Calibration curves by <sup>60</sup>Co with low dose rate are different in terms of dose estimation – a comparative study

Mendes, Mariana Esposito; Mendonça, Julyanne Conceição Goes de; Hwang, Suy; Giorgio, Marina Di; Lima, Fabiana Farias de; Santos, Neide

doi:10.1590/1678-4685-GMB-2018-0370

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Human and Medical Genetics • Genet. Mol. Biol. 43 (01) • 2020 • https://doi.org/10.1590/1678-4685-GMB-2018-0370 copy

Calibration curves by ⁶⁰Co with low dose rate are different in terms of dose estimation – a comparative study

Authorship SCIMAGO INSTITUTIONS RANKINGS

Abstract

Biological dosimetry aims to estimate individual absorbed doses due ionizing radiation exposure. The dicentric chromosomes are considered the most specific biomarker for dose estimation. This study aimed to compare calibration curves for linear low energy transfer (LET) radiation built from low dose rates and whether they vary in terms of dose estimation. For that we did a search in the literature of all calibration curves produced with low dose rates and we simulated the dose estimation from pre-established dicentric’s frequencies. The information on methodologies and cytogenetic results of each study were analyzed. As expected dose rate influence β coefficients, especially at higher doses. However, we have seen that some doses were not statistically different but they should be, because there is a significant association between the productions of dicentrics and dose rate. This comparative study reinforced the robustness of the dicentric assay and its importance in biological dosimetry. We also emphasized that the dose rate was an important factor in dose estimations. Thus, intercomparison exercises should take into account the dose rates of the participating laboratories, because the dose rates might explain why some results of estimated doses fall outside the recommendations.

Keywords:
Dicentrics; gamma radiation; biological dosimetry; intercomparisons

Introduction

Biological dosimetry aims to estimate individual absorbed doses due ionizing radiation exposure. The determination of absorbed dose using a biological method is very important, because offers essential information that will support the medical management of patients in emergencies (Di Giorgio et al., 2011Di Giorgio M, Barquinero JF, Vallerga MB, Radl A, Taja MR, Seoane A, De Luca J, Oliveira MS, Valdivia P, Lima OG et al. (2011) Biological dosimetry intercomparison exercise: an evaluation of triage and routine mode results by robust methods. Radiat Res 175:38-649.; Gruel et al., 2013Gruel G, Grégoire E, Lecas S, Martin C, Roch-Lefevre S, Vaurijoux A, Voisin P, Voisin P and Barquinero JF (2013) Biologival dosimetry by automated dicentric scoring in a simulated emergency. Radiat Res 179:557-569.).

Adequate dose estimation is based on biomarkers analysis that should be specific and sensitive to radiation, and independent of other environmental exposures. The international biodosimetry considers the dicentric chromosome assay as “gold standard” for recent radiation exposures, because in general, the yield of dicentrics is very low (~0.5–1.0 per 1000 cells) in natural occurrence. Besides that, dicentrics can be used to individual dose assessment for homogeneous whole-body exposures to doses as low as 100 mGy for low linear energy transfer (LET) radiation, if up to 1000 cells are analyzed. It is also possible differentiates between partial and whole body exposures, as well as high or low LET radiation (IAEA, 2011IAEA - International Atomic Energy Agency (2011) Cytogenetic analysis for radiation dose assessment: a manual. International Atomic Energy Agency, Vienna.; Lee et al., 2012Lee JK, Han E, Lee S, Ha W, Barquinero JF, Lee HR and Cho MS (2012) Cytogenetic biodosimetry for Fukushima travelers after the nuclear power plant accident: no evidence of enhanced yield of dicentrics. J Radiat Res 53:876-881.; Pernot et al., 2012Pernot E, Hall J, Baatout S, Benotmane MB, Blanchardon E, Bouffler S, El Saghire H, Gomolka M, Guertler A, Harms-Ringdahl M et al. (2012) Ionizing radiation biomarkers for potential use in epidemiological studies. Mutat Res 751:258-286.; Wong et al., 2013Wong KF, Siu LLP, Ainsbury E and Moquet J (2013) Cytogenetic biodosimetry: what it is and how we do it. Hong Kong Med J 19:168-73., Hall et al., 2017Hall J, Jeggo PA, West C, Gomolka M, Quintens R, Badie C, Laurent O, Aerts A, Anastasov N, Azimzadeh O et al. (2017) Ionizing radiation biomarkers in epidemiological studies–an update. Mutat Res 771:59-84.).

Several studies have used dicentrics for dose estimation after accidental exposure of workers, such as two radiographers and their driver who were seriously exposed to an ¹⁹²Ir industrial radiography source, that became detached from its wind-out cable (Sevan’kaev et al., 2002Sevan’kaev AV, Lloyd DC, Edwards AA, Moquet JE, Nugis VY, Mikhailova GM, Potetnya OI, Khvostunov IK, Guskova AK, Baranov AE et al. (2002) Cytogenic investigations of serious overexposures to an industrial gamma radiography source. Radiat Prot Dosimetry 102:201-206.), and technician involved in the maintaining of X-ray equipment (Thierens et al., 2005Thierens H, De Ruyck K, Vral A, de Gelder V, Whitehouse CA, Tawn EJ and Boesman I (2005) Cytogenetic biodosimetry of an accidental exposure of a radiological worker using multiple assays. Radiat Prot Dosimetry 113:408-414.). There are also major accidents, such as soldiers carrying small sources of ¹³⁷Cs in their pockets, leading to partial and prolonged body exposures; employees involved in the ²³⁵U enrichment process were exposed to gamma rays and neutrons; and radiotherapy breast cancer patients were undergoing were exposed to electrons, which reached about 100 Gy (Wojcik et al., 2004Wojcik A, Gregoire E, Hayata I, Roy L, Sommer S, Stephan G and Voisin P (2004) Cytogenetic damage in lymphocytes for the purpose of dose reconstruction: a review of three recent radiation accidents. Cytogenet Genome Res 104:200-205.). As well as large-scale radiation accidents, such as Chernobyl, Ukraine, in 1986 (Hatch et al., 2005Hatch M, Ron E, Bouville A, Zablotska L and Howe G (2005) The Chernobyl disaster: cancer following the accident at the Chernobyl nuclear power plant. Epidemiol Rev 27:56-66.; Beresford and Copplestone, 2011Beresford NA and Copplestone D (2011) Effects of ionizing radiation on wildlife: what knowledge have we gained between the Chernobyl and Fukushima accidents? Integr Environ Asses 7:371-373.), Goiânia, Brazil, in 1987 (Ramalho et al., 1988Ramalho AT, Nascimento ACH and Natarajan AT (1988) Dose assessments by cytogenetic analysis in the Goiania (Brazil) radiation accident. Radiat Prot Dosimetry 25:97-100., 1991Ramalho AT, Nascimento ACH, Littlefield LG, Natarajan AT and Sasaki MS (1991) Frequency of chromosomal aberrations in a subject accidentally exposed to 137Cs in the Goiania (Brazil) radiation accident: Intercomparison among four laboratories. Mutat Res/Environ Mutat Relat Subj 252: 157-160.), Fukushima, Japan, in 2011 (Beresford and Copplestone, 2011Beresford NA and Copplestone D (2011) Effects of ionizing radiation on wildlife: what knowledge have we gained between the Chernobyl and Fukushima accidents? Integr Environ Asses 7:371-373.; Yasunari et al., 2011Yasunari TJ, Stohl A, Hayano RS, Burkhart JF, Eckhardt S and Yasunari T (2011) Cesium-137 deposition and contamination of Japanese soils due to the Fukushima nuclear accident. Proc Natl Acad Sci U S A 108:19530-19534.; Gering et al., 2013Gering F, Gerich B, Wirth E and Kirchner G (2013) Potential consequences of the Fukushima accident for off-site nuclear emergency management: a case study for Germany. Radiat Prot Dosimetry 155:146-154.).

