论文信息 - Physical and Biological Organ Dosimetry Analysis for International Space Station Astronauts

Physical and Biological Organ Dosimetry Analysis for International Space Station Astronauts

Abstract Cucinotta, F. A., Kim, M-H. Y., Willingham, V. and George, K. A. Physical and Biological Organ Dosimetry Analysis for International Space Station Astronauts. Radiat. Res. 170, 127–138 (2008). In this study, we analyzed the biological and physical organ dose equivalents for International Space Station (ISS) astronauts. Individual physical dosimetry is difficult in space due to the complexity of the space radiation environment, which consists of protons, heavy ions and secondary neutrons, and the modification of these radiation types in tissue as well as limitations in dosimeter devices that can be worn for several months in outer space. Astronauts returning from missions to the ISS undergo biodosimetry assessment of chromosomal damage in lymphocyte cells using the multicolor fluorescence in situ hybridization (FISH) technique. Individual-based pre-flight dose responses for lymphocyte exposure in vitro to γ rays were compared to those exposed to space radiation in vivo to determine an equivalent biological dose. We compared the ISS biodosimetry results, NASA's space radiation transport models of organ dose equivalents, and results from ISS and space shuttle phantom torso experiments. Physical and biological doses for 19 ISS astronauts yielded average effective doses and individual or population-based biological doses for the approximately 6-month missions of 72 mSv and 85 or 81 mGy-Eq, respectively. Analyses showed that 80% or more of organ dose equivalents on the ISS are from galactic cosmic rays and only a small contribution is from trapped protons and that GCR doses were decreased by the high level of solar activity in recent years. Comparisons of models to data showed that space radiation effective doses can be predicted to within about a ±10% accuracy by space radiation transport models. Finally, effective dose estimates for all previous NASA missions are summarized.

[1] Francis F. Badavi,et al. Time serial analysis of the induced LEO environment within the ISS 6A , 2006 .

[2] F. Cucinotta,et al. A Comparison of Depth Dependence of Dose and Linear Energy Transfer Spectra in Aluminum and Polyethylene , 2000, Radiation research.

[3] G D Badhwar,et al. Effective Dose Equivalent on the Ninth Shuttle–Mir Mission (STS-91) , 2000, Radiation research.

[4] Marco Durante,et al. Cancer risk from exposure to galactic cosmic rays: implications for space exploration by human beings. , 2006, The Lancet. Oncology.

[5] L W Townsend,et al. Radiation protection guidance for activities in low-Earth orbit. , 2002, Advances in space research : the official journal of the Committee on Space Research.

[6] G. Reitz,et al. Chromosomal aberrations in blood lymphocytes of astronauts after long-term space flights. , 1997, International journal of radiation biology.

[7] G. Badhwar,et al. TRACK STRUCTURE AND RADIATION TRANSPORT MODEL FOR SPACE RADIOBIOLOGY STUDIES , 1996 .

[8] Leif E. Peterson,et al. Space Radiation Cancer Risks and Uncertainties for Mars Missions , 2001, Radiation research.

[9] M. Durante,et al. Chromosome aberrations of clonal origin are present in astronauts’ blood lymphocytes , 2004, Cytogenetic and Genome Research.

[10] F A Cucinotta,et al. Chromosome Aberrations in the Blood Lymphocytes of Astronauts after Space Flight , 2001, Radiation research.

[11] F A Cucinotta,et al. Once we know all the radiobiology we need to know, how can we use it to predict space radiation risks and achieve fame and fortune? , 2001, Physica medica : PM : an international journal devoted to the applications of physics to medicine and biology : official journal of the Italian Association of Biomedical Physics.

[12] F. Cucinotta,et al. The influence of shielding on the biological effectiveness of accelerated particles for the induction of chromosome damage , 2006 .

[13] G. Reitz,et al. Radiation measurements on the Mir Orbital Station. , 2002, Radiation measurements.

[14] F A Cucinotta,et al. Space Radiation and Cataracts in Astronauts , 2001, Radiation research.

[15] D. Goodhead,et al. M-FISH analysis shows that complex chromosome aberrations induced by α-particle tracks are cumulative products of localized rearrangements , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[16] M. Bauchinger,et al. The Effectiveness of Monoenergetic Neutrons at 565 keV in Producing Dicentric Chromosomes in Human Lymphocytes at Low Doses , 2000, Radiation research.

[17] F A Cucinotta,et al. Karyotypes of Human Lymphocytes Exposed to High-Energy Iron Ions , 2002, Radiation research.

[18] M. Durante,et al. Chromosome aberration dosimetry in cosmonauts after single or multiple space flights , 2004, Cytogenetic and Genome Research.

[19] M. Cornforth,et al. Evidence that Unrejoined DNA Double-Strand Breaks are not Predominantly Responsible for Chromosomal Radiosensitivity of AT Fibroblasts , 2004, Radiation research.

[20] R. Delongchamp,et al. Detection of stable chromosome aberrations by FISH in A-bomb survivors: comparison with previous solid Giemsa staining data on the same 230 individuals , 2001, International journal of radiation biology.

