Division of Translational Radiation Sciences, Department of Radiation Oncology, University of Maryland School of Medicine, Baltimore, Maryland 21201.
Center for Translational Medicine, University of Maryland School of Pharmacy, Baltimore, Maryland 21201.
Radiat Res. 2023 Apr 1;199(4):319-335. doi: 10.1667/RADE-22-00178.1.
The objective of the current study was to establish a mouse model of acute radiation syndrome (ARS) after total-body irradiation with 2.5% bone marrow sparing (TBI/BM2.5) that progressed to the delayed effects of acute radiation exposure, specifically pneumonitis and/or pulmonary fibrosis (DEARE-lung), in animals surviving longer than 60 days. Two hundred age and sex matched C57L/J mice were assigned to one of six arms to receive a dose of 9.5 to 13.25 Gy of 320 kV X-ray TBI/BM2.5. A sham-irradiated cohort was included as an age- and sex-matched control. Blood was sampled from the facial vein prior to irradiation and on days 5, 10, 15, 20, 25, and 30 postirradiation for hematology. Respiratory function was monitored at regular intervals throughout the in-life phase. Animals with respiratory dysfunction were administered a single 12-day tapered regimen of dexamethasone, allometrically scaled from a similar regimen in the non-human primate. All animals were monitored daily for up to 224 days postirradiation for signs of organ dysfunction and morbidity/mortality. At euthanasia due to criteria or at the study endpoint, wet lung weights were recorded, and blood sampled for hematology and serum chemistry. The left lung, heart, spleen, small and large intestine, and kidneys were processed for histopathology. A dose-response curve with the estimated lethal dose for 10-99% of animals with 95% confidence intervals was established. The median survival time was significantly prolonged in males as compared to females across the 10.25 to 12.5 Gy dose range. Animal sex played a significant role in overall survival, with males 50% less likely to expire prior to the study endpoint compared to females. All animals developed pancytopenia within the first one- to two-weeks after TBI/BM2.5 followed by a progressive recovery through day 30. Fourteen percent of animals expired during the first 30-days postirradiation due to ARS (e.g., myelosuppression, gastrointestinal tissue abnormalities), with most deaths occurring prior to day 15. Microscopic findings show the presence of radiation pneumonitis as early as day 57. At time points later than day 70, pneumonitis was consistently present in the lungs of mice and the severity was comparable across radiation dose arms. Pulmonary fibrosis was first noted at day 64 but was not consistently present and stable in severity until after day 70. Fibrosis was comparable across radiation dose arms. In conclusion, this study established a multiple organ injury mouse model that progresses through the ARS phase to DEARE-lung, characterized by respiratory dysfunction, and microscopic abnormalities consistent with radiation pneumonitis/fibrosis. The model provides a platform for future development of medical countermeasures for approval and licensure by the U.S. Food and Drug Administration under the animal rule regulatory pathway.
本研究的目的是建立一个经过全身照射(TBI/BM2.5)后进展为急性辐射暴露延迟效应(DEARE-肺部)的急性辐射综合征(ARS)小鼠模型,特别是放射性肺炎和/或肺纤维化(DEARE-肺部),在动物存活时间超过 60 天的情况下。将 200 只年龄和性别匹配的 C57L/J 小鼠分为六组中的一组,接受 9.5 至 13.25 Gy 的 320 kV X 射线 TBI/BM2.5 照射。包括一个假照射队列作为年龄和性别匹配的对照。在照射前和照射后第 5、10、15、20、25 和 30 天,从面部静脉采集血液进行血液学检查。在整个生存阶段定期监测呼吸功能。对呼吸功能障碍的动物给予单次 12 天的地塞米松递减方案,该方案是根据非人类灵长类动物的类似方案进行的。所有动物在照射后最多 224 天内每天监测,以观察器官功能障碍和发病率/死亡率的迹象。根据标准或研究终点,因 Criteria 而安乐死或因 Criteria 而安乐死,记录湿肺重量,并采集血液进行血液学和血清化学检查。建立了剂量-反应曲线,其中包括 95%置信区间内 10-99%动物的致死剂量。与女性相比,男性在 10.25 至 12.5 Gy 剂量范围内的中位生存时间明显延长。动物性别在总生存率中起着重要作用,与女性相比,雄性在研究终点前死亡的可能性降低 50%。所有动物在 TBI/BM2.5 后一至两周内均出现全血细胞减少,随后在第 30 天前逐渐恢复。由于 ARS(例如骨髓抑制、胃肠道组织异常),14%的动物在照射后 30 天内死亡,大多数死亡发生在第 15 天之前。显微镜检查结果显示,早在第 57 天就出现放射性肺炎。在第 70 天以后的时间点,肺炎始终存在于小鼠的肺部,并且在各个辐射剂量组之间,肺炎的严重程度相当。第 64 天首次出现肺纤维化,但直到第 70 天以后,纤维化才始终存在且稳定,严重程度也相当。纤维化在各个辐射剂量组之间相当。总之,本研究建立了一个多器官损伤的小鼠模型,该模型经历了 ARS 阶段进展到 DEARE-肺部,表现为呼吸功能障碍和与放射性肺炎/纤维化一致的显微镜异常。该模型为未来开发美国食品和药物管理局批准和许可的医学对策提供了一个平台,这些对策是根据动物规则监管途径开发的。