Team:ITB Indonesia/Safety
From 2013.igem.org
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- | + | <p><strong>Do the biological materials used in your lab work pose any of the following risks? Please describe.</strong><br /> | |
- | + | <br /> | |
- | + | <strong>a. Risks to the safety and health of team members or others working in the lab?</strong><br /> | |
- | + | Our team works with <em>Escherichia coli</em> DH5α and BL21(DE3). According to Material Safety Data Sheet (MSDS), the wild-type strain of <em>E. coli</em> may irritate the skin, eyes, respiratory tract, blood circulation, and kidney. We modified the strain it so we know the desired target sample by inserting the coding sequences, promoters, and reporter genes. The insertion are not expected to increase bacterial pathogenicity in any way. In addition to our work with <em>E. coli</em>, our team also works with aflatoxin which, a carcinogenic and harmful chemical. To minimize the risk, our team and the researchers in our lab always working safely by using gloves, lab coats, mask, and goggles (if necessary). <br /> | |
- | + | The vector used in this project is standarized, widely used, and resistent to some antibiotics such as pSB1C3 (Registry of Standard Biological Parts). It is not expected to pose any risk to human health, nor should such resistance determinants be passed to other bacteria.<br /> | |
- | + | <strong>b. Risks to the safety and health of the general public, if released by design or by accident?</strong><br /> | |
- | + | Our project would not impact the environment in a harmful way. This can be seen not only in the use of device but is also in the lab practice, all of waste bacteria, medium, and disposable goods are discarded according to the procedure. For waste bacteria and the medium, it must pass through destruction stages by autoclaving to ensure all bacteria die before actually dumped into disposal.<br /> | |
- | + | Additionally, we designed our whole-cell biosensor from modified <em>E. coli</em> strain. To maintain the pblic health safety and health, our device is equipped with membrane that doesn't allow <em>E. coli</em> to exit the device so we ensured the safety of the user. The final device will use freeze-dried <em>E. coli</em> which is susceptible to moisture (hygroscopic) so that if there is any leakage in the device the freeze-dried <em>E. coli</em> inside will be damaged and no longer works. This system would reduce the risk to the public and environment.<br /> | |
- | + | <strong>c. Risk to the environment, if released by design or by accident?</strong><br /> | |
- | + | As detailed above we have thought carefully about how to prevent our modified strains from entering the environment. Inserted genes are not expected to increase the ability of the organisms to survive in the external environment and cause harm to any other organisms.<br /> | |
- | + | <strong>d. Risk to security through malicious misuse by individuals, groups, or countries?</strong><br /> | |
- | + | In addition to the hazards posed by the lab workers, as well as the design in our devices, the potential danger is also determined by abuse committed by careless people. Modified strains could be used as a biological weapon to cause new diseases and potentially mess up a country. This is most likely not going to happen to our device, because we use freeze-dried <em>E. coli</em> that can only survive inside the device and are not resistant to changes in humidity and oxygen levels. So if malicious people try to steal the modified strains in our device, it can be ascertained that the modified strains will defunct when the thieves want to use it.<br /> | |
- | + | <strong>If your project moved from a small-scale lab study to become widely used as a commercial/industrial product, what new risk might arise? (Consider the different categories of risks that are listed in parts a-d of the previous question.) also, what risk might arise if the knowledge you generate or the methods you develop became widely available ? (Note: this is meant to be a somewhat open-ended discussion question.)</strong><br /> | |
- | + | Our primary motive to design our project is public well-being, to improve global health by monitoring the food safety. We have also foresee the public and environmental implication as stated above. Actually, making our device can be used commercially by the industry is a long way because it must pass through stages of validation with a series of tests, such as allergicity test, toxicity test, immunity test, and other test support. Although it has been ascertained that the modified strains in our device will not work when there is a change of oxygen and humidity levels the tests and validations still have to be implemented for the health and safety of the user and the environment.<br /> | |
- | + | <strong>Does your project include any design features to address safety risks? (For example: kill switches, auxotrophic chassis, etc.) Note that including such features is not mandatory to participate in iGEM, but many groups choose to include them.</strong><br /> | |
