptual model, an effect of the EMF would notbe observed in a large sample because oppositely directed changeswould be averaged away. A single small sample might reveal theputative effect (due to incomplete averaging), but tests on smallsamples lack statistical power. We therefore developed a statisticalprocedure that might permit us to infer the occurrence of irregularchanges.

The likelihood approach allows differences in means from replicate series of exposed and control groups to be combined totest an overall hypothesis (5), in our case the hypothesisthat changes occurred. The log-likelihood ratio of the t statisticfor a t-test between an exposed and control group is

l=2n ln<FENCE><IT>1+</IT><FR><NU><IT>1</IT></NU><DE><IT>2n−2</IT></DE></FR><IT> t<SUP>2</SUP></IT></FENCE> (1)

where n is the number of animals in each group. The distribution of l is approximately $chi$ ² with one degree of freedom. For k pairs, the overall value ofthe test statistic, L, is L = ₁^kl_i, where l_i is the ratio for t for the i^th parameter. L also approximately follows the $chi$ ² distribution, with k degrees of freedom under the hypothesisof no treatment effect. Because L is sensitive to the differencebetween the exposed and control groups but not to the directionof the difference, L is suitable for testing a single overallhypothesis regarding occurrence of EMF-induced change in the kreplicates.

The occurrence of changes in the immune system due to exposure to 60-Hz magnetic fields was assessed on the basis of whetherL = $chi$ _k,0.005², with k = 3 and n = 5. We chose a group size of five, becausepreliminary studies suggested it was large enough to characterizea population but small enough to permit the large number of plannedmeasurements on each animal (see Immune Measurements). For smallsamples (n = 5), probabilities for L determined from the $chi$ ² distribution were slightly overestimated or underestimated, dependingon t. These deviations from large-sample probabilities had noeffect on our results (see DISCUSSION). Controls included sham-exposedmice paired with each exposed group and experiments in which bothgroups were sham exposed. Additionally, by sampling from two differentmathematically defined chaotic systems, we studied whether theL test was capable of recognizing that the systems actually differed.The occurrence of consistent change in the immune data (whichwould suggest the applicability of a linear model or a nonlinearnonchaotic model) was evaluated by combining the individual measurementsin the three replicates before analysis (L = $chi$ _1,0.05², with n = 15). This procedure was equivalent to performing at-test on the combineddata.

More than 4,800 individual measurements of 20 different immune parameters were made. Of this total, ~15 measurements differedby more than five standard deviations from their respective means.The outliers were included in the analysis because we had no objectivebasis to excludethem.

Exposure System

Magnetic fields were produced using an arrangement of four square coils (21, 33). The coils were dipped in epoxy and wrappedwith grounded, interrupted metal shielding. Four sets of fourcoils arranged in an octapole configuration (33) constituteda unit. One unit was used to produce magnetic fields. It was energizedby a power supply consisting of an isolation transformer, autotransformer,and capacitors operated in series resonance at 60 Hz to eliminatepowerline harmonics. The unit was designed using commercial software(MF3D, Electric Research and Management, Pittsburgh, PA) to producemagnetic fields that were homogeneous (±5%) throughout the regionoccupied by the mice with a negligible fringing field. The designspecifications were verified by direct measurements (BartingtonMAG-03, GMW, Redwood City, CA). Another unit was short circuitedand used to house the control mice. The ambient 60-Hz field atthat location averaged 0.4 mG and never exceeded 0.7mG.

The exposure room was continuously maintained under temperature and humidity control with an unvarying 12:12-h light-darkcycle. Room air was replaced 15 times per hour with fresh air.A virtual instrument (Labview, National Instruments, Austin, TX)was created to continuously monitor and record room temperature,coil current, magnetic field, and current harmoniccontent.

Animals

This work was part of a larger study that employed both males and females. The experiments described here were performed onmale mice, except where noted. C57BL/6 mice (Jackson Laboratories,Bar Harbor, MN), 6 wk old at arrival, were rested a minimum of2 wk before use. The mice were housed in a totally nonmetallicenvironment. The water bottle was placed inside the cage to minimizedifferences in electrical potential between the mice and the water.The animal cages sat on plastic shelves that were wall mountedto prevent vibrational coupling between the coils and the cages.The mice were exposed continuously, except for the time neededto service the cages (~1 h/wk).

