Revision as of 21:16, 24 September 2018

Project Description

What is Pixcell?

As part of the international Genetically Engineered Machine (iGEM) competition in synthetic biology, we are developing PixCell, a foundational technology using an electrogenetic mechanism which links a bacterial response to an electrical stimuli. The system consists of genetically engineered bacteria encoding genetic networks that are activated or deactivated at specific voltages. We are developing hardware (an electrode array), software (in silico models and computational controller) and genetic networks (DNA circuits which produce fluorescence in response to electrical signals) to build a predictable, programmable system for spatial patterning of cells.

Biological Modules

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Electrochemical Modules

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Pixcell

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Why is Pixcell useful?

Turning specific genes on and off is a fundamental step towards controlling biological systems. If we want to be able to engineer cells, tissues and perhaps entire organisms using a bottom-up approach (from the DNA components to the biological system) we need a way to control the spatio-temporal expression of genes. Our technology is a foundational advance in this field.

Pixcell is The Future

There are several alternative methods that allow spatio-temporal control of gene expression. The classic way is to use chemical inducers that bind control transcription factors (which affect expression of genes) which are orthogonal (taken from an organism other than the chassis being used to prevent interactions with the host’s genetic networks). Gene expression can also be achieved via physical signals, such as temperature, pressure and light. The field of optogenetics, which uses light to control gene expression, is a competitive alternative to the electrogenetic system we are developing due to its ease of computational control. (Important: the addition of new sets of tools for this purpose can open possibilities regards control that cannot be archived by only one methodology)

BASICS & Automation Methods

Not only the project itself, the methods we used are also novel.

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 <div class="what">
-     <h2>What is Pixcell?</h2>
+     <h3>What is Pixcell?</h3>
      <p2>As part of the international Genetically Engineered Machine (iGEM) competition in synthetic biology, we are developing PixCell, a foundational technology using an electrogenetic mechanism which links a bacterial response to an electrical stimuli. The system consists of genetically engineered bacteria encoding genetic networks that are activated or deactivated at specific voltages. We are developing hardware (an electrode array), software (in silico models and computational controller) and genetic networks (DNA circuits which produce fluorescence in response to electrical signals) to build a predictable, programmable system for spatial patterning of cells.</p2>
 </div>
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 <div class="why">
-         <h2>Why is Pixcell useful?</h2>
+         <h3>Why is Pixcell useful?</h3>
          <p2> Turning specific genes on and off is a fundamental step towards controlling biological systems. If we want to be able to engineer cells, tissues and perhaps entire organisms using a bottom-up approach (from the DNA components to the biological system) we need a way to control the spatio-temporal expression of genes. Our technology is a foundational advance in this field.</p2>
 </div>
 <div class="how">
-         <h2>Pixcell is The Future</h2>
+         <h3>Pixcell is The Future</h3>
          <p2> There are several alternative methods that allow spatio-temporal control of gene expression. The classic way is to use chemical inducers that bind control transcription factors (which affect expression of genes) which are orthogonal (taken from an organism other than the chassis being used to prevent interactions with the host&#8217;s genetic networks). Gene expression can also be achieved via physical signals, such as temperature, pressure and light. The field of optogenetics, which uses light to control gene expression, is a competitive alternative to the electrogenetic system we are developing due to its ease of computational control. (Important: the addition of new sets of tools for this purpose can open possibilities regards control that cannot be archived by only one methodology)</p2>
          <h2>BASICS & Automation Methods</h2>
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 <div class="manual">
-         <h2>Manual Guide</h2>
+         <h3>Manual Guide</h3>
          <iframe src=""></iframe>
 </div>

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