Biochemical indicators of whole-body gamma-radiation effects in the pig.

PURPOSE: Validation of the pig as an experimental animal model for dose assessment after ionizing irradiation. MATERIALS AND METHODS: The evolution of haematological and biochemical parameters was followed for up to 7 days after irradiation in pigs exposed to whole-body 60Co gamma-radiation at doses between O and 6 Gy. RESULTS: Some biochemical indicators showed significant variations: amylase, LDH, alkaline and acid phosphatases, ALT and iron. None of the studied parameters alone presents a reliable dose-effect relationship; however, there was evidence that the combination of lymphocyte and neutrophil counts and the determination of LDH, ALT, AST and urea levels allowed some dose determination, independent of time, if blood samples were taken within 7 days post-irradiation. CONCLUSION: The results confirm the main problems of biochemical dosimetry. However, the pig model could represent a useful alternative to the non-human primate in radiobiology research, especially in the case of partial-body exposure. A multiparametric approach to dose assessment seems to be possible in the pig model. Confirmation should be carried out using blood samples from patients undergoing radiotherapy treatment.

Role of alveolar macrophage lysosomes in metal detoxification.

The intracellular behaviour of different toxic mineral elements inhaled as soluble aerosols or as insoluble particles was studied in the rat by electron microscopy, electron probe microanalysis, and electron microdiffraction. This study showed that, after inhalation, aerosols of soluble elements like cerous chloride, chromic chloride, uranyl nitrate, and aluminium chloride, are concentrated in the lysosomes of alveolar macrophages and are precipitated in the lysosomes in the form of insoluble phosphate, probably due to the activity of acid phosphatase (intralysosomial enzyme). Also, after inhalation of crystalline particles that are insoluble or poorly soluble in water such as the illites (phyllosilicates), ceric oxides (opaline), and industrial uranium oxides (U3O8), the small crystals are captured by the alveolar macrophage lysosomes and transformed over time into an amorphous form. This structural transformation is associated with changes in the chemical nature of particles inhaled in the oxide form. Microanalysis of amorphous deposits observed after inhalation of uranium or ceric oxides has shown that they contain high concentrations of phosphorus associated with the initial elements cerium and uranium. These different processes tend to limit the diffusion of these toxic elements within the organism, whether they are inhaled in soluble form or not.