Difference between revisions of "Team:UNSW Australia/Human Practices/Law"

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<div id="legal-content" class="to-load">
 
<h2>Overview</h2>
 
<h2>Overview</h2>
<p>The legal frameworks surrounding synthetic biology are critically important because they determine what type of research can be undertaken, by selecting for research that is legally allowable, available and has potential commercial implications. However, scientists often fail to effectively lobby for frameworks that support their research needs whilst the current law remains inadequate<sup><a href=#references>1</a></sup></p>.
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<p>The legal frameworks surrounding synthetic biology are critically important because they determine what type of research can be undertaken, by selecting for research that is legally allowable, available and has potential commercial implications. However, scientists often fail to effectively lobby for frameworks that support their research needs whilst the current law remains inadequate<sup><a href=#references>1</a>.</sup></p>
 
<p>Our UNSW team discovered, as part of our foray into commercialisation and due diligence on our scaffold elements, that biotechnological patent law is difficult to comprehend from the scientific perspective. In Australia particularly, the legal test for patents is long and convoluted, and requires a thorough understanding of previous cases<sup><a href=#references>1</a></sup>. However, our team successfully interpreted the law to conclude that our scaffold was not patentable (reinforcing our modular ‘Foundational Advance’ technology approach) and that we could use our preferred protein-protein bonding mechanism.</p>
 
<p>Our UNSW team discovered, as part of our foray into commercialisation and due diligence on our scaffold elements, that biotechnological patent law is difficult to comprehend from the scientific perspective. In Australia particularly, the legal test for patents is long and convoluted, and requires a thorough understanding of previous cases<sup><a href=#references>1</a></sup>. However, our team successfully interpreted the law to conclude that our scaffold was not patentable (reinforcing our modular ‘Foundational Advance’ technology approach) and that we could use our preferred protein-protein bonding mechanism.</p>
 
<p>Considering this context, the UNSW team has come up with a creative solution – we have created a scientist’s guide to writing a policy proposal for government change, and written an example submission. We have also documented our discussions with various stakeholders, including the pharmaceutical industry, intellectual property academics, the UNSW Law Society, and the 2018 Pasteur Paris iGEM team.</p>
 
<p>Considering this context, the UNSW team has come up with a creative solution – we have created a scientist’s guide to writing a policy proposal for government change, and written an example submission. We have also documented our discussions with various stakeholders, including the pharmaceutical industry, intellectual property academics, the UNSW Law Society, and the 2018 Pasteur Paris iGEM team.</p>

Revision as of 15:58, 16 October 2018

Law and Regulation