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Pneumonitis and fibrosis are potentially lethal, delayed effects of acute radiation exposure. In this study, male rhesus macaques received whole-thorax lung irradiation (WTLI) with a target dose of 10.74 Gy prescribed to midplane at a dose rate of 0.80 ± 0.05 Gy/min using 6 MV linear accelerator-derived photons. The study design was comprised of four animal cohorts: one control and three treated with AEOL 10150 (n = 20 animals per cohort). AEOL 10150, a metalloporphyrin antioxidant, superoxide dismutase mimetic was administered by daily subcutaneous injection at 5 mg/kg in each of three schedules, beginning 24 ± 2 h postirradiation: from day 1 to day 28, day 1 to day 60 or a divided regimen from day 1 to day 28 plus day 60 to day 88. Control animals received 0.9% saline injections from day 1 to day 28. All animals received medical management and were followed for 180 days. Computed tomography (CT) scan and baseline hematology values were assessed prior to WTLI. Postirradiation monthly CT scans were collected, and images were analyzed for evidence of lung injury (pneumonitis, fibrosis, pleural and pericardial effusion) based on differences in radiodensity characteristics of the normal versus damaged lung. The primary end point was survival to 180 days based on all-cause mortality. The latency, incidence and severity of lung injury were assessed through clinical, radiographic and histological parameters. A clear survival relationship was observed with the AEOL 10150 treatment schedule and time after lethal WTLI. The day 1–60 administration schedule increased survival from 25 to 50%, mean survival time of decedents and the latency to nonsedated respiratory rate to >60 or >80 breaths/min and diminished quantitative radiographic lung injury as determined by CT scans. It did not affect incidence or severity of pneumonitis/fibrosis as determined by histological evaluation, pleural effusion or pericardial effusion as determined by CT scans. Analysis of the Kaplan-Meier survival curves suggested that treatment efficacy could be increased by extending the treatment schedule to 90 days or longer after WTLI. No survival improvement was noted in the AEOL 10150 cohorts treated from day 1–28 or using the divided schedule of day 1–28 plus day 60–88. These results suggest that AEOL 10150 may be an effective medical countermeasure against severe and lethal radiation-induced lung injury.

Radiation-induced lung injury (RILI) is a delayed effect of acute radiation exposure that can limit curative cancer treatment therapies and cause lethality following high-dose whole-thorax lung irradiation (WTLI). To date, the exact mechanisms of injury development following insult remain ill-defined and there are no FDA approved pharmaceutical agents or medical countermeasures. Traditionally, RILI development is considered as three phases, the clinically latent period, the intermediate acute pneumonitis phase and the later fibrotic stage. Utilizing matrix-assisted laser desorption ionization mass spectrometry imaging, we identified a number of lipids that were reflective of disease state or injury. Lipids play central roles in metabolism and cell signaling, and thus reflect the phenotype of the tissue environment, making these molecules pivotal biomarkers in many disease processes. We detected decreases in specific surfactant lipids irrespective of the different pathologies that presented within each sample at 180 days post whole-thorax lung irradiation. We also detected regional increases in ether-linked phospholipids that are the precursors of PAF, and global decreases in lipids that were reflective of severe fibrosis. Taken together our results provide panels of lipids that can differentiate between naïve and irradiated samples, as well as providing potential markers of inflammation and fibrosis.

Treatment of individuals exposed to potentially lethal doses of radiation is of paramount concern to health professionals and government agencies. We evaluated the efficacy of filgrastim to increase survival of nonhuman primates (NHP) exposed to an approximate mid-lethal dose (LD50/60) (7.50 Gy) of LINAC-derived photon radiation. Prior to total-body irradiation (TBI), nonhuman primates were randomized to either a control (n = 22) or filgrastim-treated (n = 24) cohorts. Filgrastim (10 μg/kg/d) was administered beginning 1 day after TBI and continued daily until the absolute neutrophil count (ANC) was >1,000/μL for 3 consecutive days. All nonhuman primates received medical management as per protocol. The primary end point was all cause overall mortality over the 60 day in-life study. Secondary end points included mean survival time of decedents and all hematologic-related parameters. Filgrastim significantly (P < 0.004) reduced 60 day overall mortality [20.8% (5/24)] compared to the controls [59.1% (13/22)]. Filgrastim significantly decreased the duration of neutropenia, but did not affect the absolute neutrophil count nadir. Febrile neutropenia (ANC <500/μL and body temperature ≥103°F) was experienced by 90.9% (20/22) of controls compared to 79.2% (19/24) of filgrastim-treated animals (P = 0.418). Survival was significantly increased by 38.3% over controls. Filgrastim, administered at this dose and schedule, effectively mitigated the lethality of the hematopoietic subsyndrome of the acute radiation syndrome.

