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Guidelines for limiting exposure to time-varying electric, magnetic, and electromagnetic fields –
ICNIRP Guidelines
41
Bernhardt, J. H. The establishment of frequency dependent limits for electric and magnetic fields
and evaluation of indirect effect. Radiat. Environ. Biophys. 27:1–27; 1988.
Bernhardt, J. H. Basic criteria of ELF-standards: worldwide achievement in public and occupational
health protection against radiation. Proceedings of the Eighth International Congress of the
International Radiation Protection Association. Geneva: IRPA; 1992: 933–936.
Blackman, C. F.; Elder, J. A.; Weil, C. M.; Benane, S. G.; Eichinger, D. C.; House, D. E. Induction
of calcium-ion efflux from brain tissue by radiofrequency radiation: effects of modulation
frequency and field strength. Radio Sci. 14:93–98; 1979.
Blank, M., ed. Electromagnetic fields: biological interactions and mechanisms. Washington, DC:
American Chemical Society Press; 1995.
Bracken, M. B.; Belanger, K.; Hellenbrand, K.; Dlugosz, L.; Holford, T. R.; McSharry, J. E.;
Addesso, K.; Leaderer, B. Exposure to electromagnetic fields during pregnancy with emphasis
on electrically heated beds: association with birthweight and intrauterine growth. Epidemiol.
6:263–270; 1995.
Brent, R. L.; Beckman, D. A.; Landel, C. P. Clinical teratology. Curr. Opin. Pediatr. 5:201–211;
1993.
Byus, C. V.; Lundak, R. L.; Fletcher, R. M.; Adey, W. R. Alterations in protein kinase activity
following exposure of cultured human lymphocytes to modulated microwave fields.
Bioelectromagnetics 5:341–351; 1984.
Byus, C. V.; Pieper, S. E.; Adey, W. R. The effects of low-energy 60 Hz environmental
electromagnetic fields upon the growth-related enzyme ornithine decarboxylase.
Carcinogenesis 8:1385–1389; 1987.
Byus, C. V.; Kartun, K.; Pieper, S.; Adey, W. R. Increased ornithine decarboxylase activity in
cultured cells exposed to low energy modulated microwave fields and phorbol ester tumor
promoters. Cancer Res. 48:4222– 4226; 1988.
Chatterjee, I.; Wu, D.; Gandhi, O. P. Human body impedance and threshold currents for perception
and pain for contact hazards analysis in the VLF-MF band. IEEE Transactions on Biomedical
Engineering 33:486–494; 1986.
Chen, J. Y.; Gandhi, O. P. Thermal implications of high SARs in the body extremities at the ANSI-
recommended MFVHF safety levels. IEEE Transactions on Biomedical Engineering 35:435–
441; 1988.
Chernoff, N.; Rogers, J. M.; Kavet, R. A review of the literature on potential reproductive and
developmental toxicity of electric and magnetic fields. Toxicology 74:91–126; 1992.
Guy, A. W.; Lin, J. C.; Kramar, P. O.; Emery, A. Effect of 2450-MHz radiation on the rabbit eye.
IEEE Transactions on Microwave Theory Technique 23:492– 498; 1975.
Heath, C. W., Jr. Electromagnetic field exposure and cancer: a review of epidemiologic evidence.
Ca. Cancer J. Clin. 46:29–44; 1996.
Hocking, B.; Gordon, I. R.; Grain, M. L.; Hatfield, G. E. Cancer incidence and mortality and
proximity to TV towers. Med. J. Australia 165:601– 605; 1996.
Hoque, M.; Gandhi, O. P. Temperature distributions in the human leg for VLF-VHF exposures at
the ANSIrecommended safety levels. IEEE Transactions on Biomedical Engineering 35:442–
449; 1988.
International Commission on Non-Ionizing Radiation Protection. Guidelines on limits of exposure
to static magnetic fields. Health Phys. 66:100 –106; 1994.
Guidelines for limiting exposure to time-varying electric, magnetic, and electromagnetic fields –
ICNIRP Guidelines
42
International Commission on Non-Ionizing Radiation Protection. Health issues related to the use of
hand-held radiotelephones and base transmitters. Health Phys. 70:587–593; 1996.
