Armed Forces Radiobiology Research Institute

Last updated

Armed Forces Radiobiology Research Institute (AFRRI)
Armed Forces Radiobiology Research Institute (USA) - logo.png
Agency overview
FormedMay 12, 1961;61 years ago (May 12, 1961) [1]
Jurisdiction Federal military research institution
Headquarters4301 Jones Bridge Road, Bethesda, Maryland, USA
38°59′5″N77°5′41″W / 38.98472°N 77.09472°W / 38.98472; -77.09472
Annual budget$27.1 million (FY2014) [1]
Agency executives
  • Col. Dr. Mohammed Naeem, Director [2]
  • Unknown, Deputy Director [1]
  • Unknown, Scientific Director [1]
Parent department United States Department of Defense
Parent agency Office of the Secretary of Defense (1961-1964), Defense Atomic Support Agency (1964-1971), Defense Nuclear Agency (DASA successor, now DTRA) (1971-1993), Uniformed Services University of the Health Sciences (1993-present)
Website AFRRI

The Armed Forces Radiobiology Research Institute (AFRRI) is an American triservice research laboratory in Bethesda, Maryland chartered by Congress in 1960 and formally established in 1961. [1] It conducts research in the field of radiobiology and related matters which are essential to the operational and medical support of the U.S. Department of Defense (DoD) and the U.S. military services. AFRRI provides services and performs cooperative research with other federal and civilian agencies and institutions.

Contents

History

Department of Defense (DoD) interest in the health effects of exposure to radiological agents (radiobiology), born in the wake of the Manhattan Project, motivated a 1958 Bureau of Medicine and Surgery proposal that a bionuclear research facility be established to study such issues. On June 8, 1960, Public Law 86-500 authorized the construction of such a facility, including a laboratory and vivarium under the Defense Atomic Support Agency (DASA, now the Defense Threat Reduction Agency (DTRA)); on December 2, 1960, DASA and the surgeons general of the Army, Navy, and Air Force approved a charter for the Armed Forces Radiobiology Research Institute (AFFRI). The institute was formally established on May 12, 1961, by DoD Directive 5154.16 as a joint agency of the Army, Navy, and Air Force under the command and administrative control of the Office of the Secretary of Defense (OSD). [1] [3]

Research at AFRRI began in January 1962, although the laboratory became fully operational only in September 1963. AFFRI included a Training, Research, Isotopes, General Atomics (TRIGA) Mark F nuclear reactor (uniquely allowing studies of nuclear weapon radiation characteristics facilities), laboratory space, and an animal facility. A high-dose cobalt-60 facility, 54-megaelectron volt (54,000,000 electron volt) linear accelerator (LINAC), and low-level cobalt-60 irradiation facility were later added. [1] [3]

In July 1964, AFRRI was moved to DASA, and the Chief of DASA became ex officio chair of AFRRI's Board of Governors. While nominally an operational field element of DASA, AFFRI functioned largely independently. In the 1960s, the institute's research was partitioned into five departments: Experimental Pathology, Behavioral Sciences, Physical Sciences, Chemistry, and Radiation Biology; it also focused on biological responses, with an emphasis on high doses of external radiation. AFRRI conducted animal testing to determine the effects of radiation doses and opened collaborations with universities, government agencies, and corporations. [1]

In 1971, DASA ceased to exist and AFRRI passed to its successor, the Defense Nuclear Agency (later DTRA). To address growing DOD concerns about the correlation between radiation presence and cancer in service members, AFRRI helped establish the Nuclear Test Personnel Review (NTPR) program in January 1978. NTPR-which still operates today-estimated the absorbed radiation dose of veterans who participated in U.S. atmospheric nuclear tests or the postwar occupations of Hiroshima and Nagasaki immediately after the atomic bombings and determined monetary compensation for long-term radiation-related illnesses accordingly. AFFRI's experience and expertise in nuclear accidents, hazardous materials, and radiological cleanup issues was later leveraged during AFRRI's joining of the International Chernobyl Site Restoration Assistance Team, which responded to the 1986 Chernobyl disaster. AFFRI later assisted environmental cleanup efforts Semipatatinck Soviet nuclear test site in modern Kazakhstan. [1] The late-70s saw AFRRI greatly increase its biomedical staff to address military radiation injury concerns. [3]

