Team:UC Davis/Electrochemistry
From 2014.igem.org
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Revision as of 05:07, 15 October 2014
Electrode Choice
Electrode Choice
System Optimization
System Optimization
Coupling Enzymes
Coupling Enzymes
Having settled on NAD+ dependent Aldehyde Dehydrogenases as our method of differentiating between aldehydes, we needed to develop an efficient electrode system to detect enzyme activity via NADH. We acquired, selected, and optimized an electrode setup for the detection of NADH at low concentrations in a complex solution. Additionally, we demonstrated the ability of the electrode setup to detect enzyme generated NADH over time, and thereby functionally deconvolute aldehyde profiles within a sample.
Electrode Choice
We developed our Electrode System to be:
- Sensitive: have a low limit of detection for NADH
- Reactive: Detect NADH with high linear range
- Selective: Be robust to any possible solution components
- Affordable: Cost accessible to the average consumer
- Efficient: Use a low sample volume
- Compatible: Be compatible with our, as well as other potentiostats
- Portable
We tested three screen printed base electrode types, and five different working electrode modification schemes in order to achieve the requisite sensitivity for our system. We settled on Dropsens screen printed #610 Electrodes, depicted above. To find out more about our electrode selection process, click here.
System Optimization
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Coupling Enzymes
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