References
- Alper T. Elkind recovery and ‘sublethal damage’: a misleading association?. British Journal of Radiology 1977; 50: 459–467
- Bedford J.S., Cornforth M.N. Relationship between the recovery from sublethal X-ray damage and the rejoining of chromosome breaks in normal human fibroblasts. Radiation Research 1987; 111: 406–423
- Belli J.A., Shelton M. Potentially lethal radiation damage: repair by mammalian cells in culture. Science 1969; 165: 490–492
- Cornforth M.N., Bedford J.A. A quantitative comparison of potentially lethal damage repair and the rejoining of interphase chromosome breaks in low passage normal human fibroblasts. Radiation Research 1987; 111: 385–405
- Denekamp J. General discussion. British Journal of Cancer 1984; 49(VI)277–284
- Dettor C.M., Dewey W.C., Winans L.F., Noel J.S. Enhancement of X-ray damage in synchronous Chinese hamster cells by hypertonic treatments. Radiation Research 1972; 52: 352–372
- Dritschilo A., Piro A.J., Belli J.A. Repair of radiation damage in plateauphase mammalian cells: relationship between sub-lethal and potentially lethal damage states. International Journal of Radiation Biology 1976; 30: 565–569
- Elkind M.M., Sutton H.A. X-ray damage and recovery in mammalian cells in culture. Nature 1959; 184: 1293–1295
- Elkind M.M., Sutton H.A. Radiation response of mammalian cells grown in culture: 1. Repair of X-ray damage in surviving Chinese hamster cells. Radiation Research 1960; 13: 556–593
- Elkind M.M., Sutton-Gilbert H., Moses W.B., Alescio T., Swain R.W. Radiation response of mammalian cells in culture. V. Temperature dependence of the repair of X-ray damage in surviving cells (aerobic and hypoxic). Radiation Research 1965; 25: 359–361
- Elkind M.M., Sutton-Gilbert H., Moses W.B., Kamper C. Sublethal and lethal radiation damage. Nature 1967; 214: 1088–1092
- Elkind M.M., Whitmore G.F. Biochemical effects (DNA, RNA and protein). The Radiobiology of Cultured Mammalian Cells. Gordon & Breach, New York 1967; 485–545
- Frankenberg D., Frankenberg-Schwager M. Interpretation of the shoulder of dose-response curves with immediate plating in terms of repair of potentially lethal lesions during a restricted time period. International Journal of Radiation Biology 1981; 39: 617–631
- Frankenberg D., Frankenberg-Schwager M., Harbich R. Split-dose recovery is due to the repair of DNA double-strand breaks. International Journal of Radiation Biology 1984; 46: 541–553
- Hahn G.M., Bagshaw M.A., Evans R.G., Gordon L.F. Repair of potentially lethal lesions in X-irradiated, density inhibited Chinese hamster cells: metabolic effects and hypoxia. Radiation Research 1973; 55: 280–290
- Hetzel F.W., Kruuv J., Frey H.E. Repair of potentially lethal damage in X-irradiated V79 cells. Radiation Research 1976; 68: 308–319
- Iliakis G. Radiation-induced potentially lethal damage: DNA lesions susceptible to fixation. International Journal of Radiation Biology 1988; 53: 541–584
- Kapiszewska M., Lange C.S. The effects of reduced temperature and/or starvation conditions on the radiosensitivity and repair of potentially lethal damage and sublethal damage in L5178Y-R and L5178Y-S cells. Radiation Research 1988; 113: 458–472
- Little J.B. Factors influencing the repair of potentially lethal radiation damage in growth inhibited human cells. Radiation Research 1973; 56: 320–333
- Phillips R.A., Tolmach L.J. Repair of potentially lethal damage in X-irradiated HeLa cells. Radiation Research 1966; 29: 413–432
- Pohlit W., Heyder I.R. The shape of dose-survival curves for mammalian cells and repair of potentially lethal damage analyzed by hypertonic treatment. Radiation Research 1981; 87: 613–634
- Pohlit W., Juling L. Split-dose recovery explained quantitatively by repair of potentially lethal lesions. British Journal of Cancer 1984; 49(VI)213–216
- Raaphorst G.P., Dewey W.C. Fixation of potentially lethal radiation damage by post-irradiation exposure of Chinese hamster cells to 0·05 m or 1·5 m NaCl solutions. International Journal of Radiation Biology 1979a; 36: 303–315
- Raaphorst G.P., Dewey W.C. A study of the repair of potentially lethal and sublethal radiation damage in Chinese hamster cells exposed to extremely hypo- or hypertonic NaCl solutions. Radiation Research 1979b; 77: 325–340
- Reddy N.M.S., Rao B.S. Genetic control of repair of radiation damage produced under euoxic and anoxic conditions in diploid yeast Saccharomyces cerevisiae. Radiation and Environmental Biophysics 1981; 19: 187–195
- Reddy N.M.S., Anjaria K.B., Subrahmanyam P. Absence of dose-rate effect and recovery from sub-lethal damage in trad52 strain of diploid yeast Saccharomyces cerevisiae exposed to gamma rays. Mutation Research 1982; 105: 145–148
- Reddy N.M.S., Stevenson A.F.G., Lange C.S. Trypsinization and the radiosensitivity of mitotic and log phase Chinese hamster V79 cells exposed to 250 kVp X-rays. International Journal of Radiation Biology 1988; 55: 105–117
- Thacker J., Stretch A. Response of 4 X-ray-sensitive mutants of different radiations and to irradiation conditions promoting cellular recovery. Mutation Research 1985; 146: 99–108
- Utsumi H., Elkind M.M. Potentially lethal damage versus sublethal damage: Independent repair processes in actively growing Chinese hamster cells. Radiation Research 1979; 77: 346–360
- Winans L.F., Dewey W.C., Dettor C.M. Repair of sublethal and potentially lethal X-ray damage in synchronous Chinese hamster cells. Radiation Research 1972; 52: 320–333