International Commission on Radiological Protection. Human respiratory tract model for
radiological protection. Oxford: Pergamon Press; ICRP Publication 66; 1994.
Institute of Electrical and Electronic Engineers. Standard for safety levels with respect to human
exposure to radiofrequency electromagnetic fields, 3 kHz to 300 GHZ. New York: Institute of
Electrical and Electronic Engineers; IEEE C95.1-1991; 1992.
International Labour Organisation. Protection of workers from power frequency electric and
magnetic fields. Geneva: International Labour Office; Occupational Safety and Health Series,
No. 69; 1994.
International Radiation Protection Association/International Non-Ionizing Radiation Committee.
Guidelines on limits of exposure to radiofrequency electromagnetic fields in the frequency
range from 100 kHz to 300 GHz. Health Phys. 54:115–123; 1988.
International Radiation Protection Association/International Non-Ionizing Radiation Committee.
Interim guidelines on limits of exposure to 50/60 Hz electric and magnetic fields. Health Phys.
58:113–121; 1990.
Jokela, K.; Puranen, L.; Gandhi, O. P. Radio frequency currents induced in the human body for
medium-frequency/ high-frequency broadcast antennas. Health Phys. 66:237– 244; 1994.
Kallen, B.; Malmquist, G.; Moritz, U. Delivery outcome among physiotherapists in Sweden: Is non-
ionizing radiation a fetal hazard? Arch. Environ. Health 37:81– 85; 1982.
Kamimura, Y.; Sato, K.; Saiga, T.; Amemiya, Y. Effects of 2.45 GHz microwave irradiation on
monkey eyes. IEICE Trans. Communications E77-B:762–765; 1994.
Kirschvink, J. L.; Kobayashi-Kirschvink, A.; Diaz Ricci, J. C.; Kirschvink, S. J. Magnetite in
human tissues: a mechanism for the biological effects of weak ELF magnetic fields.
Bioelectromagnetics Suppl. 1:101–113; 1992a.
Kirschvink, J. L.; Kobayashi-Kirschvink, A.; Woodford, B. J. Magnetite biomineralization in the
human brain. Proc. Nat. Acad. Sci. 89:7683–7687; 1992b.
Kues, H. A.; Hirst, L. W.; Lutty, G. A.; D’Anna, S. A.; Dunkelberger, G. R. Effects of 2.45-GHz
microwaves on primate corneal endothelium. Bioelectromagnetics 6:177– 188; 1985.
Kuster, N.; Balzano, Q. Energy absorption mechanisms by biological bodies in the near-field of
dipole antennas. IEEE Transactions on Vehicular Technololgy 42:17–23; 1992.
Lacy-Hulbert, A.; Wilkins, R. C.; Hesketh, T. R.; Metcalfe, J. C. No effect of 60 Hz
electromagnetic fields on MYC or beta-actin expression in human leukemic cells. Rad Res.
144:9 –17; 1995.
Lai, H.; Singh, N. P. Acute low-intensity microwave exposure increases DNA single-strand breaks
in rat brain cells. Bioelectromagnetics 16:207–210; 1995.
Lai, H.; Singh, N. P. Single- and double-strand DNA breaks in rat brain cells after acute exposure to
radiofrequency electromagnetic radiation. Int. J. Radiation Biol. 69:513–521; 1996.
Larsen, A. I.; Olsen, J.; Svane, O. Gender-specific reproductive outcome and exposure to high-
frequency electromagnetic radiation among physiotherapists. Scand. J. Work Environ. Health
17:324 –329; 1991.
Li, D.; Ceckoway, H.; Mueller, B. A. Electric blanket use during pregnancy in relation to the risk of
congenital urinary tract anomalies among women with a history of subfertility. Epidemiology
6:485– 489; 1995.
Guidelines for limiting exposure to time-varying electric, magnetic, and electromagnetic fields –
ICNIRP Guidelines
43
Li, C. Y.; Theriault, G.; Lin, R. S. Epidemiological appraisal of studies of residential exposure to
power frequency magnetic fields and adult cancers. Occup. Environ. Med. 53:505–510; 1996.
