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− | < | + | <h3>Microbial Fuel Cell with Yeast</h3> |
<p>Our original experiment, which used yeast as the electron transport agent, followed the University of Reading’s protocol kindly given to us by Dr Ed Milner, Dr Paniz Izadi and Professor Ian Head. The protocol can be seen <a href="https://2016.igem.org/Team:Newcastle/Protocols">here</a> </p> | <p>Our original experiment, which used yeast as the electron transport agent, followed the University of Reading’s protocol kindly given to us by Dr Ed Milner, Dr Paniz Izadi and Professor Ian Head. The protocol can be seen <a href="https://2016.igem.org/Team:Newcastle/Protocols">here</a> </p> | ||
− | < | + | <h3>Microbial Fuel Cell with E. coli</h3> |
<p>After discussing the ethical issues of using yeast with <a href="https://2016.igem.org/Team:Newcastle/Integrated_Practices">PEALS</a>, we decided to build novel genetic constructs for <i>E. coli</i>. However, we used the same protocol as above and made only slight changes, such as dissolving 1g of arabinose as well as the 9g of glucose into 50ml of potassium phosphate buffer solution. 4ml of the BBa_K1895004 and the BBa_K1895005 cell cultures were added to individual fuel cells during the experiments.</p> | <p>After discussing the ethical issues of using yeast with <a href="https://2016.igem.org/Team:Newcastle/Integrated_Practices">PEALS</a>, we decided to build novel genetic constructs for <i>E. coli</i>. However, we used the same protocol as above and made only slight changes, such as dissolving 1g of arabinose as well as the 9g of glucose into 50ml of potassium phosphate buffer solution. 4ml of the BBa_K1895004 and the BBa_K1895005 cell cultures were added to individual fuel cells during the experiments.</p> | ||
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<p>As evidenced by the given growth curves above, we can confirm that by placing the constructs under the pBAD arabinose-induced promoter, we can increase the overall growth of the battery constructs. Therefore we believe we have improved upon <a href="https://2013.igem.org/Team:Bielefeld-Germany/Project/MFC#Do_It_Yourself">the part developed by Bielefeld 2013 </a> who struggled to get their part to grow when placed under a T7 promoter.</p> | <p>As evidenced by the given growth curves above, we can confirm that by placing the constructs under the pBAD arabinose-induced promoter, we can increase the overall growth of the battery constructs. Therefore we believe we have improved upon <a href="https://2013.igem.org/Team:Bielefeld-Germany/Project/MFC#Do_It_Yourself">the part developed by Bielefeld 2013 </a> who struggled to get their part to grow when placed under a T7 promoter.</p> | ||
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Revision as of 18:02, 18 October 2016
Microbial Fuel Cell with Yeast
Our original experiment, which used yeast as the electron transport agent, followed the University of Reading’s protocol kindly given to us by Dr Ed Milner, Dr Paniz Izadi and Professor Ian Head. The protocol can be seen here
Microbial Fuel Cell with E. coli
After discussing the ethical issues of using yeast with PEALS, we decided to build novel genetic constructs for E. coli. However, we used the same protocol as above and made only slight changes, such as dissolving 1g of arabinose as well as the 9g of glucose into 50ml of potassium phosphate buffer solution. 4ml of the BBa_K1895004 and the BBa_K1895005 cell cultures were added to individual fuel cells during the experiments.
The fuel cells were left to run for an hour and the voltage taken every 3 minutes.
Figure 1. Reading microbial fuel cell output (mean±SE, mV). BBa_K1895005 caused overexpression of large porins , BBa_K1895004 caused overexpression of small porins. Separately, BBa_K1895004 with glucose only (no porin expression induction by arabinose) and LB broth only were used as negative controls. For both negative controls error bars are negligible and therefore difficult to distinguish on the graph. Voltages were measured every 3 minutes via digital voltmeter and the experiment stopped after 60 minutes.
Figure 2. Output of our microfluidic microbial fuel cell (mean±SE, mV) using the BBa_K1895004 construct undergoing porin expression. Solutions were made up as per the larger fuel cell, thoroughly mixed and injected by syringe to fill each chamber following insertion of the cation exchange membrane. Voltages were measured every 3 minutes via digital voltmeter and the experiment stopped after 60 minutes. For more information on how we designed the miniature fuel cell, please see our hardware design page
Conclusion
As evidenced by the given growth curves above, we can confirm that by placing the constructs under the pBAD arabinose-induced promoter, we can increase the overall growth of the battery constructs. Therefore we believe we have improved upon the part developed by Bielefeld 2013 who struggled to get their part to grow when placed under a T7 promoter.