The Defense Nuclear Agency transferred control of AFRRI to the Uniformed Services University of the Health Sciences (USUHS) in 1993. The end of the Cold War saw AFRRI's funding and personnel levels diminish and its termination proposed. However, the lack of alternative research institutions led to military leaders' decision to keep AFRRI operational. American interest in nuclear preparedness resurged in the late-1990s as India and Pakistan developed and tested nuclear weapons and suspicions grew that Iraq and North Korea sought to do the same. As private companies lacked the incentive to develop radioprotectants (drugs protecting against radiation damage) and countermeasures for the military, funding for AFRRI was increased in 2000. [1]

Post-9/11 fears of terrorist threats also stimulated support for AFFRI. The attacks helped expand AFRRI's scope of work to include minimizing the effects of radiological dispersal devices (i.e. dirty bombs), terrorist access to radiation sources, and sabotage of nuclear reactors. Despite this, AFRRI remained limited by a lack of proper funding, facilities, and personnel. Extra support granted in 2003 and 2004 allowed for infrastructural upgrades and the development of a radioprotective drug, 5-androstenediol. [1] [3]

As of the 2010s and 2020s, AFRRI is DOD's only medical research and development initiative dedicated to nuclear and radiological defense. It serves the military by performing medical research and development, education, and advisory and consultative functions to increase understanding of the effects and risks of ionizing radiation. [1]

Mission

AFRRI is charged with executing DoD's Medical Radiological Defense Research Program. Its civilian and active duty military personnel conduct exploratory and developmental research to identify and develop medical countermeasures against ionizing radiation. Core areas of study include prevention, assessment, and treatment of radiological injuries. The program seeks to develop prophylactic (disease preventing) and therapeutic drugs, such as Ex-Rad, that prevent and treat radiation injuries and to develop rapid high-precision analytical methods that assess radiation exposure doses from clinical samples and thus aid in the triage and medical management of radiological casualties. New drug candidates and biological dose assessment technologies are developed up to and through preclinical testing and evaluation.

Primary research areas of the Institute include biodosimetry, combined injury (radiation with other medical insults), internal contamination and metal toxicity, medical countermeasure development, animal welfare, assessment of radiation injury, and radiation facilities. [1] [4]

Research Mission

AFRRI's research focuses on its goals to:

Responsibilities

AFRRI is charged with the following:

Organization

AFRRI is a joint entity of the three military departments and is subject to the authority and direction of the president of the Uniformed Services University of the Health Sciences (USU), Assistant Secretary of Defense for Health Affairs, and Under Secretary of Defense for Personnel and Readiness. The institute is led by a Director and Scientific Director. [1]

Director

The director of the Armed Forces Radiobiology Research Institute is appointed by the surgeons general of the Army, Navy, and Air Force to a four-year term. Additionally, the director must hold a doctoral degree in the life sciences and be a military officer. It is the director's responsibility to act as liaison to the heads of DoD's components and other governmental and nongovernmental agencies and to ensure that other DoD components are appraised of AFRRI's activities. All directors have been captains or colonels. [1] The current director is Col. Dr. Mohammed Naeem as of August 2021. [2] [6]

Subordinate to the director are a deputy director, secretary, scientific advisor, radiation safety officer, director for administration, senior enlisted advisor, and chief of staff (overseeing a chief of finance and deputy chief of staff). [1]

Scientific Director

AFRRI's scientific director exercises scientific leadership and the administration and supervision of the institute's research-oriented departments and the overall scientific and technical planning of the research program. He or she also serves as the scientific liaison to outside entities. There is also a scientific advisor who counsels the director and acts as a liaison with outside agencies but is not a part of the chain of command. Generally, scientific directors are civilian Ph.D.-holders. [1]

Board of Governors

AFRRI's Board of Governors, which once meet at least once every year, comprises the following members:

Departments

As of 2014, AFRRI comprised the following departments, each headed by a department head or manager:

Research components

AFFRI subdivides its laboratory research program into four area-specific laboratories and one center [4] discussed in length in this page's Laboratories, center, and equipment section.

Outreach and support education components

AFFRI's Military Medical Operations (MMO) Team, staffed by health physicists and radiation trained physicians, exists to apply and make useful AFRRI's research. Education outreach is provided by the Medical Effects of Ionizing Radiation (MEIR) Course and operational support by the Medical Radiobiology Advisory Team (MRAT), both available at all times to assist with radiation education or provide emergency advice. [7]

Medical Effects of Ionizing Radiation (MEIR) Course

The MEIR Course is a post-graduate instructional course concerning the biomedical consequences of radiation exposure, how the effects can be reduced, and how to medically manage casualties. The training includes combat and noncombat and weapon and non-weapons nuclear incidents. Main focuses include health physics, biological effects of radiation, medical/health effects, and psychological effects. [8]

