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• Published: 12 June 2024

Precision radiation opens a new window on cancer therapy

• Melanie Senior 1  

Nature Biotechnology volume  42 ,  pages 1003–1008 ( 2024 ) Cite this article

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Targeted radiopharmaceuticals offer resistance-free potency, pre-treatment imaging and widespread combination potential. Big pharma and investors are piling in.

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Senior, M. Precision radiation opens a new window on cancer therapy. Nat Biotechnol 42 , 1003–1008 (2024). https://doi.org/10.1038/s41587-024-02295-z

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Mansoor M Ahmed, Ph.D., is the Program Director in Radiotherapy Development Branch and lead organizer of Molecular Radiation Therapeutics Working Groups in Radiation Research Program. Dr. Ahmed promotes and manages a portfolio of grants in signal transduction, radiation immune response, cancer stem cells, and in vitro and in vivo models in radiotherapy. He conducts cancer research outreach activities in India, China, and IAEA through NCI’s Center for Global Health.

Dr. Mansoor M. Ahmed received his Ph.D. from the University of Madras in Environmental Toxicology studying cytogenetics and molecular biology of pesticide-induced myelodysplastic syndrome in farmers from South India. He then had 18 months of training as a Monbusho Scholar at the Research Institute for Radiation Biology and Medicine, Hiroshima University, Japan, where he studied the molecular biology of Non-Hodgkin’s lymphoma and T-cell leukemia in A-bomb survivors. Dr. Ahmed studied micro-dissection of chromosomes in solid tumors and radiation-induced signal transduction during his post-doctoral training at Thomas Jefferson University in Pennsylvania and the University of Kentucky. He held his first faculty position at the University of Kentucky, Department of Radiation Medicine, where he established a Molecular Radiation Biology Program. After his tenure at the University of Kentucky, Dr. Ahmed joined Weis Center for Research at Geisinger Clinic and, later, the University of Miami, Department of Radiation Oncology, where he established programs in Molecular Radiation Biology. At all three centers, including Fox Chase Cancer Center, he taught Mammalian Radiation Biology for residents of radiation oncology.

His primary research focuses involved employing various novel strategies to increase the therapeutic ratio through two broad areas: (1) the manipulation of tumor control by modulating the processes that control cell cycle and apoptosis; and (2) the reduction of normal tissue morbidity by applying the emerging information on the molecular mechanistic basis of radiation or chemotherapeutic sensitivity. His seminal contributions include

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Prospects and status of the dosimetry system for atomic bomb survivor cohort study conducted at Research Institute for Radiation Biology and Medicine of Hiroshima University

Affiliation.

• 1 Department of Radiation Biophysics, Research Institute for Radiation Biology and Medicine (RIRBM), Hiroshima University, Kasumi 1-2-3, Minami-ku, Hiroshima City, Hiroshima 734-8533, Japan.
• PMID: 33978168
• PMCID: PMC8114224
• DOI: 10.1093/jrr/rrab020

The Research Institute for Radiation Biology and Medicine (RIRBM) of Hiroshima University has been conducting a cohort study of atomic bomb survivors (ABS). Cohort members include those who were issued an Atomic Bomb Health Handbook from the Hiroshima local government. A series of dosimetry systems for the ABS were developed at RIRBM to evaluate the health effects associated with radiation exposure. The framework used to estimate individual doses in our dosimetry systems for ABS is mainly based on the Dosimetry System 86, and its revisions developed by the Radiation Effect Research Foundation. This article describes the design and computational principles for the dosimetry systems in RIRBM and the history of the revisions, from the first version of the system, ABS93D, to the most recent version, ABS16D. We then provide a perspective for further improvement and application of the dosimetry system.

Keywords: DS02; DS86; Hiroshima; atomic bomb survivor (ABS); dosimetry.

© The Author(s) 2021. Published by Oxford University Press on behalf of The Japanese Radiation Research Society and Japanese Society for Radiation Oncology.

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The relationship among free-in-air kerma,…

The relationship among free-in-air kerma, shielded kerma, organ dose, and their conversion factors.

The dose on the active…

The dose on the active bone marrow in ABS16D relative to the distance…

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The Future of Radiobiology

David g kirsch.

1 Department of Radiation Oncology and Department of Pharmacology and Cancer Biology, Duke University Medical Center, Durham, NC

2 Department of Radiation Oncology, Stanford Cancer Institute, and Institute for Stem Cell Biology and Regenerative Medicine, Stanford University School of Medicine, Stanford, CA

Aparna H Kesarwala

3 Radiation Oncology Branch, National Institutes of Health, Bethesda, MD

5 Department of Radiation Oncology Perelman School of Medicine, University of Pennsylvania, Philadelphia, PA

Meredith A Morgan

6 Department of Radiation Oncology, University of Michigan, Ann Arbor, MI

Julie K Schwarz

8 Department of Radiation Oncology, Washington University School of Medicine, St. Louis, MO

Robert Bristow

9 Department of Radiation Oncology, Princess Margaret Cancer Center, Toronto, ON, Canada

Sandra Demaria

10 Department of Radiation Oncology and Department of Pathology and Laboratory Medicine, Weill Cornell Medical College, New York, NY

Robert J Griffin

11 Department of Radiation Oncology, University of Arkansas for Medical Sciences, Little Rock, AR

Daphne Haas-Kogan

12 Department of Radiation Oncology, Harvard Medical School, Dana-Farber Cancer Institute, Brigham and Women's Hospital, Boston Children's Hospital, Boston, MA

Geoff S Higgins

13 Department of Oncology, University of Oxford, Oxford, Oxfordshire, UK

Alec C Kimmelman

14 Perlmutter Cancer Center and Department of Radiation Oncology, New York University Langone Medical Center, New York, NY

Randall J Kimple

15 Department of Human Oncology, University of Wisconsin School of Medicine and Public Health, Madison, WI

Isabelle M Lombaert

7 Department of Biologic and Materials Sciences, Biointerfaces Institute, School of Dentistry, University of Michigan, Ann Arbor, MI

16 Department of Experimental Radiation Oncology, The University of Texas MD Anderson Cancer Center, Houston, TX

Brian Marples

17 Department of Radiation Oncology, University of Miami, Miami, FL

Frank Pajonk

19 Department of Radiation Oncology, University of California, Los Angeles, CA

Catherine C Park

20 David Geffen School of Medicine, University of California, Los Angeles, CA

21 Department of Radiation Oncology, Helen Diller Family Comprehensive Cancer Center, University of California, San Francisco, CA

Dörthe Schaue

18 Division of Molecular and Cellular Oncology, University of California, Los Angeles, CA

Phuoc T. Tran

22 Department of Radiation Oncology and Molecular Radiation Sciences, Oncology and Urology, Johns Hopkins University School of Medicine, Baltimore, MD

Henning Willers

23 Department of Radiation Oncology, Massachusetts General Hospital and Harvard Medical School, Boston, MA

Brad G. Wouters

24 Department of Radiation Oncology (RB), Princess Margaret Cancer Center

Eric J Bernhard

4 Radiation Research Program, Division of Cancer Treatment and Diagnosis, National Cancer Institute, National Institutes of Health, Bethesda, MD

Associated Data

Innovation and progress in radiation oncology depend on discovery and insights realized through research in radiation biology. Radiobiology research has led to fundamental scientific insights, from the discovery of stem/progenitor cells to the definition of signal transduction pathways activated by ionizing radiation that are now recognized as integral to the DNA damage response (DDR). Radiobiological discoveries are guiding clinical trials that test radiation therapy combined with inhibitors of the DDR kinases DNA-dependent protein kinase (DNA-PK), ataxia telangiectasia mutated (ATM), ataxia telangiectasia related (ATR), and immune or cell cycle checkpoint inhibitors. To maintain scientific and clinical relevance, the field of radiation biology must overcome challenges in research workforce, training, and funding. The National Cancer Institute convened a workshop to discuss the role of radiobiology research and radiation biologists in the future scientific enterprise. Here, we review the discussions of current radiation oncology research approaches and areas of scientific focus considered important for rapid progress in radiation sciences and the continued contribution of radiobiology to radiation oncology and the broader biomedical research community.

Role of Radiation Biology Research in the Research Enterprise

Past research into the cellular response to ionizing radiation led to fundamental biological insights, such as demonstrating the existence of stem/progenitor cells ( 1 ) and identifying key components of the DNA damage response pathway ( 2 ). These and current advances in radiobiology impact clinical radiation oncology, improving cancer patients’ outcomes ( 3 ). Basic insights from radiobiology can be applied to societally important topics such as carcinogenesis risk estimation from medical, occupational, or space travel radiation exposure ( 4 ) and the development of medical treatments for radiation injury ( 5 ). Despite the substantial impact of radiation biology in the past and its potential for future contributions, the field of radiation biology is facing challenges in research workforce, training, and funding, exacerbated by a clinical emphasis on technological rather than biologic science advances. Therefore, the National Cancer Institute (NCI) convened a workshop to discuss the role and future of radiation biology research and radiation biologists in the context of radiation oncology.

The radiobiology research workforce faces ongoing challenges of critical mass and identity that have been a topic of discussion for more than a decade ( 6 ). The number of principle investigators whose research focuses on radiation biology is limited, and researchers in radiation oncology departments often define themselves as cancer biologists or immunologists, rather than as radiation biologists. While this diversity of expertise is a strength, maintaining a research focus that is clinically relevant to radiation oncology is essential to improving patient care.

For radiobiology, as for other scientific disciplines, scientific reproducibility is an absolute requirement. To facilitate replication of radiation research, it is particularly important to standardize radiation dosimetry ( 7 ) and sufficiently describe experimental details of combining drugs and radiation ( 8 ). Rigorous application of basic radiobiological principles and techniques will enhance the reproducibility and scientific impact, but this requires maintaining a workforce with an advanced working knowledge of these basic principles.

