Introduction
Due to increased utilization of radioactive materials and nuclear technologies in various fields, radiation accidents may be expected to occur at an unanticipated rate. In radiation emergencies, it is important to conduct a rapid dose estimation to apply the effective medical management. Biological dosimetry plays a valuable role by contributing in the early period after radiation emergencies. Thailand has experienced a serious radiological accident in Samut Prakan in 2000 when a disused 60Co teletherapy head was partially dismantled, taken from an unsecured storage location and sold as scrap metal. That accident resulted in ten people receiving high radiation doses and three of those people died within 2 months of the accident as a consequence of their overexposure.[1] From the International Atomic Energy Agency's investigation of the accident, it was reported that there was apparently no adequate biological dosimetry to assess the probable range of the radiation doses received by the individuals involved.
Furthermore, at least five of the ten Southeast Asian countries, Indonesia, Malaysia, Philippines, Vietnam, and Thailand, are moving ahead with acquiring nuclear power plants. The time frame for the start of operation of the nuclear power plants extends from 2020. Therefore, radiation emergency preparedness including biological dosimetry concept has become a priority to establish support in the event of mass radiation casualties and to strengthen national and international radiation protection programs. The conventional cytogenetic assay using chromosome aberrations, such as dicentrics, fragments, and ring chromosomes, in an exposed cell can be regularly used for biological dosimetry. Dicentric chromosome assay (DCA) is an accepted method for whole-body individual dose assessment of <6 Gy whereas premature chromosome condensation (PCC) assay is appropriate in the high-dose range (>6 Gy).[2] The PCC assay can also discriminate between whole- and partial-body exposures at low doses.[3] The estimated dose can be derived from the constructed in vitro dose-response curves. Because of interlaboratory technical differences, laboratories performing biodosimetry should construct their own dose-response curves.[4] This study aimed to generate dose-response curves for dicentrics and PCC rings to cover low- and high-dose exposures to support radiation emergency preparedness in Thailand. The dose-estimation accuracy of those calibration curves was tested by performing an in vitro irradiation and blind scoring.
Materials and Methods
Blood collection and irradiation
The study was conducted in accordance with the guidelines prescribed by our Institutional Review Board. Volunteers were recruited from the faculty by informing the objectives and the experimental details of the study. The personal data including gender, age, alcohol and tea/coffee consumption, chronic disease, use of therapeutic drugs, and previous exposure to diagnostic X-ray were recorded in the questionnaire. Finally, three healthy nonsmoking volunteers were chosen as blood donors in the study. Written informed consent was obtained from each volunteer before the experiment. Blood samples from two donors were used for construction of dose-response curves and those from one donor were used for validation of curves.
Peripheral blood was irradiated with 137Cs gamma rays (Gammacell 40 Exactor, MDS Nordion, Canada) at a constant dose-rate of 0.652 Gy/min with doses of 0.1, 0.25, 0.5, 0.75, 1, 2, 3, 4, and 5 Gy for DCA, and 5, 10, 15, 20, and 25 Gy for PCC technique. The blood samples were further incubated for 2 h at 37°C to allow for repair of DNA damage.
Lymphocyte culturing and slide preparation
Whole blood cultures were set up using a standard protocol,[4] in RPMI 1640 medium supplemented with 20% fetal bovine serum and phytohemagglutinin and incubated at 37°C for 48 h. For DCA technique, colcemid was added to the culture at starting.[5] For PCC assay, calyculin A (50 nM) was added to the medium at the last 30 min before harvesting.[6] The cells were harvested with hypotonic treatment (0.075 M KCl) then fixed with Carnoy's fixative (methanol: glacial acetic acid, 3:1, v/v), dropped on a precleaned glass slide, air dried, and stained with 5% Giemsa solution in phosphate buffer.
Scoring
Chromosome aberrations were scored according to the criteria previously described in the literature.[4] A minimum of 100 dicentrics or 1000 cells were analyzed for DCA. A minimum of 80–100 PCC rings with a visible hole with or without centromere in G2/M-PCC cells were analyzed. Analysis of slides was carried out using an automated metaphase finding system (Carl Zeiss Axio Imager and Metafer supplied by MetaSystems, Germany).
Statistical analysis
The dose-response curves for DCA and PCC rings were fitted to linear quadratic equations using Chromosome Aberration Calculation Software (CABAS, version 2.0) (Institute of Nuclear Chemistry and Technology, Warsaw, Poland). The goodness of fit and homogeneity were determined using this software.
