Background and purpose: Pneumonitis and fibrosis constitute dose-limiting side effects of thorax or total body irradiation. An improved understanding of the underlying mechanisms is a prerequisite for the development of effective radioprotective strategies. Here we characterized the behavior of resident and immune cells in a murine model of radiation-induced pneumopathy.
Materials and methods: Wild type (WT) or RAG-2 deficient C57BL/6 mice received 15 Gray of (hemi)-thorax irradiation in a single dose. Bronchoalveolar lavage fluid (BALF) and lung tissue were collected at defined time points post-irradiation for the determination of apoptosis, microvascular injury, and histological and immunohistochemical analyses.
Results: Higher albumin levels and increased apoptosis were detected in the BALF 21 days after irradiation, indicative for delayed damage to resident cells. Irradiation also induced time-dependent changes in the BALF cytokine profile, the recruitment of activated T-cells into the lung and the formation of lipid-loaded resident cells. Lung fibrosis occurred earlier in RAG-2(-/-) mice, which lack mature T and B cells, compared to WT mice.
Conclusions: Thorax irradiation triggers a delayed disturbance of tissue integrity and lipid metabolism in the lung. Activated T-lymphocytes infiltrating the lung tissue upon thorax irradiation participate in the protection of the lung from radiation-induced fibrosis.
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