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Biological warfare (also known as germ warfare) is the use of biological toxins or infectious agents such as bacteria, viruses, and fungi with intent to kill or incapacitate humans, animals or plants as an act of war. Biological weapons (often termed "bio-weapons" or "bio-agents") are living organisms or replicating entities (viruses) that reproduce or replicate within their host victims. Entomological (insect) warfare is also considered a type of BW.
Biological weapons may be employed in various ways to gain a strategic or tactical advantage over an adversary, either by threat or by actual deployment. Like some of the chemical weapons, biological weapons may also be useful as area denial weapons. These agents may be lethal or non-lethal, and may be targeted against a single individual, a group of people, or even an entire population. They may be developed, acquired, stockpiled or deployed by nation states or by non-national groups. In the latter case, or if a nation-state uses it clandestinely, it may also be considered bioterrorism.[1]
There is an overlap between biological warfare and chemical warfare, as the use of toxins produced by living organisms is considered under the provisions of both the Biological Weapons Convention and the Chemical Weapons Convention. Toxins and Psychochemical weapons are often referred to as midspectrum agents. Unlike bioweapons, these midspectrum agents do not reproduce in their host and are typically characterized by shorter incubation periods.[2]
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Offensive biological warfare, including mass production, stockpiling and use of biological weapons, was outlawed by the 1972 Biological Weapons Convention (BWC). The rationale behind this treaty, which has been ratified or acceded to by 163 countries as of 2009, is to prevent a biological attack which could conceivably result in large numbers of civilian fatalities and cause severe disruption to economic and societal infrastructure. Many countries, including signatories of the BWC, currently pursue research into the defense or protection against BW, which is not prohibited by the BWC.
A nation or group that can pose a credible threat of mass casualty has the ability to alter the terms on which other nations or groups interact with it. Biological weapons allow for the potential to create a level of destruction and loss of life far in excess of nuclear, chemical or conventional weapons, relative to their mass and cost of development and storage. Therefore, biological agents may be useful as strategic deterrents in addition to their utility as offensive weapons on the battlefield.[3][4]
As a tactical weapon for military use, a significant problem with a BW attack is that it would take days to be effective, and therefore might not immediately stop an opposing force. Some biological agents (especially smallpox, plague, and tularemia) have the capability of person-to-person transmission via aerosolized respiratory droplets. This feature can be undesirable, as the agent(s) may be transmitted by this mechanism to unintended populations, including neutral or even friendly forces. While containment of BW transmission is less of a concern for certain criminal or terrorist organizations, it remains a significant concern for the military and civilian populations of virtually all nations.
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Rudimentary forms of biological warfare have been practiced repeatedly throughout history. Many examples are recorded from Antiquity[5]. During the 6th century B.C., the Assyrians poisoned enemy wells with a fungus that would render the enemy delirious. In 184 BC, Hannibal of Carthage had clay pots filled with venomous snakes and instructed his soldiers to throw the pots onto the decks of Pergamene ships.
Historical accounts from medieval Europe detail the use of infected animal carcasses, by Mongols, Turks and other groups, to infect enemy water supplies. Prior to the bubonic plague epidemic known as the Black Death, Mongol and Turkish armies were reported to have catapulted disease-laden corpses into besieged cities. The last known incident of using plague corpses for BW purposes occurred in 1710, when Russian forces attacked the Swedes by flinging plague-infected corpses over the city walls of Reval (Tallinn).
The Native American population was decimated after contact with the Old World due to the inadvertent introduction of many fatal infectious diseases. The British army at least once attempted to use smallpox as a weapon, when they gave contaminated blankets to the Lenape during Pontiac's War. It is suspected but not confirmed that BW was used against the Indians at other times as well.
The advent of the germ theory and advances in bacteriology brought a new level of sophistication to the theoretical use of bio-agents in war. Biological sabotage — in the form of anthrax and glanders — was undertaken on behalf of the Imperial German government during World War I (1914-1918), with indifferent results[6]. Use of such bioweapons was banned in international law by the Geneva Protocol of 1925. (The 1972 Biological and Toxin Weapons Convention (BWC) extended the ban to almost all production, storage and transport. However, both the Soviet Union and Iraq, at a minimum, secretly defied the treaty and continued research and production of offensive biological weapons, despite being signatories to it. Major public proof of the Soviet program, called Biopreparat, came when Dr. Kanatjan Alibekov, its first deputy director, defected to the U.S. in 1992[7].)
During the Sino-Japanese War (1937-1945) and World War II (1939-1945), the Special Research Units of the Imperial Japanese Army, such as Unit 731, conducted human experimentation on thousands of Chinese, among others. In its military campaigns, the Japanese used BW on Chinese soldiers and civilians. This employment has been largely viewed as ineffective due to inefficient delivery systems. However, firsthand accounts testify that the Japanese infected civilians through the distribution of plagued foodstuffs and newer estimates suggest over 580,000 victims, largely due to plague and cholera outbreaks.
