Distribution of radiation‐induced exchange aberrations in all human chromosomes

References

• BARQUINERO, J. F., KNEHR, S., BRASELMANN, H., FIGL, M. and BAUCHINGER, M., 1998, DNA-proportional distribution of radiation-induced chromosome aberrations analysed by fluorescence in situ hybridization painting of all chromo-somes of a human female karyotype. International Journal of Radiation Biology, 74, 315–323.
   PubMed Web of Science ®Google Scholar
• BAUCHINGER, M., 1995, Quantification of low-level radiation exposure by conventional chromosome aberration analysis. Mutation Research, 339, 177–189.
   PubMed Web of Science ®Google Scholar
• BAUCHINGER, M., 1998, Retrospective dose reconstruction of human radiation exposure by FISH/chromosome painting. Mutation Research, 404, 89–96.
   PubMed Web of Science ®Google Scholar
• BAUCHINGER, M., SCHMID, E., ZITZELSBERGER, H., BRASELMANN, H. and NAHRSTEDT, U., 1993, Radiation-induced chromo-some aberrations analyzed by two-colour fluorescence in situ hybridization with composite whole-chromosome-specific DNA-probes and a pancentromeric DNA-probe. International Journal of Radiation Biology, 64, 179–184.
   PubMed Web of Science ®Google Scholar
• BOEI, J. J. W. A., VERMEULEN, S. and NATARAJAN, A. T., 1997, Differential involvement of chromosome 1 and 4 in the formation of chromosomal aberrations inhuman lymphocytes after X-irradiation. International Journal of Radiation Biology, 72, 139–145.
   Google Scholar
• CIGARRÁN, S., BARRIOS, L., BARQUINERO, J. F., CABALLIN, M. R., RrBAs, M. and EGOZCUE, J., 1998, Relationship between the DNA content of human chromosomes and their involvement in radiation-induced structural aberrations, analysed by painting. International Journal of Radiation Biology, 74, 449–455.
   Google Scholar
• D'AGOSTINO, R. B. and RUSSEL, SR, H. K., 1998, Multiple endpoints, P level procedures. In P. Armitage and
   Google Scholar
• T.Colton (eds), Encyclopedia of Biostatistics, vol. 4(New York: Wiley), pp. 2762-2772.
   Google Scholar
• FERNANDEZ, J. L., CAMPOS, A., GOYANES, V., LOSADA, C., VE1RAS, C. and EDWARDS, A. A., 1995, X-ray biological dosimetry performed by selective painting of human chromosomes 1 and 2. International Journal of Radiation Biology, 67, 295–302.
   Google Scholar
• GRANATH, F., GIUGOREVA, M. and NATARAJAN, A. T., 1996, DNA content proportionality and persistence of radiation-induced chromosomal aberrations by FISH. Mutation Research, 366, 145–152.
   PubMed Web of Science ®Google Scholar
• HUBER, R., KULKA, U., LORCH, TH., BRASELMANN, H., ENGERT, D., FIGEL, M. and BAUCHINGER, M., 2001, Technical Report: application of the Metafer2 fluorescence scanning system for the analysis of radiation-induced chromosome aber-rations measured by FISH-chromosome painting. Mutation Research, 492, 51–57.
   PubMed Web of Science ®Google Scholar
• JOHNSON, K. L., BRENNER, D. J., NATH, J., TUCKER, J. D. and GEARD, C. R., 1999, Review: Radiation-induced misre-joining in human chromosomes: random or non-random? International Journal of Radiation Biology, 75, 131–141.
   PubMed Web of Science ®Google Scholar
• JOHNSON, K. L., TUCKER, J. D. and NATH, J., 1998, Frequency, distribution and clonality of chromosome damage in human lymphocytes by multi-color FISH. Mutagenesis, 13, 217–227.
   PubMed Web of Science ®Google Scholar
• KNEBR, S., HUBER, R., BRASELMANN, H. and BAUCHINGER, M., 1999, Multicolour FISH painting for the analysis of chromosomal aberrations induced by 220 kV X-rays and fission neutrons. International Journal of Radiation Biology, 75, 407–418.
   PubMed Web of Science ®Google Scholar
• KNEHR, S., ZITZELSBERGER, H., BRASELMANN, H. and BAUCHINGER, M., 1994, Analysis for DNA-proportional distribution of radiation-induced chromosome aberrations in various triple combinations of human chromosomes using fluorescence in situ hybridization. International Journal of Radiation Biology, 65, 683–690.
