Team:Queens Canada/Safety/Bioterrorism
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- | <regulartext> Our team envisions an international co-operative effort to limit the possibility of bioterrorism. Similar to 'tiger | + | <regulartext> Our team envisions an international co-operative effort to limit the possibility of bioterrorism. Similar to 'tiger teams' in the aerospace industry, whose primary task was to identify every possible source of error in a spacecraft, an antiBT task force would begin with a preventative approach. The purpose of an antiBT task force would be to imagine every conceivable synthetic biology device that could be used for terrorist applications and then to design a countermeasure. Of course, this would have to be done entirely in secret to avoid giving inspiration to the enemy. |
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<h3green>Design and Production of Countermeasures </h3green><p> | <h3green>Design and Production of Countermeasures </h3green><p> | ||
- | <regulartext> The antiBT task force should design and produce a variety of bioterrorism countermeasures. First, there are the standard countermeasures to a biological attack, vaccines and antibiotics. Anthrax and smallpox are thought to be the most likely candidates for use in a bioterrorist attack [ | + | <regulartext> The antiBT task force should design and produce a variety of bioterrorism countermeasures. First, there are the standard countermeasures to a biological attack, vaccines and antibiotics. Anthrax and smallpox are thought to be the most likely candidates for use in a bioterrorist attack [1]. So, a sufficient stockpile of vaccinia virus vaccine (for smallpox) and anthrax vaccine adsorbed (AVA) to immunize a significant portion of the population would be ideal. Also, there should be sufficient cyprofloxin and doxycycline (anthrax antibiotics) to administer to all victims of a bioterrorist attack. Currently, Canada’s stockpile of such vaccines and antibiotics may not be sufficient to deal with all victims of a bioterrorist incident. It may be necessary for the antiBT task force to pioneer more efficient ways to make the vaccines and antibiotics. </regulartext> <p> |
- | <regulartext> New techniques might involve synthetic biology, which has been used by Ro and colleagues to cheaply, efficiently, and quickly produce the antimalarial drug artemisinin [ | + | <regulartext> New techniques might involve synthetic biology, which has been used by Ro and colleagues to cheaply, efficiently, and quickly produce the antimalarial drug artemisinin [2]. E. coli were equipped with heterologous enzymes from the bacterium S. cerevisiae, which enabled the E. coli to produce artemisinic acid, an immediate precursor of artemisinin, from acetyl-CoA. Acetyl-CoA is a TCA cycle intermediate produced naturally by E. coli. In traditional organic synthesis, the products of each synthetic step have to be isolated and purified before the beginning of the next step. A key advantage of an engineered bacterial chassis is that isolation and purification are unnecessary. Also, the conventional approach to isolating artemisinin from its natural producer, the Artemisia annua plant, is rate-limited by the availability of the plant. Bacterial production of artemisinin, by contrast, is limited by a facility’s capacity to produce E. coli, which is much less expensive than A. annua. The antiBT task force should pursue similar metabolic engineering approaches for the development of antibiotics for anthrax and other pathogens. </regulartext> <p> |
<regulartext> Another issue with stockpiling is that vaccines and antibiotics will eventually expire, requiring constant replenishment. It would be useful for the antiBT task force to develop a better system for storing vaccines to increase their longevity. Alternatively, it may be a better idea to design an apparatus capable of quickly producing a large quantity of vaccine. This system would not be used except in the wake of a bioterrorist attack. Such a system would eliminate the problem of expiry and ensure that no vaccine is produced wastefully. An apparatus based on engineered E. coli cells might have the capacity to produce vaccines and antibiotics quickly and flexibly. </regulartext> <p> | <regulartext> Another issue with stockpiling is that vaccines and antibiotics will eventually expire, requiring constant replenishment. It would be useful for the antiBT task force to develop a better system for storing vaccines to increase their longevity. Alternatively, it may be a better idea to design an apparatus capable of quickly producing a large quantity of vaccine. This system would not be used except in the wake of a bioterrorist attack. Such a system would eliminate the problem of expiry and ensure that no vaccine is produced wastefully. An apparatus based on engineered E. coli cells might have the capacity to produce vaccines and antibiotics quickly and flexibly. </regulartext> <p> | ||