Previous surveys and workshops have reported that the number of National Institutes of Health (NIH)–funded researchers within radiation oncology departments is small, which reflects a small and shrinking applicant pool ( 9 ). However, the success rate of radiobiology applications has not been substantially different from that of other oncology disciplines. To update these reports, we conducted a survey of FY2016 radiation-related federal awards using the NIH RePORTER search engine ( https://projectreporter.nih.gov/reporter.cfm ). There were 72 304 projects reported in this fiscal year (including multiple reporting of multiproject awards), 634 of which were retrieved in our search focused on ionizing radiation studies. Review of the abstracts was done to ensure that only awards directly exploring radiation-related topics were counted. Topics with relevance to radiation (eg, DNA repair, cancer stem cell studies) that did not mention studies with ionizing radiation were not included; thus the results are a conservative estimate. Two-hundred ninety-two awards were identified, funded through the various NIH institutes and centers, primarily the NCI, as well as through the US Food and Drug Administration and Veterans Administration under a variety of grant and contract mechanisms ( Table 1 ; Supplementary Table 1, available online ). The majority of these (n = 183) focused on radiobiology, with 56 awards focused on a clinical question and 15 awards whose scope included both.

Overview of radiation-related grants awarded in FY2016

A concern raised by Steinberg et al. in 2013 was that most radiation researchers with an NIH grant were full professors, while only 4.6% of the grants were career development awards, indicating a limited pipeline of early career investigators within the radiation sciences ( 9 ). Our RePORTER survey showed that this trend continued in 2016, with 11 (3.8%) K-type awards or K99/R00 career development awards identified. However, these data were somewhat mitigated by the finding that 27 (9.4%) awards were awarded to investigators who were identified as new or early-stage investigators. Nevertheless, it is evident that as established radiation researchers retire, investing in training junior investigators to perform radiation research and teaching will be essential to maintaining the field’s vitality ( 10 , 11 ). To retain clinical radiobiology expertise, increased emphasis on training and retention of PhD- and MD/PhD-level radiobiologists by academic radiation oncology departments will be key, as well as supporting active research programs in these departments.

Successful development of new physician scientists in radiation oncology will require opportunities for mentored research training extending beyond residency. Trainees making the transition to scientific independence should be encouraged to apply for K08, K99, and other career development awards. Academic departments must invest in junior scientists by providing both mentoring and sufficient support to develop a research program. For clinician scientists, protected time and adequate technical support are essential. In addition, clinician scientists can initially be embedded as mentored but independent researchers within a laboratory of an established scientist, thereby reducing practical laboratory management duties. Newly independent researchers in radiation research should apply to diverse funding sources, including NIH agencies, the Department of Defense, NASA, pharmaceutical companies, and various foundations (eg, American Cancer Society, Capcure, Lustgarten, etc.).

Given the challenges of maintaining a critical mass of investigators in the radiation research workforce, here we review current radiation research approaches and areas of scientific focus that should be considered for future investment.

Model Systems for Studying Radiobiology

Clonogenic survival is the gold standard assay for assessing radiation sensitivity in vitro as well as for testing the efficacy of agents that modify radiation survival. The advantage of this assay is that its colony formation end point integrates all forms of cell death and measures the reproductive capacity of individual cells, thus defining a cell’s ability to replicate and form a tumor ( 12 ). While clonogenic assays are sensitive across a range of radiation doses, they are relatively low throughput and may not be suitable for all cells. Throughput is being addressed through development of medium/high-throughput-adapted colony formation assays ( 13 ). These screens have nominated targets for radiosensitization that have been validated for efficacy and selectivity and subsequently advanced to drug development programs ( 14 ).

To enable higher-throughput siRNA, CRISPR/Cas9, or small molecule library screens with radiation, investigators use multiwell plate formats with surrogates for clonogenic radiation survival including radiation-induced foci (eg, γ−H2AX) ( 14 , 15 ), viability measured by Adenosine Triphosphate (ATP), or luciferase-based reporters ( 16 , 17 ). Clonogenic assays should still be done to validate the hits in these screens because they do not measure clonogenic survival.

For in vivo radiobiology studies, orthotopic ( 18 ) and subcutaneous Patient Derived Xenograft (PDX) models are rapidly being integrated as model systems in radiation research. Orthotopic models better approximate the tumor microenvironment of human tumors than do subcutaneous tumors, an important consideration for measuring radiation responses. However, orthotopic models introduce challenges for radiation delivery. The availability of small animal radiation micro-irradiators equipped with computed tomography (CT) imaging has made irradiation of orthotopic tumors feasible, but image-guided radiotherapy (IGRT) in mice can be limited by cost, throughput, and radiation toxicity when treating specific organs. Because PDX tumors are normally implanted into immune-deficient mice, this limits opportunities to study the immune system contribution to radiotherapy response, which has been shown to have an impact on radiocurability in syngeneic mouse models ( 19 ). The radiosensitivity of DNA-PK-deficient host mice is also a concern in radiobiological studies. Genetically engineered mouse models (GEMMs), while not fully recapitulating the genetic complexity of human tumor counterparts, generate autochthonous tumors within a native microenvironment in an immune competent animal, thus providing a critical model for dissecting mechanisms of tumor responses to radiation ( 20–23 ). GEMMs and GEMM-derived tumors ( 20–23 ) have been used for assessing experimental radiation sensitizers, including those targeting immune checkpoints ( 24 ).

The therapeutic potential of radiosensitizing agents is determined both by efficacy against and selectivity for tumor cells. Animal models of dose-limiting toxicities are more reliable than in vitro models for assessing normal tissue radiation toxicities, given the limitations of established cell lines in culture (eg, poor colony-forming efficiency, nonphysiologic in vitro growth conditions). Mouse models are routinely used for monitoring normal tissue toxicity such as those occurring in the oral mucosa and small intestine, which limit radiation dose in the clinic for head and neck and pancreatic cancers, respectively ( 25 , 26 ). Other animal models can be of high value in translational radiobiology, including swine and canine models of normal tissue injury ( 27 , 28 ) and companion animals with spontaneous tumors as advanced models for studying responses to radiation and combined modality treatments ( 29 ).

There is also great interest in using 3D models for radiobiological studies (eg, spheroids, organoids). These maintain some of the key physiologic and structural features of tumors (eg, cell-matrix interactions, hypoxia). They are less expensive than in vivo models, can be genetically modified, and can be employed for large-scale experiments ( 30 ). These models may better predict response than 2D cultures ( 30 ).

Molecular Targets and Radiosensitivity

A major goal of radiobiology is to achieve selective radiosensitization of cancer cells by modulating the molecular response to radiation injury. Ataxia-telangiectasia mutated (ATM) and ataxia telangiectasia and Rad3 related (ATR) are key proteins in the DNA damage response pathways ( 31 ). Substrate analysis has identified more than 900 phosphorylation sites containing a consensus ATM or ATR phosphorylation motif in 700 proteins that are phosphorylated in response to ionizing radiation ( 32 ). These proteins regulate DNA repair, RNA post-translational modification, and cell morphology, suggesting opportunities to enhance tumor radiosensitivity by modulating ATM or ATR pathways.

ATM inhibitors have been shown to preferentially radiosensitize p53 mutant tumor cells in mouse xenografts when delivered via osmotic pump, thus offering some indication of selectivity ( 33 , 34 , 35 ). The orally available ATM inhibitor AZD0156, which has sub-nanomolar potency in cell-based assays with selectivity of greater than 1000-fold over other kinases such as ATR, shows synergy with DNA double-strand break-inducing agents in mouse xenograft models ( 36 ). A phase I clinical trial is currently testing AZD0156 alone or with other systemic drugs such as the PARP inhibitor olaparib in patients with advanced cancer (NCT02588105). There are no trials of ATM inhibitors with radiotherapy to date, and it will be important to determine whether this combination will have acceptable toxicities.

Two ATR inhibitors are currently in clinical trials. VE-822, also known as VX-970, radiosensitized pancreatic cancer cells as a single agent both in vitro and in xenograft models and synergistically sensitized lung cancer cells to cisplatin ( 37 , 38 ). Based on these preclinical data, a phase I trial is testing VX-970 with whole brain radiotherapy for patients with brain metastases from non–small cell lung cancer (NCT02589522). VX-970 is also being tested with radiation therapy and cisplatin for patients with human papillomavirus (HPV)–negative head and neck squamous cell carcinoma (NCT02567422). Another ATR inhibitor, AZD6738, is in a phase I trial as a single agent in combination with radiation therapy for refractory solid tumors (NCT02223923) ( 39 , 40 ).

The epithelial-to-mesenchymal transition (EMT), which generates cells with stem cell properties, is another target for radiosensitization. EMT can be modulated by extracellular factors, such as transforming growth factor-beta, tumor necrosis factor-alpha, and platelet-derived growth factor, or transcription factors, such as Twist, Snail, and zinc finger E-box-binding homeobox 1 (ZEB1) ( 41 ). Cancer stem-like cells preferentially activate the DNA damage response and repair pathways, thereby promoting radiation survival ( 42 , 43 ). A mechanistic link between EMT and radiation response signaling is that ZEB1 is phosphorylated and stabilized by ATM in response to DNA damage. Phosphorylated ZEB1 appears to promote DNA repair via USP7-mediated stabilization of checkpoint kinase 1, a process that can be reversed via microRNA (miR)-205 to enhance radiosensitivity ( 44 , 45 ). MiRs have yet to be approved by the US Food and Drug Administration for therapeutic use but are candidates for therapeutic interventions. Off-target effects may, however, complicate their clinical use, as was seen in a phase I trial of the liposomal miR-34 mimetic MRX34. MRX34 was used to downregulate oncogene expression (NCT01829971), but the trial was terminated due to immune-related adverse events.

The phosphatidylinositol-4,5-bisphosphonate 3-kinase (PI3K)/protein kinase B (AKT)/mammalian target of rapamycin (mTOR) pathway is another example of a pathway that has been studied extensively for its impact on radiosensitivity through a number of mechanisms ( 46 , 47 ). A critical question in the translation of molecular therapeutics to clinical trials with radiation is how to best test molecularly targeted agents. Stratification of patients to therapies by tumor molecular features is routinely utilized for systemic therapy trials, and this approach should be better integrated into clinical trials of radiation therapy. Developing and applying biomarkers to radiotherapy trials, particularly when testing radiation response modulators, would be an important advance.

