1. Pomeroy, Chairman, Advisory Committee on Nuclear Waste,
letter to Chairman Jackson, Nuclear Regulatory Commission, July 10, 1996.
2. Radiation, Science, and Health, (1998) Low-Level Radiation Health Effects :
Compiling the Data, J. Muckerheide, Ed., Radiation, Science, and Health, Inc., Needham,
MA.
3. BEIR V (1990) Health effects of exposure to low levels of ionizing
radiation, Report of the Advisory Committee on the Biological Effects of Ionizing
Radiations (BEIR Committee) National Academy of Sciences-National Research Council,
Washington, D.C.
4. Cardis, E., et al (1995) Effects of low doses and low dose rates of external
ionizing radiation: Cancer mortality among nuclear industry workers in three countries,
Radiat. Res., 145, 647.
5. Muckerheide, J. (1995b) The health effects of low level radiation science,
data, and corrective actions, Nuclear News, 38, 11 (Sep).
6. Pollycove, M. (1994) Positive health effects of low level radiation in human
populations, In: Biological Effects of Low-Level Exposures: Dose-Response Relationships,
Calabrese, Ed., Lewis Publishers, Boca Raton, FL
7. Schillaci, M.E. (1995) Radiation, A look at the data, ANS/ENS Embedded
Topical Meeting: Low Level Radiation Health Effects, ANS Trans., 75:p
8. Mendelsohn, M.L. (1996) Final Report of the Ethics Committee Investigation,
21 Nov 1996
9. Selby, P. (1998) ORNL, Personal Communication
10. Willis, C.A. (1996) Transcript, ACRS/ACNW Joint Subcommittee Meeting #1,
March 26, 1996
11. Matanoski, G.M. (1991) Health effects of low-level radiation in shipyard
workers final report, June 1991, DOE, DE-AC02-79, EV10095.
12. Cameron, J. (1992) The good news about low level radiation exposure: Health
effects of low level radiation in shipyard workers, Health Phys. Soc. Newsletter 20:9.
13. Cameron, J. (1994) What does the nuclear shipyard worker tell us, ANS
Trans, Vol 71, p36.
14. Thomas, R.G. (1994) The US radium luminisers: A case for a policy of
‘below regulatory concern’ , J. Radiol. Prot., 14, 2, pp 141-153.
15. Thomas, R.G. (1995) Radiation is not always harmful to human health, ANS
Transactions, Vol 72, p.6.
16. Rowland, R.E. (1997) Bone sarcoma in humans induced by radium: a threshold
response? In: Proceedings of the 27th Annual Meeting of the European Society for Radiation
Biology, Radioprotection colloques, 32, C1/p331.
17. Fry, S. (1995) Followup study of workers exposed to >50 mSv/y radiation,
ANS Transactions Vol. 72, p8.
18. Walinder, G. (1995) Has Radiation Protection become a Health Hazard?,
Karnkraftsakerhet & Utbildning AB (The Swedish Nuclear Training and Safety Center)
Nykoping, Sweden.
19. Sagan, L.A. (1987) What is hormesis and why haven’t we heard about it
before, Health Phys. 52:pp521-525.
20. Taylor, L.S. (1980) Proceedings 5th International Congress of the
International Radiation Protection Assoc., Vol. 1, Some nonscientific influences on
radiation protection standards and practice. pp. 307-319. The Israel Health Physics
Society, Jerusalem.
21. Walinder, G. (1996b) personal communication.
22. NCRP (1987) Exposure of the Population of the US and Canada from Natural
Background Radiation, NCRP Report 94, National Council on Radiation Protection and
Measurements, Bethesda, Md.
23. Luckey, T.D. (1980a) Hormesis with Ionizing Radiation. CRC Press, Boca
Raton, FL
24. Luckey, T.D. (1991) Radiation Hormesis, CRC Press, Boca Raton, FL.
25. Pollycove, M. and Feinendegen, L. (1998) Quantification of human total and
mis/unrepaired DNA alterations: intrinsic and radiation induced, to be published.
26. UNSCEAR (1993) Sources and effects of ionizing radiation. United Nations
Scientific Committee on the Effects of Atomic Radiation, 1993 Report to the General
Assembly, Annex E: Mechanisms of radiation oncogenesis, United Nations, New York.
