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Occupational Health and Safety Measures in Agricultural Areas Contaminated by Radionuclides: The Chernobyl Experience

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Massive contamination of agricultural lands by radionuclides occurs, as a rule, due to large accidents at the enterprises of nuclear industry or nuclear power stations. Such accidents occurred at Windscale (England) and South Ural (Russia). The largest accident happened in April 1986 at the Chernobyl nuclear power station. The latter entailed intensive contamination of soils over several thousands of square kilometres.

The major factors contributing to radiation effects in agricultural areas are as follows:

  • whether radiation is from a single or a long-term exposure
  • total quantity of radioactive substances entering the environment
  • ratio of radionuclides in the fallout
  • distance from the source of radiation to agricultural lands and settlements
  • hydrogeological and soil characteristics of agricultural lands and the purpose of their use
  • peculiarities of work of the rural population; diet, water supply
  • time since the radiological accident.

 

As a result of the Chernobyl accident more than 50 million Curies (Ci) of mostly volatile radionuclides entered the environment. At the first stage, which covered 2.5 months (the “iodine period”), iodine-131 produced the greatest biological hazard, with significant doses of high-energy gamma radiation.

Work on agricultural lands during the iodine period should be strictly regulated. Iodine-131 accumulates in the thyroid gland and damages it. After the Chernobyl accident, a zone of very high radiation intensity, where no one was permitted to live or work, was defined by a 30 km radius around the station.

Outside this prohibited zone, four zones with various rates of gamma radiation on the soils were distinguished according to which types of agricultural work could be performed; during the iodine period, the four zones had the following radiation levels measured in roentgen (R):

  • zone 1—less than 0.1 mR/h
  • zone 2—0.1 to 1 mR/h
  • zone 3—1.0 to 5 mR/h
  • zone 4—5 mR/h and more.

 

Actually, due to the “spot” contamination by radionuclides over the iodine period, agricultural work in these zones was performed at levels of gamma irradiation from 0.2 to 25 mR/h. Apart from uneven contamination, variation in gamma radiation levels was caused by different concentrations of radionuclides in different crops. Forage crops in particular are exposed to high levels of gamma emitters during harvesting, transportation, ensilage and when they are used as fodder.

After the decay of iodine-131, the major hazard for agricultural workers is presented by the long-lived nuclides caesium-137 and strontium-90. Caesium-137, a gamma emitter, is a chemical analogue of potassium; its intake by humans or animals results in uniform distribution throughout the body and it is relatively quickly excreted with urine and faeces. Thus, the manure in the contaminated areas is an additional source of radiation and it must be removed as quickly as possible from stock farms and stored in special sites.

Strontium-90, a beta emitter, is a chemical analogue of calcium; it is deposited in bone marrow in humans and animals. Strontium-90 and caesium-137 can enter the human body through contaminated milk, meat or vegetables.

The division of agricultural lands into zones after the decay of short-lived radionuclides is carried out according to a different principle. Here, it is not the level of gamma radiation, but the amount of soil contamination by caesium-137, strontium-90 and plutonium-239 that are taken into account.

In the case of particularly severe contamination, the population is evacuated from such areas and farm work is performed on a 2-week rotation schedule. The criteria for zone demarcation in the contaminated areas are given in table 1.

Table 1. Criteria for contamination zones

Contamination zones

Soil contamination limits

Dosage limits

Type of action

1. 30 km zone

Residing of
population and
agricultural work
are prohibited.

2. Unconditional
resettlement

15 (Ci)/km2
caesium- 137
3 Ci/km2
strontium- 90
0.1 Ci/km2 plutonium

0.5 cSv/year

Agricultural work is performed with 2-week rotation schedule under strict radiological control.

3. Voluntary
resettlement

5–15 Ci/km2
caesium-137
0.15–3.0 Ci/km2
strontium-90
0.01–0.1 Ci/km2
plutonium

0.01–0.5
cSv/year

Measures are undertaken to reduce
contamination of
upper soil layer;
agricultural work
is carried out under strict radiological
control.