Metabolism as a Therapeutic Target

Otto Warburg observed in 1924 that tumors consumed large quantities of glucose while secreting high levels of lactate, irrespective of tissue oxygen concentration, a phenomenon now known as the “Warburg effect.” This “aerobic glycolysis” has since been shown to benefit tumor growth by providing intermediates needed to maintain high rates of cellular division ( 48 ). In addition, tumor-specific genetic alterations drive metabolic phenotypes. For example, RAS -driven cancers use alternate carbon sources (both extracellular and intracellular) as fuel for the Tricarboxylic Acid (TCA) cycle ( 49 ). MYC -driven cancers engage in glutaminolysis, while other cancers may not require glutamine for growth ( 50 ). Thus, it is important to consider metabolic therapies in the appropriate genetic context.

Within tumor cells, high rates of glucose metabolism are needed to support intracellular redox balance. The connection between glucose metabolism and redox stress is relevant for radiation therapy. The consumption of glucose via the pentose phosphate pathway generates ribose, which can be used to generate nucleotides for DNA replication and repair; however, an important byproduct of this reaction is NADPH, which can be used by tumor cells as a source of reducing equivalents. Radiation increases intracellular redox stress. Therefore, interfering with metabolic pathways that support intracellular redox balance may enhance the efficacy of radiation ( 51 , 52 ). Tumors can use alternative fuel sources and rely on additional pathways to maintain reducing equivalents, which may also be attractive therapeutic targets.

Additional study is needed to characterize normal vs tumor metabolism and the impact of this difference on radiosensitivity. Also, understanding radiation effects on tumor metabolic phenotypes is needed in order to devise rational combinations of radiation and drugs that target tumor metabolism. Given the diversity in tumor metabolic phenotypes and the influence of specific gene mutations, it is critical to perform these studies in a defined genetic context. For these studies, it will also be important to understand the metabolic impact of the interaction between tumor and stroma using in vivo model systems and to harness the power of imaging to track treatment-associated changes in tumor metabolism after radiation, drug, or combined treatment.

Cancer Stem Cells

Cancer stem cells (CSCs) were initially described in early 2000 as a cell population capable of tumor regeneration ( 53 , 54 ). CSCs differ from their progeny in their metabolic state, which can convert easily between aerobic glycolysis and oxidative phosphorylation depending on the local microenvironment ( 55 , 56 ). CSCs increase the expression of enzymes that regulate intracellular redox metabolism ( 57 , 58 , 59 ) and activation of DNA repair mechanisms ( 42 ), and as such may represent a unique cell population for radiation therapy.

It has also been shown that Glioblastoma Multiforme (GBM) CSCs can migrate within the brain to the subventricular zone (SVZ) and thereby escape regions of high radiation dose ( 60 , 61 ). Environmental stress such as radiotherapy, chemotherapy, hypoxia, and low pH can increase CSC subpopulations and influence radiation sensitivity, and it has been proposed that some normal and non-neoplastic cells can convert spontaneously to a stem-like state ( 62 ).

In the future, methods and criteria for the identification of radiobiologically important CSCs should be developed and standardized. Further study is needed to understand CSC migration and determine whether CSC safe harbors like the SVZ need to be included in radiotherapy treatment fields. It may be possible to target the invasive phenotype of CSCs for therapy. Finally, further study is needed to understand how phenotypic plasticity influences radiotherapy outcomes. Drugs that limit phenotypic plasticity in tumors should be incorporated into radiotherapy clinical trials.

Radiation Toxicity to Normal Tissues and Stem Cells

Following ionizing radiation, cell death is initiated when cells with chromosomal aberrations attempt to divide. Thus, the timing of radiation toxicity in normal tissues often correlates with the cell cycle rate within that organ ( 63 ). Acute radiation toxicity occurs quickly in highly proliferative tissues, while slower-cycling organs often show late radiation responses. An exception is the salivary gland, which has a slow turnover rate yet responds acutely to radiation. Radiation first affects the plasma membrane of secretory cells, resulting in the disruption of stimulated water secretion and loss of organ function before any parenchymal cell death. Therefore, acute toxicity can derive from multiple factors in addition to cell loss. Intermediate to late side effects of radiation toxicity may include inflammation, fibrosis, loss of endothelial function ( 64 ), and potential neuronal dysregulation ( 65 ). When a given radiation dose exceeds an organ’s tolerance, reduced and progressive loss of organ function can occur and persist for the patient’s lifetime. Organ recovery after radiation depends on the number of surviving and functional stem/progenitor cells ( 66 ), which continuously replenish differentiated cell types within the organ. Multiple epithelial stem/progenitor cells are distributed along the organ to locally balance homeostasis by providing new cells, but also by cross-communicating with cells in the surrounding niche ( 67 ), such as stromal, endothelial, and neuronal-derived cells. Radiation not only impacts epithelial stem/progenitors, but also their niche’s internal communication network to induce survival in neighboring cells and promote repair.

Efforts to reduce radiation toxicity are primarily focused on prevention and mitigation strategies. Preventative radioprotectors have tremendous potential, but clinical adoption has been hampered by concern over potential radioprotection of tumor and/or side effects. Mitigators delivered after radiation, which suppress cell death and/or enhance cell proliferation of surviving stem/progenitor cells, may prevent loss of organ function by impacting one or more cell types. To minimize organ dysfunction, an optimal radiation delivery technique to limit normal tissues to radiation should be combined with novel radioprotectors and local delivery of organ-specific radiation mitigators ( 68 , 69 ). The timing of applying these factors (ie, simultaneous or sequential) will be critically important as delivering antioxidants, prosurvival, pro-proliferation, and/or anti-inflammatory agents at the wrong time points may reduce their effects and potentially even enhance toxicity. Using sophisticated radiation delivery methods to avoid irradiating the most sensitive areas within an organ may also reduce toxicity, as has been described for salivary glands ( 70 ). Predictive models can be used to assist in minimizing the dose to critical areas, where potential clusters of crucial epithelial stem cells and essential surrounding niches reside. Further study of regenerative therapies in the context of radiobiology, including cell transplantation, gene transfer, and tissue engineering, will provide novel approaches to repair radiation-damaged organs. Combining spatio-temporal radiation planning with protective and mitigating strategies may be the optimal approach.

Combining Radiotherapy With Immunotherapy

Radiation therapy has historically been a means of improving local control. However, mounting preclinical and clinical evidence indicates that radiation therapy can augment a systemic immune response directed against tumor cells when combined with immunomodulatory drugs ( 71 ). In some preclinical studies, mice bearing two synchronous tumors were used in order to test the ability of radiation delivered to one tumor to induce an out-of-field response in the other tumor (abscopal effect). Such responses reflect the development of robust antitumor T cells and have been achieved when radiation is combined with immunotherapies, such as anti-CTLA4 or anti-PD-1 antibodies, that are otherwise ineffective in these tumor models ( 72–74 ).

Several case reports, retrospective series, and a recent prospective trial support the clinical relevance of the observations made in preclinical models. In melanoma, Postow et al. described marked regression of nonirradiated metastases in a patient who had progressive disease on the anti-CTLA4 antibody ipilimumab and was subsequently treated palliatively with radiation to a paraspinal mass ( 75 ). Since the approval of ipilimumab for melanoma, several retrospective analyses have reported abscopal responses in patients treated with radiation during/after immunotherapy ( 76 , 77 ). The results of a phase I clinical trial that combined ipilimumab with hypofractionated radiation in patients with metastatic melanoma were recently reported, showing a response rate of 18% in unirradiated lesions ( 74 ). Responses to combination therapy have also been reported in tumors that did not initially show a clinical response to ipilimumab alone ( 78 ), suggesting that radiation could reposition immunotherapies for cancers that are not optimal candidates for these treatments. Importantly, a phase I–II trial of combination radiotherapy with granulocyte-macrophage colony-stimulating factor produced objective abscopal responses in more than 25% of patients with metastatic solid tumors, establishing radiotherapy as a potential in situ antitumor vaccine ( 79 ).

The mechanisms by which radiotherapy promotes a tumor-specific immune response are multifactorial and have been reviewed elsewhere ( 80–82 ). Radiation may act as a personalized vaccine by causing the release of danger signals and tumor-specific antigens, which are subsequently presented by dendritic cells to elicit a T-cell-mediated immune response ( 83–85 ). Because radiation can activate immune-inhibitory pathways as well as immune-stimulatory ones, the net effect of these opposing forces may ultimately determine whether radiation will drive a beneficial immune response in a specific patient ( 86 ). Thus, identification and targeting of the immunosuppressive pathways that are induced or exacerbated by radiation will be critical ( 87 ).

The notion that a healthy immune system contributes to successful radiotherapy has been around for decades ( 19 ), as has the immense potential that lies in combining radiation with immunotherapy ( 88 ). These concepts can now be revisited with newer immune targeting strategies. For example, radiation could convert an immune-privileged tumor into one that is T-cell-inflamed, which immune checkpoint inhibitors alone seem unable to do. Clinical testing and further mechanistic research will provide answers to outstanding questions to establish the role of radiation in immuno-oncology ( 89 ). Studies should be designed to assure that the contribution of radiation can be assessed, keeping in mind that immunotherapy can show delayed tumor responses. The radiation dose and fractionation and sequencing with immunotherapy that provide the optimal effect remain to be established, but recent mechanistic studies may provide a rationale for dose selection ( 90 , 91 ). Whether the site that is irradiated matters for radiation to potentiate an immune response is also unknown, and the main antigenic targets of radiation-induced immune responses are unclear. Most importantly, the identification of useful biomarkers that predict which patients will eventually have a clinical response is an important area of investigation that may guide patient selection and early evaluation of treatment response. In this regard, expression of Trex1, an upstream negative regulator of radiation-induced antitumor immunity, was recently shown to be a potential biomarker for determining the optimal radiation dose and fractionation to promote immune activation ( 91 ). Perhaps one of the great challenges and opportunities for the radiation oncology field will be to undertake big data studies that integrate sophisticated imaging technology and personalized radiation treatment planning with complex, multidimensional immune monitoring data and patient outcome ( 92 , 93 ).