The establishment of at least one appropriate calibration curve is an essential condition for dose estimation. It is necessary to build a pre-defined dose-response calibration curve, where the yields of chromosomal aberrations are dose related by the linear quadratic equation for low LET, and by the linear equation for high LET radiation. The standard curve to be used must have a radiation quality equal to or very similar to the specific type of radiation involved in the emergency (IAEA, 2011IAEA - International Atomic Energy Agency (2011) Cytogenetic analysis for radiation dose assessment: a manual. International Atomic Energy Agency, Vienna.; Roy et al., 2012Roy L, Grégoire E, Gruel G, S. Roch-Lefevre S, Voisin P, Busset A, Martin C and Voisin P (2012) Effect of lymphocytes culture variations on the mitotic index and on the dicentric yield following gamma radiation exposure. Radiat Prot Dosimetry 151:135-143.). The International Atomic Energy Agency (IAEA, 2011IAEA - International Atomic Energy Agency (2011) Cytogenetic analysis for radiation dose assessment: a manual. International Atomic Energy Agency, Vienna.) recommends that each biodosimetry laboratory define its own calibration curve, as intrinsic differences in protocols and dose interpretation using a calibration curve produced elsewhere may introduce extra uncertainty in dose estimation.

Most in vitro calibration curves built and published refer to acute exposure using dose rates of 0.5 Gy/min. However, major accidental exposure scenarios involve irradiation for an uncertain period varying distances and dose rates (Vinnikov et al., 2010Vinnikov VA, Ainsbury EA, Maznyk, NA, Lloyd DC and Rothkamm K (2010) Limitations associated with analysis of cytogenetic data for biological dosimetry. Radiat Res 174:403-414.; IAEA, 2011IAEA - International Atomic Energy Agency (2011) Cytogenetic analysis for radiation dose assessment: a manual. International Atomic Energy Agency, Vienna.). However, there is one mathematical model for estimating dose for accidents involving a lower dose rate employing the time-dependent factor known as G-function (Lea and Catcheside, 1942 apudIAEA, 2011IAEA - International Atomic Energy Agency (2011) Cytogenetic analysis for radiation dose assessment: a manual. International Atomic Energy Agency, Vienna.). This time-dependent factor is use to modify the dose squared coefficient and thus allow for the effects of dose protraction (IAEA, 2011IAEA - International Atomic Energy Agency (2011) Cytogenetic analysis for radiation dose assessment: a manual. International Atomic Energy Agency, Vienna.). However, some biodosimetry groups have chosen to produce a non-acute calibration curve in order to better understanding how the quadratic coefficient should be modified to interpret aberration yields in accidents involving prolonged irradiation.

In this context, this study aimed to compare calibration curves for linear low energy transfer (LET) radiation built from low dose rates and whether they vary in terms of dose estimation. For that, we performed a search in the literature of all gamma radiation calibration curves produced at low dose rates and simulated dose estimation from pre-established dicentrics frequencies.

Materials and Methods

Construction of calibration curve

Firstly, we built a reference calibration curve for our laboratory. For this purpose, blood samples (5 mL) were collected from a voluntary non-smoking woman with informed consent (ethics approval no. 269.483). Each sample was irradiated with Cobalt60 irradiator (Gammacell 220 ® - MDS Nordion, Ottawa, Canada) with average energies of 1.25 MeV at Departamento de Energia Nuclear (DEN-UFPE, Recife, Brazil). With dose rates of 0.055 to 0.048 Gy/min with uncertainty of 2% at the point of irradiation. The blood sample tubes were wrapped in 4 mm of dense material (following IAEA, 2011IAEA - International Atomic Energy Agency (2011) Cytogenetic analysis for radiation dose assessment: a manual. International Atomic Energy Agency, Vienna.). For the elaboration of the calibration curve, blood samples were irradiated between 0.15 - 5 Gy, and after incubated for 2 h at 37 ºC.

Heparinized whole blood (0.5 ml) were culture for 48h in 4 mL of RPMI-1640 (Sigma) medium supplemented with 0.2 mL of phytohaemagglutinin (Sigma), and 1 mL of fetal bovine serum (Biological Industries). In addition, 0.1 mL of 0.0016% colchicine (Sigma) was added 46 hours after culture started. At the end of 48 h, the supernatant was removed, and the cell pellet homogenized in 8 mL of 0.075M KCl, and placed at 37 ^oC for 20 min, after the supernatant was removed and cells fixed in 7 mL Carnoy’s fixative solution (3:1 methanol: glacial acetic acid mixture). Finally, chromosomal preparations were stained with a 5% Giemsa stain in pH 6.8 buffer for 6 min. We also followed the IAEA (2011)IAEA - International Atomic Energy Agency (2011) Cytogenetic analysis for radiation dose assessment: a manual. International Atomic Energy Agency, Vienna. recommendation that only complete metaphases be recorded, i.e. those with 46 centromeres and if the cell contains unstable aberrations, then it should balance. Therefore, if a spread containing a dicentric should also have an acentric fragment, yet still count to 46 pieces.

Selected calibration curves

For this comparative study, we made an exhaustive literature search of experimental studies on Web of Science, relying on the following keywords: “dosimetry”, “dose response”, “calibration curve”, “gamma radiation” and “dicentrics”. Once we located these papers, we tested if they fulfilled our inclusion criteria. We also searched the reference lists of all identified publications in an attempt to locate additional publications. We included (1) calibration curves already defined by selected cobalt-60 sources at dose rates below 0.5 Gy/min and a single curve was used as the standard (dose rate 0.5 Gy/min); (2) studies that presented all information about dicentric frequencies; (3) dose effect curves established by manual scoring. Exclusion criteria were (1) studies that presented only information on dicentric plus ring frequencies; (2) studies without dicentric distribution per cell; (3) studies in which dose effect curves were established by automatic or semiautomatic scoring. Until April 10, 2019, we found seven studies following these criteria. Then, we compared information on methodologies (dose analysis, scored cells) and cytogenetic results from each study (frequencies and distribution of dicentrics).

Comparison of Calibration Curves

All selected calibration curves were compared using two approaches: 1) the parameters of each methodology, as well as dicentrics distribution data with no modifications; and 2) all data (including statistic coefficients) were standardized using Dose Estimate software (Ainsbury et al., 2010Ainsbury EA and Lloyd DC (2010) Dose Estimation Software for Radiation Biodosimetry. Health Physics Soc 98:290-295.) to perform the statistics. Thus, all results were re-tested to analyze their conformity with Poisson distribution by means of the Papworth’s u test (Acharya et al., 2009Acharya S, Sanjeev G, Bhat NN, Siddappa K and Narayana Y (2009) The effect of electron and gamma irradiation on the induction of micronuclei in cytokinesis-blocked human blood lymphocytes. Radiat Environ Biophys 48:197-203.; IAEA, 2011IAEA - International Atomic Energy Agency (2011) Cytogenetic analysis for radiation dose assessment: a manual. International Atomic Energy Agency, Vienna.). Thereafter, using R-based tools2 (R Development Core Team, 2012R Development Core Team (2012) R: A language and environment for statistical computing, http://www.R-project.org/.
http://www.R-project.org/... ) the Pearson’s Chi-squared test was applied to determine whether the yield of dicentric varies according to calibration curves.

Firstly, we simulate the dose estimation from six pre-determined dicentric frequencies between 0.02-1 dicentric per cell. Thus, all results of estimated absorbed doses along with their lower and upper confidence limits were used. The confidence limits were based on exact Poisson error on yield, because this simplified method is more commonly encountered in biodosimetry comparison exercise (Szluinska et al., 2007Szluinska M, Edwards A and Lloyd D (2007) Presenting statistical uncertainty on cytogenetic dose estimates. Radiat Protect Dos 123:443-449.).

In addition, we used ANOVA test to compare dose estimation among all calibration curve. ANOVA is a parametric method of analysis, which is generally applied to normal data, but the data type distributed by Poisson also approximates normal distribution sufficiently to ensure that ANOVA can be applied. When performing a variance analysis, the null hypothesis considered is that there is no difference in treatment averages; consequently, in these cases, there is no difference between the estimated doses (IAEA, 2011IAEA - International Atomic Energy Agency (2011) Cytogenetic analysis for radiation dose assessment: a manual. International Atomic Energy Agency, Vienna.; Wilkins et al., 2015Wilkins RC, Beaton-Green LA, Lachapelle S, Kutzner BC, Ferrarotto C, Chauhan V, Marro1 L, Livingston GK, Greene HB and Flegal FN (2015) Evaluation of the annual Canadian biodosimetry network intercomparisons. Int J Radiat Biol 91:443-451.). Subsequently, Tukey’s multiple comparison tests were conducted to find significantly different media.

