Open Access Articles- Top Results for Biodefense
Journal of Bioterrorism & BiodefenseProbable Bioweapon: Influenza Type A Virus A Short Case Report.
Journal of Bioterrorism & BiodefenseBioterrorism: An Emerging Global Health Threat
Journal of Bioterrorism & BiodefenseLow Level of Awareness in Biosafety and Biosecurity among Professionals in Uganda: A Potential Risk in the Dual-Use Dilemma
Journal of Bioterrorism & BiodefenseBiosecurity and Biodefense: Lessons from Ebola Virus Outbreak
Journal of Bioterrorism & BiodefenseEmerging Infectious Disease and Bioterrorism
Biodefense refers to short term, local, usually military measures to restore biosecurity to a given group of persons in a given area who are, or may be, subject to biological warfare— in the civilian terminology, it is a very robust biohazard response. It is technically possible to apply biodefense measures to protect animals or plants, but this is generally uneconomic. However, protection of water supplies and food supplies are often a critical part of biodefense. Various definitions of biosafety emerged in different professions to guarantee non-human health.
Biodefense applies to two distinct target populations: civilian non-combatant and military combatant (troops in the field).
Biodefense of troops in the field
Military biodefense in the United States began with the United States Army Medical Unit (USAMU) at Fort Detrick, Maryland, in 1956. (In contrast to the U.S. Army Biological Warfare Laboratories [1943–1969], also at Fort Detrick, the USAMU's mission was purely to develop defensive measures against bio-agents, as opposed to weapons development.) The USAMU was disestablished in 1969 and succeeded by today's United States Army Medical Research Institute of Infectious Diseases (USAMRIID).
The United States Department of Defense (or "DoD") has focused since at least 1998 on the development and application of vaccine-based biodefenses. In a July 2001 report commissioned by the DoD, the "DoD-critical products" were stated as vaccines against anthrax (AVA and Next Generation), smallpox, plague, tularemia, botulinum, ricin, and equine encephalitis. Note that two of these targets are toxins (botulinum and ricin) while the remainder are infectious agents.
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Role of public health and disease surveillance
It is important to note that all of the classical and modern biological weapons organisms are animal diseases, the only exception being smallpox. Thus, in any use of biological weapons, it is highly likely that animals will become ill either simultaneously with, or perhaps earlier than humans.
Indeed, in the largest biological weapons accident known– the anthrax outbreak in Sverdlovsk (now Yekaterinburg) in the Soviet Union in 1979, sheep became ill with anthrax as far as 200 kilometers from the release point of the organism from a military facility in the southeastern portion of the city (known as Compound 19 and still off limits to visitors today, see Sverdlovsk Anthrax leak).
Thus, a robust surveillance system involving human clinicians and veterinarians may identify a bioweapons attack early in the course of an epidemic, permitting the prophylaxis of disease in the vast majority of people (and/or animals) exposed but not yet ill.
For example in the case of anthrax, it is likely that by 24 – 36 hours after an attack, some small percentage of individuals (those with compromised immune system or who had received a large dose of the organism due to proximity to the release point) will become ill with classical symptoms and signs (including a virtually unique chest X-ray finding, often recognized by public health officials if they receive timely reports). By making these data available to local public health officials in real time, most models of anthrax epidemics indicate that more than 80% of an exposed population can receive antibiotic treatment before becoming symptomatic, and thus avoid the moderately high mortality of the disease.
Identification of bioweapons
The goal of biodefense is to integrate the sustained efforts of the national and homeland security, medical, public health, intelligence, diplomatic, and law enforcement communities. Health care providers and public health officers are among the first lines of defense. In some countries private, local, and provincial (state) capabilities are being augmented by and coordinated with federal assets, to provide layered defenses against biological weapons attacks. During the first Gulf War the United Nations activated a biological and chemical response team, Task Force Scorpio, to respond to any potential use of weapons of mass destruction on civilians.