Hypoxia, Tumor Vasculature, and Radiotherapy

The solid tumor microenvironment (TME) is often characterized by poor vasculature and inadequate blood supply ( 94 ). As a consequence, tumors may contain regions exhibiting increased interstitial fluid pressure, hypoxia, excess lactate accumulation, lowered pH, and a lack of nutrients. This hostile microenvironment may select for cells that are particularly resistant to killing, and may also contribute to phenotypic diversity within the tumor. However, reliable technologies to properly measure or predict outcomes based on average pH, interstitial fluid pressure, or oxygenation remain elusive.

Hypoxia is associated with poor prognosis in many cancers, irrespective of treatment ( 94–96 ). Hypoxic cells are more resistant to radiotherapy and some chemotherapies because O 2 participates in chemical reactions that enhance initial DNA damage, so without O 2 there is less DNA damage ( 96 ). Additionally, hypoxia influences biological signaling pathways, including the activation of the transcription factor hypoxia-inducible factor 1 (HIF-1), which promotes changes in cellular metabolism and other pathways that affect radiation response ( 20–23 ). Hypoxia-induced biological changes have been shown to promote the generation and maintenance of cancer stem cells in discrete regions of the tumor ( 43 ), which, as discussed above, may be more resistant to DNA damage. Hypoxia may also create an immunosuppressive tumor microenvironment that promotes evasion of immune surveillance. Lastly, hypoxia can promote malignant progression by increasing genomic instability and metastatic potential ( 97 ).

Specifically relating to hypoxia and radiation therapy, hypoxic cell radiosensitizers (nitroimidazoles) are reduced selectively in hypoxic cells to form covalent cross-links and also act to fix radiation damage. Some nitroimidazoles have shown modest benefit in clinical trials ( 98 ). Bioreductive prodrugs are also being studied as hypoxic cytotoxins; some of these are now in clinical trials ( 99 ). The alternative approaches of reducing tumor hypoxia using hyperbaric oxygen during radiotherapy or administering a gas mixture containing higher levels of O 2 in combination with vasodilators (ARCON) have also shown modest improvements in local control ( 100 ).

An approach currently under investigation is the reduction of hypoxia by decreasing tumor O 2 consumption. Based on mathematical modeling, Secomb et al. predicted that even a 30% decrease in O 2 consumption would decrease the hypoxic fraction from 37% to 11% ( 101 ). Studies have shown metformin reducing O 2 consumption and tumor hypoxia, which may enhance radiation sensitivity selectively in hypoxic tumors ( 98 , 102 ).

In addition to directly targeting hypoxia within tumors, another therapeutic approach is to target the aberrant vasculature within the TME. Many strategies have been tried, ranging from starving tumors by collapsing their blood supply with vascular-disrupting agents to reducing hypoxia via vascular normalization ( 103 ). More recent work has shown the contribution of myeloid cells to vasculogenesis and metastasis after therapy, and the ability to block their recruitment to tumors by disrupting the CXCR4/CXCL12 interaction ( 104 , 105 ). These novel approaches to targeting or normalizing tumor vasculature, and to preventing revascularization after therapy, may improve treatment outcomes. Moreover, characterizing the hypoxia status of the tumor may help identify tumors that will recur or metastasize after primary therapy ( 106 , 107 ). Lastly, the field of nanomedicine is well positioned to develop multifunctional agents that preferentially act in or around the tumor microvasculature. These platforms have the potential to facilitate both imaging for and therapy with radiation ( 108–110 ).

There is growing evidence from a number of groups that radiation itself may lead to vascular dysfunction in certain settings, for example, when using doses on the order of 10 Gy or more per fraction ( 111–113 ). These are the types of doses used in stereotactic body radiotherapy (SBRT). As SBRT is increasingly used in the clinic, it is important in the future to understand how much of its efficacy is due to direct tumor cell killing vs indirect killing via vascular ablation. Experiments using dual recombinase technology in a genetically engineered mouse model of soft tissue sarcoma indicate that the killing of blood vessels contributes to growth delay, but not local control following SBRT ( 20–23 ). Further experiments in other model systems are needed to determine if these conclusions extend to other tumor types. In addition, a better understanding of how much the presence of hypoxia within tumors (and what specific type or signature of hypoxia) contributes to local failures after SBRT and whether adjuvant therapies such as vascular-targeted nanoparticles or high-frequency ultrasound ablation (HiFU) tumor debulking can increase local control following SBRT may expand the indications of SBRT to more tumor types and anatomical sites.

Extracellular Matrix and Physical-Mechanical Properties of the Tumor Microenvironment and Radiotherapy

The extracellular matrix (ECM) is another key factor in the tumor microenvironment affecting cancer cell survival after radiation. ECM comprises the structural, cellular, and molecular stromal components including the basal lamina or basement membrane that physically separate the epithelial compartment from the stroma ( 114 ). The integrin family of receptors, necessary for cell adhesion to the basement membrane, has largely defined adhesion-mediated signaling between the epithelial and stromal compartments. Integrin-mediated cell–ECM interactions can enhance radiation and chemoresistance of several tumor types by activating prosurvival signaling ( 115–118 ). Furthermore, adhesion of tumor cells to ECM proteins modulates the efficacy of molecularly targeted therapy ( 119 , 120 ). Therefore, a better understanding of the biochemical signaling pathways from the ECM should lead to new targets for sensitizing tumors to radiation and other therapies. In addition, investigating the mechanical signals that impact cell survival is now possible due to advances in the field of biophysical mechanics in cell biology ( 121 ).

Integrins induce biochemical signaling from direct binding of ECM ligands via multiple possible combinations of integrin heterodimers and ECM molecules. Further complexity lies in the specific physical and mechanical properties of individual ECM molecules, which can enhance integrin signaling by facilitating increased ligand-receptor engagement ( 122 ). The biophysical properties of ECM and tissues play a critical role in cellular function and signaling ( 123 ). Tumors are inherently stiffer than their normal tissue counterparts, and stiffness itself has been shown to enhance tumor progression ( 124 ). Indeed, multiple types of receptors and signaling that respond to biophysical changes in TME are now evident ( 114 ), including the YAP/TAZ cotranscription factors downstream of the HIPPO pathway, which have oncogenic properties ( 125 ). Signaling via HIPPO-YAP/TAZ ties developmental pathways regulating proliferation and organ size with cancer pathophysiology. Tumor stiffness regulates response to growth factor–mediated signaling via YAP/TAZ, demonstrating the broad relevance of this signaling network related to biophysical properties ( 119 ). Advanced 3D models reproducing physiologically relevant microenvironments and capable of tuning elastic modulus and microfabricating the size and shape of culture platforms with “stretch” capability will improve our understanding of the molecular and mechanical mechanisms underlying cancer and cancer cell survival mechanisms under physiologic conditions and enhance the testing of innovative treatment strategies to combine with radiotherapy.

Predictive Biomarkers for Radiotherapy

Predictive biomarkers that allow rational selection of treatments for individual patients are playing a central role in the precision cancer medicine revolution ( 126 ). While biomarkers have transformed approaches for systemic cancer treatment, few predictive biomarkers are currently available for radiotherapy in the clinic ( 127 , 128 ). In many disease sites, there is considerable heterogeneity in outcomes, both with regard to tumor control and treatment toxicity. Thus, biomarkers that predict tumor control probability and normal tissue complication probability would advance the care of individual patients ( 129 ). Although few biology-informed parameters currently influence radiation therapy decisions in the clinic, a number of areas of active investigation promise to deliver novel predictive biomarkers in the near future ( Table 2 ).

Future of predictive tumor biomarkers in curative radiation oncology *

One promising avenue of research for biomarkers predictive of radiation response relates to the altered function of genes involved in DNA repair. Ionizing radiation kills cells through direct or indirect induction of DNA damage, with DNA double-strand breaks (DSB) being the most important lesion ( 130 ). Cancers with defective DSB repair are, therefore, expected to display increased sensitivity to radiation. Markers of DSB repair defects, for example, mutations in or altered gene expression of DNA repair genes, might therefore be ideal predictive biomarkers ( 131–134 ). Unfortunately, data convincingly linking mutations in DSB repair genes such as BRCA1 to increased tumor radiosensitivity in the clinic have not yet materialized ( 135 ). Furthermore, recurrent mutations in individual genes are rare, and DNA damage response and repair networks are complex ( 136 , 137 ). Therefore, comprehensive studies examining the association of DSB repair pathway alterations and clinical radiosensitivity are an important area of future investigation. It is also possible that tumors with such alterations may be particularly sensitive to combined treatment with radiotherapy and DNA repair inhibitors, such as those targeting PARP1, ATR, or CHK1 ( 138 ).

Other molecular characteristics of tumors could serve as potential predictive biomarkers for radiation therapy. For example, numerous studies have shown that patients with HPV-positive head and neck squamous cell carcinomas have relatively good outcomes after treatment with radiation therapy alone or combined with chemotherapy, corroborating preclinical work demonstrating key roles for HPV oncogenes in modulating radiation sensitivity ( 139 , 140 ). Indeed, therapy de-escalation studies are already underway to test if less intense treatment can achieve similarly good outcomes with fewer side effects in this patient population (NCT01084083, NCT01525927, NCT01716195, NCT01663259, NCT01302834, NCT01898494) ( 141 ). Mutations in cancer driver genes may also affect tumor radioresistance, but have been incompletely explored. Also, gene expression signatures that predict radioresistance/radiosensitivity warrant further exploration ( 142 ).