4. Radio- ecological
monitoring

1–5 Ci/km2
caesium-137
0.02–0.15 Ci/km2
strontium-90
0.05–0.01 Ci/km2
plutonium

0.01 cSv/year

Agricultural work is
carried out in usual way but under
radiological control.

 

When people work on agricultural lands contaminated by radionuclides, the intake of radionuclides by the body through respiration and contact with soil and vegetable dusts may occur. Here, both beta emitters (strontium-90) and alpha emitters are extremely dangerous.

As a result of accidents at nuclear power stations, part of radioactive materials entering the environment are low-dispersed, highly active particles of the reactor fuel—“hot particles”.

Considerable amounts of dust containing hot particles are generated during agricultural work and in windy periods. This was confirmed by the results of investigations of tractor air filters taken from machines which were operated on the contaminated lands.

The assessment of dose loads on the lungs of agricultural workers exposed to hot particles revealed that outside the 30 km zone the doses amounted to several millisieverts (Loshchilov et al. 1993).

According to the data of Bruk et al. (1989) the total activity of caesium-137 and caesium-134 in the inspired dust in machine operators amounted to 0.005 to 1.5 nCi/m3. According to their calculations, over the total period of field work the effective dose to lungs ranged from 2 to
70 cSv.

The relation between the amount of soil contamination by caesium-137 and radioactivity of work zone air was established. According to the data of the Kiev Institute for Occupational Health it was found that when the soil contamination by caesium-137 amounted to 7.0 to 30.0 Ci/km2 the radioactivity of the breathing zone air reached 13.0 Bq/m3. In the control area, where the density of contamination amounted to 0.23 to 0.61 Ci/km3, the radioactivity of work zone air ranged from 0.1 to 1.0 Bq/m3 (Krasnyuk, Chernyuk and Stezhka 1993).

The medical examinations of agricultural machine operators in the “clear” and contaminated zones revealed an increase in cardiovascular diseases in workers in the contaminated zones, in the form of ischaemic heart disease and neurocirculatory dystonia. Among other disorders dysplasia of the thyroid gland and an increased level of monocytes in the blood were registered more frequently.

Hygienic Requirements

Work schedules

After large accidents at nuclear power stations, temporary regulations for the population are usually adopted. After the Chernobyl accident temporary regulations for a period of one year were adopted, with the TLV of 10 cSv. It is assumed that workers receive 50% of their dose due to external radiation during work. Here, the threshold of intensity of radiation dose over the eight-hour work day should not exceed 2.1 mR/h.

During agricultural work, the radiation levels at workplaces can fluctuate significantly, depending on the concentrations of radioactive substances in soils and plants; they also fluctuate during technological processing (siloing, preparation of dry fodder and so on). In order to reduce dosages to workers, regulations of time limits for agricultural work are introduced. Figure 1 shows regulations which were introduced after the Chernobyl accident.

Figure 1. Time limits for agricultural work depending on intensity of gamma-ray  radiation at workplaces.

DIS090T2

Agrotechnologies

When carrying out agricultural work in conditions of high contamination of soils and plants, it is necessary to strictly observe measures directed at prevention of dust contamination. The loading and unloading of dry and dusty substances should be mechanized; the neck of the conveyer tube should be covered with fabric. Measures directed at the decrease of dust release must be undertaken for all types of field work.

Work using agricultural machinery should be carried out taking due account of cabin pressurization and the choice of the proper direction of operation, with the wind at the side being preferable. If possible it is desirable to first water the areas being cultivated. The wide use of industrial technologies is recommended so as to eliminate manual work on the fields as much as possible.

It is appropriate to apply substances to the soils which can promote absorption and fixation of radionuclides, changing them into insoluble compounds and thus preventing the transfer of radionuclides into plants.

Agricultural machinery

One of the major hazards for the workers is agricultural machinery contaminated by radionuclides. The allowable work time on the machines depends on the intensity of gamma radiation emitted from the cabin surfaces. Not only is the thorough pressurization of cabins required, but due control over ventilation and air conditioning systems as well. After work, wet cleaning of cabins and replacement of filters should be carried out.

When maintaining and repairing the machines after decontamination procedures, the intensity of gamma radiation at the outer surfaces should not exceed 0.3 mR/h.