Liburdy, R. P. Biological interactions of cellular systems with time-varying magnetic fields. Ann.
NY Acad. Sci. 649:74– 95; 1992.
Lillienfeld, A. M.; Tonascia, J.; Tonascia, S.; Libauer, C. A.; Cauthen, G. M. Foreign service health
status study— evaluation of health status of foreign service and other employees from selected
eastern European posts. Final report. Washington, DC: Department of State; Contract No.
6025-619073, NTIS PB-288163; 1978.
Lin, J. C. Microwave auditory effects and applications. Springfield, IL: Charles C. Thomas; 1978
Lindbohm, M. L.; Hietanen, M.; Kyyro.nen, P.; Sallmen, M.; van Nandelstadh, P.; Taskinen, H.;
Pekkarinen, M.; Ylikoski, M.; Hemminki, K. Magnetic fields of video display terminals and
spontaneous abortion. Am. J. Epidemiol. 136:1041–1051; 1992.
Linet, M. S.; Hatch, E. E.; Kleinerman, R. A.; Robinson, L. L.; Kaune, W. T.; Friedman, D. R.;
Severson R. K.; Haines, C. M.; Hartsock, C. T.; Niwa, S.; Wacholder, S.; Tarone, R. E.
Residential exposure to magnetic fields and acute lymphoblastic leukemia in children. New
Eng. J. Med. 337:1–7; 1997.
Litovitz, T. A.; Krause, D.; Mullins, J. M. Effect of coherence time of the applied magnetic field on
ornithine decarboxylase activity. Biochem. Biophys. Res. Comm. 178:862– 865; 1991.
Litovitz, T. A.; Montrose, C. J.; Wang, W. Dose-response implications of the transient nature of
electromagnetic-fieldinduced bioeffects: theoretical hypotheses and predictions.
Bioelectromagnetics Suppl. 1:237–246; 1992.
Litovitz, T. A.; Krause, D.; Penafiel, M.; Elson, E. C.; Mullins, J. M. The role of coherence time in
the effect of microwaves on ornithine decarboxylase activity. Bioelectromagnetics 14:395–
403; 1993.
Loscher, W.; Mevissen, M.; Lehmacher, W.; Stamm, A. Tumor promotion in a breast cancer model
by exposure to a weak alternating magnetic field. Cancer Letters 71:75– 81; 1993.
Loscher, W.; Mevissen, M. Linear relationship between flux density and tumor co-promoting effect
of prolonging magnetic exposure in a breast cancer model. Cancer Letters 96:175–180; 1995.
Lovsund, P.; O. berg, P.; Nilsson, S. E. G. Magneto- and electrophosphenes: a comparative study.
Med. Biol. Eng. Computing 18:758 –764; 1980.
London, S. J.; Thomas, D. C.; Bowman, J. D.; Sobel, E.; Cheng, T. C.; Peters, J. M. Exposure to
residential electric and magnetic fields and risk of childhood leukemia. Am. J. Epidemiol.
134:923–937; 1991.
Loomis, D. P.; Savitz, D. A.; Ananth, C. V. Breast cancer mortality among female electrical
workers in the United States. J. Nat. Cancer Inst. 86:921–925; 1994.
Lyle, D. B.; Schechter, P.; Adey, W. R.; Lundak, R. L. Suppression of T-lymphocyte cytotoxicity
following exposure to sinusoidally amplitude-modulated fields. Bioelectromagnetics 4:281–
292; 1983.
Magin, R. L.; Liburdy, R. P.; Persson, B. Biological effects and safety aspects of nuclear magnetic
resonance imaging and spectroscopy. Ann. NY Acad. Sci. 649; 1992.
Matanoski, G. M.; Breysse, P. N.; Elliott, E. A. Electromagnetic field exposure and male breast
cancer. Lancet 337:737; 1991.
McCann, J.; Dietrich, F.; Rafferty, C.; Martin, A. A critical review of the genotoxic potential of
electric and magnetic fields. Mutation Res. 297:61–95; 1993.