In addition to genomics-based biomarkers, the predictive power of assays that measure classic aspects of radiobiology also warrants further exploration. For example, functional assays of DSB, such as γ H2AX staining performed on biopsies before and after in vivo or ex vivo irradiation, could potentially serve as a direct indicator of patient-specific radiosensitivity ( 143 , 144 ). Current challenges of using such assays include the need for representative tumor biopsies and the use of fresh tissue, and more research is needed to develop techniques that can be more easily adopted in the clinic. Several groups are currently developing cell-penetrating anti-γ−H2AX tracers with the ultimate aim of using them as PET-based imaging tools to assess differences in DSB repair in radiotherapy patients ( 145 ). Furthermore, it would be useful to identify molecular correlates of α/β ratios, which describe cell killing for tumor and normal tissues that could be employed to predict dose fractionation dependencies in radiotherapy ( 129 ). The use of increased fraction sizes in tumors with low α/β ratios, such as breast and prostate cancers, has already advanced into the clinic. However, α/β ratios currently cannot be measured for individual patients. If this were possible, fractionation regimens could potentially be individualized to maximize tumor cell killing while minimizing normal tissue toxicity.

Identification of predictive biomarkers for radiation therapy has been hampered by the fact that, except for prostate cancer studies ( 146 ), large multi-omics profiling efforts such as The Cancer Genome Atlas and the International Cancer Genome Consortium have by and large not included specimens from patients treated with radiation therapy. One technical hurdle for performing such studies is that only small amounts of tumor tissue are often available for radiotherapy patients. An attractive approach for overcoming this challenge is the use of liquid biopsies, including analysis of circulating tumor DNA (ctDNA) and circulating tumor cells (CTCs) ( 147 , 148 ). An important advantage of liquid biopsy approaches is the ability to noninvasively and repeatedly sample molecular aspects of tumors. Liquid biopsies have a number of potential applications, including 1) noninvasive genotyping of tumors being treated with radiation therapy for which no or minimal tissue is available; 2) quantitation of tumoral heterogeneity as a biomarker; 3) early response assessment during radiation therapy to allow escalation or de-escalation of treatment; and 4) identification of radiographically occult residual disease after completion of radiation therapy to identify patients at high risk for recurrence. For example, presence of residual circulating tumor-derived EBV DNA in patients with nasopharyngeal cancer after treatment with radiation therapy predicts outcome ( 149 ). Modification of adjuvant therapy based on post-treatment EBV DNA levels is currently being explored in a prospective trial (NCT02135042). Based on recent advances in ctDNA detection technologies that focus on somatic mutations instead of viral DNA, similar approaches could likely be extended to most other cancers ( 150 ).

Identification of biomarkers that can predict outcomes prior to initiating radiation therapy will be an important advance. However, no single biomarker approach will likely achieve this goal; therefore, combination biomarkers that include measuring multiple analytes should be explored. Two such developing strategies include genomic-adjusted radiation dose (GARD) ( 151 ) and Post-Operative Radiation Therapy Outcomes Score (PORTOS) ( 152 ). Such gene expression–based platforms may be able to personalize radiotherapy tumor dose or the need for postoperative radiation. Biomarker studies will need to be performed rigorously and should adhere to “best practices” guidelines such as STARD and REMARK ( 153 , 154 ). Any predictive biomarker that is discovered will need to be validated in independent cohorts. Finally, the most rapid progress in this field will likely be through collaborative efforts and multi-institutional teams. If successful, predictive biomarkers hold the promise to transform both our understanding of radiobiology and the clinical management of patients treated with radiation therapy.

Conclusions

The field of radiobiology has made and continues to make critical contributions to science. To continue this work, challenges to the training and retention of the radiation research workforce and limitations in radiobiology research funding must be overcome. The potential for major advances in radiation research remains high because of the availability of new model systems, genome editing tools, and technology for genome-wide analyses. Decades of research investigating mechanisms of DNA damage response to ionizing radiation are now bearing fruit, with clinical trials combining radiation therapy with radiosensitizers that target these pathways. Continued investment in understanding mechanisms of tumor and normal tissue response to radiation can lead to a new generation of clinical trials to improve the therapeutic ratio of radiotherapy. Already, preclinical studies combining radiation with immunotherapy have led to a large number of clinical trials, which could transform radiation therapy from a local treatment to a treatment employed to achieve systemic tumor elimination. To have maximum impact for individual patients, predictive biomarkers should be identified that enable the rational selection of treatments to combine with radiation therapy. Further research into the radiobiology of tumor metabolism, cancer stem cells, and the tumor microenvironment has the potential to translate current knowledge and future gains to the clinic. Future investment by academic radiation oncology departments, professional societies, the NCI, and other biomedical research funding groups will ensure that the radiation research enterprise remains vibrant as a key contributor to increasing basic science knowledge and improving the outcomes of cancer patients.

The workshop, which is summarized in this manuscript, was supported by the National Cancer Institute (NCI). We acknowledge grant support from the NCI: 1R35CA197616 to DGK, R01CA188298 to MD, R01CA163895 to MAM, R01CA181745 to JKS, R01CA201246 to SD, 5R01NS091620 to DHK, and R01CA157490 to ACK. HW is supported by the American Cancer Society 123420RSG-12-224-01-DMC, and GSH is supported by a Clinician Scientist Grant C34326/A19590.

Authors: David G. Kirsch, Max Diehn, Aparna H. Kesarwala, Amit Maity, Meredith A. Morgan, Julie K. Schwarz, Robert Bristow, Sandra Demaria, Iris Eke, Robert J. Griffin, Daphne Haas-Kogan, Geoff S. Higgins, Alec C. Kimmelman, Randall J. Kimple, Isabelle M. Lombaert, Li Ma, Brian Marples, Frank Pajonk, Catherine C. Park, Dörthe Schaue, Phuoc T. Tran, Henning Willers, Brad G. Wouters, Eric J. Bernhard

Affiliations of authors: Department of Radiation Oncology and Department of Pharmacology and Cancer Biology, Duke University Medical Center, Durham, NC (DGK); Department of Radiation Oncology, Stanford Cancer Institute, and Institute for Stem Cell Biology and Regenerative Medicine, Stanford University School of Medicine, Stanford, CA (MD); Radiation Oncology Branch (AHK, IE) and Radiation Research Program, Division of Cancer Treatment and Diagnosis (EJB), National Cancer Institute, National Institutes of Health, Bethesda, MD; Department of Radiation Oncology Perelman School of Medicine, University of Pennsylvania, Philadelphia, PA (AM); Department of Radiation Oncology (MAM) and Department of Biologic and Materials Sciences, Biointerfaces Institute, School of Dentistry (IML), University of Michigan, Ann Arbor, MI; Department of Radiation Oncology, Washington University School of Medicine, St. Louis, MO (JKS); Department of Radiation Oncology (RB), Princess Margaret Cancer Center (BGW), Toronto, ON, Canada; Department of Radiation Oncology and Department of Pathology and Laboratory Medicine, Weill Cornell Medical College, New York, NY (SD); Department of Radiation Oncology, University of Arkansas for Medical Sciences, Little Rock, AR (RJG); Department of Radiation Oncology, Harvard Medical School, Dana-Farber Cancer Institute, Brigham and Women's Hospital, Boston Children's Hospital, Boston, MA (DHK); Department of Oncology, University of Oxford, Oxford, Oxfordshire, UK (GSH); Perlmutter Cancer Center and Department of Radiation Oncology, New York University Langone Medical Center, New York, NY (ACK); Department of Human Oncology, University of Wisconsin School of Medicine and Public Health, Madison, WI (RJK); Department of Experimental Radiation Oncology, The University of Texas MD Anderson Cancer Center, Houston, TX (LM); Department of Radiation Oncology, University of Miami, Miami, FL (BM); Division of Molecular and Cellular Oncology (DS), Department of Radiation Oncology (FP), David Geffen School of Medicine, University of California, Los Angeles, CA; Department of Radiation Oncology, Helen Diller Family Comprehensive Cancer Center, University of California, San Francisco, CA (CCP); Department of Radiation Oncology and Molecular Radiation Sciences, Oncology and Urology, Johns Hopkins University School of Medicine, Baltimore, MD (PTT); Department of Radiation Oncology, Massachusetts General Hospital and Harvard Medical School, Boston, MA (HW); Departments of Radiation Oncology and Medical Biophysics, University Health Network, Toronto, ON, Canada (BGW).

The sponsor and funders had no role in the writing of the review or decision to submit it for publication.

We thank two anonymous reviewers and the associate editor for their valuable comments and suggestions.

Disclosures: David G. Kirsch is on the Scientific Advisory Board of Lumicell, Inc., owns stock in Lumicell, and receives royalty payments for a patent on an imaging device, is a co-founder and has financial interests in XRAD Therapeutics, which is developing radiosensitizers, and has received grant support to his institution to support lab research from GlaxoSmithKline, Janssen, and XRAD Therapeutics, and to support a clinical trial from Merck. Max Diehn is a consultant for Roche, is a co-founder and has financial interests in CiberMed, Inc., has received grant support to his institution from Varian Medical Systems and Sanofi Genzyme to support clinical trials, and is an inventor on patents pertaining to cancer treatment resistance mechanisms and cancer biomarkers. Amit Maity has received a grant from Merck to his institution to support a clinical trial. Robert Bristow has received grants to his institution to support lab research from GenomeDx and AstraZeneca. Sandra Demaria has received a grant to her institution to support lab research and honorariums from Lytix Biopharma. She also received honorariums as a scientific advisor from Eisai, Inc., Nanobiotix, and EMD Serono. Robert J. Griffin has received grants from Pinnacle Biologics to develop photosensitizers, Graphitic Nano Onions, LLC, to develop radiation-modulating carbon agents, and is an inventor on patents related to Calithera Biosciences compounds that block glutaminase and radiosensitize tumors. Daphne Haas-Kogan is on the Scientific Advisory Board of Cellworks. Geoff S. Higgins is on the Radiotherapy Advisory Board for Artios Pharma Limited. Alec C. Kimmelman has financial interests in Vescor Therapeutics, LLC, is an inventor on patents pertaining to Kras regulated metabolic pathways, redox control pathways in pancreatic cancer, targeting GOT1 as a therapeutic approach, and the autophagic control of iron metabolism, and is on the Scientific Advisory Board of Cornerstone Pharmaceuticals. Randall J. Kimple has received research support to his institution to support lab research from Threshold Pharmaceutical and Peloton Therapeutics. Catherine C. Park is a co-founder and owns stock in Oncosynergy, Ltd. Phuoc T. Tran has been on Medical Advisory Boards for GenomeDx Biosciences, Medivation Inc-Astellas Pharma Inc., Regeneron Pharmaceuticals, Dendreon Pharmaceuticals, Inc., and RefleXion Medical, has received grants from Medivation Inc-Astellas Pharma Inc., has had travel paid by RefleXion Medical and Dendreon Pharmaceuticals, Inc., and has a patent for Compounds and Methods of Use in Ablative Radiotherapy. Bradly G. Wouters is a founder and consultant to Northern Biologics, owns stock in Northern Biologics, and has received funding to his institution to support lab research from Pfizer. Aparna H. Kesarwala and Eric J. Bernhard are employed by the government (NCI).