- | + | Yes, it does. We would engineer our strains to contain kill-switches. It is associated with the disposable nature of our device. To ensure the safety and health of the users and the environment, we want to apply the principle of kill-switches so that after the aflatoxin detection process is finished, modified strains can die in the time set, and can be safely disposed.<br /> | |
- | + | <strong>What safety training have you received (or plan to receive in the future) ? Provide a brief description, and a link to your institution’s safety training requirements, if available.</strong><br /> | |
- | + | Specific safety training is not done by our campus, but the materials on health and has become compulsory for credits in several courses at ITB. The name of the course varies for each study program, such as the Health and Safety in Bioindustry Workplace, Biosafety, Security in Process Factory, etc.. We'll have a meeting and discussion with a number of faculty staff who are experts in this field to discuss the biosafety our device, besides writing scholarly articles about health and safety of using Genetically Modified Microorganisms.<br /> | |
- | + | <strong>Under what biosafety provisions will/do you work?</strong><br /> | |
- | + | <strong>a. Please provide a link to your institution biosafety guidelines</strong><br /> | |
- | + | <br /> | |
- | + | <a href="http://www.che.itb.ac.id/safety">http://www.che.itb.ac.id/safety</a></p> | |
- | + | <p><a href="http://www.tf.itb.ac.id/files/2011/11/SOP-K3-Laboratorium-Teknik-Fisika.pdf">http://www.tf.itb.ac.id/files/2011/11/SOP-K3-Laboratorium-Teknik-Fisika.pdf</a></p> | |
- | + | <p><a href="http://www.tf.itb.ac.id/files/2011/11/KEPUTUSAN-sop-kedaruratan.pdf">http://www.tf.itb.ac.id/files/2011/11/KEPUTUSAN-sop-kedaruratan.pdf</a></p> | |
- | + | <p><strong>b. Does your institution have an Institutional Biosafety Committee, or an equivalent group? If yes, have you discussed your project with them? Describe any concerns they raised with your project, and any changes you made to your project plan based on their review.</strong><br /> | |
- | + | Our institution has a committee dealing with environmental security, health, safety, and (K3L). But they didn’t concerned in biosafety of modified organisms. In addition, our biosafety committe (K3L) deals only in laboratory safety and environment security.<br /> | |
- | + | <strong>c. Does your country have national biosafety regulations or guidelines? If so, please provide the link to these regulations or guidelines if possible.</strong><br /> | |
- | + | Yes, our country does. It can be accessed in <a href="http://indonesiabch.or.id/tentang-bkkhi/">http://indonesiabch.or.id/tentang-bkkhi/</a> <br /> | |
+ | <strong>d. According to the WHO Biosafety Manual, what is the BioSafety Level rating of your lab? </strong><br /> | ||
+ | BioSafety Level 1<br /> | ||
+ | <strong>e. What is the Risk Group of your chasis organism(s), as you stated in question 1 ? if it does not match the BSL rating of your laboratory, please explain what additional safety measures you are taking.</strong><br /> | ||
+ | Risk Group 1</p> | ||
<b>References</b> | <b>References</b> | ||
<p>[1]http://oba.od.nih.gov/oba/rac/Guidelines/NIH_Guidelines.htm#_Appendix_C-II-A._Exceptions</p> | <p>[1]http://oba.od.nih.gov/oba/rac/Guidelines/NIH_Guidelines.htm#_Appendix_C-II-A._Exceptions</p> |
Latest revision as of 03:09, 28 September 2013
Project Safety
Do the biological materials used in your lab work pose any of the following risks? Please describe.
a. Risks to the safety and health of team members or others working in the lab?
Our team works with Escherichia coli DH5α and BL21(DE3). According to Material Safety Data Sheet (MSDS), the wild-type strain of E. coli may irritate the skin, eyes, respiratory tract, blood circulation, and kidney. We modified the strain it so we know the desired target sample by inserting the coding sequences, promoters, and reporter genes. The insertion are not expected to increase bacterial pathogenicity in any way. In addition to our work with E. coli, our team also works with aflatoxin which, a carcinogenic and harmful chemical. To minimize the risk, our team and the researchers in our lab always working safely by using gloves, lab coats, mask, and goggles (if necessary).
The vector used in this project is standarized, widely used, and resistent to some antibiotics such as pSB1C3 (Registry of Standard Biological Parts). It is not expected to pose any risk to human health, nor should such resistance determinants be passed to other bacteria.
b. Risks to the safety and health of the general public, if released by design or by accident?
Our project would not impact the environment in a harmful way. This can be seen not only in the use of device but is also in the lab practice, all of waste bacteria, medium, and disposable goods are discarded according to the procedure. For waste bacteria and the medium, it must pass through destruction stages by autoclaving to ensure all bacteria die before actually dumped into disposal.
