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<p>The more complex the system, the more control is required. PixCell introduces a new method of control to synthetic biology: electronic control.</p> | <p>The more complex the system, the more control is required. PixCell introduces a new method of control to synthetic biology: electronic control.</p> | ||
− | <img class="centerimg" src="https://static.igem.org/mediawiki/2018/ | + | <img class="centerimg" src="https://static.igem.org/mediawiki/2018/c/c2/T--Imperial_College--FIGX2T.gif"> |
<p> Electronic control circuits have provided us with the complex technology we use everyday of our lives. With PixCell we bring electronic control to synthetic biology. We also prove how it can provide the spatiotemporal control required for a key condition of biological complexity: patterning. </p> | <p> Electronic control circuits have provided us with the complex technology we use everyday of our lives. With PixCell we bring electronic control to synthetic biology. We also prove how it can provide the spatiotemporal control required for a key condition of biological complexity: patterning. </p> | ||
Revision as of 22:16, 16 October 2018
PixCell
Electronic Stimulation of Gene Expression
Pixcell: Electronic Control of Biological Patterning
The more complex the system, the more control is required. PixCell introduces a new method of control to synthetic biology: electronic control.
Electronic control circuits have provided us with the complex technology we use everyday of our lives. With PixCell we bring electronic control to synthetic biology. We also prove how it can provide the spatiotemporal control required for a key condition of biological complexity: patterning.