27. NCRP (1995) Principles and Application of Collective Dose in Radiation
Protection. NCRP Report No. 121 National Council on Radiation Protection and Measurements,
Bethesda. MD; 45.
28. Bond, V.P., Feinendegen, L.E. and Sondhaus, C.A. (1987) Microdosimetric
concepts applied to hormesis, Health. Phys., 52, 659.
29. Azzam, E.I., de Toledo, S.M., Raaphorst, G.P. and Mitchel, R.E.J. (1996)
Low-Dose Ionizing Radiation Decreases the Frequency of Neoplastic Transformation to a
Level below the Spontaneous Rate in C3H 10T1/2 Cells, Radiat. Res. 146, p369.
30. Sakamoto, K., Miyamoto, M. and Watabe, N. (1987a) The effect of low-dose
total body irradiation on tumor control. Ganto Kagaku-Ryoho, 14, 247; Jpn J. Cancer Clin.,
33, 1633; Jpn. J. Cancer-Chemother 14, 1545.
31. Sakamoto, K. and Miyamoto, M. (1987b) Tumor control effect by total body
irradiation, Oncologia, 20 2, 86.
32. Sakamoto, K and Myojin, M. (1996). Fundamental and clinical studies on
tumor control by total body irradiation, Am. Nucl. Soc. Trans. 75, 404.
33. Liu, S.Z. (1997) Cellular and molecular basis of the stimulatory effect of
low dose radiation on immunity, In: Wei, L., Sugahara, T. and Tao, Z., High Levels of
Natural Radiation 1996: Radiation Dose and Health Effects, Beijing, Elsevier, pp341-353.
34. Azzam, E.I., de Toledo, S.M., Gooding, T. and Little, J.B. (1998)
Intercellular communication is involved in the bystander regulation of gene expression in
human cells exposed to very low fluences of alpha particles, Radiat. Res. 150, pp497-504
35. Bogen, K.T. (1996b) A cytodynamic two-stage model that predicts radon
hormesis (decreased, then increased lung-cancer risk vs. exposure), Preprint
UCRL-JC-123219. Lawrence Livermore National Laboratory, Livermore, CA (40 p150 references)
36. Fleck, C.M. et al. (1999) Modeling Radioprotective Mechanisms for the Dose
Effect Relation at Low Does and Low Doses Rates of Ionizing Radiation, Math. Biosci. (in
press)
37. Schollnberger, H. et al (1999) Cell Cycle Delay
and Misrepair in a Biophysical model of Adaptive Response in Carcinogenic Processes (in
press)
38. Balaram, P., and Mani, K.S. (1994) Review: Low dose radiation A
curse or a boon?, Nat. Med. J. India, 7, 4.
39. van Wyngaarden, K.E. and Pauwels, E.K.J.(1995) Hormesis: are low doses of
ionizing radiation harmful or beneficial?, European J. Nucl. Med., 22,5.
40. Pollycove, M. (1996) Positive health effects of low-level radiation....and
why, University of California, San Francisco.
41. Muckerheide, J. and Rockwell, T. (1997) The hazards of U.S. policy on
low-level radiation, 21st Century Sci. Tech. 10:pp126-22.
42. Calabrese, E.J., Ed. (1992) Biological effects of low level exposures to
chemicals and radiation, Lewis Publishers, Chelsea, MI.
43. Calabrese, E.J., Ed. (1994) Biological effects of low level exposures: dose
response relationships, Boca Raton, FL: Lewis Publishers.
44. Smith-Sonneborn, J. (1992) The role of ëstress protein responseí in
hormesis, In: Low Dose Irradiation and Biological Defense Mechanisms (T. Sugahara, L.
Sagan and T. Aoyama, eds.). Excerpta Medica, Amsterdam, Holland, pp399-404.
45. Smith-Sonneborn, J. (1996) Heat shock proteins as an adaptive response:
Oxidant and exercise induced stress response, Third BELLE Conference, Toxicological
Defense Mechanisms and the Shape of Dose-Response Relationships.