Results

The distributions of dicentric cells selected for our calibration curve followed a Poisson distribution (Table 1), and the curve was adjusted to linear-quadratic model (Table 2) as expected for blood samples homogeneously exposed to low LET gamma-radiation (IAEA, 2011IAEA - International Atomic Energy Agency (2011) Cytogenetic analysis for radiation dose assessment: a manual. International Atomic Energy Agency, Vienna.). A tendency toward under-dispersion was observed in the distributions of dicentric cells, but this trend was not statistically significant, except at the 3 Gy dose (Table 1).

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Table 1
Distribution of dicentric chromosomes produced using low dose rate with respective dispersion indexes and u values from this work.

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Table 2
Comparison of methodologies and coefficient values of calibration curve produced by cobalt-60 sources with low dose rates.

All compared studies were performed with different parameters, based on the different methodologies used in building each calibration curve. Consequently, these curves had different coefficient values (Table 2). Most of these studies used 48 h for the lymphocyte cultures, and a few studies did not use bromodeoxyuridine (BrdU). Other differences between studies included the irradiation conditions (low dose rates and dose ranges) and the number of volunteers. We did not consider differences in slide scoring criteria, because that information was not available in most selected studies.

To reduce the differences between the coefficients values used for curve fitting in statistical analyses, we decided to re-analyze all published calibration curves with a single software program (Dose Estimate). After this re-analysis, we found minimal differences between the newly generated coefficients and the coefficients previously published, with the exception of one linear coefficient (α) from the study by Top et al. (2000)Top A, Coskun M and Orta T (2000) Biological dosimetry of Co-60 gamma radiation. Turk J Haematol 17:189-196. (Table 2).

The frequencies of dicentrics increased with the absorbed dose and with the dose rate; these same tendencies were observed in the distributions of dicentrics per cell. To confirm this behavior, we performed the Pearson’s Chi-squared test. We compared only doses of 0.5, 1, and 2 Gy, because these doses were included in all calibration curves. We found a significant association between production of one dicentric per cell at doses of 1 and 2 Gy and in cases of more than one dicentric per cell, we found significant differences among dose rates, mainly at the 2 Gy dose. This finding was confirmed with a Chi-squared test (Table S1).

To evaluate whether these differences in dose rates generated diverse estimated doses, we analyzed six different dicentric frequencies (0.02 – 1 dicentric per cell) that resulted in absorbed doses of 0.5 to 5 Gy (Table 3). As expected, we observed two major trends: (1) as the dicentric frequencies increased, the estimated doses and their uncertainties (SE) increased, particularly for curves that included included the lower dose rate; and (2) in studies with the highest dose rates, the number of dicentrics could predict the lowest absorbed doses (Table 3).

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Table 3
Comparison of estimated absorbed doses by selected calibration curves using Dose Estimate software.

First, the ANOVA results showed that the estimated doses were different at almost all frequencies tested (the first column number of groups compared in Table 4). Second, Tukey´s test, applied only when the ANOVA results showed a significant difference, indicated significant differences among calibration curves (Table 5), principally the absorbed doses from Schmid et al. (2002)Schmid E, Regulla D, Guldbakke S, Schlegel D and Roos M (2002) relative biological effectiveness of 144 keV neutros in producing dicentric chromosomes in human lymphocytes compared with 60Co gamma rays under heading-heat conditions. Radiat Res 157:453-460. with Köksal et al. (1995)Köksal G, Pala FS and Dalci DO (1995) In vitro dose-response curve for chromosome aberrations induced in human lymphocytes by 60Co γ -radiation. Mut Res 329:57-61. and Lloyd et al. (1986)Lloyd DC, Edwards AA and Prosser JS (1986) Chromosome abberations induced in human lymphocytes by in vitro acute X and gamma radiation. Radiat Prot Dosimetry 15:83-88..

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Table 4
Comparison results of estimated absorbed doses by ANOVA after jackknife-like resampling method.

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Table 5
Results of Tukey’s test after comparing all possible pairs of means.

To gain a better understanding of the sources of bias, including the potential effects of outlier curves in dose estimations, we replicated our analysis with a jackknife-like resampling method. First, absorbed doses from Schmid et al. (2002)Schmid E, Regulla D, Guldbakke S, Schlegel D and Roos M (2002) relative biological effectiveness of 144 keV neutros in producing dicentric chromosomes in human lymphocytes compared with 60Co gamma rays under heading-heat conditions. Radiat Res 157:453-460. were withdrawn from the analysis group. However, the significant differences between estimated doses persisted (Tables 4 and 5) until some estimated doses did not present statistical significance (Table 4).

All compared estimated doses and their respective uncertainties were not significantly different at the 0.02 dicentric frequency. On the other hand, at the intermediate frequencies of 0.15 and 0.20 dicentrics per cell, we observed more conflicts (p-values < 0.05) than we observed at the more elevated frequencies. We speculated that this result was influenced by the 95% confidence limits, because the uncertainties were low in dose estimates at intermediate frequencies, which were defined with exact Poisson errors (Tables 4 and 5).

Discussion

Dicentric chromosomes represent specific, sensitive biomarkers for estimated absorbed doses. Indeed, this chromosomal aberration appears, regardless of the protocol used for dose estimation (Table 2) (Lee et al., 2012Lee JK, Han E, Lee S, Ha W, Barquinero JF, Lee HR and Cho MS (2012) Cytogenetic biodosimetry for Fukushima travelers after the nuclear power plant accident: no evidence of enhanced yield of dicentrics. J Radiat Res 53:876-881.; Wong et al., 2013Wong KF, Siu LLP, Ainsbury E and Moquet J (2013) Cytogenetic biodosimetry: what it is and how we do it. Hong Kong Med J 19:168-73.). When dose-response curves are constructed, interlaboratory differences might well occur, due to inherent protocol differences. The differences in coefficients might be explained by several factors, including the total absorbed dose, dose rate, irradiated cell lines, biological endpoints, LET, and energy (IAEA, 2011IAEA - International Atomic Energy Agency (2011) Cytogenetic analysis for radiation dose assessment: a manual. International Atomic Energy Agency, Vienna.; Lee, 2011Lee JK (2011) Practical applications of cytogenetic biodosimetry in radiological emergencies. Korean J Hematol 46:62-64.; Okumura et al., 2013Okumura K, Kinashi Y, Kubota Y, Kitajima E, Okayasu R, Ono K and Takahashi S (2013) Relative biological effects of neutron mixed-beam irradiation for boron neutron capture therapy on cell survival and DNA double-strand breaks in cultured mammalian cells. J Radiat Res 54:70-75.). Another factor that might affect the results is the number of volunteers used in constructing the calibration curves, because inter-individual variability might affect the results. However, until recently, the construction of curves based on individual variability of dicentric chromosomes have not been well studied. Martins et al. (2013)Martins V, Antunes AC and Monteiro Gil O (2013) Implementation of a dose-response curve for γ-radiation in the Portuguese population by use of the chromosomal aberration assay. Mutat Res 750:50–54. produced calibration curves based on data from sixteen donors. The donors were distributed by age and gender to examine potential effects on any differences observed. However, in general, all the curves constructed showed good fits to the data. Although the fits were somewhat less accurate for data from females and from the oldest age group, but no significant differences were found.

Some variables are highly critical in constructing dose-response curves; e.g., the dose rate and the scoring criteria. The dose rate is a critical factor when analyzing chromosomal aberrations, because prolonged irradiation times reduce the frequency of dicentrics induced by low LET radiation. Extended irradiation times allow cellular repair mechanisms to correct the damage, which then reduces the frequency of dicentrics. To generate a dicentric, two lesions, one in the DNA double helix of each unreplicated chromosome, must be produced within a target zone. With low LET radiation, the probability is low that two ionizing events will occur in a single track. Therefore, two ionizations are necessary to cause damage in two chromosomes to produce a dicentric. Dicentrics produced by one irradiation will occur at a frequency proportional to a linear dose function (linear coefficient - α), and dicentrics induced by two irradiations will have a frequency proportional to the square of the dose (quadratic coefficient - β). When lesions are produced by two independent irradiations, and the dose rate is low, the likelihood is high that an injury produced by the first irradiation will be repaired before the second irradiation causes damage. Thus, the two lesions are unlikely to form a dicentric chromosome (Vinnikov et al., 2010Vinnikov VA, Ainsbury EA, Maznyk, NA, Lloyd DC and Rothkamm K (2010) Limitations associated with analysis of cytogenetic data for biological dosimetry. Radiat Res 174:403-414.; IAEA, 2011IAEA - International Atomic Energy Agency (2011) Cytogenetic analysis for radiation dose assessment: a manual. International Atomic Energy Agency, Vienna.).