In response to suspected BW development in Nazi Germany, the U.S., U.K., and Canada initiated a BW development program in 1941 that resulted in the weaponization of anthrax, brucellosis, and botulism toxin. (Fear of the German program turned out to be vastly exaggerated.) The center for U.S. military BW research was Fort Detrick, Maryland[8]. The biological and chemical weapons developed during that period were tested at the Dugway Proving Grounds in Utah. Research carried out in the U.K. during World War II left Gruinard Island in Scotland contaminated with anthrax for the next 48 years.
Considerable research into BW was undertaken throughout the Cold War era (1947-1991) by the U.S., U.K. and U.S.S.R., and probably other major nations as well, although it is generally believed that such weapons were never used. This view was challenged by China and North Korea, who accused the U.S. of large-scale field testing of BW against them during the Korean War (1950-1953), but this claim has been discredited as wartime propaganda. By 2011, 165 countries had signed the treaty. The U.S. maintained a stated national policy of never using BW under any circumstances since an Executive Decision in November, 1969, by President Richard Nixon. In 1972, the U.S., U.K., U.S.S.R., and many other nations signed the BWC, which banned "development, production and stockpiling of microbes or their poisonous products except in amounts necessary for protective and peaceful research." By then, the U.S. and U.K. had transparently destroyed all their bioweapons stockpiles.
Today, according to the U.S. Department of Defense, more than ten countries are suspected to have continuing offensive BW programs, including Russia, Israel, China, Iran, Syria and North Korea. Offensive BW programs in Iraq were dismantled after the first Gulf War (1990-91). Libya dismantled and disavowed its BW program in 2003. The fate of the vast network of clandestine sites comprising the old Soviet BW program, as well as its many tons of weaponized smallpox, remains undocumented.
It has been argued that rational people would never use biological weapons offensively. The argument is that biological weapons cannot be controlled: the weapon could backfire and harm the army on the offensive, perhaps having even worse effects than on the target. An agent like smallpox or other airborne viruses would almost certainly spread worldwide and ultimately infect the user's home country. However, this argument does not necessarily apply to bacteria. For example, anthrax can easily be controlled and even created in a garden shed. Also, using microbial methods, bacteria can be suitably modified to be effective in only a narrow environmental range, the range of the target that distinctly differs from the army on the offensive. thus only the target might be affected adversely.
Ideal characteristics of a biological agent to be used as a weapon against humans are high infectivity, high virulence, non-availability of vaccines, and availability of an effective and efficient delivery system. Stability of the weaponized agent (ability of the agent to retain its infectivity and virulence after a prolonged period of storage) may also be desirable, particularly for military applications.
The primary difficulty is not the production of the biological agent, as many biological agents used in weapons can often be manufactured relatively quickly, cheaply and easily. Rather, it is the weaponization, storage and delivery in an effective vehicle to a vulnerable target that pose significant problems.
For example, Bacillus anthracis is considered an effective agent for several reasons. First, it forms hardy spores, perfect for dispersal aerosols. Second, this organism is not considered transmissible from person to person, and thus rarely if ever causes secondary infections. A pulmonary anthrax infection starts with ordinary influenza-like symptoms and progresses to a lethal hemorrhagic mediastinitis within 3–7 days, with a fatality rate that is 90% or higher in untreated patients. Finally, friendly personnel can be protected with suitable antibiotics.
A large-scale attack using anthrax would require the creation of aerosol particles of 1.5 to 5 microns. Too large and the particles would not reach the lower respiratory tract. Too small and the particles would be exhaled back out into the atmosphere. At this size, conductive powders tend to aggregate because of electrostatic charges, hindering dispersion. So the material must be treated to insulate and neutralize the charges. The weaponized agent must be resistant to degradation by rain and ultraviolet radiation from sunlight, while retaining the ability to efficiently infect the human lung. There are other technological difficulties as well, chiefly relating to storage of the weaponized agent.
Agents considered for weaponization, or known to be weaponized, include bacteria such as Bacillus anthracis, Brucella spp., Burkholderia mallei, Burkholderia pseudomallei, Chlamydophila psittaci, Coxiella burnetii, Francisella tularensis, some of the Rickettsiaceae (especially Rickettsia prowazekii and Rickettsia rickettsii), Shigella spp., Vibrio cholerae, and Yersinia pestis. Many viral agents have been studied and/or weaponized, including some of the Bunyaviridae (especially Rift Valley fever virus), Ebolavirus, many of the Flaviviridae (especially Japanese encephalitis virus), Machupo virus, Marburg virus, Variola virus, and Yellow fever virus. Fungal agents that have been studied include Coccidioides spp..[9][10]
Toxins that can be used as weapons include ricin, staphylococcal enterotoxin B, botulinum toxin, saxitoxin, and many mycotoxins. These toxins and the organisms that produce them are sometimes referred to as select agents. In the United States, their possession, use, and transfer are regulated by the Centers for Disease Control and Prevention's Select Agent Program.