[21] J. Wilson,et al. Effects of target fragmentation on evaluation of LET spectra from space radiation in low-earth orbit (LEO) environment: impact on SEU predictions. , 1995, IEEE transactions on nuclear science.

[22] G. Badhwar,et al. An analysis of interplanetary space radiation exposure for various solar cycles. , 1994, Radiation research.

[23] A. Rubanovich,et al. Cytogenetic studies of blood lymphocytes from cosmonauts after long-term space flights on Mir station. , 2001, Advances in space research : the official journal of the Committee on Space Research.

[24] G. Badhwar,et al. The radiation environment in low-Earth orbit. , 1997, Radiation research.

[25] K. George,et al. Estimate of true incomplete exchanges using fluorescence in situ hybridization with telomere probes. , 1998, International journal of radiation biology.

[26] M. Durante,et al. Biological Effectiveness of Accelerated Particles for the Induction of Chromosome Damage Measured in Metaphase and Interphase Human Lymphocytes , 2003, Radiation research.

[27] J. Wiegant,et al. Insights into the sites of X ray and neutron induced chromosomal aberrations in human lymphocytes using COBRA-MFISH. , 2002, Radiation protection dosimetry.

[28] Ronald J. White,et al. Humans in space , 2001, Nature.

[29] L Sabatier,et al. Radiation-induced chromosome damage in astronauts' lymphocytes. , 1996, International journal of radiation biology.

[30] Ram K. Tripathi,et al. Isotopic dependence of GCR fluence behind shielding , 2006 .

[31] D. Papworth,et al. X-ray-induced simple, pseudosimple and complex exchanges involving two distinctly painted chromosomes. , 1999, International journal of radiation biology.

[32] J. Wilson,et al. Galactic cosmic ray transport methods: past, present, and future. , 1994, Advances in space research : the official journal of the Committee on Space Research.

[33] F F Badavi,et al. Space Radiation Absorbed Dose Distribution in a Human Phantom , 2002, Radiation research.

[34] J. Wilson,et al. Measurements of the secondary particle energy spectra in the Space Shuttle. , 1995, Radiation measurements.

[35] John W. Norbury,et al. Transport Methods and Inter-actions for Space Radiations , 2003 .

[36] J. Wilson,et al. Nuclear absorption cross sections using medium modified nucleon-nucleon amplitudes. , 1998, Nuclear instruments & methods in physics research. Section B, Beam interactions with materials and atoms.

[37] M. Cornforth,et al. Complex Chromosome Exchanges Induced by Gamma Rays in Human Lymphocytes: An mFISH Study , 2001, Radiation research.

[38] T. Kawata,et al. High- and low-LET induced chromosome damage in human lymphocytes: a time-course of aberrations in metaphase and interphase , 2001, International journal of radiation biology.

[39] J. Wilson,et al. Issues in space radiation protection: galactic cosmic rays. , 1995, Health physics.

[40] F. Cucinotta,et al. A temporal forecast of radiation environments for future space exploration missions , 2007, Radiation and environmental biophysics.

[41] Icrp. 1990 Recommendations of the International Commission on Radiological Protection , 1991 .

[42] D. Hassler,et al. Description of light ion production cross sections and fluxes on the Mars surface using the QMSFRG model , 2007, Radiation and environmental biophysics.

[43] Francis A. Cucinotta,et al. Evaluating shielding effectiveness for reducing space radiation cancer risks , 2006 .

[44] E. V. Benton,et al. Summary of radiation dosimetry results on U.S. and Soviet manned spacecraft. , 1986, Advances in space research : the official journal of the Committee on Space Research.

[45] D. Goodhead,et al. Complex chromosome aberrations in peripheral blood lymphocytes as a potential biomarker of exposure to high-LET alpha-particles. , 2000, International journal of radiation biology.

[46] F A Cucinotta,et al. Radiation risk and human space exploration. , 2003, Advances in space research : the official journal of the Committee on Space Research.

[47] F A Cucinotta,et al. Analysis of MIR-18 results for physical and biological dosimetry: radiation shielding effectiveness in LEO. , 2000, Radiation measurements.

[48] J. Wilson,et al. Neutron environments on the Martian surface. , 2001, Physica medica : PM : an international journal devoted to the applications of physics to medicine and biology : official journal of the Italian Association of Biomedical Physics.

[49] M. Durante,et al. Biodosimetry results from space flight Mir-18. , 1997, Radiation research.

[50] R. Sievert,et al. Book Reviews : Recommendations of the International Commission on Radiological Protection (as amended 1959 and revised 1962). I.C.R.P. Publication 6. 70 pp. PERGAMON PRESS. Oxford, London and New York, 1964. £1 5s. 0d. [TB/54] , 1964 .

[51] Francis A Cucinotta,et al. Radiation dosimetry and biophysical models of space radiation effects. , 2003, Gravitational and space biology bulletin : publication of the American Society for Gravitational and Space Biology.