Buildings

Routine wet cleaning should be done inside and outside buildings. Buildings should be equipped with showers. When preparing fodder which contains dust components, it is necessary to adhere to procedures aimed at prevention of dust intake by the workers, as well as to keep the dust off the floor, equipment and so on.

Pressurization of the equipment should be under control. Workplaces should be equipped with effective general ventilation.

Use of pesticides and mineral fertilizers

The application of dust and granular pesticides and mineral fertilizers, as well as spraying from aeroplanes, should be restricted. Machine spraying and application of granular chemicals as well as liquid mixed fertilizers are preferable. The dust mineral fertilizers should be stored and transported only in tightly closed containers.

Loading and unloading work, preparation of pesticide solutions and other activities should be performed using maximum individual protective equipment (overalls, helmets, goggles, respirators, rubber gauntlets and boots).

Water supply and diet

There should be special closed premises or motor vans without draughts where workers can take their meals. Before taking meals workers should clean their clothes and thoroughly wash their hands and faces with soap and running water. During summer periods field workers should be supplied with drinking water. The water should be kept in closed containers. Dust must not enter containers when filling them with water.

Preventive medical examinations of workers

Periodic medical examinations should be carried out by a physician; laboratory analysis of blood, ECG and tests of respiratory function are compulsory. Where radiation levels do not exceed permissible limits, the frequency of medical examinations should be not less than once every 12 months. Where there are higher levels of ionizing radiation the examinations should be carried out more frequently (after sowing, harvesting and so on) with due account of radiation intensity at workplaces and the total absorbed dose.

Organization of Radiological Control over Agricultural Areas

The major indices characterizing the radiological situation after fallout are gamma radiation intensity in the area, contamination of agricultural lands by the selected radionuclides and content of radionuclides in agricultural products.

The determination of gamma radiation levels in the areas allows the drawing of the borders of severely contaminated areas, estimation of doses of external radiation to people engaged in agricultural work and the establishing of corresponding schedules providing for radiological safety.

The functions of radiological monitoring in agriculture are usually the responsibility of radiological laboratories of the sanitary service as well as veterinary and agrochemical radiological laboratories. The training and education of the personnel engaged in dosimetric control and consultations for the rural population are carried out by these laboratories.

 

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Contents

Disasters, Natural and Technological References

American Psychiatric Association (APA). 1994. DSM-IV Diagnostic and Statistical Manual of Mental Disorders. Washington, DC: APA.

 

Andersson, N, M Kerr Muir, MK Ajwani, S Mahashabde, A Salmon, and K Vaidyanathan. 1986. Persistent eye watering among Bhopal survivors. Lancet 2:1152.

 

Baker, EL, M Zack, JW Miles, L Alderman, M Warren, RD Dobbin, S Miller, and WR Teeters. 1978. Epidemic malathion poisoning in Pakistan malaria working. Lancet 1:31-34.

 

Baum, A, L Cohen, and M Hall. 1993. Control and intrusive memories as possible determinants of chronic stress. Psychosom Med 55:274-286.

 

Bertazzi, PA. 1989. Industrial disasters and epidemiology. A review of recent experiences. Scand J Work Environ Health 15:85-100.

 

—. 1991. Long-term effects of chemical disasters. Lessons and result from Seveso. Sci Total Environ 106:5-20.

 

Bromet, EJ, DK Parkinson, HC Schulberg, LO Dunn, and PC Condek. 1982. Mental health of residents near the Three Mile Island reactor: A comparative study of selected groups. J Prev Psychiat 1(3):225-276.

 

Bruk, GY, NG Kaduka, and VI Parkhomenko. 1989. Air contamination by radionuclides as a result of the accident at the Chernobyl power station and its contribution to inner irradiation of the population (in Russian). Materials of the First All-Union Radiological Congress, 21-27 August, Moscow. Abstracts (in Russian). Puschkino, 1989, vol. II:414-416.

 

Bruzzi, P. 1983. Health impact of the accidental release of TCDD at Seveso. In Accidental Exposure to Dioxins. Human Health Aspects, edited by F Coulston and F Pocchiari. New York: Academic Press.

