Team:IBB Pune/BIOETHICS
From 2009.igem.org
(Difference between revisions)
(6 intermediate revisions not shown) | |||
Line 1: | Line 1: | ||
{{Team:IBB_Pune/header}} | {{Team:IBB_Pune/header}} | ||
{{Team:IBB_Pune/menu}} | {{Team:IBB_Pune/menu}} | ||
- | + | [[Image:Ethics_IBB_Pune.png|center]] | |
- | + | ||
- | + | ||
- | + | ||
- | + | ||
<html> | <html> | ||
<span style="font-weight:bold; font-size:150%; color:#0000cc;">BioEthics</span></html> | <span style="font-weight:bold; font-size:150%; color:#0000cc;">BioEthics</span></html> | ||
Line 26: | Line 22: | ||
<p> | <p> | ||
- | As scientists and citizens, we must address questions and controversies surrounding the use of biotechnology and make choices that will best serve humanity. We should be committed to the socially responsible use of biotechnology in health care, food and agriculture, industry and the environment. As biotechnology | + | As scientists and citizens, we must address questions and controversies surrounding the use of biotechnology and make choices that will best serve humanity. We should be committed to the socially responsible use of biotechnology in health care, food and agriculture, industry and the environment. As biotechnology strives to provide us with benefits such as treatments for intractable diseases such as Cancer, Alzheimer’s and Parkinson’s; abundant, nutritious food; industrial sustainability; and a cleaner world, we encourage public discussion of the ethical, legal and social implications of biotechnology research. Responsible and ethical testing of new technologies and decisions regarding whether and how to use medical products and technologies must always be made with profound regard for the rights of patients. In our view, appropriate regulation of biotechnology is solidly rooted in values such as autonomy, privacy, beneficence, social justice and intellectual freedom. |
</p> | </p> | ||
Line 35: | Line 31: | ||
</html> | </html> | ||
- | <span style="font-weight:bold; font-size:125%; color:#0000cc;"><p>1. Synthetic Biology: How is it different from the ad-hoc molecular cloning / Genetic Engineering/RDT?</p></span> | + | <span style="font-weight:bold; font-size:125%; color:#0000cc;"><p>1. Synthetic Biology: How is it different from the ad-hoc molecular cloning / Genetic Engineering / RDT?</p></span> |
- | <span style="font-weight:bold; font-size:100%; color:#0000cc;"><p> The scope | + | <span style="font-weight:bold; font-size:100%; color:#0000cc;"><p> The scope is now wider and simpler.</p></span> |
<html> | <html> | ||
Line 68: | Line 64: | ||
<li>''Risks involved in synthetic biology practices'' | <li>''Risks involved in synthetic biology practices'' | ||
- | Some of the risks posed by products of synthetic biology are outlined below. As we move up the classification hierarchy of synthetic biology products, and thus on to higher levels of integration, the risks increase. | + | Some of the risks posed by products of synthetic biology are outlined below. As we move up the classification hierarchy of synthetic biology products, and thus on to higher levels of integration, the risks increase. Also, with initiatives like iGEM, the layman gets an easier access to such sensitive technologies and the risks involved are enormous. Hence a thorough and well thought-out safety structure is essential. |
<li>''Risk of negative environmental impact:'' | <li>''Risk of negative environmental impact:'' | ||
Line 75: | Line 71: | ||
<li>'' Risk of natural genome pool contamination:'' Any genetic exchange between a synthetic biological entity and a naturally occurring biological entity would result in natural genome contamination. This is similar to the problem of “gene-flow” in the context of transgenic plants. | <li>'' Risk of natural genome pool contamination:'' Any genetic exchange between a synthetic biological entity and a naturally occurring biological entity would result in natural genome contamination. This is similar to the problem of “gene-flow” in the context of transgenic plants. | ||
- | <li>''Run-off risk (“Grey-goo” problem):'' This is similar to the problem often discussed in the context of nanotechnology. Synthetic biology products released into the environment to accomplish a specific task should have a controlled lifespan outside the lab. If this in not the case, one can envision unintended consequences of a system | + | <li>''Run-off risk (“Grey-goo” problem):'' This is similar to the problem often discussed in the context of nanotechnology. Synthetic biology products released into the environment to accomplish a specific task should have a controlled lifespan outside the lab. If this in not the case, one can envision unintended consequences of a system running amuck. |