Studies have shown that the linear coefficient (α) is independent of the dose rate, and that the quadratic coefficient (β) decreases as the dose rate decreases (Brewen and Luippold, 1971Brewen JG and Luippold HE (1971) Radiation-induced human chromosome abberrations: In vitro dose rate studies. Mutat Res 12:105-314.; Lloyd et al., 1975Lloyd DC, Purrott RJ, Dolphin GW, Bolton D and Edwards AA (1975) The relationship between chromosome aberrations and low LET radiation dose to human lymphocytes. Int J Radiat Biol 28:75-90., 1981Lloyd DC and Purrott RJ (1981) Chromosome aberration analysis in radiological protection dosimetry. Radiat Prot Dosimetry 1:19-28.; Bauchinger et al., 1979Bauchinger M, Schmid E and Dresp J (1979) Calculation of the dose-rate dependence of the dicentric yield after Co y-irradiation of human lymphocytes. Int J Radiat Biol 35:229-233., 1983Bauchinger M, Schmid E, Streng S and Dresp J (1983) Quantitative analysis of the chromosome damage at first division of human lymphocytes after 60Co γ -irradiation. Radiat Environ Biophys 22:225-229.). This behavior was also observed in the calibration curves compared in this study. We noted a reduction in the β term of the calibration curve as the dose rate decreased (Table 2).

However, the β coefficient of Schmid et al. (2002)Schmid E, Regulla D, Guldbakke S, Schlegel D and Roos M (2002) relative biological effectiveness of 144 keV neutros in producing dicentric chromosomes in human lymphocytes compared with 60Co gamma rays under heading-heat conditions. Radiat Res 157:453-460. behaved differently from the expected behavior. Those authors also noted that reductions in the β coefficient could not be attributed to a dose-rate effect; instead, other protocol aspects might have influenced this coefficient value, such as the scoring criteria. Scoring depends on two main factors (i) the spreading quality and metaphase selection, and (ii) the dicentric identification (Roy et al., 2004Roy L, Buard V, Delbos M, Durand V, Paillole N, Grégoire E and Voisin P (2004) International intercomparison for criticality dosimetry: the case of biological dosimetry. Radiat Prot Dosimetry 110: 471-476.). These factors might influence the criteria for identifying dicentrics, which could then increase or decrease the number of dicentrics considered in the total analysis.

In this comparison study, we observed the greatest divergences in intermediate dicentric frequencies, because the uncertainties in dose estimations were relatively small. At the higher dicentric frequencies, the respective uncertainties were larger; thus, the uncertainty in dosing contributed to the lack of significant differences (Szluinska et al., 2007Szluinska M, Edwards A and Lloyd D (2007) Presenting statistical uncertainty on cytogenetic dose estimates. Radiat Protect Dos 123:443-449.). We decided to perform an identical analysis with the ANOVA and Tukey’s test, except that we used the 95% confidence limits from combined Poisson and calibration curve errors. However, we observed the same performances as those mentioned in the Results section. Nevertheless, the differences among calibration curves were less pronounced, because the uncertainties in dose estimations were numerically higher. Consequently, in the comparison analysis, there were smaller differences among estimated doses (results shown Tables S2-https://minio.scielo.br/documentstore/1678-4685/8dZ5Ckq8sy3TGYSWjxv8vXK/0b9d8589b4c82437abdcab0f0bf4096e9331ec46.pdf S4).

In some cases, the estimated doses were not statistically different, but they should have been, because there is a significant association between the productions of dicentrics and dose rate (IAEA, 2011IAEA - International Atomic Energy Agency (2011) Cytogenetic analysis for radiation dose assessment: a manual. International Atomic Energy Agency, Vienna.). Moreover, problems related to dose rate could also appear in intercomparison exercises. The propose of intercomparison exercises is to establish an operational network in biodosimetry for managing large numbers of potentially overexposed individuals, with mutual assistance, in cases of emergency (Oestreicher et al., 2017Oestreicher U, Samaga D, Ainsbury E, Antunes AC, Baeyens A, Barrios L, Beinke C, Beukes P, Blakely WF, Cucu A et al. (2017) RENEB intercomparisons applying the conventional Dicentric Chromosome Assay (DCA). Int J Radiat Biol 93:20-29.). Intercomparison exercises can be performed with distinct methods and statistical analyses. For example, biodosimetry labs might receive irradiated blood samples to set up lymphocyte cultures, according to their own standard protocols (Beinke et al., 2013Beinke C, Barnard S, Boulay-Greene H, De Amicis A, De Sanctis S, Herodin F, Jones A, Kulka U, Lista F, Lloyd D et al. (2013) Laboratory intercomparison of the dicentric chromosome analysis assay. Radiat Res 180:129-137.; Wilkins et al., 2015Wilkins RC, Beaton-Green LA, Lachapelle S, Kutzner BC, Ferrarotto C, Chauhan V, Marro1 L, Livingston GK, Greene HB and Flegal FN (2015) Evaluation of the annual Canadian biodosimetry network intercomparisons. Int J Radiat Biol 91:443-451.; Oestreicher et al., 2017Oestreicher U, Samaga D, Ainsbury E, Antunes AC, Baeyens A, Barrios L, Beinke C, Beukes P, Blakely WF, Cucu A et al. (2017) RENEB intercomparisons applying the conventional Dicentric Chromosome Assay (DCA). Int J Radiat Biol 93:20-29.), or they might receive slides (Ramalho et al., 1991Ramalho AT, Nascimento ACH, Littlefield LG, Natarajan AT and Sasaki MS (1991) Frequency of chromosomal aberrations in a subject accidentally exposed to 137Cs in the Goiania (Brazil) radiation accident: Intercomparison among four laboratories. Mutat Res/Environ Mutat Relat Subj 252: 157-160.; Roy et al., 2004Roy L, Buard V, Delbos M, Durand V, Paillole N, Grégoire E and Voisin P (2004) International intercomparison for criticality dosimetry: the case of biological dosimetry. Radiat Prot Dosimetry 110: 471-476.; Di Giorgio et al., 2011Di Giorgio M, Barquinero JF, Vallerga MB, Radl A, Taja MR, Seoane A, De Luca J, Oliveira MS, Valdivia P, Lima OG et al. (2011) Biological dosimetry intercomparison exercise: an evaluation of triage and routine mode results by robust methods. Radiat Res 175:38-649.; Liu et al., 2016Liu JX, Pan Y, Ruan JL, Piao C and Su X (2016) Intercomparison in cytogenetic dosimetry among 22 laboratories in China. Genome Integ 7:1-4.). The reported estimated doses per laboratory can be compared with the mean absolute difference (MAD), the z test, or an ANOVA (Di Giorgio et al., 2011Di Giorgio M, Barquinero JF, Vallerga MB, Radl A, Taja MR, Seoane A, De Luca J, Oliveira MS, Valdivia P, Lima OG et al. (2011) Biological dosimetry intercomparison exercise: an evaluation of triage and routine mode results by robust methods. Radiat Res 175:38-649.; Beinke et al., 2013Beinke C, Barnard S, Boulay-Greene H, De Amicis A, De Sanctis S, Herodin F, Jones A, Kulka U, Lista F, Lloyd D et al. (2013) Laboratory intercomparison of the dicentric chromosome analysis assay. Radiat Res 180:129-137.; Wilkins et al., 2015Wilkins RC, Beaton-Green LA, Lachapelle S, Kutzner BC, Ferrarotto C, Chauhan V, Marro1 L, Livingston GK, Greene HB and Flegal FN (2015) Evaluation of the annual Canadian biodosimetry network intercomparisons. Int J Radiat Biol 91:443-451.). For intercomparison exercises, labs that only receive slides have a greater advantage, because slide samples avoid the effects of blood preparation; consequently, this sort of intercomparison is only affected by dicentric scoring. The results from intercomparison studies have indicated that this sort of exercise produced less variation among laboratories (Roy et al., 2004Roy L, Buard V, Delbos M, Durand V, Paillole N, Grégoire E and Voisin P (2004) International intercomparison for criticality dosimetry: the case of biological dosimetry. Radiat Prot Dosimetry 110: 471-476.; Di Giorgio et al., 2011Di Giorgio M, Barquinero JF, Vallerga MB, Radl A, Taja MR, Seoane A, De Luca J, Oliveira MS, Valdivia P, Lima OG et al. (2011) Biological dosimetry intercomparison exercise: an evaluation of triage and routine mode results by robust methods. Radiat Res 175:38-649.; Liu et al., 2016Liu JX, Pan Y, Ruan JL, Piao C and Su X (2016) Intercomparison in cytogenetic dosimetry among 22 laboratories in China. Genome Integ 7:1-4.).

