Limites de radiação não ionizante

Limites de radiação não ionizante

(Parte 7 de 13)

M.; Mariutti, G. F.; Matthes, R.; McKinlay, A. F.; Steinmetz, M.; Vecchia, P.; Whillock, M. Proposals for basic restrictions for protection against occupational exposure to electromagnetic non-ionizing radiations. Recommendations of an International Working Group set up under the auspices of the Commission of the European Communities. Phys. Med. VII:7–89; 1991.

American Conference of Government Industrial Hygienists.

Threshold limit values for chemical substances and physical agents and biological exposure indices. Cincinnati, OH: American Conference of Governmental Industrial Hygienists; 1996.

Astumian, R. D.; Weaver, J. C.; Adair, R. K. Rectification and signal averaging of weak electric fields by biological cells. PNAS 92:3740–3743; 1995.

Balcer-Kubiczek, E. K.; Harrison, G. H. Neoplastic transformation of C3H/10T1/2 cells following exposure to 120 Hz modulated 2.45 GHz microwaves and phorbol ester tumor promoter. Radiat. Res. 126:65–72; 1991.

Baris, D.; Armstrong, B. G.; Deadman, J.; Theriault, G. A mortality study of electrical utility workers in Quebec. Occ. Environ. Med. 53:25–31; 1996.

Barron, C. I.; Baraff, A. A. Medical considerations of exposure to microwaves (radar). J. Am. Med. Assoc. 168:1194–19; 1958.

Baum, A.; Mevissen, M.; Kamino, K.; Mohr, U.; Loscher, W.

A histopathological study on alterations in DMBA-induced mammary carcinogenesis in rats with 50 Hz, 100 mT magnetic field exposure. Carcinogenesis 16:119–125; 1995.

Bawin, S. M.; Gavalas-Medici, R. J.; Adey, W. R. Reinforcement of transient brain rhythms by amplitude modulated VHF fields. In: Llaurado, J. G.; Sances, A.; Battocletti, J. H., eds. Biological and clinical effects of low frequency magnetic and electric fields. Springfield, IL: Charles C. Thomas; 1974: 172–186.

Bawin, S. M.; Kaczmarek, L. K.; Adey, W. R. Effects of modulated VHF fields on the central nervous system. Ann. NY Acad. Sci. 274:74–81; 1975.

Beall, C.; Delzell, E.; Cole, P.; Brill, I. Brain tumors among electronics industry workers. Epidemiology 7:125–130; 1996.

Beniashvili, D. S.; Bilanishvili, V. G.; Menabde, M. Z. The effect of low-frequency electromagnetic fields on the development of experimental mammary tumors. Vopr. Onkol. 37:937–941; 1991.

Bergqvist, U. Pregnancy outcome and VDU work—a review.

In: Luczak, H.; Cakir, A.; An Cakir, G., eds. Work with display units ‘92—Selected Proceedings of the 3rd International Conference WWDO ‘92, Berlin Germany, 1–4 September 1992. Amsterdam: Elsevier; 1993: 70–76.

Bernhardt, J. H. The direct influence of electromagnetic fields on nerve and muscle cells of man within the frequency range of 1 Hz to 30 MHz. Radiat. Environ. Biophys. 16:309–323; 1979.

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 3:486–494; 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.

515Guidelines for limiting exposure to time-varying electric, magnetic, and electromagnetic fields c ICNIRP GUIDELINES

Chou, C.-K.; Guy, A. W.; Kunz, L. I.; Johnson, R. B.; Crowley,

J. J.; Krupp, J. H. Long-term, low-level microwave irradiation of rats. Bioelectromagnetics 13:469–496; 1992.

Cohen, B. H.; Lillienfield, A. M.; Kramer, A. M.; Hyman,

L. C. C. Parental factors in Down9s syndrome: results of the second Baltimore case control study. In: Hook, E. B.; Porter, I. H., eds. Population cytogenetics—studies in humans. New York: Academic Press; 1977: 301–352.

Coleman, M. P.; Bell, C. M. J.; Taylor, H. L.; Primic-Zakelj,

M. Leukemia and residence near electricity transmission equipment: a case-control study. Br. J. Cancer 60:793–798; 1989.

Commission on Radiological Protection. Protection against low-frequency electric and magnetic fields in energy supply and use. Recommendation, approved on 16th/17th February 1995. In: Berichte der Strahlenschutzkommission des Bundesministeriums fur Umwelt, Naturschutz und Reaktorsicherheit, Heft 7. Stuttgart: Fischer; 1997.

Cook, M. R.; Graham, C.; Cohen, H. D.; Gerkovich, M. M. A replication study of human exposure to 60-Hz fields: effects on neurobehavioral measures. Bioelectromagnetics 13:261– 285; 1992.

Cridland, N. A. Electromagnetic fields and cancer: a review of relevant cellular studies. Chilton, UK: National Radiological Protection Board; Report NRPB-R256; 1993.

Daels, J. Microwave heating of the uterine wall during parturition. Obstet. Gynecol. 42:76–79; 1973.

Daels, J. Microwave heating of the uterine wall during parturition. J. Microwave Power 1:166–167; 1976.

D’Andrea, J. A.; DeWitt, J. R.; Gandhi, O. P.; Stensaas, S.;

Lords, J. L.; Neilson, H. C. Behavioral and physiological effects of chronic 2450-MHz microwave irradiation of the rat at 0.5 mW/cm2. Bioelectromagnetics 7:45–56; 1986.

De Lorge, J. O.; Ezell, C. S. Observing responses of rats exposed to 1.28- and 5.62-GHz microwaves. Bioelectromagnetics 1:183–198: 1980.

Demers, P. A.; Thomas, D. B.; Sternhagen, A.; Thompson,

W. D.; Curnen, M. G. M.; Satariano, W.; Austin, D. F.; Issacson, P.; Greenberg, R. S.; Key, C.; Kolonel, L. K.; West, D. W. Occupational exposure to electromagnetic fields and breast cancer in men. Am. J. Epidemiol. 132:775– 776; 1991.

Dimbylow, P. J. FDTD calculations of the whole-body averaged SAR in an anatomically realistic voxel model of the human body from 1 MHz to 1 GHz. Phys. Med. Biol. 42:479–490; 1997.

Dimbylow, P. J.; Mann, S. M. SAR calculations in an anatomically realistic model of the head for mobile communication transceivers at 900 MHz and 1.8 GHz. Phys. Med. Biol. 39:1537–1553; 1994.

(Parte 7 de 13)

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