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Three principal techniques were deployed: internal dosimetry<\/strong> through bioassay and whole body monitoring, cytogenetic dosimetry<\/strong> via chromosomal aberration analysis, and external dosimetry<\/strong> based on scenario reconstruction and observed biological effects. Each approach faced significant practical constraints \u2014 from laboratories designed for low-activity routine samples suddenly handling intensely radioactive specimens, to the difficulty of disentangling external irradiation from the continuous dose delivered by internally deposited caesium-137.<\/p>\n Potential internal contamination pathways included inhalation, ingestion, and wound absorption. Air monitoring data subsequently confirmed that inhalation was not a major route. The immediate action focused on estimating caesium-137 intakes by monitoring urine and faecal samples.<\/p>\n The sheer intensity of the contamination created operational hurdles. At the prevailing radioactivity levels, samples had to be collected with extreme care to prevent cross-contamination. Specimens were gathered in Goi\u00e2nia and flown to the IRD<\/strong> (Institute for Radiation Protection and Dosimetry) laboratory in Rio de Janeiro. Many initial samples were so radioactive that a portable dose rate meter yielded high readings \u2014 this simple screening method served both for hospital patient triage and for flagging samples requiring special handling.<\/p>\n Caesium-137 standards were prepared specifically for urine and faecal bioassay. An unexpected need arose when internally contaminated babies were identified: a phantom for disposable nappies had to be developed \u2014 something unprecedented in the radiological protection literature.<\/p>\n In early November 1987, a whole body counter<\/strong> specifically designed for measuring the high dose rates of Goi\u00e2nia patients was installed at the Goi\u00e2nia General Hospital. Internally contaminated individuals were periodically monitored, at a frequency dependent on each person’s caesium intake and decontamination treatment. Three patients from the Marc\u00edlio Dias Naval Hospital in Rio de Janeiro were measured at IRD’s whole body monitoring facility before returning to Goi\u00e2nia, and the results were consistent with those obtained at the improvised Goi\u00e2nia facility.<\/p>\n Because people of a broad age range had been contaminated \u2014 from newborns to adults \u2014 the team adopted age-specific modeling to provide physicians with clinically relevant data: caesium intakes, excretion rates, and committed dose profiles over various time periods.<\/p>\n The model was based on reports from Oak Ridge National Laboratory<\/strong> (ORNL-TM-8265 and ORNL-TM-8385). Models were produced for six biotypes: newborn, one-year-old, five-year-old, ten-year-old, 15-year-old, and adult. The table below shows the variation in the 70-year committed dose from a single uptake of caesium-137, without Prussian Blue administration.<\/p>\n These values illustrate how physiology at each life stage affects retention and the resulting dose.<\/p>\nIn This Article<\/h2>\n
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Internal Dosimetry: Bioassay and Whole Body Counting<\/h2>\n
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Age-Specific Modeling and Committed Dose<\/h2>\n
70-Year Committed Dose per Unit Uptake of Cs-137<\/h3>\n