Your search keyword '"Di Giorgio M"' showing total 3 results

1. The Internet's role in a biodosimetric response to a radiation mass casualty event.

Author

Sugarman SL, Livingston GK, Stricklin DL, Abbott MG, Wilkins RC, Romm H, Oestreicher U, Yoshida MA, Miura T, Moquet JE, Di Giorgio M, Ferrarotto C, Gross GA, Christiansen ME, Hart CL, and Christensen DM

Subjects

Cells, Cultured, Chromosomes, Human genetics, Cobalt Radioisotopes adverse effects, Dose-Response Relationship, Radiation, Humans, Image Processing, Computer-Assisted, Lymphocytes radiation effects, Metaphase radiation effects, Radiation Injuries genetics, Radiation Injuries prevention & control, Radioactive Hazard Release prevention & control, Radiometry, Biological Assay methods, Chromosome Aberrations radiation effects, Chromosomes, Human radiation effects, Internet statistics & numerical data, Laboratories standards, Mass Casualty Incidents prevention & control, Radiation Injuries diagnosis

Abstract

Response to a large-scale radiological incident could require timely medical interventions to minimize radiation casualties. Proper medical care requires knowing the victim's radiation dose. When physical dosimetry is absent, radiation-specific chromosome aberration analysis can serve to estimate the absorbed dose in order to assist physicians in the medical management of radiation injuries. A mock exercise scenario was presented to six participating biodosimetry laboratories as one individual acutely exposed to Co under conditions suggesting whole-body exposure. The individual was not wearing a dosimeter and within 2-3 h of the incident began vomiting. The individual also had other medical symptoms indicating likelihood of a significant dose. Physicians managing the patient requested a dose estimate in order to develop a treatment plan. Participating laboratories in North and South America, Europe, and Asia were asked to evaluate more than 800 electronic images of metaphase cells from the patient to determine the dicentric yield and calculate a dose estimate with 95% confidence limits. All participants were blind to the physical dose until after submitting their estimates based on the dicentric chromosome assay (DCA). The exercise was successful since the mean biological dose estimate was 1.89 Gy whereas the actual physical dose was 2 Gy. This is well within the requirements for guidance of medical management. The exercise demonstrated that the most labor-intensive step in the entire process (visual evaluation of images) can be accelerated by taking advantage of world-wide expertise available on the Internet.

Published

2014

2. Interlaboratory comparison of dicentric chromosome assay using electronically transmitted images.

Author

García O, Di Giorgio M, Vallerga MB, Radl A, Taja MR, Seoane A, De Luca J, Stuck Oliveira M, Valdivia P, Lamadrid AI, González JE, Romero I, Mandina T, Pantelias G, Terzoudi G, Guerrero-Carbajal C, Arceo Maldonado C, Espinoza M, Oliveros N, Martínez-López W, Di Tomaso MV, Méndez-Acuña L, Puig R, Roy L, and Barquinero JF

Subjects

Biological Assay, Dose-Response Relationship, Radiation, Humans, Radiometry, Chromosome Aberrations radiation effects, Chromosomes, Human radiation effects, Gamma Rays adverse effects, Laboratories standards, Lymphocytes radiation effects

Abstract

The bottleneck in data acquisition during biological dosimetry based on a dicentric assay is the need to score dicentrics in a large number of lymphocytes. One way to increase the capacity of a given laboratory is to use the ability of skilled operators from other laboratories. This can be done using image analysis systems and distributing images all around the world. Two exercises were conducted to test the efficiency of such an approach involving 10 laboratories. During the first exercise (E1), the participant laboratories analysed the same images derived from cells exposed to 0.5 and 3 Gy; 100 images were sent to all participants for both doses. Whatever the dose, only about half of the cells were complete with well-spread metaphases suitable for analysis. A coefficient of variation (CV) on the standard deviation of ∼15 % was obtained for both doses. The trueness was better for 3 Gy (0.6 %) than for 0.5 Gy (37.8 %). The number of estimated doses classified as satisfactory according to the z-score was 3 at 0.5 Gy and 8 at 3 Gy for 10 dose estimations. In the second exercise, an emergency situation was tested, each laboratory was required to score a different set of 50 images in 2 d extracted from 500 downloaded images derived from cells exposed to 0.5 Gy. Then the remaining 450 images had to be scored within a week. Using 50 different images, the CV on the estimated doses (79.2 %) was not as good as in E1, probably associated to a lower number of cells analysed (50 vs. 100) or from the fact that laboratories analysed a different set of images. The trueness for the dose was better after scoring 500 cells (22.5 %) than after 50 cells (26.8 %). For the 10 dose estimations, the number of doses classified as satisfactory according to the z-score was 9, for both 50 and 500 cells. Overall, the results obtained support the feasibility of networking using electronically transmitted images. However, before its implementation some issues should be elucidated, such as the number and resolution of the images to be sent, and the harmonisation of the scoring criteria. Additionally, a global website able to be used for the different regional networks, like Share Points, will be desirable to facilitate worldwide communication.

Published

2013

3. Intercomparison in cytogenetic dosimetry among five laboratories from Latin America.

Author

Garcia OF, Ramalho AT, Di Giorgio M, Mir SS, Espinoza ME, Manzano J, Nasazzi N, and López I

Subjects

Adult, Algorithms, Calibration, Chromosome Aberrations, Chromosomes, Human radiation effects, Chromosomes, Human ultrastructure, Cobalt Radioisotopes, Dose-Response Relationship, Radiation, Gamma Rays, Humans, International Agencies, Latin America, Lymphocytes radiation effects, Lymphocytes ultrastructure, Male, Metaphase, Micronucleus Tests standards, Observer Variation, Reproducibility of Results, Cytogenetics, Laboratories, Mutagenicity Tests standards, Radiation Dosage

Abstract

As part of a regional International Atomic Energy Agency (IAEA) collaborative project within Latin America, five countries participated in an intercomparison in cytogenetic dosimetry. Coded slides for chromosomal aberrations and micronucleus analyses were prepared by the coordinator laboratory which organized the exercise and sent to the other participating laboratories. For estimates of dose, each laboratory scored the frequency of dicentrics in metaphases and the frequency of micronuclei in binucleated cells. The lymphocytes were irradiated with 60Co gamma-rays (0, 0.75, 1.5 and 3.0 Gy). Eleven of the 15 estimates of dose based on dicentrics and nine of the 12 based on micronuclei fell within +/- 30% of the true dose. When considering the uncertainties of the dose estimates, the true dose fell within the 95% confidence limits of the estimates on eight of the 15 occasions for dicentrics and four of the 12 for micronuclei.

Published

1995