A proposed change to astronaut exposures limits is a giant leap backwards for radiation protection.
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Francis A Cucinotta | Walter Schimmerling | Eleanor A Blakely | Tom K Hei | E. Blakely | T. Hei | F. Cucinotta | W. Schimmerling
[1] Leif E. Peterson,et al. NASA Study of Cataract in Astronauts (NASCA). Report 1: Cross-Sectional Study of the Relationship of Exposure to Space Radiation and Risk of Lens Opacity , 2009, Radiation research.
[2] M. C. Angulo,et al. Sex-Specific Cognitive Deficits Following Space Radiation Exposure , 2020, Frontiers in Behavioral Neuroscience.
[3] Francis A. Cucinotta,et al. How Safe Is Safe Enough? Radiation Risk for a Human Mission to Mars , 2013, PloS one.
[4] Non-Targeted Effects Models Predict Significantly Higher Mars Mission Cancer Risk than Targeted Effects Models , 2017, Scientific Reports.
[5] A. Fornace,et al. Heavy Ion Radiation Exposure Triggered Higher Intestinal Tumor Frequency and Greater β-Catenin Activation than γ Radiation in APCMin/+ Mice , 2013, PloS one.
[6] Francis A. Cucinotta,et al. Physical and Biological Organ Dosimetry Analysis for International Space Station Astronauts , 2008, Radiation research.
[7] D. Fairchild,et al. Harderian Gland Tumorigenesis: Low-Dose and LET Response , 2016, Radiation Research.
[8] Javier Gómez-Elvira,et al. Comparison of Martian surface ionizing radiation measurements from MSL‐RAD with Badhwar‐O'Neill 2011/HZETRN model calculations , 2014 .
[9] W Schimmerling,et al. Dose and dose rate effectiveness of space radiation. , 2006, Radiation protection dosimetry.
[10] P. Powers-Risius,et al. The relative biological effect of high-Z, high-LET charged particles for spermatogonial killing. , 1981, Radiation research.
[11] Cécile Huin-Schohn,et al. Could spaceflight‐associated immune system weakening preclude the expansion of human presence beyond Earth's orbit? , 2009, Journal of leukocyte biology.
[12] D. Hoel. Comments on the DDREF Estimate of the BEIR VII Committee , 2015, Health physics.
[13] N. Hamada,et al. Occupational exposure to chronic ionizing radiation increases risk of Parkinson's disease incidence in Russian Mayak workers. , 2019, International journal of epidemiology.
[14] P. Powers-Risius,et al. Tumorigenic potential of high-Z, high-LET charged-particle radiations. , 1993, Radiation research.
[15] F. Cucinotta,et al. Predictions of space radiation fatality risk for exploration missions. , 2017, Life sciences in space research.
[16] David J Brenner,et al. Biological effects in unirradiated human tissue induced by radiation damage up to 1 mm away. , 2005, Proceedings of the National Academy of Sciences of the United States of America.
[17] David B Richardson,et al. Ionising radiation and risk of death from leukaemia and lymphoma in radiation-monitored workers (INWORKS): an international cohort study , 2015, The Lancet. Haematology.
[18] J. Little,et al. Induction of sister chromatid exchanges by extremely low doses of alpha-particles. , 1992, Cancer research.
[19] Ianik Plante,et al. Ionization and excitation cross sections for the interaction of HZE particles in liquid water and application to Monte Carlo simulation of radiation tracks , 2008 .
[20] J. Baulch,et al. What happens to your brain on the way to Mars , 2015, Science Advances.
[21] Dale L Preston,et al. Solid Cancer Incidence among the Life Span Study of Atomic Bomb Survivors: 1958–2009 , 2017, Radiation Research.
[22] R. Ullrich,et al. Neutron carcinogenesis. Dose and dose-rate effects in BALB/c mice. , 1977, Radiation research.
[23] Mi-Ae Park,et al. Space-like 56Fe irradiation manifests mild, early sex-specific behavioral and neuropathological changes in wildtype and Alzheimer’s-like transgenic mice , 2019, Scientific Reports.
