Test2

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|[[Image:2005-logo.jpg]]
|[[Image:2005-logo.jpg]]
|'''2005'''
|'''2005'''
|In the summer of 2005, 13 teams worked on projects involving chemotaxis regulation systems, cell-cell genetic communications systems, cellular/biological wires, thermometers, biological sketch pads (drawing systems), cellular relay races, a digital counter, and more. [[Igem 2005|Read more]]
|In the summer of 2005, 13 teams worked on projects involving chemotaxis regulation systems, cell-cell genetic communications systems, cellular/biological wires, thermometers, biological sketch pads (drawing systems), cellular relay races, a digital counter, and more. [[Igem 2005|Read more]]
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|[[Image:2004-logo.jpg]]
|[[Image:2004-logo.jpg]]
|'''2004'''
|'''2004'''
|This year marked the first true Synthetic Biology Competition. Teams from five schools competed to build cellular state machines and counters. The teams came together for a ''jamboree'' in early November to compare their results.  The most graphic project was "photographic biofilm" that could capture an image (now called ''coliroid film''). [[Igem 2004|Read more]]
|This year marked the first true Synthetic Biology Competition. Teams from five schools competed to build cellular state machines and counters. The teams came together for a ''jamboree'' in early November to compare their results.  The most graphic project was "photographic biofilm" that could capture an image (now called ''coliroid film''). [[Igem 2004|Read more]]
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|[[Image:2004-iap.jpg]]
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|'''2004'''
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|During the January  [[Iap 2004|2004 IAP]], MIT-based teams designed genetic systems to create cellular patterns varying from bull’s-eyes to polka dots, and even dynamic designs where cells would swim together.  From these designs, many standard biological parts (BioBricks) were designed and synthesized.
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|[[Image:2003-iap.jpg]]
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|'''2003'''
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|During MIT's [[Iap 2003|Independent Activity Periods (IAP) of January 2003]], students designed biological oscillators coupled to fluorescent reporters.  These genetic blinkers were intended to improve on Elowitz's Repressilator.  One team coupled two oscillators to even out the oscillations.  Another used cell-cell signaling to coordinate the oscillators in a colony.
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Revision as of 15:18, 14 August 2006

Previous Years

2005-logo.jpg 2005 In the summer of 2005, 13 teams worked on projects involving chemotaxis regulation systems, cell-cell genetic communications systems, cellular/biological wires, thermometers, biological sketch pads (drawing systems), cellular relay races, a digital counter, and more. Read more
2004-logo.jpg 2004 This year marked the first true Synthetic Biology Competition. Teams from five schools competed to build cellular state machines and counters. The teams came together for a jamboree in early November to compare their results. The most graphic project was "photographic biofilm" that could capture an image (now called coliroid film). Read more
2004-iap.jpg 2004 During the January 2004 IAP, MIT-based teams designed genetic systems to create cellular patterns varying from bull’s-eyes to polka dots, and even dynamic designs where cells would swim together. From these designs, many standard biological parts (BioBricks) were designed and synthesized.
2003-iap.jpg 2003 During MIT's Independent Activity Periods (IAP) of January 2003, students designed biological oscillators coupled to fluorescent reporters. These genetic blinkers were intended to improve on Elowitz's Repressilator. One team coupled two oscillators to even out the oscillations. Another used cell-cell signaling to coordinate the oscillators in a colony.
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