Supplementary Material

Supplementary data.

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For 20 undergraduate students at USC, stem cell research is more than the topic of a lecture or an article in a textbook. It’s the focus of a comprehensive two-year program designed to prepare juniors and seniors for careers in stem cell biology and regenerative medicine.

Known as USC COMPASS: Creating Opportunities through Mentorship and Partnership Across Stem Cell Science, the program launched in summer 2023 as a multidisciplinary collaboration among three USC schools: the Keck School of Medicine, the Viterbi School of Engineering, and the Dornsife College of Arts, Letters, and Sciences.

The program is supported by a $2.9 million grant from the California Institute for Regenerative Medicine (CIRM) , the voter-created state agency that distributes public funding to support stem cell research and education. CIRM established a total of 16 COMPASS programs, including several at University of California, California State University, and community college campuses. USC is the only private research university to host a COMPASS program.

“A major goal of the program is to increase diversity in the field of stem cell biology and regenerative medicine,” said USC COMPASS Program Director Senta Georgia , a principal investigator at the Center for Endocrinology, Diabetes, and Metabolism at Children’s Hospital Los Angeles, and an assistant professor of pediatrics and stem cell biology and regenerative medicine at USC.

“We want COMPASS to point the way to stem cell careers for undergraduates with a variety of backgrounds and experiences, and who may have encountered previous barriers to success,” said USC COMPASS Program Co-director Francesca Mariani , an associate professor of stem cell biology and regenerative medicine, and integrative anatomical sciences.

The program starts with a four-week summer “boot camp,” which provides an immediate opportunity to learn on hands-on laboratory techniques, develop academic and career skills, and bond with their cohort.

“I’ve never been in a research lab before, so I was nervous about how my first experience would be in a lab,” said Brandon Barnes, a human biology major with a minor in health administration. “But it’s a really guided approach and teaches you a lot of information and a lot of lab techniques pretty quickly. The second day we were here, we came straight into the lab and did some small things with pipetting. And once we started pipetting more, we got straight into working with mouse embryonic stem cells, and that was the coolest thing.”

After completing the boot camp, the students match with research laboratories, where they spend the remainder of the first summer and continue to work for 10 hours per week during junior year.

“Over that summer, when we were deciding which labs we want to work with or what we want to focus on, it was the first time that I was actually able to consider what type of research I want to do, rather than being desperate to just get into a research lab and have those qualifications,” said Chris Young, a biological sciences major pursuing a progressive master’s degree in stem cell biology and regenerative medicine. “So I would say COMPASS gave me the confidence and the ability to actually start thinking about what I want to do, and it’s providing me the tools for how to achieve those things. I feel like I’ve gained confidence as a researcher and as a student. This is probably the best decision I made in college, being a part of COMPASS.”

During their senior years, students can choose to continue these laboratory research internships, or to explore other stem cell-related interests. For example, students can spend the second summer interning at biotech companies, or can commit their entire second year to training experience in USC’s cell manufacturing facility.

During their junior and senior years, COMPASS students also pursue 12 units of required course work and electives, which partially meet the requirements for a minor in stem cell biology and regenerative medicine.

In addition, the students conduct bioinformatics or bioengineering projects, capstone projects culminating in a public symposium, and community outreach projects.

The students also participate in workshops and seminars covering topics ranging from research ethics to laboratory skills to imposter syndrome. Guest speakers from a variety of industries also share their career paths and advice.

“In this program, I was genuinely surprised by how multifaceted being a researcher is,” said Henry Le, a human biology major. “Being a researcher is not only about knowing the science, but also about learning to become a leader. It’s about being a person who is high-integrity and a person who is able to communicate science effectively and translate that into the real world. And in so in many ways, being trained as a researcher prepares you for all aspects of your life.”

To guide the students through these experiences and to prepare them for the next steps in their academic and professional careers, the program relies on a strong network of academic and professional mentors. USC faculty or staff provide one-on-one mentorship, and external mentors from the biotech industry offer additional guidance.

“Having so many different mentors and different avenues of support has been really beneficial to me,” said Maddie Pierce, a biomedical engineering major pursuing a progressive master’s degree in medical device and diagnostic engineering. “I’m a first-generation student, so I really appreciate any insight into what I can do with my future. COMPASS exposed me to a lot that I probably wouldn’t have had the opportunity to know about if I wasn’t in the program.”

While participating in COMPASS, the students earn summer stipends, academic year stipends, and a tuition credits to offset their living and educational expenses. This allows them to concentrate on developing themselves as researchers, without the pressure to find additional employment to support themselves.

In summer 2025 and summer 2026, the USC COMPASS program will welcome two additional cohorts of 10 rising juniors and incoming transfer students. To continue in summer 2027, the program will require either a renewal of CIRM funding or philanthropic support.

“For many of our undergraduate students, the COMPASS program has been completely lifechanging,” said Charles (Chuck) Murry, Chair of the Department of Stem Cell Biology and Regenerative Medicine, and Director of the Eli and Edythe Broad Center for Regenerative Medicine and Stem Cell Research. “We’re grateful to CIRM for their vision and partnership in opening this pathway to success for USC’s talented and diverse undergraduates, who are poised to become tomorrow’s leaders in regenerative medicine.”

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Basic Information

Major professional backgrounds, educational backgrounds, academic degrees.

• In Charge of Education
• In Charge of Primary Major Programjs

Research Fields

Research keywords, affiliated academic societies, educational activity.

• Courses in Charge

Research Activities

Academic papers, publications such as books, invited lecture, oral presentation, poster presentation, external funds, acceptance results of competitive funds, social activities, history as committee members, organizing academic conferences, etc., history as peer reviews of academic papers, nobuyuki hirohashi.

Last Updated :2024/09/02

• 1993/04/01, 1995/05/31, The University of Kansas
• 1995/06/01, 1997/04/30, Kurume University, Research Associate
• 1997/04/01, 1999/03/31, Professor
• 1999/04/01, 2005/03/31, Kurume University, Lecturer
• 2005/04/01, 2005/07/31, St. Marianna University School of Medicine, Researcher
• 2005/08/01, 2006/10/31, Kurume University, Lecturer
• 2006/11/01, 2007/03/31, Kurume University, Associate Professor
• 2007/04/01, 2012/03/31, Hiroshima University, Graduate School of Biomedical Sciences, Associate Professor
• 2012/04/01, 2017/01/31, Hiroshima University, Institute of Biomedical & Health Sciences, Associate Professor
• 2017/02/01, Hiroshima University, Research Institute for Radiation Biology and Medicine, Professor
• Kurume University, Japan, 1989/04, 1993/03
• Kurume University, Japan, 1983/04, 1989/03
• Doctor of Philosophy in Medical Science, Kurume University
• [Bachelor Degree Program] School of Medicine : Program of Medicine : Medicine
• [Master's Program] Graduate School of Biomedical and Health Sciences : Division of Integrated Health Sciences : Program of Biomedical Science
• [Doctoral Program] Graduate School of Biomedical and Health Sciences : Division of Integrated Health Sciences : Program of Biomedical Science
• [Doctoral Program] Graduate School of Biomedical and Health Sciences : Division of Biomedical Sciences : Program of Radiation Biology and Medicine

In Charge of Primary Major Programs

• Medicine,dentistry, and pharmacy;Clinical surgery;Emergency medicine
• EMERGENCY MEDICINE RADIATION DISASTER MEDICINE CRITICAL CARE MEDICINE ACUTE MEDICINE AEROMEDICAL SERVICES BLOOD PURIFICATION IN CRUTICAL CARE
• Japanese Association for Acute Medicine, 1989/06
• Japanese Society for Emergency Medicine, 1998/06
• Japan Society for Blood Purification in Criticsl Care, 1997/06
• Japanese Society of Intensive Care Medicine, 1999/04
• Japanese Asoociation for the Surgery of Trauma, 1997/06
• Japanese Society for Aeromedical Services, 2003/10
• Japanese Society of Clinical Toxicology, 1997/06
• Japanese Society for Burn Injuries, 1997/06
• Japanese Society for Abdominal Emergency Medicine, 1997/06
• Japan Endotoxin Society, 1995/11
• Japan Shock Society, 2007/09
• Society of Critical Care Medicine, 2007/09
• International Endotoxin & Innate Immunity Society, 1994/08
• Japanese Association for Radiation Accident Disaster Medicine, 2013
• The Japanese Radiation Research Society