In separate experiments, mice were exposed to 1 G, 60 Hz for 1, 5, 10, 21, 49, and 105 days. In addition, to evaluate thereliability of the L procedure, two sham experiments were performedin which all mice received the control treatment; these experimentsused female mice. For each exposure period, three replicates wereevaluated, each consisting of five exposed and five control mice.The 10 mice in a particular pair were killed (cervical dislocation)on the same morning, and the minimum time between deaths of anytwo pairs was 1wk.

Immune Measurements

Flow cytometry. Spleen and thymus cells were obtained by gently dispersing the organs between glass slides, and bone marrow cells were obtainedby removing and flushing both femurs with PBS. The cells werecounted (Z1, Coulter, Hialeah, FL) and then resuspended at 10⁷ cells per milliliter in staining buffer (PBS, 2% fetal bovineserum, 1 g/l sodium azide), and populations of interest were identifiedby two-color flow cytometric analysis using fluorescein isothyocyanateand phycoerythrin (Epics Profile II, Coulter, Hialeah, FL). Cellpopulations were enumerated by staining with PK 136, for the NK1.1antigen on NK cells, GK1.5, 2.43, 2C11, and anti-Thy1.2 for therespective CD4, CD8, CD3, and CD90 antigens on T cells, and anti-IgM,anti-IgD, and anti-CD45R for antigens on B cells. Antibodies werepurified from hybridomas (American Type Culture Collection, Rockville,MD) or purchased (Pharmingen, San Diego, CA; Southern, Birmingham,AL). To prevent nonspecific binding, the cells were incubatedwith 50 µl of the appropriately diluted anti-Fc receptorantibody.

Assays. Cytotoxic T lymphocytes (CTL) were generated in a one-way mixed lymphocyte culture (MLC) by coculturing B6 spleen cells andgamma-irradiated A/J spleen stimulator for 5 days. Proliferationwas quantified (after 3 days' incubation) using a commercial proliferationassay (CellTiter96 AQ, Promega, Madison, WI). The result was expressedas the ratio of absorption units obtained from stimulated andunstimulated culture (stimulation index). The lytic activity ofspleen NK cells was enhanced by culturing spleen cells for 18h in medium containing interleukin-2 (800 units/ml) (34).

⁵¹Cr-labeled target cells were combined with various numbers of effector cells to give a range of effector-to-target (E/T) ratios(2:1, 3:1, 6:1, 13:1, 25:1, 50:1, and 100:1) that were each assayedin triplicate. The specific lysis (SL) was calculated as SL =(E $-$ S)/(M $-$ S), where E and S were, respectively, the countsper minute released in the presence of the effector cells andthe presence of medium alone, and M was the maximum value (determinedby lysing the target cells with acetic acid). For determinationof NK cell cytotoxicity, YAC-1 and P815 cells were used as positiveand negative targets, respectively. YAC-1 and IL-4 cells wereused as the respective positive and negative targets for the CTLgenerated in the MLC. For simplicity, the results are expressedin terms of a single predetermined E/T ratio for eachassay.

The absence of numeric or functional data due to technical errors is shown in thetables.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Twenty immune parameters were measured in each of five mice exposed to 1 G for 105 days and in each of five sham-exposed controlmice, and the mean ± SD for each parameter was determined. Withthe use of Equation 1, l was calculated for each of the 20 comparisonsbetween the two groups. The entire procedure was repeated twice,totaling three replicates, and 20 L values were computed by summingthe corresponding constituent l_i (Table 1). We tested hypothesesconcerning the occurrence of field-induced change by using thereplicate means to assess whether L exceeded the critical value(P < 0.05) of the $chi$ ² distribution with three degrees of freedom and found six significantdifferences (Table 1).

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Table 1. Immune parameters in mice exposed in 3 replicates to 1 G, 60 Hz, for 105 days

The experiment was repeated five additional times, corresponding to exposures of 1, 5, 10, 21, and 49 days. After exposurefor 49 days, statistically significant differences in five immuneparameters were found (Table 2), and seven such differences werefound after exposure for 21 days (Table 3). Two significant changeswere found after exposure for 1 or 10 days, and 3 significantchanges were found after exposure for 5 days (data not shown).