Guidelines for limiting exposure to time-varying electric, magnetic, and electromagnetic fields –
ICNIRP Guidelines
44
McDowall, M. Mortality in persons resident in the vicinity of electricity transmission facilities. Br.
J. Cancer 53:271–279; 1985.
McKinlay, A. F.; Andersen, J. B.; Bernhardt, J. H.; Grandolfo, M.; Hossmann, K.-A.; Mild, K. H.;
Swerdlow, A. J.; Van Leeuwen, M. Verschaeve, L.; Veyret, B. Radiotelephones and human
health—proposal for a European research programme. Report of a European Commission
Expert Group. Brussels: European Commission Directorate General XIII; 1996.
McLean, J.; Stuchly, M. A.; Mitchel, R. E.; Wilkinson, D.; Yang, H.; Goddard, M.; Lecuyer, D. W.;
Schunk, M.; Callary, E.; Morrison, D. Cancer promotion in a mouse-skin model by a 60-Hz
magnetic field: II. Tumor development and immune response. Bioelectromagnetics 12:273–
287; 1991.
Mevissen, M.; Stamm, A.; Buntenkotter, S.; Zwingelberg, R.; Wahnschaffe, U.; Lo.scher, W.
Effects of magnetic fields on mammary tumor development induced by 7,12-
dimethylbenz(a)anthracene in rats. Bioelectromagnetics 14:131–143; 1993.
Mevissen, M.; Kietzmann, M.; Lo.scher, W. In vivo exposure of rats to weak alternating magnetic
field increases ornithine decarboxylase activity in the mammary gland by a similar extent as
the carcinogen DMBA. Cancer Letters 90:207– 214; 1995.
Michaelis, J.; Schuz, J.; Meinert, R.; Menger, M.; Grigat, J.-P.; Kaatsch, P.; Kaletsch, U.; Miesner,
A.; Stamm, A.; Brinkmann, K.; Karner, H. Childhood leukemia and electromagnetic fields:
results of a population-based case-control study in Germany. Cancer Causes and Control
8:167–174; 1997.
Michaelson, S. M. Biological effects and health hazards of RF and MW energy: fundamentals and
overall phenomenology. In: Grandolfo, M.; Michaelson, S. M.; Rindi, A., eds. Biological
effects and dosimetry of non-ionizing radiation. New York: Plenum Press; 1983: 337–357.
Michaelson, S. M.; Elson, E. C. Modulated fields and ‘window’ effects. In: Polk, C.; Postow, E.,
eds. Biological effects of electromagnetic fields. Boca Raton, FL: CRC Press; 1996: 435–533.
Milham, S., Jr. Mortality from leukemia in workers exposed to electrical and magnetic fields. New
Engl. J. Med. 307:249; 1982.
Miller, A. B.; To, T.; Agnew, D. A; Wall, C.; Green, L. M. Leukemia following occupational
exposure to 60-Hz electric and magnetic fields among Ontario electric utility workers. Am. J.
Epidemiol. 144:150 –160; 1996.
Murphy, J. C.; Kaden, D. A.; Warren, J.; Sivak, A. Power frequency electric and magnetic fields: a
review of genetic toxicology. Mutation Res. 296:221–240; 1993.
Myers, A.; Cartwright, R. A.; Bonnell, J. A.; Male, J. C.; Cartwright, S. C. Overhead power lines
and childhood cancer. International Conference of Electric and Magnetic Fields in Med. and
Biology, London, December 4–5. IEEE Conf. Publ. No. 257; 1985:126.
National Academy of Science/National Research Council. Possible health effects of exposure to
residential electric and magnetic fields. Washington, DC: National Academy Press; 1996.
National Council on Radiation Protection. Radiofrequency electromagnetic fields. Properties,
quantities and units, biophysical interaction, and measurement. Washington, DC: National
Council on Radiation Protection and Measurement; NCRP Report 67; 1981.
National Council on Radiation Protection. A practical guide to the determination of human
exposure to radiofrequency fields. Washington, DC: National Council on Radiation Protection
and Measurement; NCRP Report 119; 1993.
National Radiological Protection Board. Biological effects of exposure to non-ionising
electromagnetic fields and radiation: III: Radiofrequency and microwave radiation. Chilton,
UK: National Radiological Protection Board; Report R-240; 1991.
