A C57L/J Mouse Model of the Delayed Effects of Acute Radiation Exposure in the Context of Evolving Multi-Organ Dysfunction and Failure after Total-Body Irradiation with 2.5% Bone Marrow Sparing

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.

[1]  Sue-Jane Wang,et al.  A Trans-Agency Workshop on the Pathophysiology of Radiation-Induced Lung Injury , 2021, Radiation Research.

[2]  M. Boerma,et al.  All for one, though not one for all: team players in normal tissue radiobiology , 2021, International journal of radiation biology.

[3]  A. Farese,et al.  Acute Radiation-induced Lung Injury in the Non-human Primate: A Review and Comparison of Mortality and Co-morbidities Using Models of Partial-body Irradiation with Marginal Bone Marrow Sparing and Whole Thorax Lung Irradiation , 2020, Health physics.

[4]  S. Authier,et al.  Efficacy of delayed administration of sargramostim up to 120 hours post exposure in a nonhuman primate total body radiation model , 2020, International journal of radiation biology.

[5]  Deborah I. Bunin,et al.  Pharmacodynamics of romiplostim alone and in combination with pegfilgrastim on acute radiation-induced thrombocytopenia and neutropenia in non-human primates , 2020, International journal of radiation biology.

[6]  K. Prado,et al.  Efficacy of Neulasta or Neupogen on H-ARS and GI-ARS Mortality and Hematopoietic Recovery in Nonhuman Primates After 10-Gy Irradiation With 2.5% Bone Marrow Sparing , 2019, Health physics.

[7]  T. MacVittie,et al.  WAG/RijCmcr rat models for injuries to multiple organs by single high dose ionizing radiation: similarities to nonhuman primates (NHP) , 2020, International journal of radiation biology.

[8]  R. Pavlović,et al.  Gene expression profiles among murine strains segregate with distinct differences in the progression of radiation-induced lung disease , 2017, Disease Models & Mechanisms.

[9]  S. Bentzen,et al.  Pathophysiological mechanisms underlying phenotypic differences in pulmonary radioresponse , 2016, Scientific Reports.

[10]  B. Marples,et al.  A survey of changing trends in modelling radiation lung injury in mice: bringing out the good, the bad, and the uncertain , 2016, Laboratory Investigation.

[11]  K. Prado,et al.  Pegfilgrastim Improves Survival of Lethally Irradiated Nonhuman Primates. , 2015, Radiation research.

[12]  M. V. Roy,et al.  Animal models in translational medicine: Validation and prediction , 2014 .

[13]  E. Hod,et al.  Efficacy of enrofloxacin in a mouse model of sepsis. , 2014, Journal of the American Association for Laboratory Animal Science : JAALAS.

[14]  S. Rankin,et al.  Antibiotic administration in the drinking water of mice. , 2014, Journal of the American Association for Laboratory Animal Science : JAALAS.

[15]  Cynthia S. Johnson,et al.  Characterization of the Dose Response Relationship for Lung Injury Following Acute Radiation Exposure in Three Well-established Murine Strains: Developing an Interspecies Bridge to Link Animal Models with Human Lung , 2014, Health physics.

[16]  G. Lasio,et al.  The Delayed Pulmonary Syndrome Following Acute High-dose Irradiation: A Rhesus Macaque Model , 2014, Health physics.

[17]  A. Farese,et al.  Filgrastim Improves Survival in Lethally Irradiated Nonhuman Primates , 2013, Radiation research.

[18]  A. Paun,et al.  Genomic and genome-wide association of susceptibility to radiation-induced fibrotic lung disease in mice. , 2012, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[19]  B. Katz,et al.  A Preclinical Rodent Model of Radiation-induced Lung Injury for Medical Countermeasure Screening in Accordance With the FDA Animal Rule , 2012, Health physics.

[20]  Cynthia S. Johnson,et al.  Establishing a Murine Model of the Hematopoietic Syndrome of the Acute Radiation Syndrome , 2012, Health physics.

[21]  Jacqueline P. Williams,et al.  Animal Models and Medical Countermeasures Development for Radiation-Induced Lung Damage: Report from an NIAID Workshop , 2012, Radiation research.

[22]  Jacqueline P. Williams,et al.  After the bomb drops: A new look at radiation-induced multiple organ dysfunction syndrome (MODS) , 2011, International journal of radiation biology.

[23]  Ž. Vujašković,et al.  A Further Comparison of Pathologies after Thoracic Irradiation among Different Mouse Strains: Finding the Best Preclinical Model for Evaluating Therapies Directed Against Radiation-Induced Lung Damage , 2011, Radiation research.

[24]  J. Down,et al.  Identifying the High Radiosensitivity of the Lungs of C57L Mice in a Model of Total-Body Irradiation and Bone Marrow Transplantation , 2010, Radiation research.

[25]  Isabel L Jackson,et al.  Revisiting Strain-Related Differences in Radiation Sensitivity of the Mouse Lung: Recognizing and Avoiding the Confounding Effects of Pleural Effusions , 2010, Radiation research.

[26]  William R Hendee,et al.  Medical response to a major radiologic emergency: a primer for medical and public health practitioners. , 2010, Radiology.

[27]  H. Bolte,et al.  Standardized quantification of pulmonary fibrosis in histological samples. , 2008, BioTechniques.

[28]  E. Travis Genetic susceptibility to late normal tissue injury. , 2007, Seminars in radiation oncology.

[29]  S. Bentzen Preventing or reducing late side effects of radiation therapy: radiobiology meets molecular pathology , 2006, Nature Reviews Cancer.

[30]  L. F. Fajardo The pathology of ionizing radiation as defined by morphologic patterns* , 2005, Acta oncologica.

[31]  P. Quesenberry,et al.  Murine marrow cellularity and the concept of stem cell competition: geographic and quantitative determinants in stem cell biology , 2004, Leukemia.

[32]  R. Gale,et al.  Hematopoietic recovery after 10-Gy acute total body radiation. , 1994, Blood.

[33]  B. Fish,et al.  Late toxicity of total body irradiation with bone marrow transplantation in a rat model. , 1989, International journal of radiation oncology, biology, physics.

[34]  N. Tarbell,et al.  Dose-limiting complications from upper half body irradiation in C3H mice. , 1988, International journal of radiation oncology, biology, physics.

[35]  S. Tucker,et al.  The relationship between functional assays of radiation response in the lung and target cell depletion. , 1986, The British journal of cancer. Supplement.

[36]  J. Van Dyk,et al.  Radiation pneumonitis following large single dose irradiation: a re-evaluation based on absolute dose to lung. , 1981, International journal of radiation oncology, biology, physics.

[37]  A. Pearson,et al.  Radiation effects on mouse incisor teeth following whole-body doses of up to 16 gray. , 1981, International journal of radiation biology and related studies in physics, chemistry, and medicine.