Course in Charge

• 2024, Undergraduate Education, First Semester, Radiation Biology & Radiation Health Risk Sciences
• 2024, Undergraduate Education, Year, Systemic Disease Control
• 2024, Undergraduate Education, Intensive, Practice for medical research
• 2024, Undergraduate Education, Intensive, Practice of Medicine I
• 2024, Graduate Education (Master's Program) , First Semester, Seminar
• 2024, Graduate Education (Master's Program) , Second Semester, Seminar
• 2024, Graduate Education (Master's Program) , First Semester, Research
• 2024, Graduate Education (Master's Program) , Second Semester, Research
• 2024, Graduate Education (Doctoral Program) , First Semester, Advanced Seminar
• 2024, Graduate Education (Doctoral Program) , Second Semester, Advanced Seminar
• 2024, Graduate Education (Doctoral Program) , First Semester, Advanced Research
• 2024, Graduate Education (Doctoral Program) , Second Semester, Advanced Research
• 2024, Graduate Education (Doctoral Program) , 1Term, Integrated Radiation Medical Science
• 2024, Graduate Education (Doctoral Program) , First Semester, Advanced Seminar on Radiation Medicine
• 2024, Graduate Education (Doctoral Program) , Second Semester, Advanced Seminar on Radiation Medicine
• 2024, Graduate Education (Doctoral Program) , First Semester, Advanced Research on Radiation Medicine
• 2024, Graduate Education (Doctoral Program) , Second Semester, Advanced Research on Radiation Medicine
• 2024, Graduate Education (Doctoral Program) , First Semester, Radiation Disaster Recovery Studies
• 2024, Graduate Education (Doctoral Program) , First Semester, Long-term Fieldwork/Long-term Internship
• 2024, Graduate Education (Doctoral Program) , Second Semester, Long-term Fieldwork/Long-term Internship
• ★, Beyond the unthinkable: Are we prepared for rare disasters?, Anaesth Crit Care Pain Med., 42(4), doi 10.1016/j.accpm.2023.101266., 20230624 Link to Paper Search Results by DOI
• Radiation Emergency Medical Preparedness in Japan: A Survey of Nuclear Emergency Core Hospitals, DISASTER MEDICINE AND PUBLIC HEALTH PREPAREDNESS, 17, 20220207 Link to Paper Search Results by DOI
• Results of the 2018 Japan Society for Blood Purification in Critical Care survey: current status and outcomes, RENAL REPLACEMENT THERAPY, 8(1), 20221112 Link to Paper Search Results by DOI
• p53 status modifies cytotoxic activity of lactoferrin under hypoxic conditions, FRONTIERS IN PHARMACOLOGY, 13, 20220919 Link to Paper Search Results by DOI
• Oncogenic Role of ADAM32 in Hepatoblastoma: A Potential Molecular Target for Therapy, CANCERS, 14(19), 202210 Link to Paper Search Results by DOI
• ★, Low-Dose-Rate Irradiation Suppresses the Expression of Cell Cycle-Related Genes, Resulting in Modification of Sensitivity to Anti-Cancer Drugs, CELLS, 11(3), 202202 Link to Paper Search Results by DOI
• Inhibiting SARS-CoV-2 infection in vitro by suppressing its receptor, angiotensin-converting enzyme 2, via aryl-hydrocarbon receptor signal, SCIENTIFIC REPORTS, 11(1), 20210817 Link to Paper Search Results by DOI
• GLIS1, a novel hypoxia-inducible transcription factor, promotes breast cancer cell motility via activation of WNT5A, CARCINOGENESIS, 41(9), 1184-1194, 20200924 Link to Paper Search Results by DOI
• Simulated microgravity enhances CDDP-induced apoptosis signal via p53-independent mechanisms in cancer cells, PLOS ONE, 14(7), 20190719 Link to Paper Search Results by DOI
• ★, Sera from Septic Patients Contain the Inhibiting Activity of the Extracellular ATP-Dependent Inflammasome Pathway, TOHOKU JOURNAL OF EXPERIMENTAL MEDICINE, 245(3), 193-204, 201807 Link to Paper Search Results by DOI
• Differentiated embryo chondrocyte plays a crucial role in DNA damage response via transcriptional regulation under hypoxic conditions, PLOS ONE, 13(2), 20180221 Link to Paper Search Results by DOI
• ★, Health effects of radiation and other health problems in the aftermath of nuclear accidents, with an emphasis on Fukushima, LANCET, 386(9992), 479-488, 20150801
• Loss of life following evacuation: lessons learned from the Fukushima Daiichi Nuclear Power Plant accident, LANCET, 379, 889-891, 2012
• Estimating the proportion of DMAT members able to act during a radiation disaster through a questionnaire survey in Chu- goku-Shikoku District and Fukushima Prefecture, Japanese Journal of Disaster Medicine, 27(1), 65-74, 20220126
• Comparison of Airway Simulators for the AirwayScope Video-Laryngoscope, Emergency Medicine Investigations, 2, DOI: 10.29011/2475-5605. 000074, 20180309
• Pediatric cardiorespiratory failure successfully managed with venoarterial-venous extracorporeal membrane oxygenation: a case report, BMC PULMONARY MEDICINE, 16, 20160812 Link to Paper Search Results by DOI
• Iwasaki Y, Namera A, Giga H, Kida Y, Ota K, Une K, Otani T, Ohshimo S, Hirohashi N, Tanigawa K: A case of severe puffer fish poisoning: serum tetrodotoxin concentration measurements for 4 days after ingestion J CLIN TOXICOL 5: 226. doi:10.4172/2161-0495.1000226, 2015, J CLIN TOXICOL, 5(226), doi:10.4172/2161-0495.-doi:10.4172/2161-0495., 2015
• Influence of clinical experience of the Macintosh laryngoscope on performance with the Pentax-AWS Airway Scope®, a rigid video-laryngoscope, by paramedics in Japan., J ANESTH, 29(5), 672-677-677, 2015
• A PILOT STUDY: A COMBINED THERAPY USING POLYMYXIN-B HEMOPERFUSION AND EXTRACORPOREAL MEMBRANE OXYGENATION FOR ACUTE EXACERBATION OF INTERSTITIAL PNEUMONIA, SARCOIDOSIS VASCULITIS AND DIFFUSE LUNG DISEASES, 31(4), 343-349, 2014
• Baseline KL-6 predicts increased risk for acute exacerbation of idiopathic pulmonary fibrosis, RESPIRATORY MEDICINE, 108(7), 1031-1039, 201407 Link to Paper Search Results by DOI
• KL-6, a Human MUC1 Mucin, as a prognostic marker for diffuse alveolar hemorrhage syndrome, ORPHANET JOURNAL OF RARE DISEASES, 7, 20121217 Link to Paper Search Results by DOI
• KL-6 concentration in pulmonary epithelial lining fluid is a useful prognostic indicator in patients with acute respiratory distress syndrome, RESPIRATORY RESEARCH, 12, 20110322 Link to Paper Search Results by DOI
• Tracheal Intubation of a Difficult Airway Using Airway Scope, Airtraq, and Macintosh Laryngoscope: A Comparative Manikin Study of Inexperienced Personnel, ANESTHESIA AND ANALGESIA, 110(4), 1049-1055, 201004 Link to Paper Search Results by DOI
• 廣橋 伸之(広島大学 大学院医歯薬保健学研究院応用生命科学部門救急医学) Source：救急医学(0385-8162)39巻5号 Page586-591(2015.05), 39(5), 586-591, 20150501
• Differential Lung Ventilation with Two Endotracheal Tubes for Blunt Tracheal Injury: A Case Report, 44(8), 534-537, 20200810
• 2017/08/14, Critical care neurology, Acute central nervous system infectious disease ( encepharitis, meningitis), encepharitis, meningitis, 2017, 8, Scholarly Book, Joint work, 日本語, 9784260017541, 4260017543, 664
• 2018/01/10, Today's therapy, Acute radiation syndrome, Acute radiation syndrome, 2018, 1, Dictionary/Encyclopedia, Single work, 日本語, Nobuyuki Hirohashi, 9784260032346, 4260032348, 2066
• On site nuclear disaster response and preparedness - On site Medical System Development Committee -, NOBUYUKI HIROHASHI, ARIFUMI HASEGAWA, 17TH REMPAN COORDINATION MEETING, 2023/09/14, With Invitation, English, WHO REMPAN / KIRAMS, Seoul, Korea, 17TH REMPAN COORDINATION MEETING Related URL
• Preparedness for the Coming Radiation Disaster, NOBUYUKI HIROHASHI, TCVGH International Medical Conference In 2023 (Taipei,Taiwan,web), 2023/10/28, With Invitation, English, TCVGH International Medical Conference In 2023 (Taipei,Taiwan,web), Taipei,Taiwan,web, TCVGH International Medical Conference In 2023 (Taipei,Taiwan,web) Related URL
• Overview of the achievements under Phoenix Leader Education Program and other collaborations between the IAEA and Hiroshima University, NOBUYUKI HIROHASHI, Coordination meeting between the IAEA and Hiroshima University on Human Resource Development in the field of Human Health (Hiroshima, Japan), 2023/07/05, With Invitation, English, IAEA/HIROSHIMA UNIVERSITY, HIROSHIMA, Coordination meeting between the IAEA and Hiroshima University on Human Resource Development in the field of Human Health (Hiroshima, Japan)
• Preparedness for the Coming Radiation Disaster - Lessons Learning from Hiroshima and Fukushima -, NOBUYUKI HIROHASHI, 43rd Congress of European Association of Poisons Centres and Clinical Toxicologists, (Mallorca, Spain)., 2023/05/24, With Invitation, English, 43rd Congress of European Association of Poisons Centres and Clinical Toxicologists,, Mallorca, Spain, Preparedness for the Coming Radiation Disaster - Lessons Learning from Hiroshima and Fukushima -, other, 43rd Congress of European Association of Poisons Centres and Clinical Toxicologists Program Related URL , Attached File's URL
• Lesson Learned From Radiation Disaster In Japan, Nonuyuki Hirohashi, The Annual Scientific Meeting of The Disaster Working Group Faculty of Medicine, Public Health and Nursing, Gadjah Mada University (FK-KMK UGM), 2023/03/30, With Invitation, English
• Inhibiting SARS-CoV-2 infection in vitro by suppressing its receptor, ACE2, via aryl-hydrocarbon receptor signal, 2022/06/04, Without Invitation, Japanese
• Significance of up-regulation of the hypoxia-inducible EFEMP2 in cancer cells, Kengo Mekata, Keiji Tanimoto, Daichi Aoki, Takahiro Fukazawa, Nobuyuki Hirohashi, 2021/11/27, Without Invitation, Japanese
• Current Status and Issues of Nuclear Disaster Medical Training in Covid-19 pandemic, Nobuyuki HIROHASHI, Satoshi Yamaga, Masaki Murao Maryami Yuliana Kosim, Kenji Kamiya, Technical Meeting on Radiation in Medicine Communications and Methodologies – International Perspectives and the Role of Science, Technology and Society in Low-Dose Radiation Settings, 2021/11/10, With Invitation, English, IAEA, Hiroshima, web
