References
- Awa A., Sofuni T., Honda T., Itoh N., Neriishi S., Otake M. Relationship between the radiation dose and chromosome aberrations in atomic bomb survivors of Hiroshima and Nagasaki. Journal of Radiation Research 1978; 19: 126–140
- Barrios L., Miró R., Caballín M.R., Fuster C., Guedea F., Subias A., Egozcue J. Cytogenetic effects of radiotherapy; breakpoint distribution in induced chromosome aberrations. Cancer Genetics and Cytogenetics 1989; 41: 61–70
- Bauchinger M., Götz G. Distribution of radiation induced lesions in human chromosomes and dose-effect relation analysed with G-banding. Radiation and Environmental Biophysics 1979; 16: 355–366
- Bauchinger M., Schmid E., Braselmann H., Willich N., Clemm Ch. Time-effect relationship of chromosome aberrations in peripheral lymphocytes after radiation therapy for seminoma. Mutation Research 1989; 211: 265–272
- Bauchinger M., Schmid E., Zitzelsberger H., Braselmann H., Nahrstedt U. Radiation-induced chromosome aberrations analysed by two-colour fluorescence in situ hybridization with composite whole chromosome-specific DNA probes and a pancentromeric DNA probe. International Journal of Radiation Biology 1993; 64: 179–184
- Buckton K.E. Identification with G- and R-banding of the position of breakage points induced in human chromosomes by in vitro X-irradiation. International Journal of Radiation Biology 1976; 29: 475–488
- Buckton K.E. Chromosome aberrations in patients treated with X-irradiation for ankylosing spondylitis. Radiation-Induced Chromosome Damage in Man, T. Ishihara, M. Sasaki. Liss, New York 1983; 491–511, In
- Buckton K., Hamilton G., Paton L., Langlands A. Chromosome aberrations in irradiated ankylosing spondilytis patients. Mutagen-Induced Chromosome Damage in Man, H. Evans, D. Lloyd. Edinburgh University Press, Edinburgh 1978; 142–150, In
- Cooke P., Seabright M., Wheeler M. The differential distribution of X-ray-induced chromosome lesions in trypsin-banded preparations from human subjects. Humangenetik 1975; 28: 221–231
- Cremer T., Popp S., Emmerich P., Lichter P., Cremer C. Rapid metaphase and interphase detection of radiation-induced chromosome aberrations in human lymphocytes by chromosomal suppression in situ hybridization. Cytometry 1990; 11: 110–118
- Dubos C., Viegas-Pequignot E., Dutrillaux B. Localization of γ-ray-induced chromatid breaks using a three consecutive staining technique. Mutation Research 1978; 49: 127–131
- Dutrillaux B., Couturier J., Viegas-Pequignot E., Schaison G. Localization of chromatid breaks in Fanconi's Anemia, using three consecutive stains. Human Genetics 1977; 37: 65–71
- Holmberg M., Jonasson J. Preferential location of X-ray-induced chromosome breakage in the R-bands of human chromosomes. Hereditas 1973; 74: 57–68
- Johnson G.D., de C. Nogueira Araujo G.M. A simple method of reducing the fading of immunofluorescence during microscopy. Immunological Methods 1981; 43: 349–350
- Lucas J.N., Awa A., Straume T., Poggensee M., Kodama Y., Nakano M., Ohtaki K., Weier H.-U., Pinkel D., Gray J., Littlefield G. Rapid translocation frequency analysis in man decades after exposure to ionizing radiation. International Journal of Radiation Biology 1992; 62: 53–63
- Lucas J.N., Sachs R.K. Using three-color chromosome painting to test chromosome aberration models. Proceedings of the National Academy of Sciences, USA 1993; 90: 1484–1487
- Lucas J.N., Tenjin T., Straume T., Pinkel D., Moore D., Litt M., Gray J.W. Rapid human chromosome aberration analysis using fluorescence in situ hybridization. International Journal of Radiation Biology 1989; 56: 35–44
- Morton N.E. Parameters of the human genome. Proceedings of the National Academy of Sciences, USA 1991; 88: 7474–7476
- Natarajan A.T., Vyas R.C., Darroudi F., Vermeulen S. Frequencies of X-ray-induced chromosome translocations in human peripheral lymphocytes as detected by in situ hybridization using chromosome-specific DNA libraries. International Journal of Radiation Biology 1992; 61: 199–203
- Pinkel D., Straume T., Gray J.W. Cytogenetic analysis using quantitative, high-sensitivity, fluorescence hybridization. Proceedings of the National Academy of Science, USA 1986; 83: 2934–2938
- Sachs R.K., Awa A., Kodama Y., Nakano M., Ohtaki K., Lucas J.N. Ratios of radiation-produced chromosome aberrations as indicators or large-scale DNA-geometry during interphase. Radiation Research 1993; 133: 345–350
- Savage J.R.K., Papworth D.G. Frequency and distribution of asymmetrical versus symmetrical chromosome aberrations. Mutation Research 1982; 95: 7–18
- Schmid E., Bauchinger M. Über das zeitliche Verhalten strahleninduzierter Chromosomomenaberrationen beim Menschen. Mutation Research 1969; 8: 599–611
- Schmid E., Zitzelsberger H., Braselmann H., Gray J.W., Bauchinger M. Radiation-induced chromosome aberrations analysed by fluorescence in situ hybridization with a triple combination of composite whole chromosome-specific DNA probes. International Journal of Radiation Biology 1992; 62: 673–678
- Straume T., Langlois R.G., Lucas J., Jensen R.H., Bigbee W.L. Novel biodosimetry methods applied to victims of the Goiâna accident. Health Physics 1991; 60: 71–76
- Straume T., Lucas J.N. A comparison of the yields of translocations and dicentrics measured using fluorescence in situ hybridization. International Journal of Radiation Biology 1993; 64: 185–187
- Tawn J. The non-random occurrence of exchanges involving chromosomes 7 and 14 in human lymphocytes—a prospective study of control individuals. Mutation Research 1988; 199: 215–220
- Tucker J.D., Ramsey M.J., Lee D.A., Minkler J.L. Validation of chromosome painting as a biodosimeter in human peripheral lymphocytes following acute exposure to ionizing radiation in vitro. International Journal of Radiation Biology 1993; 64: 27–37
- Weier H.-U.G., Lucas J.N., Poggensee M., Segraves R., Pinkel D., Gray J.W. Two-color hybridization with high complexity chromosome-specific probes and a degenerate alpha-satellite probe DNA allows unambiguous discrimination between symmetrical and asymmetrical transloctions. Chromosoma 1991; 100: 371–376