46. Croute, F., Vidal, S., Soleilhavoup, J.P., Vincent, C., Serre, G. and
Planel, H. (1986) Effects of a very low dose rate of chronic ionizing radiation on the
division potential of human embryonic lung fibroblasts in vitro, Exp. Gerontol. 21:pp1-11.
47. Planel, H., Soleilhavoup, J.P., Tixador, R., Conter, A., Croute, F.
Caratero, C. and Gaubin, Y. (1987) Influence on Cell Proliferation of Background Radiation
or Exposure to Very Low, Chronic g Radiation, Health Physics, Pergamon Press, N.Y. Vol.
52, No. 5, pp 571-578,
48. Kondo, S. (1993) Health Effects of Low-Level Radiation, Kinki University
Press, Osaka, and Medical Physics Publishing Co., Madison, WI.
49. Hattori, S. (1994a) State of research and perspectives on radiation
hormesis in Japan, Intern. J. Occup. Med. Toxicol.,3:pp203-217.
50. Alvarez, J.L. and Seiler, F.A. (1996) New Approaches to Low-Dose Risk
Modeling, Technology: J. Franklin Inst. 333A, pp33-51.
51. Mine, M., Nakamura, T., Mori, H., Kondo, H. and Okajima, S. (1981) The
current mortality rates of A-bomb survivors in Nagasaki City, Jpn. J. Public Health, 28,
pp337-342 (in Japanese with English abstract).
52. Mine, M., Okumura, Y., Ichimara, M., Nakamura, T. and Kondo, S. (1990)
Apparently beneficial effect of low to intermediate doses of a-bomb radiation on human
lifespan, Int. J. Radial. Biol. 58:1035.
53. Pollycove, M. (1994) Positive Health Effects of Low Level Radiation in
Human Populations. In: Biological Effects of Low Level Exposures:Dose-Response
Relationships, Ed. Calabrese, E.J. Lewis Boca Raton pp171
54. Jaworowski, Z. (1995a) Beneficial Radiation, Nukleonika, 40, pp3-11.
55. Matanoski, G.M. (1991) Health effects of low-level radiation in shipyard
workers final report, June 1991, DOE, DE-AC02-79, EV10095.
56. Luckey, T.D. (1997) Low-dose irradiation reduces cancer deaths, Rad.
Protect. Mgmt., Nov/Dec 1997, pp58-64.
57. Berry, R.J., et al (1994) Biological markers, morbidity, and mortality in a
long-serving radiation worker population, ANS Trans., Vol. 71 (Nov) pp40.
58. Patterson, H.W. (1997) Setting standards for radiation protection: The
process appraised, Health Physics 72, p450.
59. Yalow, R.S. (1994) Concerns with low level ionizing radiation, Mayo Clinic
Proc., Vol. 69, pp 436-440.
60. Henry, H. F. (1961) Is all nuclear radiation harmful?, J. Am. Med. Assoc.,
176, 671.
61. Smith, P.G. and Doll, R. (1981) Mortality from cancer and all causes among
British radiologists. Br. J. Radiol. 54:187-94
62. Jablon, S. and Miller, R.W. (1978) Army technologists: 29-year follow up
for cause of death. Radiology 126:677-79
63. Boice, J.D., Mandel, J.S. and Doody, M.M. (1995) Breast cancer among
radiologic technologists, JAMA Vol. 274 No. 5, pp394-401
64. Holm, L.E., Hall, P., Wiklund, K., Lundell, G., Berg, G., Bjelkengren, G.,
et al. (1991) Cancer risk after iodine-131 therapy for hyperthyroidism, J. Natl. Cancer
Inst.; 83:pp1072-1077.
65. Boice, J.D. Jr, Morin, M.M., Glass, A.G., Friedman, G.D., Stovall, M.,
Hoover, R.N. and Fraumeni, J.F. Jr (1991) Diagnostic x-ray procedures and risk of
leukemia, lymphoma, and multiple myeloma, Epidemiology and Biostatistics Program, National
Cancer Institute, Bethesda, MD 20852. JAMA 265:pp1290-1294.