   PubMed Web of Science ®Google Scholar
• KNEHR, S., ZITZELSBERGER, H., BRASELMANN, H., NAFIRSTEDT, U. and BAUCHINGER, M., 1996, Chromosome analysis by fluorescence in situ hybridization: further indications for a non-DNA-proportional involvement of single chromosomes in radiation-induced structural aberrations. International Journal of Radiation Biology, 70, 385–392.
   PubMed Web of Science ®Google Scholar
• KULKA, U., HUBER, R., MULLER, P., KNEFIR, S. and BAUCHINGER, M., 1995, Combined FISH painting and harlequin staining for cell-cycle controlled chromosome analysis in human lymphocytes. International Journal of Radiation Biology, 68, 25–27.
   PubMed Web of Science ®Google Scholar
• LUCAS, J. N., AWA, A., STRAUME, T., POGGENSEE, M., KODAMA, Y., NAKANO, M., OurAm, K., WElER, H.-U., FINKEL, D., GRAY," and LrrrrEFIELD, G., 1992, Rapid translocation frequency analysis in man decades after exposure to ionizing radiation. International Journal of Radiation Biology, 62, 53–63.
   Google Scholar
• LUOMAHAARA, S., LINDHOLM, C., MUSTONEN, R. and SALOMAA, S., 1999, Distribution of radiation-induced exchange aber-rations in human chromosomes 1, 2 and 4. International Journal of Radiation Biology, 75, 1551–1556.
   PubMed Web of Science ®Google Scholar
• MORTON, N. E., 1991, Parameters of the human genome. Proceedings of the National Academy of Sciences, USA, 88, 7474–7476.
   PubMed Web of Science ®Google Scholar
• SACHS, R. K., AWA, A., KODAMA, Y., NAKANO, M., OurAKI, K. and LUCAS, J. N., 1993, Ratios of radiation-produced chromosome aberrations as indicators of large-scale DNA geometry during interphase. Radiation Research, 133, 345–350.
   PubMed Web of Science ®Google Scholar
• SAcHs, R. K., ROGOFF, A" CHEN, A. M., SIIVIPSON, P. J.5 SAVAGE, J. R., HAHNFELDT, P. and HLATKY, L. R., 2000, Underpre-diction of visibly complex chromosome aberrations by a recombinational-repair ('one-hit') model. International Journal of Radiation Biology, 76, 129–148.
   Google Scholar
• SAVAGE, J. R. K. and SIMPSON, P. J., 1994a, On the scoring of FISH-painted chromosome exchange aberrations. Mutation Research, 307, 345–353.
   Google Scholar
• SAVAGE," R. K. and SIIVIPSON, P. J., 1994b, Fish painting patterns resulting from complex exchanges. Mutation Research, 312, 51–60.
   Google Scholar
• SCHMID, E., ZITZELSBERGER, H., BRASELMANN, H., GRAY, J. W. and BAUCHINGER, M., 1992, Radiation-induced chromosome aberrations analysed by fluorescence in situ hybridisation with a triple combination of composite whole-chromosome-specific DNA probes. International Journal of Radiation Biology, 62, 673–678.
   PubMed Web of Science ®Google Scholar
• STEPHAN, G. and PRESSL, S., 1997, Chromosome aberrations in human lymphocytes analysed by fluorescence in situ hybridization after in vitro irradiation, and in radiation workers, 11 years after an accidental radiation exposure. International Journal of Radiation Biology, 71, 293–299.
   PubMed Web of Science ®Google Scholar
• TUCKER, J. D., MORGAN, W. F., AWA, A. A., BAUCHINGER, M., BLAKEY, D., CORNFORTH, M. N., LrrnEFTELD, L. G., NATARAJAN, A. T. and SHASSERRE, C., 1995, A proposed system for scoring structural aberrations detected by chromosome painting. Cytogenetics and Cell Genetics, 68, 211–221.
   PubMedGoogle Scholar
• TUCKER, J. D., RAMSEY, M. J., LEE, D. A. and MlNKLER, J. L., 1993, Validation of chromosome painting as a biodosimeter in human peripheral lymphocytes following acute exposure to ionizing radiation in vitro. International Journal of Radiation Biology, 64, 27–37.
   PubMed Web of Science ®Google Scholar
• WEIER, H.-U. G., LUCAS, J. N., POGGENSEE, M., SEGRAVES, R., PINKEL, D. and GRAY, J. W., 1991, Two-color hybri-dization with high complexity chromosome-specific probes and a degenerate alpha-satellite probe DNA allows unambiguous discrimination between symmetrical and asymmetrical translocations. Chromosoma, 100, 371–376.
   PubMed Web of Science ®Google Scholar