Results and Discussion
Dicentric chromosome analysis
Dicentrics were observed in metaphase chromosome in blood samples exposed to 0.1 to 5 Gy. For the analysis, only complete metaphases with 46 chromosomes were recorded. If the cell contained unstable aberrations, then it should be balanced. For example, a metaphase containing a dicentric should also have an acentric fragment, yet still count to 46 pieces. By contrast, a centric ring will also have an accompanying fragment, but the total number of objects in the cell will count to 47.[4] Metaphase chromosomes in control and exposed samples are shown in Figure 1. It is envisaged that tricentric aberrations are equivalent to two dicentrics and have two accompanying fragments, while tetracentrics will have three fragments.
The frequency and distribution of polycentric aberrations are shown in Table 1. The background level for dicentrics is very low as no dicentric was found in the 1000 cells analyzed. This implied that the larger number of scored metaphases is needed to see the dicentric yield and it accordingly requires a significantly longer period. From Table 1, it was shown that tricentrics were found at doses above 2.0 Gy whereas tetracentrics were found only in the dose of 5.0 Gy.
The dose-response curve was fitted by means of the CABAS, version 2.0, as illustrated in Figure 2. The dicentric yield has been shown to best fit to a linear-quadratic model as the following equation: Y = aD2 + bD + c, where Y is the yield of dicentric frequency, D is absorbed dose in Gy, a is the corresponding quadratic coefficient = 0.0758 ± 0.0050, b is the linear coefficient = 0.0190 ± 0.0067, and c is the background frequency = 0 ± <0.0001.
This finding is in good agreement with the earlier reports.[78] Based on the resulting coefficients, the dose estimation was done by computing the number of aberrations observed and cells scored. When the given dose was 1.5 Gy, the dose calculated from CABAS was 1.31 Gy ranging from 1.17 to 1.46 Gy with 95% confidence limits.
Premature chromosome condensation analysis
The application of calyculin A-induced PCC rings has been widely used for dose estimation due to its advantage over conventional metaphase analysis for high-dose exposure that results in mitotic delay and disappearance of lymphocytes from peripheral blood circulation.[9] Calyculin A induces chromosome condensation in lymphocytes by specifically inhibiting protein phosphatases Type 1 and Type 2A (serine/threonine) in all phases of the cell cycle. The PCC morphology varies based on the stage of interphase in which the cells are present, namely, G1, S, and G2-PCC.[10] In our experiment, PCC rings were observed in the G2/M phase. To generate a calibration curve for PCC rings, a total of 500 cells or a minimal of 80–100 PCC rings per dose were scored.
Figure 3 shows an image of PCC rings in a sample exposed to 15 Gy. The G2/M-PCC rings were clearly observed because the elongated chromosomes enable easier visualization. The PCC ring frequency increased with the dose from 0 at 0 Gy to 1.15 at 15 Gy, and then slightly increased and saturated with the dose above 15 Gy as given in Table 2. This due to the mitotic delay was induced at the high doses from 15 to 25 Gy. These results are in good agreement with those reported in other studies.[9] The frequency of PCC rings with the doses from 0 to 15 Gy was fitted to a linear quadratic equation [Figure 4], where the corresponding quadratic coefficient: a = 0.0036 ± 0.0008, the linear coefficient: b = 0.0214 ± 0.0070, and the background frequency: c = 0 ± <0.0001. When the given dose was 7.5 Gy, the dose estimated from dose-response curve was 7.9 with its 95% confidence limit. The dose estimated ranged from 6.9 to 8.9 Gy.
Conclusion
The dose-response curves of dicentrics and PCC rings for 137Cs gamma radiation were established for the first time in our laboratory. These curves should be further developed and validated to be used for in vitro dose reconstruction in medical management in cases of radiological emergency in the country. The scoring of dicentrics and PCC rings is time consuming and highly expertise-dependent, and we lack experienced personal; therefore, the next step is to establish an in-house quality assurance program such as proficiency test of personnel qualifications, procedure manual, instrumentation, calibration, data reduction, record system, and data reporting as required to ensure the quality of a biological dosimetry laboratory's output.[4] Moreover, the International Organization for Standardization 19238 which provides standard criteria for service laboratories performing biological dosimetry by cytogenetics[11] should be adopted in the future.