Leukocyte growth factors (LGF), such as filgrastim, pegfilgrastim and sargramostim, have been used to mitigate the hematologic symptoms of acute radiation syndrome (ARS) after radiation accidents. Although these pharmaceuticals are currently approved for treatment of chemotherapy-induced myelosuppression, such approval has not been granted for myelosuppression resulting from acute radiation exposure. Regulatory approval of drugs used to treat radiological or nuclear exposure injuries requires their development and testing in accordance with the Animal Efficacy Rule, set forth by the U.S. Food and Drug Administration. To date, filgrastim is the only LGF that has undergone efficacy assessment conducted under the Animal Efficacy Rule. To confirm the efficacy of another LGF with a shorter dosing regimen compared to filgrastim, we evaluated the use of pegfilgrastim (Neulasta®) in a lethal nonhuman primate (NHP) model of hematopoietic acute radiation syndrome (H-ARS). Rhesus macaques were exposed to 7.50 Gy total-body irradiation (the LD50/60), delivered at 0.80 Gy/min using linear accelerator 6 MV photons. Pegfilgrastim (300 μg/kg, n = 23) or 5% dextrose in water (n = 23) was administered on day 1 and 8 postirradiation and all animals received medical management. Hematologic and physiologic parameters were evaluated for 60 days postirradiation. The primary, clinically relevant end point was survival to day 60; secondary end points included hematologic-related parameters. Pegfilgrastim significantly (P = 0.0014) increased 60 day survival to 91.3% (21/23) from 47.8% (11/23) in the control. Relative to the controls, pegfilgrastim also significantly: 1. decreased the median duration of neutropenia and thrombocytopenia; 2. improved the median time to recovery of absolute neutrophil count (ANC) ≥500/μL, ANC ≥1,000/μL and platelet (PLT) count ≥20,000/μL; 3. increased the mean ANC at nadir; and 4. decreased the incidence of Gram-negative bacteremia. These data demonstrate that pegfilgrastim is an additional medical countermeasure capable of increasing survival and neutrophil-related parameters when administered in an abbreviated schedule to a NHP model of lethal H-ARS.

The development of medical countermeasures against acute and delayed multi-organ injury requires animal models predictive of the human response to radiation and its treatment. Late chronic injury is a well-known feature of radiation nephropathy, but acute kidney injury has not been reported in an appropriate animal model. We have established a single-fraction partial-body irradiation model with minimal marrow sparing in non-human primates. Subject-based medical management was used including parenteral fluids according to prospective morbidity criteria. We show herein that 10 or 11 Gy exposures caused both acute and chronic kidney injury. Acute and chronic kidney injury appear to be dose-independent between 10 and 11 Gy. Acute kidney injury was identified during the first 50 days postirradiation and appeared to resolve before the occurrence of chronic kidney injury, which was progressively more severe up to 180 days postirradiation, which was the end of the study. These findings show that mitigation of the acute radiation syndrome by medical management will unmask delayed late effects that occur months after partial-body irradiation. They further emphasize that both acute and chronic changes in kidney function must be taken into account in the use and timing of mitigators and medical management for acute radiation syndrome and delayed effects of acute radiation exposure (DEARE).

Radiation-induced lung injury is a highly complex combination of pathological alterations that develop over time and severity of disease development is dose-dependent. Following exposures to lethal doses of irradiation, morbidity and mortality can occur due to a combination of edema, pneumonitis and fibrosis. Protein glycosylation has essential roles in a plethora of biological and immunological processes. Alterations in glycosylation profiles have been detected in diseases ranging from infection, inflammation and cancer. We utilized mass spectrometry imaging to spatially map N-glycans to distinct pathological alterations during the clinically latent period and at 180 days post-exposure to irradiation. Results identified alterations in a number of high mannose, hybrid and complex N-glycans that were localized to regions of mucus and alveolar-bronchiolar hyperplasia, proliferations of type 2 epithelial cells, accumulations of macrophages, edema and fibrosis. The glycosylation profiles indicate most alterations occur prior to the onset of clinical symptoms as a result of pathological manifestations. Alterations in five N-glycans were identified as a function of time post-exposure. Understanding the functional roles N-glycans play in the development of these pathologies, particularly in the accumulation of macrophages and their phenotype, may lead to new therapeutic avenues for the treatment of radiation-induced lung injury.

In this study, nonhuman primates (NHPs) exposed to lethal doses of total body irradiation (TBI) within the gastrointestinal (GI) acute radiation syndrome range, sparing ∼5% of bone marrow (TBI-BM5), were used to evaluate the mechanisms involved in development of the chronic GI syndrome. TBI increased mucosal permeability in the jejunum (12–14 Gy) and proximal colon (13–14 Gy). TBI-BM5 also impaired mucosal barrier function at doses ranging from 10–12.5 Gy in both small intestine and colon. Timed necropsies of NHPs at 6–180 days after 10 Gy TBI-BM5 showed that changes in small intestine preceded those in the colon. Chronic GI syndrome in NHPs is characterized by continued weight loss and intermittent GI syndrome symptoms. There was a long-lasting decrease in jejunal glucose absorption coincident with reduced expression of the sodium-linked glucose transporter. The small intestine and colon showed a modest upregulation of several different pro-inflammatory mediators such as NOS-2. The persistent inflammation in the post-TBI-BM5 period was associated with a long-lasting impairment of mucosal restitution and a reduced expression of intestinal and serum levels of alkaline phosphatase (ALP). Mucosal healing in the postirradiation period is dependent on sparing of stem cell crypts and maturation of crypt cells into appropriate phenotypes. At 30 days after 10 Gy TBI-BM5, there was a significant downregulation in the gene and protein expression of the stem cell marker Lgr5 but no change in the gene expression of enterocyte or enteroendocrine lineage markers. These data indicate that even a threshold dose of 10 Gy TBI-BM5 induces a persistent impairment of both mucosal barrier function and restitution in the GI tract and that ALP may serve as a biomarker for these events. These findings have important therapeutic implications for the design of medical countermeasures.