66. Linos, A., Gray, J.E., Orvis, A.L., Kyle, R.A., O’Fallon, W.M. and
Kurland, L.T. (1980) Low Dose Radiation and Leukemia, New England J. Med. 302:pp1101-1105.
67. Miller, A.B., Howe, G.R., Sherman, G.J., Lindsay, J.P., Yaffe, M.J.,
Dinner, P.J., Risch, H.A. and Preston, D.L. (1989) Mortality from breast cancer after
irradiation during fluoroscopic examination in patients being treated for tuberculosis, N.
Engl. J. Med. 321:1285.
68. Howe, G.R. and McLaughlin, J. (1996) Breast cancer mortality-survivors
study, Radiation Res. 145;pp694-707
69. Kaplan, I.I. (1959) Genetic effects in children and grandchildren of women
treated for infertility and sterility by radiation therapy, Radiology, 72, 518.
70. Evans, R.D. (1974) Radium in Man, Health Physics, 27, pp497-510.
71. Rundo, J. et al Eds: (1983) Radiobiology of Radium and the Actinides in
Man. Health Phys. 44S1
72. Maletskos, C.J. (1994) Radium in man - 20 years later, ANS Transactions,
vol 71, p33.
73. Raabe, O.G. (1994) Health Physics Society Summer School, Med Phys Pub
Madison WI
74. Spiers, F.W., et al. (1983) Leukemia incidence in the U.S. Dial Workers,
Health Phys. Soc. Newsletter, 44:1.
75. Robinette, C., Jablon, S. and Preston, T.L. (1985) Studies of participants
in nuclear tests, Final Rep. DOE/EV/0157, Nat. Res. Council, Washington, DC.
76. National Academy of Sciences/Institute of Medicine (1996) Health Effects of
Naval Personnel Participating in Operation Crossroads, National Academy Press, Washington,
D.C.
77. Kumatori, T., Ishihara, T. et al (1980) Follow-up studies over a 25 year
period on the Japanese fishermen exposed to radioactive fallout in l954. In: The Medical
Basis for Radiation Preparedness (Hubner, K.F. and Fry, A.A., eds.) Elsevier, NY, pp33-54.
78. Luckey, T.D. (1996) The evidence for radiation hormesis, 21st Century Sci.
Tech. 9:pp12-20.
79. Jaworowski, Z. (1995b) Stimulating effects of ionizing radiation: New
issues for regulatory policy, Regulatory Toxicology and Pharmacology, 22:2.
80. Brodsky, A. (1996) Review of radiation risks and uranium toxicity with
application to decisions associated with decomissioning clean-up criteria, RSA
Publications, ISBN-0-9630191-2-0, Hebron, CT.
81. Jaworowski, Z. (1997) All the Chernobyl's victims, Nukleonika, in press.
82. Shantyr I.I., Makarova N.V. and Saigina E.B. (1997) Cancer Morbidity Among
the Emergency Workers of the Chernobyl Accident, In: Low Doses of Ionizing Radiation:
Biological Effects and Regulatory Control, IAEA-TECDOC-976, IAEA-CN-67/115, p366.
83. Sohrabi, M. (1997a) World high level natural radiation and/or radon-prone
areas with special regard to dwellings, In: High Levels of Natural Radiation 1996:
Radiation Dose and Health Effects, Editors: Wei, Luxin; Sugahara, Tsatomu and Tao, Zufan,
Beijing; Elsevier Science Publishers, B.V. Amsterdam, pp57-68.
84. Wei, L. (1997) High background radiation area-an important source of
exploring the health effects of low dose ionizing radiation, In: High Levels of Natural
Radiation 1996: Radiation Dose and Health Effects, Editors: Wei, L.; Sugahara, T. and Tao,
Z., Beijing; Elsevier, Amsterdam, pp1-14; 58-59, pp63-66.
85. Frigerio, N.A., Eckerman, K.F. and Stowe, R.S. (1973) Carcinogenic Hazard
from Low-Level, Low-Rate Radiation, Part I, Rep. ANL/ES-26. Argonne Nat. Lab
86. Frigerio, N.A., 1978, personal communication.
87. Sandquist, G., Kunze, J. et al (1997) Assessing Latent Health Effects from
US Background Radiation, ANS Trans. (Nov)
88. Goldman, M. (1989) Cancer and Background Radiation in U.S. States, HPS
Newsletter
89. Cohen, B.L. (1987) Tests of the linear, no-threshold dose-response
relationship for high-let radiation, Health Phys. 52:629.