MEIR Courses are three-days in length and conducted at major U.S. military bases worldwide; intended students are military medical personnel such as physicians, nurses, medical planners, and first responders. [8]

Medical Radiobiology Advisory Team (MRAT)

MRAT provides health physics, medical, and radiobiological advice to military and civilian command and control operations worldwide in response to nuclear and radiological incidents requiring coordinated federal responses. [9]

MRATs are deployable team responsible for providing expert advice to incident commanders and staff during radiological incident. Each MRAT is a two-person team, usually consisting of one health physicist and one physician, both specializing in the health effects of radiation, biodosimetry, and treatment of radiation casualties. [10] Through what the AFRRI terms "reachback," deployed MRAT responders can call on the knowledge and skills of radiobiologists, biodosimetrists, and other research professionals at AFRRI and other Department of Defense response teams. [9]

Other

AFRRI has a Radiation Biodosimetry Division. [5] Additionally, AFRRI publishes various guidebooks and manuals regarding nuclear accident response and treatment, [11] as well as journal articles, books, and scientific and technical reports. [1]

Facilities and infrastructure

Headquarters

Construction at AFRRI's main headquarters/facility in Bethesda, Maryland began in November 1960, preceding the organization's official charter and establishment dates. It was occupied by January 1962 and fully operational by November 1963. Facilities include a Training, Research, Isotopes, General Atomics (TRIGA) nuclear reactor, laboratory space, an animal facility. a high-dose cobalt-60 facility, a 54-megaelectron volt linear accelerator (LINAC), and a low-level cobalt-60 irradiation facility. [1] [3]

AFRRI's Bethesda TRIGA reactor is still operational and has a power level of 1,100 kW. [12]

TRIGA NRC violation

An April 2019 followup investigation by the Nuclear Regulatory Commission, which oversees nuclear facilities such as those operated by AFRRI, found a Severity Level IV violation. [13]

Laboratories, center, and equipment

AFRRI is a fully equipped research facility capable of state of the art molecular, cellular, microbiology, genetic and biochemical research. Its four laboratories and one center are:

Awards, recognition, and accomplishments

In 2004, AFRRI was awarded the Joint Meritorious Unit Award for "exceptionally meritorious achievements" between September 11, 2001, and February 17, 2004, in response to acts of terrorism and nuclear/radiological threats worldwide. [14] [15]

In August 2009, the American Nuclear Society designated AFRRI a nuclear historic landmark as the U.S.'s primary source of medical nuclear and radiological research, preparedness, and training. [14]

AFRRI has contributed significantly to the development of Amifostine, Neupogen, Neulasta, Nplate, and Leukine, a series of drugs treating or preventing radiation injuries. [14]

Related Research Articles

Background radiation is a measure of the level of ionizing radiation present in the environment at a particular location which is not due to deliberate introduction of radiation sources.

<span class="mw-page-title-main">Acute radiation syndrome</span> Health problems caused by exposure to high levels of ionizing radiation

Acute radiation syndrome (ARS), also known as radiation sickness or radiation poisoning, is a collection of health effects that are caused by being exposed to high amounts of ionizing radiation in a short period of time. Symptoms can start within an hour of exposure, and can last for several months. Early symptoms are usually nausea, vomiting and loss of appetite. In the following hours or weeks, initial symptoms may appear to improve, before the development of additional symptoms, after which either recovery or death follow.

Ionizing radiation, including nuclear radiation, consists of subatomic particles or electromagnetic waves that have sufficient energy to ionize atoms or molecules by detaching electrons from them. Some particles can travel up to 99% of the speed of light, and the electromagnetic waves are on the high-energy portion of the electromagnetic spectrum.

Medical physics deals with the application of the concepts and methods of physics to the prevention, diagnosis and treatment of human diseases with a specific goal of improving human health and well-being. Since 2008, medical physics has been included as a health profession according to International Standard Classification of Occupation of the International Labour Organization.

<span class="mw-page-title-main">Health physics</span>

Health physics, also referred to as the science of radiation protection, is the profession devoted to protecting people and their environment from potential radiation hazards, while making it possible to enjoy the beneficial uses of radiation. Health physicists normally require a four-year bachelor’s degree and qualifying experience that demonstrates a professional knowledge of the theory and application of radiation protection principles and closely related sciences. Health physicists principally work at facilities where radionuclides or other sources of ionizing radiation are used or produced; these include research, industry, education, medical facilities, nuclear power, military, environmental protection, enforcement of government regulations, and decontamination and decommissioning—the combination of education and experience for health physicists depends on the specific field in which the health physicist is engaged.