Even some labs reporting higher frequencies of aberrations when the data are converted into absorbed doses with reference to the laboratory’s own calibration curve the inter-laboratory difference is removed (Grégoire et al., 2013Grégoire E, Hadjidekova V, Hristova R, Hadjidekova V, Hritova R, Gruel G, Roch-Lefevre S, Voisin P, Staynova A, Deleva S et al. (2013) Biological dosimetry assessments of a serious radiation accident in Bulgaria in 2011. Radiat Protect Dos 155:418-422.). The RENEB intercomparisons (Oestreicher et al., 2017Oestreicher U, Samaga D, Ainsbury E, Antunes AC, Baeyens A, Barrios L, Beinke C, Beukes P, Blakely WF, Cucu A et al. (2017) RENEB intercomparisons applying the conventional Dicentric Chromosome Assay (DCA). Int J Radiat Biol 93:20-29.) caught our attention, because they included cases, where laboratories defined the frequency of dicentrics near to general dicentrics mean from other laboratories, but the estimated doses fell outside the recommended statistical criteria. The RENEB study was a global exercise that used dicentrics for dose assessments. A total of 42 laboratories from 31 countries all over the world participated. Blood samples were irradiated with ¹³⁷Cs gamma rays (dose rate 0.495 Gy/min), and each laboratory was asked to set up at least two lymphocyte cultures per sample, according to their own standard protocols, with consideration of the IAEA recommendations (IAEA, 2011IAEA - International Atomic Energy Agency (2011) Cytogenetic analysis for radiation dose assessment: a manual. International Atomic Energy Agency, Vienna.) and the International Organization for Standardization (ISO) standards (ISO 19238, 2014ISO - International Organization for Standardization 19238 (2014) Radiation protection-performance criteria for service laboratories performing biological dosimetry by cytogenetics. International Organization for Standardization, Geneva.; ISO 21243, 2008ISO - International Organization for Standardization 21243 (2008) Radiation protection – performance criteria for laboratories performing cytogenetic triage for assessment of mass casualties in radiological or nuclear emergencies – general principles and application to dicentric assay. International Organization for Standardization, Geneva.). As expected, all calibration curves had a specific shape, but some curves had low β coefficients (those from L10, N8, N9, and N14 labs). Those laboratories showed very good agreement between the number of dicentrics detected in slides of 50 cells/slide; the numbers fell within the theoretically expected range, even though they used different lymphocyte cultures and scoring criteria. However, their estimated doses were above the recommended range, for both simulated doses (0.85 Gy and 2.7 Gy). Consequently, these intercomparison results corroborated our results, which showed that curves with lower β coefficients generated higher than expected estimated doses. Thus, the results generated were outside the recommended means, independent of the type of test used (i.e., the z test in this intercomparison study and the ANOVA in our comparison study).

Another interesting point of this intercomparison exercise was that the percentage of correct dose estimations did not change (81–76%) for the low dose-point (0.85 Gy) comparing only eighteen laboratories involved in the RENEB with 42 labs. However, in the intercomparison exercise, the percentage of correct dose estimations for the high dose-point (2.7 Gy) increased from 39 to 61%, when all labs were included. This increase in correct dose estimations might be due to the higher number of curves compared or to an increase in uncertainties, rather than improvements in lab performances.

Conclusions

This comparative study reinforced the robustness of the dicentric assay and its importance in biological dosimetry. We also emphasized that the dose rate was an important factor in dose estimations. Thus, intercomparison exercises should take into account the dose rates of the participating laboratories, because the dose rates might explain why some results of estimated doses fall outside the recommendations.

Acknowledgments

Authors would like to acknowledge CNPq, CAPES and Centro Regional de Ciências Nucleares do Nordeste (CRCN-NE) for the financial support. We thank Dr. Cibele Gomes de Sotero-Caio and Suzy Hwang for helpful reviews of the manuscript.

Conflict of Interests

The authors report no conflicts of interest.

Author Contributions

MEM, JCGM, SH, MDG and FFL contributed to specific sections of the manuscript, NS conceived the study and revised the manuscript. All authors read and approved the submitted version of the manuscript.

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Supplementary material

The following online material is available for this article:

Table S1 P-values from Pearson’s Chi-squared test.

Table S2 Comparison of estimated absorbed doses by selected calibration curves using Dose Estimate software.

Table S3 Comparison results of estimated absorbed doses by ANOVA after jackknife-like resampling method.

Table S4 Results of Tukey’s test after compared all possible pairs of means.

Associate Editor: Daisy Salvadori

Publication Dates

Publication in this collection
17 Feb 2020
Date of issue
2020

History

Received
17 Feb 2018
Accepted
17 Dec 2019

License information: This is an open-access article distributed under the terms of the Creative Commons Attribution License (type CC-BY), which permits unrestricted use, distribution and reproduction in any medium, provided the original article is properly cited.

Distribution of dicentrics
Dose (Gy)	Cells scored	Dicentrics	0D	1D	2D	3D	4D	5D	Yield	σ²/y	U
0	4571	5	4566	5					0.001	0.999	-0.047
0.15	2029	10	2019	10					0.005	0.996	-0.149
0.25	1004	7	997	7					0.007	0.994	-0.145
0.5	1006	18	988	18					0.018	0.983	-0.39
0.75	1000	33	967	33					0.033	0.968	-0.727
1	1000	59	941	59					0.059	0.942	-1.31
1.5	1000	80	923	74	3				0.08	0.996	-0.09
2	490	93	406	75	9				0.190	1.010	0.091
3	223	100	135	76	12				0.448	0.795	-2.17
4	136	103	61	55	14	4	2		0.757	0.988	-0.101
5	80	112	19	30	19	6	4	2	1.4	1.06	0.377

References	Country	Volunteers Number	Colcemid time (h)	BrdU	Dose range (Gy)	Dose rate (Gy/min)	Dose rate/0.5 (Gy/min)	C	SE	α	± SE (Gy^-1)	β	± SE (Gy^-2)
*Bauchinger et al.* (1983)**Bauchinger M, Schmid E, Streng S and Dresp J (1983) Quantitative analysis of the chromosome damage at first division of human lymphocytes after 60Co γ -irradiation. Radiat Environ Biophys 22:225-229.	Germany	1 (M)	-	Yes	0.5 – 4	0.017	3%	0.0009	0.0009	0.0095	0.0064	0.0415	0.0035
*Schmid et al.* (2002)**Schmid E, Regulla D, Guldbakke S, Schlegel D and Roos M (2002) relative biological effectiveness of 144 keV neutros in producing dicentric chromosomes in human lymphocytes compared with 60Co gamma rays under heading-heat conditions. Radiat Res 157:453-460.	Germany	1 (W)	44	Yes	0.25 – 4	0.033	7%	0.0003	0.0002	0.0139	0.0052	0.0304	0.0030
This work	Brazil	1 (W)	46	No	0 – 5	0.055-0.048	11%	0.0014	0.0008	0.0074	0.0069	0.0449	0.0044
*Martins et al.* (2013)**Martins V, Antunes AC and Monteiro Gil O (2013) Implementation of a dose-response curve for γ-radiation in the Portuguese population by use of the chromosomal aberration assay. Mutat Res 750:50–54.	Portugal	16	47	No	0 – 3	0.18-0.13	36%	0.0011	0.0006	0.0098	0.0036	0.0489	0.0020
*Lindholm et al.* (1998)**Lindholm C, Luomahaara S, Koivistoinen A, Ilus T, Edwards AA and Salomaa S (1998) Comparison of dose-response curves for chromosomal aberrations established by chromosome painting and conventional analysis. Int J Radiat Biol 74:27-34.	England	2 (1M and 1W)	45.5	No	0 – 5	0.24	48%	0.0006	0.0003	0.0136	0.0045	0.0542	0.0035
*Top et al.* (2000)**Top A, Coskun M and Orta T (2000) Biological dosimetry of Co-60 gamma radiation. Turk J Haematol 17:189-196.	Turkey	3 (2M and 1W)	45	Yes	0 – 5	0.425	85%	0.0007	0.0008	0.0070	0.0067	0.0601	0.0034
*Köksal et al.* (1995)**Köksal G, Pala FS and Dalci DO (1995) In vitro dose-response curve for chromosome aberrations induced in human lymphocytes by 60Co γ -radiation. Mut Res 329:57-61.	Turkey	1 (W)	45	Yes	0.98 – 4.89	0.4573	91%	0.0005	0.0003	0.0216	0.0060	0.0706	0.0025
*Lloyd et al.* (1986)**Lloyd DC, Edwards AA and Prosser JS (1986) Chromosome abberations induced in human lymphocytes by in vitro acute X and gamma radiation. Radiat Prot Dosimetry 15:83-88.	England	a panel	45	Yes	0.05 – 5.05	0.5	100%	0.0004	0.0009	0.0145	0.0060	0.0760	0.0030