- | <regulartext>Novel vaccine and drug discovery would be also be worthy endeavours for the antiBT task force. There is an emerging understanding that synthetic biology can be used to accelerate the drug discovery process. Traditionally, organic chemistry methods have been used to isolate natural products that are useful as human therapeutics. However, those natural products likely evolved for a purpose other than fighting disease in humans. Thus, although effective, they may not be ideally suited for human therapeutics. Terpenes, for instance, have numerous applications as antifungal and anticancer agents [ | + | <regulartext>Novel vaccine and drug discovery would be also be worthy endeavours for the antiBT task force. There is an emerging understanding that synthetic biology can be used to accelerate the drug discovery process. Traditionally, organic chemistry methods have been used to isolate natural products that are useful as human therapeutics. However, those natural products likely evolved for a purpose other than fighting disease in humans. Thus, although effective, they may not be ideally suited for human therapeutics. Terpenes, for instance, have numerous applications as antifungal and anticancer agents [3]. However, the use of synthetic biology to generate novel families of terpenes may lead to the discovery of novel or more effective medicines. One approach is to outfit E. coli cells with a variety of enzymes relevant to terpene production. Combinatorial expression of these enzymes may result in a transgenic host capable of producing new terpenes for drug discovery [4]. The antiBT task force could apply a similar approach to drug discovery with other families of compounds. </regulartext><p> |
<regulartext>Synthetic biology can also inform innovations in vaccine delivery systems. Engineered bacterial chassis can be used to more efficiently deliver drugs to a particular cell or tissue type. Traditional vaccines are administered through the skin and induce a systemic immune response [6]. But, many pathogens use mucosal tissues as a site of entry, and a mucosal immune response may be more appropriate [6]. In the case of bioterrorism, where pathogens are often delivered in aerosol form, a vaccine that induces a mucosal immune response would be especially useful. The issue with mucosal vaccines is that antigens delivered to mucosal surfaces tend to evoke weak immune responses due to poor absorption [6]. To increase absorption, the vaccine could be loaded into a bacterial chassis engineered to permeate mucosal membranes. Such a system would increase the efficiency of vaccine delivery. Work on this kind of bacterial chassis would contribute to bioterrorism preparedness and healthcare in general. | <regulartext>Synthetic biology can also inform innovations in vaccine delivery systems. Engineered bacterial chassis can be used to more efficiently deliver drugs to a particular cell or tissue type. Traditional vaccines are administered through the skin and induce a systemic immune response [6]. But, many pathogens use mucosal tissues as a site of entry, and a mucosal immune response may be more appropriate [6]. In the case of bioterrorism, where pathogens are often delivered in aerosol form, a vaccine that induces a mucosal immune response would be especially useful. The issue with mucosal vaccines is that antigens delivered to mucosal surfaces tend to evoke weak immune responses due to poor absorption [6]. To increase absorption, the vaccine could be loaded into a bacterial chassis engineered to permeate mucosal membranes. Such a system would increase the efficiency of vaccine delivery. Work on this kind of bacterial chassis would contribute to bioterrorism preparedness and healthcare in general. | ||
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<h3green> Dealing with Increased Antibiotic Resistance </h3green><p> | <h3green> Dealing with Increased Antibiotic Resistance </h3green><p> | ||