 

Cardis, E, ES Gilbert, and L Carpenter. 1995. Effects of low doses and low dose rates of external ionizing radiation: Cancer mortality among nuclear industry workers in three countries. Rad Res 142:117-132.

 

Centers for Disease Control (CDC). 1989. The Public Health Consequences of Disasters. Atlanta: CDC.

 

Centro Peruano-Japones de Investigaciones Sismicas y Mitigacióm de Desastres. Universidad Nacional de Ingeniería (CISMID). 1989. Seminario Internacional De Planeamiento Diseño,

 

Reparación Y Adminstración De Hospitales En Zonas Sísmicas: Conclusiones Y Recommendaciones. Lima: CISMID/Univ Nacional de Ingeniería.

 

Chagnon, SAJR, RJ Schicht, and RJ Semorin. 1983. A Plan for Research on Floods and their Mitigation in the United States. Champaign, Ill: Illinois State Water Survey.

 

Chen, PS, ML Luo, CK Wong, and CJ Chen. 1984. Polychlorinated biphenyls, dibenzofurans, and quaterphenyls in toxic rice-bran oil and PCBs in the blood of patients with PCB poisoning in Taiwan. Am J Ind Med 5:133-145.

 

Coburn, A and R Spence. 1992. Earthquake Protection. Chichester: Wiley.

 

Council of the European Communities (CEC). 1982. Council Directive of 24 June on the major accident hazards of certain industrial activities (82/501/EEC). Off J Eur Communities L230:1-17.

 

—. 1987. Council Directive of 19 March amending Directive 82/501/EEC on the major accident hazards of certain industrial activities (87/216/EEC). Off J Eur Communities L85:36-39.

 

Das, JJ. 1985a. Aftermath of Bhopal tragedy. J Indian Med Assoc 83:361-362.

 

—. 1985b. The Bhopal tragedy. J Indian Med Assoc 83:72-75.

 

Dew, MA and EJ Bromet. 1993. Predictors of temporal patterns of psychiatric distress during ten years following the nuclear accident at Three Mile Island. Social Psych Psychiatric Epidemiol 28:49-55.

 

Federal Emergency Management Agency (FEMA). 1990. Seismic considerations: Health care facilities. Earthquake Hazard Reduction Series, No. 35. Washington, DC: FEMA.

 

Frazier, K. 1979. The Violent Face of Nature: Severe Phenomena and Natural Disasters. Floods. New York: William Morrow & Co.

 

Freidrich Naumann Foundation. 1987. Industrial Hazards in Transnational Work: Risk, Equity and Empowerment. New York: Council on International and Public Affairs.

 

French, J and K Holt. 1989. Floods: Public Health Consequences of Disasters. Centers for Disease Control Monograph. Atlanta: CDC.

 

French, J, R Ing, S Von Allman, and R Wood. 1983. Mortality from flash floods: A review of National Weather Service reports, 1969-1981. Publ Health Rep 6(November/December):584-588.

 

Fuller, M. 1991. Forest Fires. New York: John Wiley.

 

Gilsanz, V, J Lopez Alverez, S Serrano, and J Simon. 1984. Evolution of the alimentary toxic oil syndrome due to ingestion of denatured rapeseed oil. Arch Int Med 144:254-256.

 

Glass, RI, RB Craven, and DJ Bregman. 1980. Injuries from the Wichita Falls tornado: Implications for prevention. Science 207:734-738.

 

Grant, CC. 1993. Triangle fire stirs outrage and reform. NFPA J 87(3):72-82.

 

Grant, CC and TJ Klem. 1994. Toy factory fire in Thailand kills 188 workers. NFPA J 88(1):42-49.

 

Greene, WAJ. 1954. Psychological factors and reticuloendothelial disease: Preliminary observations on a group of males with lymphoma and leukemia. Psychosom Med:16-20.

 

Grisham, JW. 1986. Health Aspects of the Disposal of Waste Chemicals. New York: Pergamon Press.

 

Herbert, P and G Taylor. 1979. Everything you always wanted to know about hurricanes: Part 1. Weatherwise (April).

 

High, D, JT Blodgett, EJ Croce, EO Horne, JW McKoan, and CS Whelan. 1956. Medical aspects of the Worcester tornado disaster. New Engl J Med 254:267-271.