<li>''Risk of creation of deadly pathogens for the purposes of bio-terrorism:'' The creation of the complete genome of Polio virus in the lab shows the potential of synthetic biology to engineer harmful pathogens. This technology, in rogue hands, could be used to engineer the genomes of deadly pathogens. The fact that the synthetic Polio virus was proven to be infectious shows the deadly potential of this technology. | <li>''Risk of creation of deadly pathogens for the purposes of bio-terrorism:'' The creation of the complete genome of Polio virus in the lab shows the potential of synthetic biology to engineer harmful pathogens. This technology, in rogue hands, could be used to engineer the genomes of deadly pathogens. The fact that the synthetic Polio virus was proven to be infectious shows the deadly potential of this technology. | ||
Line 111: | Line 107: | ||
<p> | <p> | ||
- | For over 200 years, intellectual property laws have been the driving force for innovation and progress. The biotechnology industry as we know it did not exist prior to the landmark US Supreme Court decision of Diamond v. Chakrabarty of 1980. The court held that anything made by the hand of man was eligible for patenting. Since this decision, the biotechnology industry has flourished and continues to grow. The patent system fosters the development of new biotechnology products and discoveries, new uses for old products and employment opportunities for millions of | + | For over 200 years, intellectual property laws have been the driving force for innovation and progress. The biotechnology industry of bioengineered organisms as we know it did not exist prior to the landmark US Supreme Court decision of Diamond v. Chakrabarty of 1980. The court held that anything made by the hand of man was eligible for patenting. Since this decision, the biotechnology industry has flourished and continues to grow. The patent system fosters the development of new biotechnology products and discoveries, new uses for old products and employment opportunities for millions of people the world over. Patents add value to laboratory discoveries, providing incentives for private sector investment into biotechnology development of new medicines and diagnostics for treatment and monitoring of intractable diseases, and agricultural and environmental products, to meet global needs. Patents facilitate academic research, because the release of information to the public is critical to the advancement of knowledge. The fact that an inventor can obtain patent protection on an invention encourages inventors not to withhold beneficial information from the public. In fact, the patent system provides strong incentive for sharing information. Not only can researchers use the information in a patent, but also by disclosing cutting-edge scientific information, the patent system helps prevent expensive duplication of efforts. |
+ | Thus, the patent system ushers in a new era of public disclosure of all new developments and patents. Thus, the public is made aware of the goings on in the world of synthetic biology. This makes it even more imperative that we as scientists should take it upon us to educate the public and stimulate everyone to think about the complex ethical issues involved in the widespread use of such sensitive technology. | ||
+ | |||
</p> | </p> | ||
Line 146: | Line 144: | ||
<br> | <br> | ||
- | <p><span style="font-weight:bold; font-size:125%; color:#0000cc;">Consideration of Ethical issues, conceptualization of projects in accordance with the | + | <p><span style="font-weight:bold; font-size:125%; color:#0000cc;">Consideration of Ethical issues, conceptualization of projects in accordance with the Bioethics:</span></p> |
- | Our project involves creation of synthetic constructs to be used for specific functions. We are attempting to construct a multi-state Turing machine which is a compound, modular computational system that has independent, interacting states which applies the above principle. This approach might overcome the shortcomings in building more complex and composite circuits | + | Our project involves creation of synthetic constructs to be used for specific functions. We are attempting to construct a multi-state Turing machine which is a compound, modular computational system that has independent, interacting states which applies the above principle. This approach might overcome the shortcomings in building more complex and composite circuits. |
<p><span style="font-weight:bold; font-size:125%; color:#0000cc;">Host organism :</span></p> | <p><span style="font-weight:bold; font-size:125%; color:#0000cc;">Host organism :</span></p> |
Latest revision as of 20:32, 22 October 2009