- | <regulartext>Synthetic biology could be used to design a novel pathogen with increased antibiotic resistance. How could the antiBT task force go about circumventing this increased resistance? Inspiration can be taken from the literature on superbugs. One approach is to tackle the pathogen’s mechanism of resistance. The antiBT task force would have to perform experiments to determine the new mechanism of resistance and way to counteract it. Traditional antibiotics used in conjunction with a countermeasure to the increased resistance should prove effective [ | + | <regulartext>Synthetic biology could be used to design a novel pathogen with increased antibiotic resistance. How could the antiBT task force go about circumventing this increased resistance? Inspiration can be taken from the literature on superbugs. One approach is to tackle the pathogen’s mechanism of resistance. The antiBT task force would have to perform experiments to determine the new mechanism of resistance and way to counteract it. Traditional antibiotics used in conjunction with a countermeasure to the increased resistance should prove effective [5]. For example, some microbes have developed resistance to the class of antibiotics called β-lactams. Resistant bacteria produce enzymes called β-lactamases which hydrolyze β-lactam antibiotics [5]. However, substances like clavulanic acid are inhibitors of β-lacamases. So, adminstration of clavulanic acid along with β-lactams can combat β-lactam resistant bacteria [5]. In the same vein, scientists in the antiBT task force should examine the antibiotic resistance engineered into a pathogen and find a drug to circumvent that resistance. |
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<h3green> Education of the Medical Community </h3green><p> | <h3green> Education of the Medical Community </h3green><p> | ||
- | <regulartext> The initial stages of a bioterrorist attack may go unnoticed. This is because pathogens can be released silently and lie dormant in the victim for a period of time. Conventional warfare can be loud and gory, but biological warfare can be stealthy and insidious. A quick and effective response to a bioterrorism crisis depends on the preparedness of the medical community. Doctors and nurses are usually not accustomed to biological warfare and may not know what warning signs to look for. Pathogens like anthrax and smallpox do not usually figure in differential diagnosis, and therefore symptoms of these agents may be attributed to other conditions [ | + | <regulartext> The initial stages of a bioterrorist attack may go unnoticed. This is because pathogens can be released silently and lie dormant in the victim for a period of time. Conventional warfare can be loud and gory, but biological warfare can be stealthy and insidious. A quick and effective response to a bioterrorism crisis depends on the preparedness of the medical community. Doctors and nurses are usually not accustomed to biological warfare and may not know what warning signs to look for. Pathogens like anthrax and smallpox do not usually figure in differential diagnosis, and therefore symptoms of these agents may be attributed to other conditions [6]. If this happens, a significant number of cases need to accumulate before it is even realized that a bioterrorist attack has taken place. Patients may not be quarantined in time to prevent the spread of the unfamiliar pathogen. Authorities may not be alerted to the crisis quickly enough to mount an effective response. Since first news of a bioterrorist crisis would likely come from a hospital, it is important for doctors to have a precise knowledge of what signs and symptoms to look for. |
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- | <regulartext>The antiBT task force should offer a training course to the medical community. The course should act as a refresher in the signs and symptoms of likely bioterrorist agents like anthrax and smallpox. It should also cover the methods by which those conditions are diagnosed, proper treatment, and quarantine protocols to prevent the spread of the pathogen to other patients [ | + | <regulartext>The antiBT task force should offer a training course to the medical community. The course should act as a refresher in the signs and symptoms of likely bioterrorist agents like anthrax and smallpox. It should also cover the methods by which those conditions are diagnosed, proper treatment, and quarantine protocols to prevent the spread of the pathogen to other patients [6]. It should cover the legal issues of imposing quarantine on a patient and allowing loved ones to enter and leave the hospital. The responsibility to alert the authorities to a bioterrorist incident should be emphasized. Physicians taking the course should be trained to deal with the media without inciting panic. |
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<h3green> Creating a Detailed Response Plan </h3green><p> | <h3green> Creating a Detailed Response Plan </h3green><p> | ||
- | <regulartext> Once the medical community becomes aware of a bioterrorist incident, police and government must | + | <regulartext> Once the medical community becomes aware of a bioterrorist incident, police and government must react quickly. It is not difficult to envision unnecessary panic on account of miscommunication between hospital staff, levels of government, the police, and the media. Confusion, inconsistency, and poor decision-making might impede a proper response to the incident. The point of a bioterrorism incident is also to cause fear, break down the social order, and shake faith in the government [7]. The antiBT task force should have a working response plan in place to make sure the response is carried out smoothly. The plan might be divided into steps and look something like the following: |