90. Cohen, B.L. (1989) Expected indoor 222Rn levels in counties with very high
and very low lung cancer rates, Health Phys. 57:897.
91. Cohen, B.L. (1990) A test of the linear-no threshold theory of radiation
carcinogenesis, Environ. Res., 53, pp193-220.
92. Cohen, B.L. and Shah, R. (1991) Mean radon levels in U.S. homes by states
and counties, Health Phys. 69:pp243-254.
93. Cohen, B.L. (1992) Compilation and integration of studies of radon levels
in U.S. homes by states and counties, Crit. Rev. Environment. Control 22:243.
94. Cohen, B.L. (1993) Relationship between exposure to radon and various types
of cancer, Health Phys. 65(5), pp529-531.
95. Cohen, B.L. (1994) Dose-response relationship for radiation carcinogenesis
in the low-dose region, Int. Arch. Occup. Environ. Health 66:pp71-75.
96. Cohen, B.L. and Colditz, G.A. (1994) Tests of the linear-no threshold
theory for lung cancer induced by exposure to radon, Environmental Res., 64:65.
97. Cohen, B.L. (1995) Test of the linear-no threshold theory of radiation
carcinogenesis for inhaled radon decay products. Health Phys., 68, pp157-174.
98.
Jagger, J. (1998) Natural background
radiation and cancer death in rocky mountain states and gulf coast states, Health Physics
75, 4.
99. Cohen, B.L. (1997a) Problems in the radon vs lung cancer test of the linear
no-threshold theory and a procedure for resolving them, Health Phys., 72, 4.
100. Cohen, B.L. (1997b) Questionnaire study of the lung cancer risk from radon
in homes, Health Phys., 72, 4.
101. Seiler, F.A. and Alvarez, J.L. (1999) Is the "Ecological
Fallacy": A Fallacy? (preprint)
102. Kondo, S. (1997) Cancer incidence in Misasa, a spa area in Japan with a
high radon background.
103. Freire-Maya, A. and Krieger, H. (1978) Human genetic studies in areas of
high natural radiation. IX. Effects on mortality, morbidity, and sex ratio, Health Phys.,
34, 61.
104. Kesavan, P.C. (1997a) Indian research on high levels of natural radiation:
pertinent observations for further studies, In: Elsevier Science B.V, High Levels of
Natural Radiation, Radiation Dose and Health Effects, pp111-117.
105. Sohrabi, M. (1990) Recent radiological studies of high level natural
radiation areas of Ramsar, Proc. International Conference of High Levels of Natural
Radiation, IAEA, Vienna, pp39-45.
106. Blot, W.J., Xu, Z.Y., Boice, J.D., Jr, Zhao, D.Z., Stone, B.J., Sun, J.,
Jing, L.B. and Fraumeni, J.F., Jr. (1990) Indoor radon and lung cancer in China, J. Natl
Cancer Inst., 82, pp1025-1030.
107. Auvinen, A., Mäkeläinen, I., Hakama, M, et al. (1996) Indoor Radon
Exposure and Risk of Lung Cancer: a Nested Case-Control Study in Finland, J. Natl. Cancer
Inst.; 88:pp966-72
108. Boxenbaum, H. (1992) Hypothesis on Mammalian Aging, Toxicity, and
Longevity Hormesis: Explication by a Generalized Gompertz Function Biological Effects of
Low Level Exposures to Chemicals and Radiation, Lewis Publishers, Chelsea, Michigan,
pp1-39.
109. Ishii, K., Hosoi, Y., Yamada, S., Ono, T. and Sakamoto, K. (1996)
Decreased Incidence of Thymic Lymphoma in AKR Mice as a Result of Chronic, Fractionated
Low-Dose Total-Body X Irradiation, Rad Res, Vol 146, No. 5, p582.
