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- | + | The only way to answer this is to actually ''try to engineer'' biological devices. | |
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The iGEM competition facilitates this by providing a library of standardized parts (we call these parts ''BioBricks'') to students, and asking them to design and build genetic machines with them. Of course, students are welcome to make their own BioBricks, too. | The iGEM competition facilitates this by providing a library of standardized parts (we call these parts ''BioBricks'') to students, and asking them to design and build genetic machines with them. Of course, students are welcome to make their own BioBricks, too. | ||
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So are we any closer to finding an answer to our question? Well, in just three years, students have managed to partially or completely build a variety of systems, from biosensors to biological photographic film, so it's looking better that engineering biology can be done. Stay tuned for the next batch of results, to be presented at the 2006 Jamboree in November. | So are we any closer to finding an answer to our question? Well, in just three years, students have managed to partially or completely build a variety of systems, from biosensors to biological photographic film, so it's looking better that engineering biology can be done. Stay tuned for the next batch of results, to be presented at the 2006 Jamboree in November. | ||
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- | The people behind iGEM | iGEM Resources | Previous iGEM years | Contact us | + | '''[[iGEM_staff|The people behind iGEM]] | [[Resources|iGEM Resources]] | [[iGEM_history|Previous iGEM years]] | [[iGEM_contact|Contact us]]''' |
Revision as of 23:46, 12 August 2006
iGEM - The international Genetically Engineered Machine competition
iGEM addresses the question: Can simple biological systems be built from standard, interchangeable parts and operated in living cells? Or is biology simply too complicated to be engineered in this way?
The only way to answer this is to actually try to engineer biological devices.
The iGEM competition facilitates this by providing a library of standardized parts (we call these parts BioBricks) to students, and asking them to design and build genetic machines with them. Of course, students are welcome to make their own BioBricks, too.
Information about BioBricks, and also some basic tools to manipulate them, are provided by the Registry of Standard Biological Parts, or simply, the [http://partsregistry.org Registry]. This is a core resource for the iGEM program.
Beyond trying to answer the question about, our broader goals include:
- To enable the systematic engineering of biology
- To promote the open and transparent development of tools for engineering biology
- And to help construct a society that can productively apply biological technology
So are we any closer to finding an answer to our question? Well, in just three years, students have managed to partially or completely build a variety of systems, from biosensors to biological photographic film, so it's looking better that engineering biology can be done. Stay tuned for the next batch of results, to be presented at the 2006 Jamboree in November.
The people behind iGEM | iGEM Resources | Previous iGEM years | Contact us