Team:ETH Zurich
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- | = Abstract = | + | = SmoColi - Abstract = |
- | '''We create a bacterio-quantifier of smoke. SmoColi cells are engineered to sense toxic substances found in cigarette smoke (for example acetaldehyde or xylene). They are immobilized in a microfluidic channel, in which a concentration gradient of the toxic substance is established. The sensor is linked to a band-pass filter that leads to input-concentration-dependent GFP expression. Continuous increase of the input concentration and its detection, therefore, establishes a moving fluorescent band in the channel. Finally, if the input concentration exceeds a certain threshold, cells produce RFP and the device turns red. Due to its modularity, our SmoColi system can be used in fact as a quantifier for a range of substances, as long as the sensor is adapted. To show that our system can be activated by different signals, as a proof of principle, we | + | '''We create a bacterio-quantifier of smoke. SmoColi cells are engineered to sense toxic substances found in cigarette smoke (for example acetaldehyde or xylene). They are immobilized in a microfluidic channel, in which a concentration gradient of the toxic substance is established. The sensor is linked to a band-pass filter that leads to input-concentration-dependent GFP expression. Continuous increase of the input concentration and its detection, therefore, establishes a moving fluorescent band in the channel. Finally, if the input concentration exceeds a certain threshold, cells produce RFP and the device turns red. Due to its modularity, our SmoColi system can be used in fact as a quantifier for a range of substances, as long as the sensor is adapted. To show that our system can be activated by different signals, as a proof of principle, we modified the circuit so that it can be induced by arabinose.''' |
{{:Team:ETH Zurich/Templates/SectionEnd}} | {{:Team:ETH Zurich/Templates/SectionEnd}} | ||
{{:Team:ETH Zurich/Templates/HeaderNewEnd}} | {{:Team:ETH Zurich/Templates/HeaderNewEnd}} |
Latest revision as of 01:31, 29 October 2011
SmoColi - Abstract
We create a bacterio-quantifier of smoke. SmoColi cells are engineered to sense toxic substances found in cigarette smoke (for example acetaldehyde or xylene). They are immobilized in a microfluidic channel, in which a concentration gradient of the toxic substance is established. The sensor is linked to a band-pass filter that leads to input-concentration-dependent GFP expression. Continuous increase of the input concentration and its detection, therefore, establishes a moving fluorescent band in the channel. Finally, if the input concentration exceeds a certain threshold, cells produce RFP and the device turns red. Due to its modularity, our SmoColi system can be used in fact as a quantifier for a range of substances, as long as the sensor is adapted. To show that our system can be activated by different signals, as a proof of principle, we modified the circuit so that it can be induced by arabinose.