110. Hattori, S. (1997) Interview: Using Low-dose Radiation for Cancer
Suppression and Vitalization. 21st Century Sci. & Tech.Summer, p55-59
111. Planel, H., Solielhavoup, J.P., Tixador, R., Croute, F. and Richoilley, G.
(1970) Demonstration of a stimulating effect of natural ionizing radiation and of very low
radiation doses on cell multiplication, In: Biological and Environmental Effects of Low
Level Radiation, Vol. 1, pp127-133, International Atomic Energy Agency, Vienna, 1976. See
also Stimul. Newsletter 1, pp29-34.
112. Soleilhavoup, J.P., Croute, F., Tixador, R., Blanquet, Y. and Planel, H.
(1975) Influence of cosmic radiation at high altitude on duration of the cell cycle, C. R.
Seances Soc. Biol. Fil. 169: pp426-429.
113. Luckey, T.D. (1986) Ionizing Radiation Promotes Protozoan Reproduction.
Rad. Research 108:215-221
114. Sheppard, S.C. and Regitnig, P.J. (1987) Factors controlling the hormesis
response in irradiated seed, Health Phys Vol 52, No 5 (May) pp599-605.
115. Kuzin, A.M. (1979) Radiation methods in agriculture, Biol. Bull. Acad.
Sci. USSR 6:pp566-572.
116. Kuzin, A.M., Ruda, V.P., Mozgovoi, E.G. (1991) The role of receptors in
radiation hormesis, Radiat. Environ. Biophys. 30, pp259-266.
117. Kuzin, A.M., Surkenova, G.N., Revin, A.F. (1996) Native protein activated
by low doses of gamma radiation as a source of secondary biogenic radiation, Radiats.
Biol. Radioecol, Mar-Apr; 36(2): pp284-90 [Article in Russian].
118. Stimulation Newsletter (1970-1976) Ed. Bhattacharya, S., Institut fur
Strahlenbotanik GSF, Hannover
119. Walinder, G. (1996a) Some views on the theoretical basis of radiological
risk estimations, I. The linear, no-threshold theory, preprint, personal comm.
120. Trosko, J.E. (1997). Heirarchical/Cybernetic Nature of Homeostatic
Adaptation to Low Level Exposures to Oxidative Stress-inducing Agents.
121. Wolff, S. (1994) Adaptation to ionizing radiation induced by prior
exposure to very low doses, Chin. Med. J. (Engl) 107:pp425-430.
122. Liu, S.Z., Liu, W.H. and Sun, J.B. (1987) Radiation hormesis: its
expression in the immune system, Health Phys 52:pp579-583.
123. Liu, S.Z., Xn, G.Z., Li, X.Y., Xia, F.C., Yu, H.Y., Qi, J., Wang F,L. and
Wang, S.K. (1985) A restudy of immune functions of the inhabitants in high background
radiation area in Guangdong, Chin. J. Radial. Med. Protect., 5, 124.
124. Ishii, K. et al. (1997) Participation of Intercellular Communication and
Intracellular Signal Transduction in the Radio-adaptive Response of Human Fibroblastic
Cells, In: Low Doses of Ionizing Radiation: Biological Effects and Regulatory Control,
IAEA-TECDOC-976, IAEA-CN-67/128, pp410-413.
125. Chernikova, S.B., Gotlib, V.I. and Pelevina, I.I. (1993) Effect of
low-dose ionizing radiation on radiosensitivity to the next irradiation, Radiats. Biol.
Radioecol. 33:pp537-541.
126. Kojima, S., Matsuki, O., Nomura, T. Takahashi, M. and Yamaoka, K. (1997)
Effect of small doses of gamma-rays on the glutathione synthesis in mouse, In: Low Doses
of Ionizing Radiation: Biological Effects and Regulatory Control, IAEA-TECDOC-976,
IAEA-CN-67/130.
127. Kondo, S. (1988) Altruistic cell suicide in relation to radiation
hormesis, Atomic Energy Research Institute, Kinki University, Osaka, Japan. Int. J.
Radiat. Biol. Relat. Stud. Phys. Chem. Med. 53: pp95-102.