• Human resource development after Fukushima accident including graduate education, Nobuyuki Hirohashi, Public Health consequences of Fukushima nuclear disaster: 10 years towards recovery WHO REMPAN Webinar Series, 2021/03/23, With Invitation, English, WHO RENPAM, WEB
• New Radiation Emergency Medical System in Japan. - Lessons learned from Fukushima and Hiroshima –, Nobuyuki HIROHASHI, 2019/12/17, Without Invitation, English
• The role of Hiroshima University as the new radiation/nuclear emergency medical support center for the next disaster, A new horizon of radiation health risk science education from the experience of nuclear disaster, Nobuyuki HIROHASHI, 2019/11/14, With Invitation, Japanese
• New Radiation Emergency Medical System in Japan. - Lessons learned from Fukushima and Hiroshima –, Nobuyuki HIROHASHI, 2019/10/28, With Invitation, English
• Code Blue,Black & Yellow - Lessons learned from Fukushima and Hiroshima and More -, Nobuyuki HIROHASHI, Joint meeting(Department of Nursing, U Indonesia and Research Institute for Radiation Biology and Medicine,U Hiroshima), 2019/10/10, With Invitation, English, Department of Nursing, U Indonesia, Depok, Indonesia
• New Radiation Emergency Medical System in Japan.   - Lessons learned from Fukushima and Hiroshima -, Nobuyuki HIROHASHI, 2019/09/02, With Invitation, English
• The role of Hiroshima University as the new radiation/nuclear emergency medical support center for the next disaster., Nobuyuki HIROHASHI, Crisis in Context: Minding the gaps in medical preparedness for a Rad/Nuke Incident The Radiation Injury Treatment Network Workshop, 2019/07/31, With Invitation, English, The Radiation Injury Treatment Network, Arlington, VA,USA, The Radiation Injury Treatment Network seeks to increase the understanding of and pre-paredness for the tremendous medical, environmental, and psychological consequences of a mass casualty radiological/nuclear incident for healthcare professionals. The 2019 RITN workshop will highlight recent developments in resource-constrained environments: (1) optimizing ARS initial assessment and triage, (2) ensuring the availability and appropriate use of medical and psycho-social supportive care, (3) disseminating the latest research in radiation-specific medical countermeasures, (4) applying technology as a force multiplier for care and education, and (5) enhancing collaboration among burn surgeons and RITN professionals. Additionally, the workshop will encourage open sharing of lessons learned from past efforts.
• New Radiation Emergency Medical System in Japan.   - Lessons learned from Fukushima and Hiroshima -, Nobuyuki HIROHASHI, 2019/07/23, Without Invitation, English
• New Radiation Emergency Medical System in Japan. , Nobuyuki HIROHASHI, Discussion were made involving authorities from the government of Mongolia Nuclear Energy Commission, General Agency for Specialized Inspection Regulatory Agency of the Government of Mongolia and Radiation Safety Committee of NCC, about how to train doctors and medical professionals for radiation accident medical response, how to organize medical care pathway., 2019/06/14, With Invitation, English, Radiation Safety Committee of National Cancer Center (NCC) Deputy Prime Minister of Mongolia, Ulaanbaatar, Mongolia, discussion were made involving authorities from the government of Mongolia Nuclear Energy Commission, General Agency for Specialized Inspection Regulatory Agency of the Government of Mongolia and Radiation Safety Committee of NCC, about how to train doctors and medical professionals for radiation accident medical response, how to organize medical care pathway. In this discussion total 20 guests attended: Dr. Hirohashi- Proffessor of Radiation Disaster Medicine Department, Hiroshima University, Toby Lowe- Radiation therapist from St.George Hospital, Australia and representatives from The government of Mongolia Nuclear Energy Commission, General Agency for Specialized Inspection Regulatory Agency of the Government of Mongolia, National Public Health Center and Second General Hospital as well as Radiation Safety Committee of NCC.
• ER(Emergency room) management of Radiation/Nuclear disaster patients, Nobuyuki HIROHASHI, The onsite training, "how to organize emergency response for radiation accident" took place at NCC Conference hall, 2019/06/14, With Invitation, English, Radiation Safety Committee of National Cancer Center (NCC) supported by Deputy Prime Minister of Mongolia, Ulaanbaatar, Mongolia, The onsite training, about how to organize emergency response for radiation accident, took place at NCC Conference hall in the extension building during 09:00 – 12:00, on 14th June 2019 and led by Prof. Hirohashi Nobuyuki. Two radiation accident cases were prepared in advance, in order to show on site medical assistance, including how doctors and nurses should wear the protection suits and undress properly. Total 97 participants from either rural or urban hospitals attended this demonstration training.
• New Radiation Emergency Medical System in Japan - Lessons learned from Fukushima and Hiroshima -, Nobuyuki HIROHASHI, Radiation Accident Prevention and Medical Response, 2019/06/13, With Invitation, English, the Deputy Prime Minister of Mongolia, Radiation Safety Committee of National Cancer Center (NCC), Ulaanbaatar,Mongolia
• NHK Documentary Battling a Radiation Emergency: The Doctors at Fukushima, Nobuyuki HIROHASHI et al., NHK Documentary :Battling a Radiation Emergency: The Doctors at Fukushima, 2019/05/11, With Invitation, Japanese, NHK
• New Radiation Emergency Medical System in Japan. - Lessons learned from Fukushima and Hiroshima -, Nobuyuki HIROHASHI, HICARE SEMINAR, 2018/10/23, With Invitation, English, John A.Burns School of Medicine, University of Hawaii HICARE, Hawaii, USA
• New Radiation Emergency Medical System in Japan.   - Lessons learned from Fukushima and Hiroshima -, Nobuyuki HIROHASHI, HICARE special seminar, 2018/10/22, With Invitation, English, Kuwakini Medical Center,HICARE, Hawaii, USA.
• The role of Hiroshima University as the new radiation/nuclear emergency medical support center on communicating radiation/nuclear emergencies to the public, Nobuyuki HIROHASHI, Kenji Kamiya, International Symposium on Communicating Nuclear and Radiological Emergencies to the Public, 2018/10/04, Without Invitation, English, IAEA, IAEA Headquarters Vienna, Austria
• New Radiation Emergency Medical System in Japan.   - Lessons learned from Fukushima and Hiroshima -, Nobuyuki HIROHASHI, REAC/TS Advanced Radiation Medicine course, 2018/08/15, With Invitation, English, REAC/TS, Oak Ridge, TN, USA
• Radiation/Nuclear Emergency Medical System, NOBUYUKI HIROHASHI, Kick-off Seminar between Soochow University and Hiroshima University, 2018/04/24, Without Invitation, English, Hiroshima University, Soochow University, Hiroshima
• ER(Emergency room) management of Radiation/Nuclear disaster patients, NOBUYUKI HIROHASHI, HICARE INTERNATIONAL TRAINING COURSE on Medical Responses to Radiation Accidents and Disasters, 2018/02/20, Without Invitation, English, HICARE, HIROSHIMA, published
• Emergency medical response to radiation and nuclear accidents:Drill, NOBUYUKI HIROHASHI, Emergency Radiation Medicine Promoting Center, Hiroshima University, HICARE INTERNATIONAL TRAINIG COURSE on Medical Responses to Radiation Accidents and Disasters, 2018/02/20, Without Invitation, English, HICARE, HIROSHIMA, published
• Consultancy meeting on STS education support on return in the context of low-dose radiation, Nobuyuki HIROHASHI, Consultancy meeting on STS education support on return in the context of low-dose radiation, 2018/01/15, With Invitation, English, IAEA, FUKUSHIMA MEDICAL UNIVERSITY, FUKUSHIMA,JAPAN
• Immediate post-accident response, NOBUYUKI HIROHASHI, Consulting meeting on review and future of science and technology studies(STS) Curriculum in Japan, 2017/08/29, With Invitation, English, Consulting meeting on review and future of science and technology studies(STS) Curriculum in Japan, FUKUSHIMA,JAPAN, published
• Detection of suppressive activity on innate immune DAMPs response in sepsis, 2016/02/13, Without Invitation, English
• Loss of life after evacuation: lessons learned from the Fukushima accident Roles of DMAT and Hiroshima University Hospital in the management of nuclear catastrophe, Hirohashi N, INU(The International Network of Universities)nursing summer workshop, 2015/08/08, With Invitation, English
• Technical Meeting on Communication on Low-Dose Radiation – the Role of Science, Technology and Society, Nobuyuki HIROHASHI(Chair Person), Technical Meeting on Communication on Low-Dose Radiation – the Role of Science, Technology and Society, With Invitation, English, IAEA/FMU, FUKUSHIMA
• New Radiation Emergency Medical System in Japan.   - Lessons learned from Fukushima and Hiroshima -, Nobuyuki HIROHASHI, Without Invitation, Japanese
• KAKENHI, Prevention of multiple organ dysfunction syndrome by modulation of the expression of endotoxin receptors (TLR4,RP105) on PBMC, 2003, 2004 Permalink
• KAKENHI, 2001, 2002 Permalink
• KAKENHI, 1998, 1999 Permalink
• KAKENHI, 1995, 1995 Permalink
• SHAMISEN STAKEHOLDER MEETING MEMBER, 2017/03/23, 2017/03/24
• IAEA/HICARE INTERNATIONAL TRAINING COURSE on Medical Responses to Radiation Accidents and Disasters, Course coordinator, 2024/01, 2024/01 Permalink
• The 7th International Symposium of the Network-type Joint Usage/Research Center for Radiation Disaster Medical Science, 2023/02, 2023/02
• 2022/11, 2022/11
• 2020/09, 2020/09
• 2022, Journal of Radiation Research, Others, reviewer, 1
• 2021, Acute Medicine & Surgery, Others, 1
• 2021, Journal of Radiation Research, Others, Reviewer, 2
• 2020, Journal of Radiation Research, Others, 4
• 2015, Associate Editor, Acute Medicine & Surgery, Others, 1
• 2016, Associate Editor, Acute Medicine & Surgery, Others
• 2018, Acute Medicine & Surgery, Others, associate editor

• Hiroshima University