Guidelines for limiting exposure to time-varying electric, magnetic, and electromagnetic fields –
ICNIRP Guidelines
45
National Radiological Protection Board. Electromagnetic fields and the risk of cancer. Report of an
Advisory Group on Non-ionizing Radiation. Chilton, UK: National Radiological Protection
Board; NRPB Documents 3(1); 1992.
National Radiological Protection Board. Electromagnetic fields and the risk of cancer. Summary of
the views of the Advisory Group on Non-ionising Radiation on epidemiological studies
published since its 1992 report. Chilton, UK: National Radiological Protection Board; NRPB
Documents 4(5); 1993.
National Radiological Protection Board. Health effects related to the use of visual display units.
Report by the Advisory Group on Non-ionising Radiation. Chilton, UK: National
Radiological Protection Board; NRPB Documents 5(2); 1994a.
National Radiological Protection Board. Electromagnetic fields and the risk of cancer.
Supplementary report by the Advisory Group on Non-ionising Radiation of 12 April 1994.
Radiol. Prot. Bull. 154:10 –12; 1994b.
Olsen, J. H.; Nielsen, A.; Schulgen, G. Residence near high voltage facilities and the risk of cancer
in children. Danish Cancer Registry; AG-NIR, 1-26; 1993. Oak Ridge Associated
Universities. Health effects of low frequency electric and magnetic fields. Oak Ridge, TN:
Oak Ridge Associated Universities; ORAU 92/F9; 1992.
Ouellet-Hellstrom, R.; Stewart, W. F. Miscarriages among female physical therapists, who report
using radio- and microwave-frequency electromagnetic radiation. Am. J. Epidemiol. 138:775–
786; 1993.
Phillips, J. L.; Haggren, W.; Thomas, W. J.; Ishida-Jones, T.; Adey, W. R. Magnetic field-induced
changes in specific gene transcription. Biochim. Biophys. Acta 1132:140 –144; 1992.
Polk, C.; Postow, E. Biological effects of electromagnetic fields. 2nd ed. Boca Raton, FL: CRC
Press; 1996.
Polson, M. J. R.; Barker, A. T.; Freeston, I. L. Stimulation of nerve trunks with time-varying
magnetic fields. Med. Biol. Eng. Computing 20:243–244; 1982.
Postow, E.; Swicord, M. L. Modulated fields and ‘window’ effects. In: Polk, C.; Postow, E., eds.
Handbook of biological effects of electromagnetic fields. Boca Raton, FL: CRC Press; 1996:
535–580.
Preston-Martin, S.; Peters, J. M.; Yu, M. C.; Garabrant, D. H.; Bowman, J. D. Myelogenous
leukemia and electric blanket use. Bioelectromagnetics 9:207–213; 1988.
Preston-Martin, S.; Navidi, W.; Thomas, D.; Lee, P.-J.; Bowman, J.; Pogoda, J. Los Angeles study
of residential magnetic fields and childhood brain tumors. Am. J. Epidemiol. 143:105–119;
1996a.
Preston-Martin, S.; Gurney, J. G.; Pogoda, J. M.; Holly, E. A.; Mueller, B. A. Brain tumor risk in
children in relation to use of electric blankets and water bed heaters: results from the United
States West Coast Childhood Brain Tumor Study. Am. J. Epidemiol. 143:1116 –1122; 1996b.
Ramsey, J. D.; Kwon, Y. C. Simplified decision rules for predicting performance loss in the heat.
In: Proceedings Seminar on heat stress indices. Luxembourg: CEC; 1988.
Rannug, A.; Ekstrom, T.; Mild, K. H.; Holmberg, B.; Gimenez- Conti, I.; Slaga, T. J. A study on
skin tumour formation in mice with 50 Hz magnetic field exposure. Carcinogenesis 14:573–
578; 1993a.
Rannug, A.; Holmberg, B.; Ekstrom, T.; Mild, K. H. Rat liver foci study on coexposure with 50 Hz
magnetic fields and known carcinogens. Bioelectromagnetics 14:17–27; 1993b.