 

Holden, C. 1980. Love Canal residents under stress. Science 208:1242-1244.

 

Homberger, E, G Reggiani, J Sambeth, and HK Wipf. 1979. The Seveso accident: Its nature, extent and consequences. Ann Occup Hyg 22:327-370.

 

Hunter, D. 1978. The Diseases of Occupations. London: Hodder & Stoughton.

 

International Atomic Energy Agency (IAEA). 1988. Basic Safety Principles for Nuclear Power Plants INSAG-3. Safety Series, No. 75. Vienna: IAEA.

 

—. 1989a. L’accident radiologique de Goiânia. Vienna: IAEA.

 

—. 1989b. A large-scale Co-60 contamination case: Mexico 1984. In Emergency Planning and Preparedness for Accidents Involving Radioactive Materials Used in Medicine, Industry, Research and Teaching. Vienna: IAEA.

 

—. 1990. Recommendations for the Safe Use and Regulation of Radiation Sources in Industry, Medicine, Reasearch and Teaching. Safety Series, No. 102. Vienna: IAEA.

 

—. 1991. The International Chernobyl Project. Technical report, assessment of radiological consequences and evaluation of protective measures, report by an International Advisory Committee. Vienna: IAEA.

 

—. 1994. Intervention Criteria in a Nuclear or Radiation Emergency. Safety Series, No. 109. Vienna: IAEA.

 

International Commission on Radiological Protection (ICRP). 1991. Annals of the ICRP. ICRP Publication No. 60. Oxford: Pergamon Press.

 

International Federation of Red Cross and Red Crescent Societies (IFRCRCS). 1993. The World Disaster Report. Dordrecht: Martinus Nijhoff.

 

International Labour Organization (ILO). 1988. Major Hazard Control. A Practical Manual. Geneva: ILO.

 

—. 1991. Prevention of Major Industrial Accidents. Geneva: ILO.

 

—. 1993. Prevention of Major Industrial Accidents Convention, 1993 (No. 174). Geneva: ILO.

 

Janerich, DT, AD Stark, P Greenwald, WS Bryant, HI Jacobson, and J McCusker. 1981. Increased leukemia, lymphoma and spontaneous abortion in Western New York following a disaster. Publ Health Rep 96:350-356.

 

Jeyaratnam, J. 1985. 1984 and occupational health in developing countries. Scand J Work Environ Health 11:229-234.

 

Jovel, JR. 1991. Los efectos económicos y sociales de los desastres naturales en América Latina y el Caribe. Santiago, Chile: Document presented at the First Regional UNDP/UNDRO Disaster Management Training Program in Bogota, Colombia.

 

Kilbourne, EM, JG Rigau-Perez, J Heath CW, MM Zack, H Falk, M Martin-Marcos, and A De Carlos. 1983. Clinical epidemiology of toxic-oil syndrome. New Engl J Med 83:1408-1414.

 

Klem, TJ. 1992. 25 die in food plant fire. NFPA J 86(1):29-35.

 

Klem, TJ and CC Grant. 1993. Three Workers Die in Electrical Power Plant Fire. NFPA J 87(2):44-47.

 

Krasnyuk, EP, VI Chernyuk, and VA Stezhka. 1993. Work conditions and health status of operators of agricultural machines in areas being under control due to the Chernobyl accident (in Russian). In abstracts Chernobyl and Human Health Conference, 20-22 April.

 

Krishna Murti, CR. 1987. Prevention and control of chemical accidents: Problems of developing countries. In Istituto Superiore Sanita’, World Health Organization, International Programme On Chemical Safety. Edinburgh: CEP Consultants.

 

Lancet. 1983. Toxic oil syndrome. 1:1257-1258.

 

Lechat, MF. 1990. The epidemiology of health effects of disasters. Epidemiol Rev 12:192.

 

Logue, JN. 1972. Long term effects of a major natural disaster: The Hurricane Agnes flood in the Wyoming Valley of Pennsylvania, June 1972. Ph.D. Dissertation, Columbia Univ. School of Public Health.

 

Logue, JN and HA Hansen. 1980. A case control study of hypertensive women in a post-disaster community: Wyoming Valley, Pennsylvania. J Hum Stress 2:28-34.