128. Trosko, J.E. (1995) Can Low-Level Radiation Cause Cancer? ANS Trans.
73:35-37
129. Pollycove, M. (1996) Positive Health Effects of Low-Level
Radiation…and Why. ACRS/ACNW Subcommittee Meeting, USNRC
130. Feinendegen, L.E., et al. (1996) Radiation Effects Induced by Low Doses,
in Complex Tissue and Their Relation to Cellular Responses, personal communication
(March).
131. Sugahara, T. (1997) The radiation paradigm regarding health risk from
exposures to low dose radiation, In: High Levels of Natural Radiation 1996: Radiation Dose
and Health Effects, Editors: Wei, L.; Sugahara, T. and Tao, Z., Beijing; Elsevier,
pp331-339.
132. Alberts, B. et al Eds. Molecular Biology of the Cell. Garland Pub New York
133. Hattori, S. (1997) State of research and perspective on adaptive response
to low doses of ionizing radiation in Japan, In: Low Doses of Ionizing Radiation:
Biological Effects and Regulatory Control, IAEA-TECDOC-976, IAEA-CN-67/126, pp402-405.
134. Makinodan, T. (1992) Cellular and subcellular alterations in immune cells
induced by chronic, intermittent exposure in vivo to very low doses of ionizing radiation
and its ameliorating effects on progression of autoimmune disease and mammary tumor
growth. In: Low Dose Irradiation and Biological Defense Mechanisms, Sugahara, T., Sagan,
L.A. and Aoyama, T. (eds) Elsevier Science Publishers, Amsterdam. pp233
135. Ohnishi, T. (1997) The induction of a tumor suppressor gene (p53)
expression by low-dose radiation and its biological meaning, IAEA-CN-67-127, pp406-409.
136. Hosoi, Y. and Sakamoto, K. (1997) Suppression of spontaneous and
artificial metastasis by low dose total body irradiation in mice, In: Low Doses of
Ionizing Radiation: Biological Effects and Regulatory Control, IAEA-TECDOC-976,
IAEA-CN-67/132, pp424-427.
137. Pollycove, M. and Paperiello, C.J. (1997) Health effects of low-dose
radiation: Molecular, cellular, and biosystem response, In: Low Doses of Ionizing
Radiation: Biological Effects and Regulatory Control, IAEA-TECDOC-976, IAEA-CN-67/63,
pp223-226.
138. Selye, H. (1956) The Stress of life, McGraw Book Co., New York.
139. Bogen, K.T. (1996a) A cytodynamic two stage model that predicts radon
hormesis (decreased, then increased lung-cancer risk vs. exposure), Summary, LLNL Preprint
UCRL-TC-123219, Lawrence Livermore National Laboratory, University of California, February
1996.
140. Bogen, K.T. (1998) Mechanistic Model Predicts a U-Shaped Relationship of
Radon Exposure to Lung CancerRisk Reflected in Combined Occupational and U.S. Residential
Data. BELLE Newsletter, Vol.7, No2
141. Downs, T.D. (1992) Biostatistical approaches for modeling U-shaped
dose-response curves and study design considerations in assessing the biological effects
of low doses, In: Biological Effects of Low Level Exposures to Chemicals and Radiation,
Lewis Publishers.
142. Fleck, C.M. et al. (1999) Modeling Radioprotective Mechanisms for the Dose
Effect Relation at Low Does and Low Doses Rates of Ionizing Radiation, Math. Biosci. (in
press)
143. Schollnberger, H. et al (1999) Cell Cycle Delay
and Misrepair in a Biophysical model of Adaptive Response in Carcinogenic Processes (in
press)
144. Weber, K.-H. (1996) Biphasic dose-effect relationships in
experimental studies of radiation cancer in animals, Strahlenbiologie und Strahlenshutz,
Hannover, 23-25 Oktober 1996, IRPA, Progress in Radiation Protection, pp95-99
145. New England Journal of Medicine (1998) Editorial May 29
146. Goldman, M. (1995) Quo vadis health physics?, Health Physics Newsletter,
February, p3
147. Becker, K. (1997a) Do we need a new cost/benefit assessment for low
radiation doses?, In: Low Doses of Ionizing Radiation: Biological Effects and Regulatory
Control, IAEA-TECDOC-976, IAEA-CN-67/137, pp436
