Carnes, B. A. and Gavrilova, N. Risk Analysis: Divergent Models and Convergent Interpretations. Radiat. Res. 156, 628–630 (2001).

Material presented at a NASA-sponsored workshop on risk models for exposure conditions relevant to prolonged space flight are described in this paper. Analyses used mortality data from experiments conducted at Argonne National Laboratory on the long-term effects of external whole-body irradiation on B6CF₁ mice by ⁶⁰Co γ rays and fission neutrons delivered as a single exposure or protracted over either 24 or 60 once-weekly exposures. The maximum dose considered was restricted to 1 Gy for neutrons and 10 Gy for γ rays. Proportional hazard models were used to investigate the shape of the dose response at these lower doses for deaths caused by solid-tissue tumors and tumors of either connective or epithelial tissue origin. For protracted exposures, a significant mortality effect was detected at a neutron dose of 14 cGy and a γ-ray dose of 3 Gy. For single exposures, radiation-induced mortality for neutrons also occurred within the range of 10–20 cGy, but dropped to 86 cGy for γ rays. Plots of risk relative to control estimated for each observed dose gave a visual impression of nonlinearity for both neutrons and γ rays. At least for solid-tissue tumors, male and female mortality was nearly identical for γ-ray exposures, but mortality risks for females were higher than for males for neutron exposures. As expected, protracting the γ-ray dose reduced mortality risks. Although curvature consistent with that observed visually could be detected by a model parameterized to detect curvature, a relative risk term containing only a simple term for total dose was usually sufficient to describe the dose response. Although detectable mortality for the three pathology end points considered typically occurred at the same level of dose, the highest risks were almost always associated with deaths caused by tumors of epithelial tissue origin.