The roentgen equivalent man (rem) is a CGS unit of equivalent dose, effective dose, and committed dose, which are dose measures used to estimate potential health effects of low levels of ionizing radiation on the human body.

<span class="mw-page-title-main">Linear no-threshold model</span> Deprecated model predicting health effects of radiation

The linear no-threshold model (LNT) is a dose-response model used in radiation protection to estimate stochastic health effects such as radiation-induced cancer, genetic mutations and teratogenic effects on the human body due to exposure to ionizing radiation. The model statistically extrapolates effects of radiation from very high doses into very low doses, where no biological effects may be observed. The LNT model lies at a foundation of a postulate that all exposure to ionizing radiation is harmful, regardless of how low the dose is, and that the effect is cumulative over lifetime.

The National Radiological Protection Board (NRPB) was a public authority in the UK created by the Radiological Protection Act 1970. Its statutory functions were to conduct research on radiological protection and provide advice and information on the subject to Government Departments and others. It was also authorized to provide technical services and charge for them. Originally NRPB dealt only with ionizing radiation, but its functions were extended in 1974 to non-ionizing radiation.

<span class="mw-page-title-main">Project 4.1</span> Radioactive fallout exposure study and experiment

Project 4.1 was the designation for a medical study and experimentation conducted by the United States of those residents of the Marshall Islands exposed to radioactive fallout from the March 1, 1954 Castle Bravo nuclear test at Bikini Atoll, which had an unexpectedly large yield. Government and mainstream historical sources point to the study being organized on March 6 or March 7, 1954, six days after the Bravo shot.

Radiobiology is a field of clinical and basic medical sciences that involves the study of the action of ionizing radiation on living things, especially health effects of radiation. Ionizing radiation is generally harmful and potentially lethal to living things but can have health benefits in radiation therapy for the treatment of cancer and thyrotoxicosis. Its most common impact is the induction of cancer with a latent period of years or decades after exposure. High doses can cause visually dramatic radiation burns, and/or rapid fatality through acute radiation syndrome. Controlled doses are used for medical imaging and radiotherapy.

David A. Schauer, ScD, CHP, is Executive Director Emeritus of the National Council on Radiation Protection and Measurements (NCRP). During his tenure a number of updated and new publications were issued by the Council.

<span class="mw-page-title-main">Radiation dose reconstruction</span>

Radiation dose reconstruction refers to the process of estimating radiation doses that were received by individuals or populations in the past as a result of particular exposure situations of concern. The basic principle of radiation dose reconstruction is to characterize the radiation environment to which individuals have been exposed using available information. In cases where radiation exposures can not be fully characterized based on available data, default values based on reasonable scientific assumptions can be used as substitutes. The extent to which the default values are used depends on the purpose of the reconstruction(s) being undertaken.

<span class="mw-page-title-main">Orders of magnitude (radiation)</span>

Recognized effects of higher acute radiation doses are described in more detail in the article on radiation poisoning. Although the International System of Units (SI) defines the sievert (Sv) as the unit of radiation dose equivalent, chronic radiation levels and standards are still often given in units of millirems (mrem), where 1 mrem equals 1/1000 of a rem and 1 rem equals 0.01 Sv. Light radiation sickness begins at about 50–100 rad.

Exposure to ionizing radiation is known to increase the future incidence of cancer, particularly leukemia. The mechanism by which this occurs is well understood, but quantitative models predicting the level of risk remain controversial. The most widely accepted model posits that the incidence of cancers due to ionizing radiation increases linearly with effective radiation dose at a rate of 5.5% per sievert; if correct, natural background radiation is the most hazardous source of radiation to general public health, followed by medical imaging as a close second. Additionally, the vast majority of non-invasive cancers are non-melanoma skin cancers caused by ultraviolet radiation. Non-ionizing radio frequency radiation from mobile phones, electric power transmission, and other similar sources have been investigated as a possible carcinogen by the WHO's International Agency for Research on Cancer, but to date, no evidence of this has been observed.

The NASA Space Radiation Laboratory (NSRL, previously called Booster Applications Facility), is a heavy ion beamline research facility; part of the Collider-Accelerator Department of Brookhaven National Laboratory, located in Upton, New York on Long Island. Its primary mission is to use ion beams (H+to Bi83+) to simulate the cosmic ray radiation fields that are more prominent beyond earth's atmosphere.

<span class="mw-page-title-main">Nuclear labor issues</span> Radiation workers health and labor issues

Nuclear labor issues exist within the international nuclear power industry and the nuclear weapons production sector worldwide, impacting upon the lives and health of laborers, itinerant workers and their families.

John Dunning Boice Jr. is an American radiation epidemiologist and health physicist.