The traditional approach toward protecting agriculture, food, and water: focusing on the natural or unintentional introduction of a disease is being strengthened by focused efforts to address current and anticipated future biological weapons threats that may be deliberate, multiple, and repetitive.
The growing threat of biowarfare agents and bioterrorism has led to the development of specific field tools that perform on-the-spot analysis and identification of encountered suspect materials. One such technology, being developed by researchers from the Lawrence Livermore National Laboratory (LLNL), employs a "sandwich immunoassay", in which fluorescent dye-labeled antibodies aimed at specific pathogens are attached to silver and gold nanowires.
The U.S. National Institute of Allergy and Infectious Diseases (NIAID) also participates in the identification and prevention of biowarfare and first released a strategy for biodefense in 2002, periodically releasing updates as new pathogens are becoming topics of discussion. Within this list of strategies, responses for specific infectious agents are provided, along with the classification of these agents. NIAID provides countermeasures after the U.S. Department of Homeland Security details which pathogens hold the most threat.
Planning and response
Planning may involve the development of biological identification systems.Until recently in the United States, most biological defense strategies have been geared to protecting soldiers on the battlefield rather than ordinary people in cities. Financial cutbacks have limited the tracking of disease outbreaks. Some outbreaks, such as food poisoning due to E. coli or Salmonella, could be of either natural or deliberate origin.
Biological agents are relatively easy to obtain by terrorists and are becoming more threatening in the U.S., and laboratories are working on advanced detection systems to provide early warning, identify contaminated areas and populations at risk, and to facilitate prompt treatment. Methods for predicting the use of biological agents in urban areas as well as assessing the area for the hazards associated with a biological attack are being established in major cities. In addition, forensic technologies are working on identifying biological agents, their geographical origins and/or their initial son. Efforts include decontamination technologies to restore facilities without causing additional environmental concerns.
Early detection and rapid response to bioterrorism depend on close cooperation between public health authorities and law enforcement; however, such cooperation is currently lacking. National detection assets and vaccine stockpiles are not useful if local and state officials do not have access to them.
In 1999, the University of Pittsburgh's Center for Biomedical Informatics deployed the first automated bioterrorism detection system, called RODS (Real-Time Outbreak Disease Surveillance). RODS is designed to draw collect data from many data sources and use them to perform signal detection, that is, to detect a possible bioterrorism event at the earliest possible moment. RODS, and other systems like it, collect data from sources including clinic data, laboratory data, and data from over-the-counter drug sales. In 2000, Michael Wagner, the codirector of the RODS laboratory, and Ron Aryel, a subcontractor, conceived the idea of obtaining live data feeds from "non-traditional" (non-health-care) data sources. The RODS laboratory's first efforts eventually led to the establishment of the National Retail Data Monitor, a system which collects data from 20,000 retail locations nation-wide.
On February 5, 2002, George W. Bush visited the RODS laboratory and used it as a model for a $300 million spending proposal to equip all 50 states with biosurveillance systems. In a speech delivered at the nearby Masonic temple, Bush compared the RODS system to a modern "DEW" line (referring to the Cold War ballistic missile early warning system).
The principles and practices of biosurveillance, a new interdisciplinary science, were defined and described in the Handbook of Biosurveillance, edited by Michael Wagner, Andrew Moore and Ron Aryel, and published in 2006. Biosurveillance is the science of real-time disease outbreak detection. Its principles apply to both natural and man-made epidemics (bioterrorism).
Data which potentially could assist in early detection of a bioterrorism event include many categories of information. Health-related data such as that from hospital computer systems, clinical laboratories, electronic health record systems, medical examiner record-keeping systems, 911 call center computers, and veterinary medical record systems could be of help; researchers are also considering the utility of data generated by ranching and feedlot operations, food processors, drinking water systems, school attendance recording, and physiologic monitors, among others. Intuitively, one would expect systems which collect more than one type of data to be more useful than systems which collect only one type of information (such as single-purpose laboratory or 911 call-center based systems), and be less prone to false alarms, and this appears to be the case.