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<h3green> Determination of Intentionality </h3green> <p> | <h3green> Determination of Intentionality </h3green> <p> | ||
- | <regulartext>Responses to imagined scenarios are important, but the antiBT task force should also be equipped to deal with real bioterrorism incidents. A key issue in counter bioterrorism is the ability to distinguish between the intentional and unintentional release of pathogens [ | + | <regulartext>Responses to imagined scenarios are important, but the antiBT task force should also be equipped to deal with real bioterrorism incidents. A key issue in counter bioterrorism is the ability to distinguish between the intentional and unintentional release of pathogens [8]. This could be done by investigating the site in which the pathogenicity was detected. Does the pattern of release fit an accident or a planned attack? Also, the task force should discern the role of synthetic biology in the attack. In the case of a bacterial or viral pathogen, are there any traits present that distinguish it from wild-type? Is there evidence of an extrachromosomal array? Has the genome of the organism been modified? Can the organism be classified as a known species or is it something distinct? Answers to these questions would require a laboratory with BSL Level 3 or Level 4 clearance. |
</regulartext> <p> | </regulartext> <p> | ||
- | <regulartext> Epidemiological tools can be helpful in distinguishing an intentional attack from an accidental release [ | + | <regulartext> Epidemiological tools can be helpful in distinguishing an intentional attack from an accidental release [8]. An epidemiological curve is drawn on a plot with time on the x-axis and number of cases on the y-axis. Normally, the curve gradually increases to a peak, and then decreases. In the case of a bioterrorist attack, infection comes from a point source, producing a compressed epidemiological curve [8]. A second peak might also appear as infected persons contaminate a second generation of sufferers. However, a similar pattern would be observed in the case of a food-borne infection outbreak. So, epidemiological tools should be used in conjunction with other evidence to yield conclusive results. |
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- | <h3green> | + | <h3green> References </h3green><p> |
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+ | 1. Russell, P.K. (1999). Vaccines in civilian defense against bioterrorism. Emerging Infectious Diseases, 5(4):531-533. <br> | ||
+ | 2. Ro, D., Paradise, E., Ouellet, M. et al. (2006). Production of the antimalarial drug precursor artemisinic acid in engineered yeast. Nature, 3:940-943.<br> | ||
+ | 3. Chosla, C., and Keasling, J.D. (2003). Metabolic engineering for drug discovery and development. Drug Discovery, <br> | ||
+ | 4. Garmory, H.S., Leary, S.E., Griffin, K.F. (2003). The use of live attenuated bacteria as a delivery system for heterologous antigens. Journal of Drug Targeting, 11:471-9.<br> | ||
+ | 5. Wright, G.D. (2000). Resisting resistance: new chemical strategies for battling superbugs. Chemistry & Biology, 7(6):127-132.<br> | ||
+ | 6. Bartlett, J.G. (1999). Applying lessons learned from anthrax case history to other scenarios. Emerging Infectious Diseases, 5(4):561-563.<br> | ||
+ | 7. O'Toole, T. (1999). Smallpox: An attack scenario. Emerging Infectious Diseases, 5(4):540-546.<br> | ||
+ | 8. Pavlin, J.A. (1999). Epidemiology of bioterrorism. Emerging Infectious Diseases, 5(4):528-530.<br> | ||
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Latest revision as of 22:31, 28 October 2011
2. Ro, D., Paradise, E., Ouellet, M. et al. (2006). Production of the antimalarial drug precursor artemisinic acid in engineered yeast. Nature, 3:940-943.
3. Chosla, C., and Keasling, J.D. (2003). Metabolic engineering for drug discovery and development. Drug Discovery,
4. Garmory, H.S., Leary, S.E., Griffin, K.F. (2003). The use of live attenuated bacteria as a delivery system for heterologous antigens. Journal of Drug Targeting, 11:471-9.
5. Wright, G.D. (2000). Resisting resistance: new chemical strategies for battling superbugs. Chemistry & Biology, 7(6):127-132.
6. Bartlett, J.G. (1999). Applying lessons learned from anthrax case history to other scenarios. Emerging Infectious Diseases, 5(4):561-563.
7. O'Toole, T. (1999). Smallpox: An attack scenario. Emerging Infectious Diseases, 5(4):540-546.
8. Pavlin, J.A. (1999). Epidemiology of bioterrorism. Emerging Infectious Diseases, 5(4):528-530.