<span class="mw-page-title-main">Lauriston S. Taylor</span>

Lauriston S. Taylor was an American physicist known for his work in the field of radiation protection and measurement.

<span class="mw-page-title-main">Philippine Nuclear Research Institute</span> Agency of the Philippine government

The Philippine Nuclear Research Institute (PNRI) is a government agency under the Department of Science and Technology mandated to undertake research and development activities in the peaceful uses of nuclear energy, institute regulations on the said uses, and carry out the enforcement of said regulations to protect the health and safety of radiation workers and the general public.

The Aurora Pulsed Radiation Simulator is a 14 TW flash gamma-ray simulator that was designed to simulate the effects of a nuclear weapon's bremsstrahlung, or gamma radiation, pulses on military electronic systems. It was built in 1971 by the U.S. Defense Atomic Support Agency (DASA), which eventually became the Defense Threat Reduction Agency, and the U.S. Department of Energy (DOE).

References

  1. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 Institute of Medicine and National Research Council (2014). Research on Health Effects of Low-Level Ionizing Radiation Exposure: Opportunities for the Armed Forces Radiobiology Research Institute (2014) (Report). National Academies Press. pp. 75–99. Retrieved August 6, 2021.{{cite report}}: CS1 maint: multiple names: authors list (link)
  2. 1 2 "DIRECTOR COL MOHAMMAD NAEEM, MC, USA". afrri.usuhs.edu. Uniformed Services University of the Health Sciences . Retrieved August 7, 2021.
  3. 1 2 3 4 5 Thomas S. Tenforde (May 12, 2011). Tribute to AFRRI on Its 50th Anniversary and Perspectives on the History and Future of Radiation Biology and Health Protection (PDF) (Report). National Council on Radiation Protection and Measurements. pp. 5–14. Retrieved August 7, 2021.
  4. 1 2 3 4 "Research". afrri.usuhs.edu. Uniformed Services University of the Health Sciences . Retrieved August 7, 2021.
  5. 1 2 "Armed Forces Radiobiology Research Institute (AFRRI)". globalbiodefense.com. Global Biodefense. Retrieved August 7, 2021.
  6. 1 2 David S. C. Chu (March 29, 2006). Department of Defense Instruction 5105.33 (PDF) (Report). United States Department of Defense . Retrieved August 7, 2021.
  7. "Education". afrri.usuhs.edu. Uniformed Services University of the Health Sciences . Retrieved August 7, 2021.
  8. 1 2 "MEIR COURSE". afrri.usuhs.edu. Uniformed Services University of the Health Sciences . Retrieved August 7, 2021.
  9. 1 2 "MEDICAL RADIOBIOLOGY ADVISORY TEAM (MRAT)". afrri.usuhs.edu. Uniformed Services University of the Health Sciences . Retrieved August 7, 2021.
  10. "Incident Responder". afrri.usuhs.edu. Uniformed Services University of the Health Sciences . Retrieved August 7, 2021.
  11. "Policies". afrri.usuhs.edu. Uniformed Services University of the Health Sciences . Retrieved August 7, 2021.
  12. "Armed Forces Radiobiology Research Institute". nrc.gov. Nuclear Regulatory Commission . Retrieved August 7, 2021.
  13. Nuclear Regulatory Commission (May 10, 2019). "AFRRI - NRC FOLLOW-UP INSPECTION REPORT NO. 05000170/2019202 AND NOTICE OF VIOLATION". Letter to Capt. Dr. John Gilstad, AFRRI Director. Retrieved August 7, 2021.
  14. 1 2 3 Bene, Balazs J.; Blakely, William F.; Burmeister, David M.; Cary, Lynnette; Chhetri, Suyog J.; Davis, Catherine M.; Ghosh, Sanchita P.; Holmes-Hampton, Gregory P.; Iordanskiy, Sergey; Kalinich, John F.; Kiang, Juliann G.; Kumar, Vidya P.; Lowy, R. Joel; Miller, Alexandra; Naeem, Mohammad; Schauer, David A.; Senchak, Lien; Singh, Vijay K.; Stewart, Aure J.; Velazquez, Elih M.; Xiao, Mang (May 2021). "Celebrating 60 Years of Accomplishments of the Armed Forces Radiobiology Research Institute1". Radiation Research. 196 (2): 129–146. doi:10.1667/21-00064.1. PMID   33979439. S2CID   234484490.
  15. DoD (January 30, 2018). Table 1. Joint Meritorious Unit Award - Approved DoD Activities (PDF) (Report). United States Department of Defense. p. 10. Retrieved August 7, 2021.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.