[24] C. Lushbaugh. Guidance on Radiation Received in Space Activities , 1990 .
[25] F. Cucinotta. A New Approach to Reduce Uncertainties in Space Radiation Cancer Risk Predictions , 2015, PloS one.
[26] Francis A. Cucinotta,et al. Space Radiation Risks for Astronauts on Multiple International Space Station Missions , 2014, PloS one.
[27] F. Cucinotta,et al. Space Radiation Quality Factors and the Delta Ray Dose and Dose-Rate Reduction Effectiveness Factor , 2016, Health physics.
[28] David B Richardson,et al. Risk of cancer from occupational exposure to ionising radiation: retrospective cohort study of workers in France, the United Kingdom, and the United States (INWORKS) , 2015, BMJ : British Medical Journal.
[29] Michael M. Weil,et al. Incidence of Acute Myeloid Leukemia and Hepatocellular Carcinoma in Mice Irradiated with 1 GeV/nucleon 56Fe Ions , 2009, Radiation research.
[30] G. Lawson,et al. Charged-Iron-Particles Found in Galactic Cosmic Rays are Potent Inducers of Epithelial Ovarian Tumors , 2018, Radiation Research.
[31] H. Sugiyama,et al. Incidence of Breast Cancer in the Life Span Study of Atomic Bomb Survivors: 1958–2009 , 2018, Radiation Research.
[32] Vipan K. Parihar,et al. Cosmic radiation exposure and persistent cognitive dysfunction , 2016, Scientific Reports.
[33] Premkumar B. Saganti,et al. Benchmarking risk predictions and uncertainties in the NSCR model of GCR cancer risks with revised low let risk coefficients. , 2020, Life sciences in space research.
[34] J. Clayton,et al. Applying the new SABV (sex as a biological variable) policy to research and clinical care , 2017, Physiology & Behavior.
[35] K. Kodama,et al. Heart Disease Mortality in the Life Span Study, 1950–2008 , 2017, Radiation Research.
[36] B. Carnes,et al. The Comparative Tumorigenic Effects of Fission Neutrons and Cobalt-60 γ Rays in the B6CF1 Mouse , 1992 .
[37] E. Wright,et al. Radiation-induced genomic instability and bystander effects: inter-related nontargeted effects of exposure to ionizing radiation , 2003, Oncogene.
[38] Premkumar B. Saganti,et al. Relative Biological Effectiveness of HZE Particles for Chromosomal Exchanges and Other Surrogate Cancer Risk Endpoints , 2016, PloS one.
[39] E. J. Ainsworth,et al. High-LET radiation carcinogenesis. , 1985 .
[40] Bahram Parvin,et al. Targeted and nontargeted effects of ionizing radiation that impact genomic instability. , 2008, Cancer research.
[41] A. Jemal,et al. Cancer Statistics, 2021 , 2021, CA: a cancer journal for clinicians.
[42] J. Coggle. Lung tumour induction in mice after X-rays and neutrons. , 1988, International journal of radiation biology and related studies in physics, chemistry, and medicine.
[43] M. Little,et al. Non-targeted effects of ionising radiation--implications for low dose risk. , 2013, Mutation research.
[44] F. Cucinotta,et al. Risks of cognitive detriments after low dose heavy ion and proton exposures , 2019, International journal of radiation biology.
[45] F. Cucinotta,et al. Safe days in space with acceptable uncertainty from space radiation exposure. , 2015, Life sciences in space research.
[46] F A Cucinotta,et al. The effects of delta rays on the number of particle-track traversals per cell in laboratory and space exposures. , 1998, Radiation research.
[47] Premkumar B. Saganti,et al. NON-TARGETED EFFECTS LEAD TO A PARIDIGM SHIFT IN RISK ASSESSMENT FOR A MISSION TO THE EARTH'S MOON OR MARTIAN MOON PHOBOS. , 2018, Radiation protection dosimetry.
[48] Walter Schimmerling. Accepting space radiation risks , 2010, Radiation and environmental biophysics.