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Table 2. Immune parameters in mice exposed in 3 replicates to 1 G, 60 Hz, for 49 days

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Table 3. Immune parameters in mice exposed in 3 replicates to 1 G, 60 Hz, for 21 days

To explore the possibility that the relatively large numbers of significant differences were somehow a by-product of the novelprocedure adopted for assessing occurrence of EMF-induced change,the experiment was performed two additional times under conditionsemployed in the experiments described above, except that the fieldwas not applied to the putatively exposed group in either shamstudy. The sham exposure lasted 21 days in 1 case and 75 daysin the other. Each sham-exposed group and its corresponding controlwere identical in every respect that was known or suspected aspotentially capable of affecting the immune system. We performedthe 20 L tests in each of the two experiments and found one significantdifference in each experiment. Table 4 lists the data for the21-day sham; the data for the 75-day sham are not shown.

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Table 4. Immune parameters in 3 replicates of sham-exposed mice

The statistically significant differences observed in all field and sham experiments are summarized in Table 5, and the cumulativefrequency of the significant results as a function of L is shownin Fig. 1.

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Table 5. The L statistic for comparisons involving the effect of exposure to 1 G, 60 Hz on immune parameters in mice

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Fig. 1. Cumulative frequency of immune parameters (out of 20) affected by electromagnetic field exposure to 1 G, 60 Hz for 1-105 days as a function of the magnitude of the test statistic. Regions beyond the dotted line indicate P < 0.05 (L > 7.83).

An additional check on the reliability of the L test was performed. We reasoned that if sets of samples were drawn from twodifferent known chaotic systems, the analytic procedure oughtto be capable of recognizing that the systems differed in at leastsome cases where conventional linear analysis failed to do so.We therefore formed three replicates (n = 5) from the logisticequations x_k = 3.89x_k₁(1 $-$ x_k_-1) and y_k = 3.99y_k1(1 $-$ y_k1),with x₀ = y₀ = 0.4, k = 1, 2, ..., 100, both of which are chaoticbut fully deterministic, and analyzed the results using L. A typicalresult is shown in Table 6. The procedure resulted in recognitionthat the two populations actually differed (L = 7.95, P < 0.05),even though no difference was found when the 15 individual sampleswere combined before computing L (L = 2.49, P > 0.05).

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Table 6. Data obtained from random sampling from chaotic systems defined by logistic equations

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Observation of Real Change

The small-sample replicate-structure procedure based on the log-likelihood ratio statistic for the t-test was capable of detectingany form of change induced by the field, whether inconsistentor consistent. In this regard, our study differed from previousEMF-bioeffects studies, most of which employed statistical designsthat were insensitive to inconsistent change. We found that ineach of two sham experiments, chance alone produced only one significantcomparison in 20 tests, which was the expected result. The increasedfrequency of significant differences observed in the groups exposedfor 1, 5, and 10 days could also, arguably, be attributed to chance.For example, there was a small possibility (P = 0.08, binomialtheorem) that all three significant comparisons at 5 days weredue to stochastic processes unrelated to the presence of the field.For exposures $>=$ 21 days, however, it is highly implausible thatthe observed frequencies of statistically significant differences(Fig. 1) occurred bychance.

The question arose whether the significant differences could somehow be due to the use of the $chi$ ² distribution, because L for small samples (n = 5) is not precisely $chi$ ². It can be shown that small-sample P is overestimated when t < 2.05 (ranging from 20% for t = 0.1 to 1% for t = 2.0); otherwiseit is underestimated. Application of the appropriate correctionfactor to each l_i in the study did not alter the results. Furthermore,as mentioned, the overall reliability of the L procedure was directlyverified in each of two sham studies. We conclude, therefore,that, at least in the experiments involving exposure for 21, 49,and 105 days, the increased rate of significant comparisons reliablyindicated that the EMFs were transduced into biological signalsthat ultimately resulted in effects involving the immune system,notwithstanding that the data were, from a particular viewpoint,inconsistent (see Nature of Change).

Nature of Change

Our experimental design avoided testing hypotheses in individual replicates in favor of evaluating a single overall hypothesisfor each parameter in a particular experiment. Nevertheless, itcan be seen that the relative value of the means of correspondingexposed and control groups varied from replicate to replicate(Tables 1-4). To illustrate the fundamental role of this inconsistencyin manifesting the determinism produced by the field, we reanalyzedthe data without using the replicate structure design that wasintended to obviate the problem that we perceived at the inceptionof this study (averaging away real effects). This was accomplishedby computing L directly from the 15 exposed and 15 control miceand evaluating for statistical significance based on the $chi$ ² distribution with one degree of freedom. This procedure producedno significant effects in any of the instances in which effectswere noted initially (Fig. 1).

