Usefulness and limits of biological dosimetry based on cytogenetic methods

doi:10.1093/rpd/nci061

Radiation Protection Dosimetry 2005 115(1-4):448-454; doi:10.1093/rpd/nci061

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Usefulness and limits of biological dosimetry based on cytogenetic methods

A. Léonard¹^,*, J. Rueff², G. B. Gerber¹ and E. D. Léonard¹

¹ Catholic University of Louvain, Brussels, Belgium
² New University of Lisbon, Lisbon, Portugal

^* Corresponding author: leonard{at}farm.ucl.ac.be

Damage from occupational or accidental exposure to ionisingradiation is often assessed by monitoring chromosome aberrationsin peripheral blood lymphocytes, and these procedures have,in several cases, assisted physicians in the management of irradiatedpersons. Thereby, circulating lymphocytes, which are in theG₀ stage of the cell cycle are stimulated with a mitogenic agent,usually phytohaemagglutinin, to replicate in vitro their DNAand enter cell division, and are then observed for abnormalities.Comparison with dose–response relationships obtained invitro allows an estimate of exposure based on scoring:

Unstableaberrations by the conventional, well-established analysisofmetaphases for chromosome abnormalities or for micronuclei;
So-called stable aberrations by the classical G-banding (Giemsa-Stain-banding)technique or by the more recently developed fluorescent in situhybridisation (FISH) method using fluorescent-labelled probesfor centromeres and chromosomes.

Three factors need to be considered in applying such biologicaldosimetry:

Radiation doses in the body are often inhomogeneous.A comparisonof the distribution of the observed aberrationsamong cellswith that expected from a normal poisson distributioncan allowconclusions to be made with regard to the inhomogeneityof exposureby means of the so-called contaminated poisson distributionmethod; however, its application requires a sufficiently largenumber of aberrations, i.e. an exposure to a rather large doseat a high dose rate.
Exposure can occur at a low dose rate(e.g. from spread or lostradioactive sources) rendering a comparisonwith in vitro exposurehazardous. Dose–effect relationshipsof most aberrationsthat were scored, such as translocations,follow a square law.Repair intervening during exposure reducesthe quadratic componentwith decreasing dose rate as exposureis spread over a longerperiod of time. No valid solution forthis problem has yet beendeveloped, although, in theory, bothdeterministic damage andaberrations might be repaired to asimilar degree; a comparisonof aberrations following a lineardose relationship might alsohelp when the doses have been sufficientlylarge.
Investigations might have been possible only a certaintimeafter the exposure. The relatively rapid disappearanceof lymphocytescarrying unstable aberrations limits their usein retrospectivedosimetry, years after exposure. Scoring stableaberrations,thought to persist in the circulating lymphocytes,might appearmore appropriate in such situations. However, theexaminationof a representative number of cells by G-bandingis extremelylaborious, and the FISH method is not only expensivebut hasnot yet been fully validated in different laboratories.

In conclusion, biological dosimetry has serious limitationsexactly for situations where the need for information is mosturgent. It renders its most useful results when an individualhas been exposed to a rather homogeneous high-level radiationover a short time interval, i.e. accidents at high-intensityradiation devices. On the other hand, it yielded less satisfactoryinformation even when the most recent techniques were used forsituations, where a low level, low dose rate exposure has occurredat some time in the past, for example for persons living inareas contaminated from the Chernobyl accident. Such negativeexperiences should be kept in mind in order to avoid futileand expensive investigations in the case of populations exposedfrom radioactivity and, notably, also from potentially clastogenicchemical agents.

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