[49] Francis A. Cucinotta,et al. Cancer and circulatory disease risks for a human mission to Mars: Private mission considerations , 2020 .
[50] A. Fornace,et al. Relative Biological Effectiveness of Energetic Heavy Ions for Intestinal Tumorigenesis Shows Male Preponderance and Radiation Type and Energy Dependence in APC(1638N/+) Mice. , 2016, International journal of radiation oncology, biology, physics.
[51] M. Hada,et al. Induction of Chromosomal Aberrations at Fluences of Less Than One HZE Particle per Cell Nucleus , 2014, Radiation research.
[52] F A Cucinotta,et al. Space Radiation and Cataracts in Astronauts , 2001, Radiation research.
[53] R. Ullrich,et al. Effects of 28Si Ions, 56Fe Ions, and Protons on the Induction of Murine Acute Myeloid Leukemia and Hepatocellular Carcinoma , 2014, PloS one.
[54] M. Barcellos-Hoff,et al. HZE Radiation Non-Targeted Effects on the Microenvironment That Mediate Mammary Carcinogenesis , 2016, Front. Oncol..
[55] A. Wyrobek,et al. Spatial Memory Performance of Socially Mature Wistar Rats is Impaired after Exposure to Low (5 cGy) Doses of 1 GeV/n 48Ti Particles , 2017, Radiation Research.
[56] Xiang Wang,et al. Relative Effectiveness at 1 Gy after Acute and Fractionated Exposures of Heavy Ions with Different Linear Energy Transfer for Lung Tumorigenesis , 2015, Radiation research.
[57] A. Fornace,et al. Enhanced intestinal tumor multiplicity and grade in vivo after HZE exposure: mouse models for space radiation risk estimates , 2010, Radiation and environmental biophysics.
[58] Michael L. Gatza,et al. Aggressive Mammary Cancers Lacking Lymphocytic Infiltration Arise in Irradiated Mice and Can Be Prevented by Dietary Intervention , 2019, Cancer Immunology Research.
[59] D. Goodhead,et al. Track structure analysis of ultrasoft X-rays compared to high- and low-LET radiations. , 1989, International journal of radiation biology.
[60] D. Richardson,et al. Site-specific Solid Cancer Mortality After Exposure to Ionizing Radiation: A Cohort Study of Workers (INWORKS) , 2018, Epidemiology.
[61] Francis A. Cucinotta,et al. Space Radiation Cancer Risk Projections and Uncertainties - 2010 , 2011 .
[62] S. Demaria,et al. Densely ionizing radiation acts via the microenvironment to promote aggressive Trp53-null mammary carcinomas. , 2014, Cancer research.
[63] R. Fry,et al. Extrapolation of the relative risk of radiogenic neoplasms across mouse strains and to man. , 1988, Radiation research.
[64] R. Fry. Experimental radiation carcinogenesis: what have we learned? , 1981, Radiation research.
[65] J. Raber,et al. Sex- and dose-dependent effects of calcium ion irradiation on behavioral performance of B6D2F1 mice during contextual fear conditioning training. , 2016, Life sciences in space research.
[66] Y. Shimada,et al. High relative biologic effectiveness of carbon ion radiation on induction of rat mammary carcinoma and its lack of H-ras and Tp53 mutations. , 2007, International journal of radiation oncology, biology, physics.
[67] T. Akiyama,et al. How does spaceflight affect the acquired immune system? , 2020, npj Microgravity.
[68] Francis A. Cucinotta,et al. Space radiation risks to the central nervous system , 2014 .
[69] H. Sugiyama,et al. Radiation Exposure and the Risk of Mortality from Noncancer Respiratory Diseases in the Life Span Study, 1950–2005 , 2013, Radiation research.
[70] R. Ullrich,et al. The influence of dose and dose rate on the incidence of neoplastic disease in RFM mice after neutron irradiation. , 1976, Radiation research.
[71] M. Weil,et al. Personalized Cancer Risk Assessments for Space Radiation Exposures , 2016, Front. Oncol..