Team:Bielefeld-CeBiTec/Results/rMFC/Construction
From 2014.igem.org
Module I - reverse microbial fuel cell (rMFC)
Construction of an electrobiochemical reactor
We planned to design a reactor system that is suitable to investigate the electrochemical behaviour in bioprocesses. That includes the possibility to characterize mediators and different electrode materials on the one hand and the electron uptake into the cells on the other.
During our research we discovered the H-cell reactor that seemed to meet with our needs. (Park et al., 1999)
We approached two different concepts to realize the reactor construction. One of our H-cell reactors was constructed with the possibilities given to us by the facillities of our university. We instructed the glass workshop to modify two glass bottles by adding a glass-flange. Besides that the technical workshop build the lids from stainless steel. This approach had the advantage that we could influence the design and had to make precise design drawings especially for the connections in the lids.
The second H-cell reactor was a commercially available system by Adams & Chittenden scientific glass. The commercial system had a smaller volume and the benefit of a larger flange diameter. The necessary lids for that system were also custom design by our workshop. In figure 1 you can see both reactors in comparison.
Figure 1: Single parts of our self-designed H-cell reactors: 1 Custom designed lids that provide connections for: a pO2-electrode, a pH-electrode, an entrance for reference and working electode, air output, heating coils and acid/ base input for pH control, 2 Heating coils, 3 Clamps for the flange connection 4 Sealing rings.
In addition to the H-cell design we thought of an alternative reactor design that meets with the requirements of direct electron transfer. To enable direct electron transfer it is necessary that there is a large electrode surface provided to the microorganisms. Furthermore substrate limitation should be avoided. To meet with these requirements it is favourable to have an reactor that can be continiously driven. Our proposed solution is a flow cell reactor (FCR) which could be driven continiously.
Testing the set up
Our first experiments were carried out with a constant power supply and we measured the voltage input and the current. The set up is shown in figure 2.
It turned out that we could not use the pH-electrode and the pO2-electrode during our cultivations, because they affected the measurement. Especially the pO2-electrode was not suitable in this set up, due to the fact that it is completely made of steel. It turned out that the electrode achieved a grounding of the system which set the lid under electric power. This resulted in a couple of unwanted oxidation processes at the weldseam of the lid. The consequence was to remove both electrodes from the system.
After the customization of the system we carried out a few test runs with differetn electrode materials. At this stage of the project we optimized the attachment of the electrodes and the isolation of the wire which was layed within a silicon tube through the lid.
THe first experiments showed that neutral red is reducable within out set up. The problems that occure if you work with a constant power supply are that the cell potential can not be kept at the same level during the experiments. The dynamic of the electrochemical reactions introduce unwelcome variabilities that cause fluctuations in the potential. Especially the presence of proliferating microorganisms can enhance this effect.
Different electrode materials
We tested different electrode materials for their potential to work in our reactor. We decided to investigate fabric carbon, fabric fleece als platinum electrodes. The different materials are shown in figure 3.
Carbon fabric is made up of individual fibres and has therefore a good stability. Another advantage is that the fibres consist of one piece and therefore has a good electrical conductivity.
The carbon fleece instead is thicker and provides a larger surface for the microorganisms to attach to the electrode material. This advantage goes at expense of stability.
Cultivation - constant voltage
The first experiments in the H-cell reactor were performed under constant direct voltage. These experiments were performed to test the set up. We investigated if E. coli was able to grow in the needed voltage range and if the different mediators influence the cells if a small electric current is applied.
Figure 5: Comparisson of the growth compatibility of the E. coli KRX WT strain if a voltage is applied or not. Both cultivations were performed in the H-cell reactor in M9 minimal media. One of the cultivatons was performed with an applied voltage of -330 mV. The optical density and the Xylose concentration were measured with technical duplicates.
Figure 5: Comparison of the growth of the E. coli KRX WT strain and the constructed E. coli ΔdcuB::oprF. Both strains were cultivated with a constant voltage of -330 mV in the H-cell reactor in M9 minimal media with 100 µM neutral red added. The optical density and the Xylose concentration were measured with technical duplicates.
Cyclic voltammetry - mediator characterization
During our experiments we used a Ag/AgCl reference electrode for measuring the working electrode potential. The counter electrode, which completes the cell circuit, was made from platinum wire. Platinum has the advantage that it is an inert conducter.
Parameter | Value |
---|---|
Mediator | Neutral red |
Scan rate [mV-s] | 35 |
Step size [mV] | 1 |
Scan limit E1 [V] | 0.3 |
Scan limit E2 [V] | -0.6 |
Electrode material | Platinum |
Aeriation | Oxygen free by aeriation with nitrogen |
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Parameter | Value |
---|---|
Mediator | Bromphenole blue |
Scan rate [mV-s] | 10 |
Step size [mV] | 1 |
Scan limit E1 [V] | 0.4 |
Scan limit E2 [V] | -0.85 |
Electrode material | Platinum |
Aeriation | Oxygen is present |
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Parameter | Value |
---|---|
Mediator | Neutral red |
Scan rate [mV-s] | 10 |
Step size [mV] | 2 |
Scan limit E1 [V] | 0.5 |
Scan limit E2 [V] | -0.6 |
Electrode material | Platinum |
Aeriation | Oxygen is present |
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Parameter | Value |
---|---|
Mediator | Neutral red |
Scan rate [mV-s] | 20 |
Step size [mV] | 1 |
Scan limit E1 [V] | 0.51 |
Scan limit E2 [V] | -0.8 |
Electrode material | Platinum |
Aeriation | Oxygen is present |
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Parameter | Value |
---|---|
Mediator | Neutral red |
Scan rate [mV-s] | 10 |
Step size [mV] | 1 |
Scan limit E1 [V] | 0.1 |
Scan limit E2 [V] | -0.6 |
Electrode material | Platinum |
Aeriation | Oxygen free by aeriation with nitrogen |
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Parameter | Value |
---|---|
Mediator | Neutral red in M9 minimal media with neutral red |
Scan rate [mV-s] | 10 |
Step size [mV] | 1 |
Scan limit E1 [V] | 0.7 |
Scan limit E2 [V] | -0.6 |
Electrode material | Platinum |
Aeriation | Oxygen present |
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Chronoamperometry - current consumption
Figure 2: Cultivation of the E. coli KRX ΔdcuB::oprF strain in M9 minimal media with 100 µM neutral red added. During the cultivation there was set a potential of -400 mV on the H-cell achieved by the chronoamperometric method. The figure shows the optical density, Xylose concentration, and the NAD/NADH level during the cultivation, plotted against time.
Figure 2: Cultivation of the E. coli KRX WT in M9 minimal media with 100 µM neutral red added. During the cultivation there was set a potential of -400 mV on the H-cell achieved by the chronoamperometric method. The figure shows the optical density, Xylose concentration, and the NAD/NADH level during the cultivation, plotted against time.
Figure 2: Cultivation of the E. coli KRX WT in M9 minimal media with 100 µM neutral red added. During the cultivation there was set a potential of -400 mV on the H-cell achieved by the chronoamperometric method. The figure shows the optical density, Xylose concentration, and the NAD/NADH level during the cultivation, plotted against time.
Flow Cell
References
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Park, D. H.,Laivenieks, M., Guettler, M. V., Jain, M. K. & Zeikus, J.G. (1999) Microbial utilization of electrically reduced neutral red as the sole electron donor for growth and metabolic production. In: Appl. Environ. Microbiol., 65 (7), pp. 2912 - 2917.