References	*Bauchinger et al.* (1983)**Bauchinger M, Schmid E, Streng S and Dresp J (1983) Quantitative analysis of the chromosome damage at first division of human lymphocytes after 60Co γ -irradiation. Radiat Environ Biophys 22:225-229.	*Schmid et al.* (2002)**Schmid E, Regulla D, Guldbakke S, Schlegel D and Roos M (2002) relative biological effectiveness of 144 keV neutros in producing dicentric chromosomes in human lymphocytes compared with 60Co gamma rays under heading-heat conditions. Radiat Res 157:453-460.	This work	*Martins et al.* (2013)**Martins V, Antunes AC and Monteiro Gil O (2013) Implementation of a dose-response curve for γ-radiation in the Portuguese population by use of the chromosomal aberration assay. Mutat Res 750:50–54.	*Lindholm et al.* (1998)**Lindholm C, Luomahaara S, Koivistoinen A, Ilus T, Edwards AA and Salomaa S (1998) Comparison of dose-response curves for chromosomal aberrations established by chromosome painting and conventional analysis. Int J Radiat Biol 74:27-34.	*Top et al.* (2000)**Top A, Coskun M and Orta T (2000) Biological dosimetry of Co-60 gamma radiation. Turk J Haematol 17:189-196.	*Köksal et al.* (1995)**Köksal G, Pala FS and Dalci DO (1995) In vitro dose-response curve for chromosome aberrations induced in human lymphocytes by 60Co γ -radiation. Mut Res 329:57-61.	*Lloyd et al.* (1986)**Lloyd DC, Edwards AA and Prosser JS (1986) Chromosome abberations induced in human lymphocytes by in vitro acute X and gamma radiation. Radiat Prot Dosimetry 15:83-88.
Country	Germany	Germany	Brazil	Portugal	England	Turkey	Turkey	England
Culture time (h)	48	47	48	48	48	48	48	48
Dose rate (Gy/min) / 0.5 Gy/min	3%	7%	11%	36%	48%	85%	91%	100%
Dicentric frequencies		Estimated doses ± 95% CL (Gy)
0.02a	0.574	0.608	0.566	0.530	0.486	0.511	0.394	0.421
	(0.420	(0.438	(0.415	(0.387	(0.354	(0.383	(0.282	(0.310
	0.743)	0.800)	0.732)	0.687)	0.633)	0.653)	0.521)	0.545)
0.15b	1.784	2.002	1.739	1.648	1.540	1.519	1.310	1.311
	(1.632	(1.825	(1.592	(1.507	(1.407	(1.392	(1.194	(1.199
	1.943)	2.186)	1.891)	1.794)	1.678)	1.651)	1.431)	1.428)
0.2c	2.079	2.345	2.022	1.919	1.797	1.764	1.535	1.528
	(1.927	(2.167	(1.876	(1.779	(1.664	(1.637	(1.419	(1.416
	2.236)	2.528)	2.174)	2.064)	1.934)	1.895)	1.655)	1.644)
0.7d	3.991	4.574	3.863	3.982	3.469	3.353	2.998	2.940
	(3.511	(4.013	(3.400	(3.238	(3.048	(2.954	(2.630	(2.585
	4.501)	5.169)	4.353)	4.151)	3.915)	3.777)	3.389)	3.316)
0.75e	4.136	4.743	4.002	3.815	3.595	3.473	3.109	3.047
	(3.655	(4.181	(3.539	(3.371	(3.174	(3.073	(2.740	(2.691
	4.644)	5.336)	4.491)	4.283)	4.040)	3.896)	3.498)	3.422)
1f	4.793	5.510	4.634	4.421	4.170	4.020	3.613	3.533
	(4.312	(4.949	(4.172	(3.977	(3.750	(3.620	(3.244	(3.177
	5.298)	6.100)	5.120)	4.886)	4.612)	4.439)	4.000)	3.906)