 

Logue, JN, ME Melick, and H Hansen. 1981. Research issues and directions in the epidemiology of health effects of disasters. Epidemiol Rev 3:140.

 

Loshchilov, NA, VA Kashparov, YB Yudin, VP Proshchak, and VI Yushchenko. 1993. Inhalation intake of radionuclides during agricultural works in the areas contaminated by radionuclides due to the Chernobyl accident (in Russian). Gigiena i sanitarija (Moscow) 7:115-117.

 

Mandlebaum, I, D Nahrwold, and DW Boyer. 1966. Management of tornado casualties. J Trauma 6:353-361.

 

Marrero, J. 1979. Danger: Flash floods—the number one killer of the 70’s. Weatherwise (February):34-37.

 

Masuda, Y and H Yoshimura. 1984. Polychlorinated biphenyls and dibenzofurans in patients with Yusho and their toxicological significance: A review. Am J Ind Med 5:31-44.

 

Melick, MF. 1976. Social, psychological and medical aspects of stress related illness in the recovery period of a natural disaster. Dissertation, Albany, State Univ. of New York.

 

Mogil, M, J Monro, and H Groper. 1978. NWS’s flash flood warning and disaster preparedness programs. B Am Meteorol Soc :59-66.

 

Morrison, AS. 1985. Screening in Chronic Disease. Oxford: OUP.

 

National Fire Protection Association (NFPA). 1993. National Fire Alarm Code. NFPA No. 72. Quincy, Mass: NFPA.

 

—. 1994. Standard for the Installation of Sprinkler Systems. NFPA No. 13. Quincy, Mass: NFPA.

 

—. 1994. Life Safety Code. NFPA No. 101. Quincy, Mass: NFPA.

 

—. 1995. Standard for the Inspection, Testing, and Maintenance of Water-Based Fire Protection Systems. NFPA No. 25. Quincy, Mass: NFPA.

 

Nénot, JC. 1993. Les surexpositions accidentelles. CEA, Institut de Protection et de Sûreté Nucléaire. Rapport DPHD/93-04.a, 1993, 3-11.

 

Nuclear Energy Agency. 1987. The Radiological Impact of the Chernobyl Accident in OECD Countries. Paris: Nuclear Energy Agency.

 

Otake, M and WJ Schull. 1992. Radiation-related Small Head Sizes among Prenatally Exposed Atomic Bomb Survivors. Technical Report Series, RERF 6-92.

 

Otake, M, WJ Schull, and H Yoshimura. 1989. A Review of Radiation-related Damage in the Prenatally Exposed Atomic Bomb Survivors. Commentary Review Series, RERF CR 4-89.

 

Pan American Health Organization (PAHO). 1989. Analysis of PAHO’s Emergency Preparedness and Disaster Relief Program. Executive Committee document SPP12/7. Washington, DC: PAHO.

 

—. 1987. Crónicas de desastre: terremoto en México. Washington, DC: PAHO.

 

Parrish, RG, H Falk, and JM Melius. 1987. Industrial disasters: Classification, investigation, and prevention. In Recent Advances in Occupational Health, edited by JM Harrington. Edinburgh: Churchill Livingstone.

 

Peisert, M comp, RE Cross, and LM Riggs. 1984. The Hospital’s Role in Emergency Medical Services Systems. Chicago: American Hospital Publishing.

 

Pesatori, AC. 1995. Dioxin contamination in Seveso: The social tragedy and the scientific challenge. Med Lavoro 86:111-124.

 

Peter, RU, O Braun-Falco, and A Birioukov. 1994. Chronic cutaneous damage after accidental exposure to ionizing radiation: The Chernobyl experience. J Am Acad Dermatol 30:719-723.

 

Pocchiari, F, A DiDomenico, V Silano, and G Zapponi. 1983. Environmental impact of the accidental release of tetrachlorodibenzo-p-dioxin(TCDD) at Seveso. In Accidental Exposure to Dioxins: Human Health Aspects, edited by F Coulston and F Pocchiari. New York: Academic Press.