Anti-crop/anti-vegetation/anti-fisheries:
Biological warfare can also specifically target plants to destroy crops or defoliate vegetation. The United States and Britain discovered plant growth regulators (i.e., herbicides) during the Second World War, and initiated an herbicidal warfare program that was eventually used in Malaya and Vietnam in counter insurgency. Though herbicides are chemicals, they are often grouped with biological warfare as bioregulators in a similar manner as biotoxins. Scorched earth tactics or destroying livestock and farmland were carried out in the Vietnam war (cf. Agent Orange)[11] and Eelam War in Sri Lanka.
The United States developed an anti-crop capability during the Cold War that used plant diseases (bioherbicides, or mycoherbicides) for destroying enemy agriculture. It was believed that destruction of enemy agriculture on a strategic scale could thwart Sino-Soviet aggression in a general war. Diseases such as wheat blast and rice blast were weaponized in aerial spray tanks and cluster bombs for delivery to enemy watersheds in agricultural regions to initiate epiphytotics (epidemics among plants). When the United States renounced its offensive biological warfare program in 1969 and 1970, the vast majority of its biological arsenal was composed of these plant diseases.
Biological weapons also target fisheries as well as water-based vegetation.
Anti-livestock:
In 1980s Soviet Ministry of Agriculture had successfully developed variants of foot-and-mouth disease, and rinderpest against cows, African swine fever for pigs, and psittacosis to kill chicken. These agents were prepared to spray them down from tanks attached to airplanes over hundreds of miles. The secret program was code-named "Ecology".[9]
Attacking animals is another area of biological warfare intended to eliminate animal resources for transportation and food. In the First World War, German agents were arrested attempting to inoculate draft animals with anthrax, and they were believed to be responsible for outbreaks of glanders in horses and mules. The British tainted small feed cakes with anthrax in the Second World War as a potential means of attacking German cattle for food denial, but never employed the weapon. In the 1950s, the United States had a field trial with hog cholera. During the Mau Mau Uprising in 1952, the poisonous latex of the African milk bush was used to kill cattle.[12]
Unconnected with inter-human wars, humans have deliberately introduced the rabbit disease Myxomatosis, originating in South America, to Australia and Europe, with the intention of reducing the rabbit population - which had devastating but temporary results, with wild rabbit populations reduced to a fraction of their former size but survivors developing immunity and increasing again.
Entomological warfare (EW) is a type of BW that uses insects to attack the enemy. The concept has existed for centuries and research and development have continued into the modern era. EW has been used in battle by Japan and several other nations have developed and been accused of using an entomological warfare program. EW may employ insects in a direct attack or as vectors to deliver a biological agent, such as plague or cholera. Essentially, EW exists in three varieties. One type of EW involves infecting insects with a pathogen and then dispersing the insects over target areas.[13] The insects then act as a vector, infecting any person or animal they might bite. Another type of EW is a direct insect attack against crops; the insect may not be infected with any pathogen but instead represents a threat to agriculture. The final method uses uninfected insects, such as bees, to directly attack the enemy.[14]
Recent research in genetics, specifically, expanding the set of bases found in DNA (A, C, G, T) and RNA (A, C, G, U) from four; expanding the set of codons (due to the expanded base set, as well as 3-base codons, to 4- and 5-base codons); and expanding the set of amino acids incorporated into polypeptides (see genetic code, proteomics), extends the new field of synthetic biology to synthetic biological warfare.[15]
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.
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.[16]
In the Netherlands, the company TNO has designed Bioaerosol Single Particle Recognition eQuipment (BiosparQ). This system would be implemented into the national response plan for bioweapons attacks in the Netherlands.[17]
Researchers at Ben Gurion University in Israel are developing a different device called the BioPen, essentially a "Lab-in-a-Pen", which can detect known biological agents in under 20 minutes using an adaptation of the ELISA, a similar widely employed immunological technique, that in this case incorporates fiber optics.[18]
Microbes that are composed of synthetic or artificial components, such as DNA or RNA or codons or amino acids can be tailored for use as biological warfare agents. As examples, if DNA used xDNA were to be coupled with synthetic codons, with synthetic anti-codons, etc. then such microbes used as biological warfare agents would be synthetic biological warfare agents.
According to the U.S. Office of Technology Assessment (since disbanded), 17 countries were believed to possess biological weapons in 1995: Libya, North Korea, South Korea, Iraq, Taiwan, Syria, Israel, Iran, China, Egypt, Vietnam, Laos, Cuba, Bulgaria, India, South Africa, and Russia.[9][19] Today, according to the U.S. Department of Defense, more than ten countries are suspected to have continuing offensive BW programs, including Russia, Israel, China, Iran, Syria and North Korea. Offensive BW programs in Iraq were dismantled after the first Gulf War (1990-91). Libya dismantled and disavowed its BW program in 2003.
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