Given the occurrence of an effect involving a particular immune parameter in a particular experiment, it would be reasonableto expect that the same parameter would be affected at other exposuretimes. Although reasonable, such expectations are not logicalnecessities and, in fact, often were not realized. In most cases,when a particular parameter was significantly affected after aspecific exposure duration, the same parameter was not affectedat either longer or shorter exposure times (Table 5). This phenomenonconstitutes a second kind of inconsistency in thedata.

Although the results reported here were inconsistent in the two senses just described, they were consistent in a more fundamentalsense. The results showed that the immune system, as characterizedby a particular set of parameters, was affected by EMF exposurefor 105, 49, and 21 days (P < 0.05) in independent experimentsand was probably affected by exposure for 5 days (P $approx$ 0.08) andfor 1 and 10 days (P $approx$ 0.26). The data were fundamentally consistentbecause, in each case, they rationalized the inference of a cause-and-effectrelationship between fields and change in the immune system and,more particularly, the inference that biological transductionof the field must haveoccurred.

Explanation of Change

The determinism reflected in the results (Tables 1-3) cannot be explained on the basis of a linear stochastic model, therebyindicating the need for some kind of nonlinear model. The bodycontains numerous nonlinear sensory and effector systems thatfunction more or less predictably. The data presented here suggestthat, at least in connection with the link between power-frequencyEMFs and change in lymphoid phenotype, there also exist nonlinearsystems that do not function with the same kind of predictabilitymanifested by known nonlinear systems. Some nonlinear mathematicaland physical systems exhibit a form of behavior in which smalldifferences in initial conditions can dramatically affect theevolution of the system with the result that, after an initialperiod, the system's behavior cannot be predicted with any morereliability than that of a guess. Such sensitivity to initialconditions has been termed deterministic chaos (28). It is possiblethat a model based on chaotic nonlinearity could explain our results(Table 6). The nature of the nonlinearity, however, cannot beestablished unequivocally, because time series data from individualanimals were notobtained.

It is worthwhile to speculate about why the effects of 60-Hz magnetic fields on the immune system happened to be inconsistent.Predictability of input-output relationships in the body's sensoryand effector systems is mediated by mechanisms that were shapedby natural selection. From an evolutionary viewpoint, however,power-frequency magnetic fields were a negligible factor. A consistentresponse would serve no evolutionary purpose, and, consequently,a mechanism capable of producing a consistent response probablydid not evolve. From this perspective, the cellular basis of EMF-inducedeffects, such as those involving the immune system, seem betterunderstood as a vulnerability in the body's sensory or regulatorysystems inherent in the specific designs of those systems thatwere selected bynature.

Finally, this study was designed to show that interaction of power-frequency EMFs with biological receptors could cause changesthat were both real and inconsistent, thereby showing that unrealitycould not validly be inferred from inconsistency. The questionof the possible biophysical mechanism responsible for the interactionhas been considered by others (7, 8, 12) and was not addressedhere. The further question of the biological significance of inconsistentchange in the immune system was similarly not addressedhere.

Perspectives

An important goal of modern science is to understand the mechanisms that mediate particular observations. But observationsare determined not simply by mechanisms, but also by the dynamiclaw that governs them. Assumption of a linear theory is oftensufficient to explain physiological data. However, many previousstudies suggested that this is not the case for changes causedby EMFs. We showed directly that only a nonlinear approach couldexplain our data. Thus, by generalizing the model to allow fornonlinear dynamic laws, it was possible to understand how EMFscould cause real physiological effects. Nonlinear effects couldbe as important as linear effects in predisposing an organismtoward disease. Consequently, the existence of nonlinear physiologicalchanges due to EMFs may necessitate reevaluation of assessmentsof potential public-health risks that were based on linear effects(2, 4, 30).

	ACKNOWLEDGEMENTS

We thank Bernard Flury for statisticaladvice.

	FOOTNOTES

This work was supported by a grant from the National Institute of Environmental HealthSciences.

Address for reprint requests and other correspondence: A. A. Marino, Dept. of Orthopaedic Surgery, LSU Health Sciences Center,P.O. Box 33932, Shreveport, LA 71130-3932 (E-mail: amarino{at}lsuhsc.edu).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.§1734 solely to indicate thisfact.

Received 3 February 2000; accepted in final form 27 March 2000.

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