 

—. 1986. The Seveso accident and its aftermath. In Insuring and Managing Hazardous Risks: From Seveso to Bhopal and Beyond, edited by PR Kleindorfer and HC Kunreuther. Berlin: Springer-Verlag.

 

Rodrigues de Oliveira, A. 1987. Un répertoire des accidents radiologiques 1945-1985. Radioprotection 22(2):89-135.

 

Sainani, GS, VR Joshi, PJ Mehta, and P Abraham. 1985. Bhopal tragedy -A year later. J Assoc Phys India 33:755-756.

 

Salzmann, JJ. 1987. ìSchweizerhalleî and Its Consequences. Edinburgh: CEP Consultants.

 

Shore, RE. 1992. Issues and epidemiological evidences regarding radiation-induced thyroid cancer. Rad Res 131:98-111.

 

Spurzem, JR and JE Lockey. 1984. Toxic oil syndrome. Arch Int Med 144:249-250.

 

Stsjazhko, VA, AF Tsyb, ND Tronko, G Souchkevitch, and KF Baverstock. 1995. Childhood thyroid cancer since accidents at Chernobyl. Brit Med J 310:801.

 

Tachakra, SS. 1987. The Bhopal Disaster. Edinburgh: CEP Consultants.

 

Thierry, D, P Gourmelon, C Parmentier, and JC Nenot. 1995. Hematopoietic growth factors in the treatment of therapeutic and accidental irradiation-induced aplasia. Int J Rad Biol (in press).

 

Understanding Science and Nature: Weather and Climate. 1992. Alexandria, Va: Time-Life.

 

United Nations Disaster Relief Coordinator Office (UNDRO). 1990. Iran earthquake. UNDRO News 4 (September).

 

United Nations Scientific Committee on the Effects of Atomic Radiation (UNSCEAR). 1988. Sources, Effects and Risks of Ionizing Radiation. New York: UNSCEAR.

 

—. 1993. Sources and Effects of Ionizing Radiation. New York: UNSCEAR.

 

—. 1994. Sources and Effects of Ionizing Radiation. New York: UNSCEAR.

 

Ursano, RJ, BG McCaughey, and CS Fullerton. 1994. Individual and Community Responses to Trauma and Disaster: The Structure of Human Chaos. Cambridge: Cambridge Univ. Press.

 

US Agency for International Development, (USAID). 1989. Soviet Union: Earthquake. OFDA/AID Annual Report, FY1989. Arlington, Va: USAID.

 

Walker, P. 1995. World Disaster Report. Geneva: International Federation of Red Cross and Red Crescent Societies.

 

Wall Street J. 1993 Thailand fire shows region cuts corners on safety to boost profits, 13 May.

 

Weiss, B and TW Clarkson. 1986. Toxic chemical disaster and the implication of Bhopal for technology transfer. Milbank Q 64:216.

 

Whitlow, J. 1979. Disasters: The Anatomy of Environmental Hazards. Athens, Ga: Univ. of Georgia Press.

 

Williams, D, A Pinchera, A Karaoglou, and KH Chadwick. 1993. Thyroid Cancer in Children Living Near Chernobyl. Expert panel report on the consequences of the Chernobyl accident, EUR 15248 EN. Brussels: Commission of the European Communities (CEC).

 

World Health Organization (WHO). 1984. Toxic Oil Syndrome. Mass Food Poisoning in Spain. Copenhagen: WHO Regional office for Europe.

 

Wyllie, L and M Durkin. 1986. The Chile earthquake of March 3, 1985: Casualties and effects on the health care system. Earthquake Spec 2(2):489-495.

 

Zeballos, JL. 1993a. Los desastres quimicos, capacidad de respuesta de los paises en vias de desarrollo. Washington, DC: Pan American Health Organization (PAHO).

 

—. 1993b. Effects of natural disasters on the health infrastructure: Lessons from a medical perspective. Bull Pan Am Health Organ 27: 389-396.

 

Zerbib, JC. 1993. Les accidents radiologiques survenus lors d’usages industriels de sources radioactives ou de générateurs électirques de rayonnement. In Sécurité des sources radioactives scellées et des générateurs électriques de rayonnement. Paris: Société française de radioprotection.