Additionally, we designed our whole-cell biosensor from modified E. coli strain. To maintain the pblic health safety and health, our device is equipped with membrane that doesn't allow E. coli to exit the device so we ensured the safety of the user. The final device will use freeze-dried E. coli which is susceptible to moisture (hygroscopic) so that if there is any leakage in the device the freeze-dried E. coli inside will be damaged and no longer works. This system would reduce the risk to the public and environment.
c. Risk to the environment, if released by design or by accident?
As detailed above we have thought carefully about how to prevent our modified strains from entering the environment. Inserted genes are not expected to increase the ability of the organisms to survive in the external environment and cause harm to any other organisms.
d. Risk to security through malicious misuse by individuals, groups, or countries?
In addition to the hazards posed by the lab workers, as well as the design in our devices, the potential danger is also determined by abuse committed by careless people. Modified strains could be used as a biological weapon to cause new diseases and potentially mess up a country. This is most likely not going to happen to our device, because we use freeze-dried E. coli that can only survive inside the device and are not resistant to changes in humidity and oxygen levels. So if malicious people try to steal the modified strains in our device, it can be ascertained that the modified strains will defunct when the thieves want to use it.
If your project moved from a small-scale lab study to become widely used as a commercial/industrial product, what new risk might arise? (Consider the different categories of risks that are listed in parts a-d of the previous question.) also, what risk might arise if the knowledge you generate or the methods you develop became widely available ? (Note: this is meant to be a somewhat open-ended discussion question.)
Our primary motive to design our project is public well-being, to improve global health by monitoring the food safety. We have also foresee the public and environmental implication as stated above. Actually, making our device can be used commercially by the industry is a long way because it must pass through stages of validation with a series of tests, such as allergicity test, toxicity test, immunity test, and other test support. Although it has been ascertained that the modified strains in our device will not work when there is a change of oxygen and humidity levels the tests and validations still have to be implemented for the health and safety of the user and the environment.
Does your project include any design features to address safety risks? (For example: kill switches, auxotrophic chassis, etc.) Note that including such features is not mandatory to participate in iGEM, but many groups choose to include them.
Yes, it does. We would engineer our strains to contain kill-switches. It is associated with the disposable nature of our device. To ensure the safety and health of the users and the environment, we want to apply the principle of kill-switches so that after the aflatoxin detection process is finished, modified strains can die in the time set, and can be safely disposed.
What safety training have you received (or plan to receive in the future) ? Provide a brief description, and a link to your institution’s safety training requirements, if available.
Specific safety training is not done by our campus, but the materials on health and has become compulsory for credits in several courses at ITB. The name of the course varies for each study program, such as the Health and Safety in Bioindustry Workplace, Biosafety, Security in Process Factory, etc.. We'll have a meeting and discussion with a number of faculty staff who are experts in this field to discuss the biosafety our device, besides writing scholarly articles about health and safety of using Genetically Modified Microorganisms.
Under what biosafety provisions will/do you work?
a. Please provide a link to your institution biosafety guidelines
http://www.che.itb.ac.id/safety
http://www.tf.itb.ac.id/files/2011/11/SOP-K3-Laboratorium-Teknik-Fisika.pdf
http://www.tf.itb.ac.id/files/2011/11/KEPUTUSAN-sop-kedaruratan.pdf
b. Does your institution have an Institutional Biosafety Committee, or an equivalent group? If yes, have you discussed your project with them? Describe any concerns they raised with your project, and any changes you made to your project plan based on their review.
Our institution has a committee dealing with environmental security, health, safety, and (K3L). But they didn’t concerned in biosafety of modified organisms. In addition, our biosafety committe (K3L) deals only in laboratory safety and environment security.
c. Does your country have national biosafety regulations or guidelines? If so, please provide the link to these regulations or guidelines if possible.
Yes, our country does. It can be accessed in http://indonesiabch.or.id/tentang-bkkhi/
d. According to the WHO Biosafety Manual, what is the BioSafety Level rating of your lab?
BioSafety Level 1
e. What is the Risk Group of your chasis organism(s), as you stated in question 1 ? if it does not match the BSL rating of your laboratory, please explain what additional safety measures you are taking.
Risk Group 1
[1]http://oba.od.nih.gov/oba/rac/Guidelines/NIH_Guidelines.htm#_Appendix_C-II-A._Exceptions
[2] World Health Organization. 2004. Laboratory Biosafety Manual, third edition. Geneva. WHO Library.
[3] Acros Organics. Aflatoxin B1 Material Safety Data Sheet. Accesed from http://www.chemdb-portal.cn/fisher_msds_pdf/1162-65-8_EN.pdf on 9 Junie 2013 at 10.05 am.