In Europe, disease surveillance is beginning to be organized on the continent-wide scale needed to track a biological emergency. The system not only monitors infected persons, but attempts to discern the origin of the outbreak.
Researchers are experimenting with devices to detect the existence of a threat:
- Tiny electronic chips that would contain living nerve cells to warn of the presence of bacterial toxins (identification of broad range toxins)
- Fiber-optic tubes lined with antibodies coupled to light-emitting molecules (identification of specific pathogens, such as anthrax, botulinum, ricin)
New research shows that ultraviolet avalanche photodiodes offer the high gain, reliability and robustness needed to detect anthrax and other bioterrorism agents in the air. The fabrication methods and device characteristics were described at the 50th Electronic Materials Conference in Santa Barbara on June 25, 2008. Details of the photodiodes were also published in the February 14, 2008 issue of the journal Electronics Letters and the November 2007 issue of the journal IEEE Photonics Technology Letters.
The United States Department of Defense conducts global biosurveillance through several programs, including the Global Emerging Infections Surveillance and Response System.
Response to bioterrorism incident or threat
Government agencies which would be called on to respond to a bioterrorism incident would include law enforcement, hazardous materials/decontamination units and emergency medical units. The US military has specialized units, which can respond to a bioterrorism event; among them are the United States Marine Corps' Chemical Biological Incident Response Force and the U.S. Army's 20th Support Command (CBRNE), which can detect, identify, and neutralize threats, and decontaminate victims exposed to bioterror agents. There are four hospitals capable of caring for anyone with an exposure to a BSL3 or BSL4 pathogen, the special clinical studies unit at National Institutes of Health is one of them. National Institutes of Health built a facility in April 2010. This unit has state of the art isolation capabilities with a unique airflow system. This unit is also being trained to care for patients who are ill due to a highly infectious pathogen outbreak, such as ebola. The doctors work closely with USAMRIID, NBACC and IRF. Special trainings take place regularly in order to maintain a high level of confidence to care for these patients.
- United States biological defense program
- United States Army Medical Research Institute of Infectious Diseases (USAMRIID)
- National Biodefense Analysis and Countermeasures Center (NBACC)
- Sensing of phage-triggered ion cascades
- Fluctuation-enhanced sensing of biological and chemical agents
- Physorg.com, "Encoded Metallic Nanowires Reveal Bioweapons", 12:50 EST, August 10, 2006.
- Bernett, Brian C. (December 2006), US Biodefense and Homeland Security: Toward Detection and Attribution (PDF), Monterey, California, United States: Naval Postgraduate School, p. 21, retrieved 2009-05-24
- Wagner, Michael M.; Espino, Jeremy;et al. (2004), "The role of clinical information systems in public health surveillance", Healthcare Information Management Systems (3 ed.), New York: Springer-Verlag, pp. 513–539
- Wagner, Michael M.; Aryel, Ron;et al. (2001-11-28), Availability and Comparative Value of Data Elements Required for an Effective Bioterrorism Detection System (PDF), Real-time Outbreak and Disease Surveillance Laboratory, retrieved 2009-05-22
- Togyer, Jason (June 2002), Pitt Magazine: Airborne Defense, University of Pittsburg, retrieved 2009-05-22
- Avalanche Photodiodes Target Bioterrorism Agents Newswise, Retrieved on June 25, 2008.
- Pellerin, Cheryl. "Global Nature of Terrorism Drives Biosurveillance." American Forces Press Service, 27 October 2011.
- Department of Defense (2001). Report on Biological Warfare Defense Vaccine Research & Development Programs. Retrieved 2005-02-25.
- Institute of Medicine and National Research Councel of the National Academies (2004). Giving Full Measure to Countermeasures: Addressing Problems in the DoD Program to Develop Medical Countermeasures Against Biological Warefare Agents. National Academy Press (Washington, D.C.). ISBN 0-309-09153-5 (paperback).
- BiodefenseEducation.org - A biodefense digital library and learning collaboratory
- NIAID Biodefense Research