The potential risk of a radiological catastrophe highlights the need for identifying and validating potential biomarkers that accurately predict radiation-induced organ damage. A key target organ that is acutely sensitive to the effects of irradiation is the gastrointestinal (GI) tract, referred to as the GI acute radiation syndrome (GI-ARS). Recently, citrulline has been identified as a potential circulating biomarker for radiation-induced GI damage. Prior to biologically validating citrulline as a biomarker for radiation-induced GI injury, there is the important task of developing and validating a quantitation assay for citrulline detection within the radiation animal models used for biomarker validation. Herein, we describe the analytical development and validation of citrulline detection using a liquid chromatography tandem mass spectrometry assay that incorporates stable-label isotope internal standards. Analytical validation for specificity, linearity, lower limit of quantitation, accuracy, intra- and interday precision, extraction recovery, matrix effects, and stability was performed under sample collection and storage conditions according to the Guidance for Industry, Bioanalytical Methods Validation issued by the US Food and Drug Administration. In addition, the method was biologically validated using plasma from well-characterized mouse, minipig, and nonhuman primate GI-ARS models. The results demonstrated that circulating citrulline can be confidently quantified from plasma. Additionally, circulating citrulline displayed a time-dependent response for radiological doses covering GI-ARS across multiple species.

We have recently reported that the RD114-pseudotyped MFGS-gp91phox vector achieves unprecedented levels of correction of the NADPH-oxidase gp91phox (approved gene symbol CYBB) defect in CD34(+) cells from patients with X-linked chronic granulomatous disease in the NOD/SCID mouse model. Considering clinical use of this vector, we transplanted autologous mobilized peripheral blood CD34(+) progenitor cells, transduced with the RD114-MFGS-gp91phox vector, into two healthy rhesus macaques following nonmyeloablative conditioning. The moderately high levels of in vivo marking seen in the first months following transduction decreased and stabilized at about 8 months posttransplant. Marking for both healthy animals after 15 months was 0.3 to 1.3 vector copies per 100 cells in lymphocytes, neutrophils, and monocytes. Vector insertion analyses performed by linear amplification-mediated PCR and sequencing identified 32 and 45 separate insertion sites in the animals. Identical insertion sites were found in myeloid cells and lymphocytes, demonstrating the successful transduction of lymphomyeloid progenitors. Some inserts landed in the vicinity of genes controlling cell cycle and proliferation. Statistical analyses of insertion sites 1 year posttransplant suggest a high diversity of insertion sites despite low marking.

The use of growth factors (GFs) in the treatment of radiation injury has focused on enhancing recovery from acute radiation syndrome. A number of new GFs have shown significant in vivo and in vitro preclinical efficacy; some of these have recently been approved by the Food and Drug Administration, some are in various phases of clinical trials, and some are moving through preclinical evaluations. The most promising new GFs in the context of enhancing the viability of irradiated hematopoietic stem cells (HSCs) are flt-3L, c-kitL, and c-mplL. These GFs, as well as interleukin 3 (IL-3), have been shown to maintain viability, suppress apoptosis, and promote the clonal growth of primitive murine and human hematopoietic progenitor cells. Further evidence suggests that these GFs may also act in synergy with each other. Additionally, three families of chimeric proteins that consist of dual GF receptor (R) agonists have been engineered: myelopoietin, promegapoietin, and progenipoietin. These proteins activate the IL-3 and granulocyte colony-stimulating factor Rs, the IL-3 and mpl Rs, and the flt-3L and granulocyte colony-stimulating factor Rs, respectively. The preclinical data indicate that the chimeric GFR agonists are potent stimulators of hematopoiesis in myelosuppressed nonhuman primates and can effectively alleviate acute radiation syndrome in animals. Acute or protracted low-level radiation exposure does not require the extensive clinical care necessary following radiation-induced myelosuppression. The main question is whether these new GFs will allow for enhanced repair of radiation-induced chromosome aberrations while promoting early survival of HSCs. Other questions include the following: Will an early, brief exposure to GFs suppress p53-dependent apoptosis and induce expression of bcl-2 with a concomitant enhancement of DNA repair capacity? What is the effect of GF stimulation of irradiated HSCs on p53 cell cycle checkpoint activity? Will GFs promote survival of \"transformed\" cells that would otherwise be eliminated by p53 activation of apoptosis-promoting genes? Relevant animal models and access to appropriate GFs will be required to answer these questions.