		Identification number of groups compared
		1	2	3	4	5	6	7	8	9	10	11	12
Dose rate (Gy/min) /0.5 Gy/min	3%	*Bauchinger et al.* (1983)**Bauchinger M, Schmid E, Streng S and Dresp J (1983) Quantitative analysis of the chromosome damage at first division of human lymphocytes after 60Co γ -irradiation. Radiat Environ Biophys 22:225-229.	*Bauchinger et al.* (1983)**Bauchinger M, Schmid E, Streng S and Dresp J (1983) Quantitative analysis of the chromosome damage at first division of human lymphocytes after 60Co γ -irradiation. Radiat Environ Biophys 22:225-229.						*Bauchinger et al.* (1983)**Bauchinger M, Schmid E, Streng S and Dresp J (1983) Quantitative analysis of the chromosome damage at first division of human lymphocytes after 60Co γ -irradiation. Radiat Environ Biophys 22:225-229.	*Bauchinger et al.* (1983)**Bauchinger M, Schmid E, Streng S and Dresp J (1983) Quantitative analysis of the chromosome damage at first division of human lymphocytes after 60Co γ -irradiation. Radiat Environ Biophys 22:225-229.	*Bauchinger et al.* (1983)**Bauchinger M, Schmid E, Streng S and Dresp J (1983) Quantitative analysis of the chromosome damage at first division of human lymphocytes after 60Co γ -irradiation. Radiat Environ Biophys 22:225-229.	*Bauchinger et al.* (1983)**Bauchinger M, Schmid E, Streng S and Dresp J (1983) Quantitative analysis of the chromosome damage at first division of human lymphocytes after 60Co γ -irradiation. Radiat Environ Biophys 22:225-229.	*Bauchinger et al.* (1983)**Bauchinger M, Schmid E, Streng S and Dresp J (1983) Quantitative analysis of the chromosome damage at first division of human lymphocytes after 60Co γ -irradiation. Radiat Environ Biophys 22:225-229.
	7%	*Schmid et al.* (2002)**Schmid E, Regulla D, Guldbakke S, Schlegel D and Roos M (2002) relative biological effectiveness of 144 keV neutros in producing dicentric chromosomes in human lymphocytes compared with 60Co gamma rays under heading-heat conditions. Radiat Res 157:453-460.											
	11%	This work	This work	This work					This work	This work	This work	This work	This work
	36%	*Martins et al.* (2013)**Martins V, Antunes AC and Monteiro Gil O (2013) Implementation of a dose-response curve for γ-radiation in the Portuguese population by use of the chromosomal aberration assay. Mutat Res 750:50–54.	*Martins et al.* (2013)**Martins V, Antunes AC and Monteiro Gil O (2013) Implementation of a dose-response curve for γ-radiation in the Portuguese population by use of the chromosomal aberration assay. Mutat Res 750:50–54.	*Martins et al.* (2013)**Martins V, Antunes AC and Monteiro Gil O (2013) Implementation of a dose-response curve for γ-radiation in the Portuguese population by use of the chromosomal aberration assay. Mutat Res 750:50–54.	*Martins et al.* (2013)**Martins V, Antunes AC and Monteiro Gil O (2013) Implementation of a dose-response curve for γ-radiation in the Portuguese population by use of the chromosomal aberration assay. Mutat Res 750:50–54.				*Martins et al.* (2013)**Martins V, Antunes AC and Monteiro Gil O (2013) Implementation of a dose-response curve for γ-radiation in the Portuguese population by use of the chromosomal aberration assay. Mutat Res 750:50–54.	*Martins et al.* (2013)**Martins V, Antunes AC and Monteiro Gil O (2013) Implementation of a dose-response curve for γ-radiation in the Portuguese population by use of the chromosomal aberration assay. Mutat Res 750:50–54.	*Martins et al.* (2013)**Martins V, Antunes AC and Monteiro Gil O (2013) Implementation of a dose-response curve for γ-radiation in the Portuguese population by use of the chromosomal aberration assay. Mutat Res 750:50–54.	*Martins et al.* (2013)**Martins V, Antunes AC and Monteiro Gil O (2013) Implementation of a dose-response curve for γ-radiation in the Portuguese population by use of the chromosomal aberration assay. Mutat Res 750:50–54.	
	48%	*Lindholm et al.* (1998)**Lindholm C, Luomahaara S, Koivistoinen A, Ilus T, Edwards AA and Salomaa S (1998) Comparison of dose-response curves for chromosomal aberrations established by chromosome painting and conventional analysis. Int J Radiat Biol 74:27-34.	*Lindholm et al.* (1998)**Lindholm C, Luomahaara S, Koivistoinen A, Ilus T, Edwards AA and Salomaa S (1998) Comparison of dose-response curves for chromosomal aberrations established by chromosome painting and conventional analysis. Int J Radiat Biol 74:27-34.	*Lindholm et al.* (1998)**Lindholm C, Luomahaara S, Koivistoinen A, Ilus T, Edwards AA and Salomaa S (1998) Comparison of dose-response curves for chromosomal aberrations established by chromosome painting and conventional analysis. Int J Radiat Biol 74:27-34.	*Lindholm et al.* (1998)**Lindholm C, Luomahaara S, Koivistoinen A, Ilus T, Edwards AA and Salomaa S (1998) Comparison of dose-response curves for chromosomal aberrations established by chromosome painting and conventional analysis. Int J Radiat Biol 74:27-34.	*Lindholm et al.* (1998)**Lindholm C, Luomahaara S, Koivistoinen A, Ilus T, Edwards AA and Salomaa S (1998) Comparison of dose-response curves for chromosomal aberrations established by chromosome painting and conventional analysis. Int J Radiat Biol 74:27-34.			*Lindholm et al.* (1998)**Lindholm C, Luomahaara S, Koivistoinen A, Ilus T, Edwards AA and Salomaa S (1998) Comparison of dose-response curves for chromosomal aberrations established by chromosome painting and conventional analysis. Int J Radiat Biol 74:27-34.	*Lindholm et al.* (1998)**Lindholm C, Luomahaara S, Koivistoinen A, Ilus T, Edwards AA and Salomaa S (1998) Comparison of dose-response curves for chromosomal aberrations established by chromosome painting and conventional analysis. Int J Radiat Biol 74:27-34.	*Lindholm et al.* (1998)**Lindholm C, Luomahaara S, Koivistoinen A, Ilus T, Edwards AA and Salomaa S (1998) Comparison of dose-response curves for chromosomal aberrations established by chromosome painting and conventional analysis. Int J Radiat Biol 74:27-34.		
	85%	*Top et al.* (2000)**Top A, Coskun M and Orta T (2000) Biological dosimetry of Co-60 gamma radiation. Turk J Haematol 17:189-196.	*Top et al.* (2000)**Top A, Coskun M and Orta T (2000) Biological dosimetry of Co-60 gamma radiation. Turk J Haematol 17:189-196.	*Top et al.* (2000)**Top A, Coskun M and Orta T (2000) Biological dosimetry of Co-60 gamma radiation. Turk J Haematol 17:189-196.	*Top et al.* (2000)**Top A, Coskun M and Orta T (2000) Biological dosimetry of Co-60 gamma radiation. Turk J Haematol 17:189-196.	*Top et al.* (2000)**Top A, Coskun M and Orta T (2000) Biological dosimetry of Co-60 gamma radiation. Turk J Haematol 17:189-196.	*Top et al.* (2000)**Top A, Coskun M and Orta T (2000) Biological dosimetry of Co-60 gamma radiation. Turk J Haematol 17:189-196.		*Top et al.* (2000)**Top A, Coskun M and Orta T (2000) Biological dosimetry of Co-60 gamma radiation. Turk J Haematol 17:189-196.	*Top et al.* (2000)**Top A, Coskun M and Orta T (2000) Biological dosimetry of Co-60 gamma radiation. Turk J Haematol 17:189-196.			
	91%	*Köksal et al.* (1995)**Köksal G, Pala FS and Dalci DO (1995) In vitro dose-response curve for chromosome aberrations induced in human lymphocytes by 60Co γ -radiation. Mut Res 329:57-61.	*Köksal et al.* (1995)**Köksal G, Pala FS and Dalci DO (1995) In vitro dose-response curve for chromosome aberrations induced in human lymphocytes by 60Co γ -radiation. Mut Res 329:57-61.	*Köksal et al.* (1995)**Köksal G, Pala FS and Dalci DO (1995) In vitro dose-response curve for chromosome aberrations induced in human lymphocytes by 60Co γ -radiation. Mut Res 329:57-61.	*Köksal et al.* (1995)**Köksal G, Pala FS and Dalci DO (1995) In vitro dose-response curve for chromosome aberrations induced in human lymphocytes by 60Co γ -radiation. Mut Res 329:57-61.	*Köksal et al.* (1995)**Köksal G, Pala FS and Dalci DO (1995) In vitro dose-response curve for chromosome aberrations induced in human lymphocytes by 60Co γ -radiation. Mut Res 329:57-61.	*Köksal et al.* (1995)**Köksal G, Pala FS and Dalci DO (1995) In vitro dose-response curve for chromosome aberrations induced in human lymphocytes by 60Co γ -radiation. Mut Res 329:57-61.	*Köksal et al.* (1995)**Köksal G, Pala FS and Dalci DO (1995) In vitro dose-response curve for chromosome aberrations induced in human lymphocytes by 60Co γ -radiation. Mut Res 329:57-61.	*Köksal et al.* (1995)**Köksal G, Pala FS and Dalci DO (1995) In vitro dose-response curve for chromosome aberrations induced in human lymphocytes by 60Co γ -radiation. Mut Res 329:57-61.				
	100%	*Lloyd et al.* (1986)**Lloyd DC, Edwards AA and Prosser JS (1986) Chromosome abberations induced in human lymphocytes by in vitro acute X and gamma radiation. Radiat Prot Dosimetry 15:83-88.	*Lloyd et al.* (1986)**Lloyd DC, Edwards AA and Prosser JS (1986) Chromosome abberations induced in human lymphocytes by in vitro acute X and gamma radiation. Radiat Prot Dosimetry 15:83-88.	*Lloyd et al.* (1986)**Lloyd DC, Edwards AA and Prosser JS (1986) Chromosome abberations induced in human lymphocytes by in vitro acute X and gamma radiation. Radiat Prot Dosimetry 15:83-88.	*Lloyd et al.* (1986)**Lloyd DC, Edwards AA and Prosser JS (1986) Chromosome abberations induced in human lymphocytes by in vitro acute X and gamma radiation. Radiat Prot Dosimetry 15:83-88.	*Lloyd et al.* (1986)**Lloyd DC, Edwards AA and Prosser JS (1986) Chromosome abberations induced in human lymphocytes by in vitro acute X and gamma radiation. Radiat Prot Dosimetry 15:83-88.	*Lloyd et al.* (1986)**Lloyd DC, Edwards AA and Prosser JS (1986) Chromosome abberations induced in human lymphocytes by in vitro acute X and gamma radiation. Radiat Prot Dosimetry 15:83-88.	*Lloyd et al.* (1986)**Lloyd DC, Edwards AA and Prosser JS (1986) Chromosome abberations induced in human lymphocytes by in vitro acute X and gamma radiation. Radiat Prot Dosimetry 15:83-88.					
Frequencies of dicentrics	p-values by ANOVA
	0.02	0.606	0.643	0.642	0.683	0.665	0.522	0.799	0.688	0.941	0.888	0.935	0.954
	0.15	<0.001^* *()** p-value < 0.05 means that the estimated doses are not statistically similar.	0.003^* *()** p-value < 0.05 means that the estimated doses are not statistically similar.	0.009^* *()** p-value < 0.05 means that the estimated doses are not statistically similar.	0.033^* *()** p-value < 0.05 means that the estimated doses are not statistically similar.	0.090	0.127	0.992	0.014^* *()** p-value < 0.05 means that the estimated doses are not statistically similar.	0.167	0.256	0.556	0.732
	0.2	<0.001^* *()** p-value < 0.05 means that the estimated doses are not statistically similar.	<0.001^* *()** p-value < 0.05 means that the estimated doses are not statistically similar.	0.003^* *()** p-value < 0.05 means that the estimated doses are not statistically similar.	0.014^* *()** p-value < 0.05 means that the estimated doses are not statistically similar.	0.050	0.089	0.945	0.005^* *()** p-value < 0.05 means that the estimated doses are not statistically similar.	0.086	0.167	0.458	0.671
	0.7	0.008^* *()** p-value < 0.05 means that the estimated doses are not statistically similar.	0.058	0.096	0.157	0.343	0.418	0.856	0.14	0.438	0.597	0.869	0.761
	0.75	0.005^* *()** p-value < 0.05 means that the estimated doses are not statistically similar.	0.051	0.096	0.187	0.318	0.399	0.848	0.127	0.408	0.544	0.72	0.752
	1	0.001^* *()** p-value < 0.05 means that the estimated doses are not statistically similar.	0.019^* *()** p-value < 0.05 means that the estimated doses are not statistically similar.	0.05	0.106	0.220	0.320	0.804	0.062	0.277	0.433	0.648	0.708

