The dose-dependent fragmentation of chromatin in human fibroblasts by 3.5-MeV alpha particles from 238Pu: experimental and theoretical considerations pertaining to single-track effects.

The technique of premature chromosome condensation (PCC) was used to examine the dose-response relationship for the production of interphase (G0) chromosome fragments in noncycling normal human fibroblasts following exposure to 238Pu alpha particles, with special emphasis on the low-dose region. The dose response was convincingly linear from 0.2 to 3.0 Gy. Analysis of further data collected over a dose range of 1.1 to 22.4 cGy provided no evidence of deviation from linearity in this low-dose region. The fact that this lower dose range extends into the region where single-particle effects are dominant suggests that a linear extrapolation of this response from higher to lower doses is valid. Ratios of coefficients for the induction of fragments produced by 238Pu alpha particles versus 60Co gamma rays gave an RBE of 2.34 +/- 0.09. Distributions of fragments among 60Co gamma-irradiated cells were consistent with a Poisson expectation of random damage. In contrast, overdispersion appeared to be a general feature of 238Pu alpha-particle-induced fragmentation, a phenomenon explainable under the assumption that single-particle traversals are capable of producing multiple PCC fragments. Data obtained were used to estimate practical and theoretical lower-dose limits of detection of initial chromatin breaks provided by current PCC methodology.