Tukey multiple comparisons of means		*Bauchinger et al.* (1983)Bauchinger M, Schmid E, Streng S and Dresp J (1983) Quantitative analysis of the chromosome damage at first division of human lymphocytes after 60Co γ -irradiation. Radiat Environ Biophys 22:225-229. versus Köksal et al. (1995)**Köksal G, Pala FS and Dalci DO (1995) In vitro dose-response curve for chromosome aberrations induced in human lymphocytes by 60Co γ -radiation. Mut Res 329:57-61.	*Bauchinger et al.* (1983)Bauchinger M, Schmid E, Streng S and Dresp J (1983) Quantitative analysis of the chromosome damage at first division of human lymphocytes after 60Co γ -irradiation. Radiat Environ Biophys 22:225-229. versus Lloyd et al. (1986)**Lloyd DC, Edwards AA and Prosser JS (1986) Chromosome abberations induced in human lymphocytes by in vitro acute X and gamma radiation. Radiat Prot Dosimetry 15:83-88.	*Schmid et al.* (2002)Schmid E, Regulla D, Guldbakke S, Schlegel D and Roos M (2002) relative biological effectiveness of 144 keV neutros in producing dicentric chromosomes in human lymphocytes compared with 60Co gamma rays under heading-heat conditions. Radiat Res 157:453-460. versus Martins et al. (2013)**Martins V, Antunes AC and Monteiro Gil O (2013) Implementation of a dose-response curve for γ-radiation in the Portuguese population by use of the chromosomal aberration assay. Mutat Res 750:50–54.	*Schmid et al.* (2002)Schmid E, Regulla D, Guldbakke S, Schlegel D and Roos M (2002) relative biological effectiveness of 144 keV neutros in producing dicentric chromosomes in human lymphocytes compared with 60Co gamma rays under heading-heat conditions. Radiat Res 157:453-460. versus Lindholm et al. (1998)**Lindholm C, Luomahaara S, Koivistoinen A, Ilus T, Edwards AA and Salomaa S (1998) Comparison of dose-response curves for chromosomal aberrations established by chromosome painting and conventional analysis. Int J Radiat Biol 74:27-34.	*Schmid et al. (2002)Schmid E, Regulla D, Guldbakke S, Schlegel D and Roos M (2002) relative biological effectiveness of 144 keV neutros in producing dicentric chromosomes in human lymphocytes compared with 60Co gamma rays under heading-heat conditions. Radiat Res 157:453-460. versus Top et al.* (2000)**Top A, Coskun M and Orta T (2000) Biological dosimetry of Co-60 gamma radiation. Turk J Haematol 17:189-196.	*Schmid et al.* (2002)Schmid E, Regulla D, Guldbakke S, Schlegel D and Roos M (2002) relative biological effectiveness of 144 keV neutros in producing dicentric chromosomes in human lymphocytes compared with 60Co gamma rays under heading-heat conditions. Radiat Res 157:453-460. versus Köksal et al. (1995)**Köksal G, Pala FS and Dalci DO (1995) In vitro dose-response curve for chromosome aberrations induced in human lymphocytes by 60Co γ -radiation. Mut Res 329:57-61.	*Schmid et al.* (2002)Schmid E, Regulla D, Guldbakke S, Schlegel D and Roos M (2002) relative biological effectiveness of 144 keV neutros in producing dicentric chromosomes in human lymphocytes compared with 60Co gamma rays under heading-heat conditions. Radiat Res 157:453-460. versus Lloyd et al. (1986)**Lloyd DC, Edwards AA and Prosser JS (1986) Chromosome abberations induced in human lymphocytes by in vitro acute X and gamma radiation. Radiat Prot Dosimetry 15:83-88.	This work versus *Köksal et al.* (1995)**Köksal G, Pala FS and Dalci DO (1995) In vitro dose-response curve for chromosome aberrations induced in human lymphocytes by 60Co γ -radiation. Mut Res 329:57-61.	This work versus *Lloyd et al.* (1986)**Lloyd DC, Edwards AA and Prosser JS (1986) Chromosome abberations induced in human lymphocytes by in vitro acute X and gamma radiation. Radiat Prot Dosimetry 15:83-88.	*Martins et al.* (2013)Martins V, Antunes AC and Monteiro Gil O (2013) Implementation of a dose-response curve for γ-radiation in the Portuguese population by use of the chromosomal aberration assay. Mutat Res 750:50–54. versus Köksal et al. (1995)**Köksal G, Pala FS and Dalci DO (1995) In vitro dose-response curve for chromosome aberrations induced in human lymphocytes by 60Co γ -radiation. Mut Res 329:57-61.	*Martins et al.* (2013)Martins V, Antunes AC and Monteiro Gil O (2013) Implementation of a dose-response curve for γ-radiation in the Portuguese population by use of the chromosomal aberration assay. Mutat Res 750:50–54. versus Lloyd et al. (1986)**Lloyd DC, Edwards AA and Prosser JS (1986) Chromosome abberations induced in human lymphocytes by in vitro acute X and gamma radiation. Radiat Prot Dosimetry 15:83-88.
Dose rate (Gy/min)/0.5 Gy/min		3% - 91%	3% - 100%	7% - 36%	7% - 48%	7% - 85%	7% - 91%	7% - 100%	11% - 91%	11% - 100%	36% - 91%	36% - 100%
Frequencies of dicentrics	Identification number of groups compared	p-values by Tukey’s test
0.15	1	0.015	0.015		0.019	0.013	0.0004	0.0004	0.032	0.033		
	2	0.011	0.011						0.022	0.022		
	3								0.018	0.018		
	4										0.056	0.057
	8	0.013							0.025			
0.20	1	0.005	0.004	0.033	0.004	0.002	0.00007	0.00006	0.012	0.011		0.058
	2	0.003	0.003						0.008	0.007	0.045	0.040
	3								0.007	0.006	0.035	0.031
	4										0.028	0.025
	8	0.004							0.010		0.047	
0.70	1						0.012	0.008				
0.75	1					0.053	0.008	0.006				
1	1		0.054		0.036	0.016	0.002	0.001				
	2	0.056	0.037									

Sociedade Brasileira de Genética Rua Cap. Adelmio Norberto da Silva, 736, 14025-670 Ribeirão Preto SP Brazil, Tel.: (55 16) 3911-4130 / Fax.: (55 16) 3621-3552 - Ribeirão Preto - SP - Brazil
E-mail: editor@gmb.org.br

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Calibration curves by 60Co with low dose rate are different in terms of dose estimation – a comparative study

Abstract

Introduction

Materials and Methods

Construction of calibration curve

Selected calibration curves

Comparison of Calibration Curves

Results

Discussion

Conclusions

Acknowledgments

Conflict of Interests

Author Contributions

References

Supplementary material

Publication Dates

History

Calibration curves by ⁶⁰Co with low dose rate are different in terms of dose estimation – a comparative study