Difference between revisions of "Team:MSU-Michigan/Description"
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<h2><font color="grey"; face="Tw Cen MT"; size="5"><b>Microbial Fuel Cells</b></font></h2> | <h2><font color="grey"; face="Tw Cen MT"; size="5"><b>Microbial Fuel Cells</b></font></h2> | ||
| + | <h3>Paper MFC Procedure</h3> | ||
| + | <ul> <font face="Tw Cen MT"; size="4"> Purpose: Create ultra-low cost MFCs to be innoculated with Shewanella Oneidensis MR-1 and then induced with a selected compound | ||
| + | Materials | ||
| + | Whatman Paper | ||
| + | Scissors | ||
| + | Razor | ||
| + | Aluminum Foil | ||
| + | 8B Graphite Pencils | ||
| + | Carbon Cement | ||
| + | Crayon | ||
| + | Superglue (cyanoacrylate) | ||
| + | Parchment Paper | ||
| + | Procedure | ||
| + | Cut out 30mm x 30mm squares of whatman paper (6 per reactor) and one piece of parchment paper of the same size | ||
| + | Colour the sides of five pieces of whatman paper (5mm in from edges) with crayon (both sides). One piece can be set aside, this will be the blank. | ||
| + | Fully Colour one piece of whatman paper. This will be the cover. | ||
| + | Draw on the center of two pieces of paper with 8B graphite pencil for at least five repititions. These will be the anode and cathode. | ||
| + | Cut out 2cm long 1cm wide strips of aluminum foil. | ||
| + | Lightly superglue aluminum foil to wax part of both anode and cathode. Allow foil to extend 1cm onto anode/cathode. | ||
| + | Paint cement glue onto the anode and cathode. Ensure proper ventilation and safety. Allow to dry a minimum of five hours. | ||
| + | Cut the center out of two pieces of coloured whatman paper. These will be the chamber pieces. | ||
| + | Superglue the whatman paper together with small dabs of glue on only the corners of the paper in the order of cover, chamber, chamber, cathode (with foil facing up), blank, parchment paper, anode(with foil facing down).</ul> | ||
</html> | </html> | ||
Revision as of 14:27, 23 October 2017
Description
Biosensing Water Contaminants with Genetically Engineered Shewanella oneidensis MR-1
As one of the most important natural resources, the declining quality of fresh water is a world-wide issue. Pollutants such as pharmaceuticals, hormones and heavy metals are rarely monitored and the need to detect and remove these compounds in an inexpensive way is what motivates this project. The marine bacterium Shewanella oneidensis MR-1 could be a part of the solution through its unique ability to interact with electronics. The Mtr pathway in S. oneidensis MR-1 is an external electron transportation pathway that is able to transfer electrons to an external acceptor such as an anode, thus generating electric current that is utilized in bioelectrochemical systems. We are utilizing S. oneidensis MR-1 △MtrB, the MtrB gene is removed, to prevent electron flow to an outside source through this key protein. We are then inserting a plasmid into this strain that contains the MtrB gene under control of a promoter that activates transcription of the protein when induced by compounds such as pesticides and metals in the water. This will allow for controlled electrical expression that can be used in microbial fuel cells to create a biosensor for the detection of these compounds. This biosensor will then be engineered to be manufactured on a large scale to be used for research, education, humanitarian efforts and even consumer use. Although the proof of concept is currently tested in a single chambered bioelectrochemical system, an affordable and portable paper microbial fuel cell system is currently in development.
Why?
As a Michigan team, water quality is an issue that hits very close to home. The Flint Water Crisisgained national attention for the extremely elevated lead contamination in the drinking water. This crisis began in 2014, however the Flint residents are advised to continue using filtered or bottled water until the pipes are fully replaced by the year 2020. Another famous American case of poor water quality is the Hinkley groundwater contamination made public by Erin Brockovich in 1993.
Microbial Fuel Cells
Paper MFC Procedure
- Purpose: Create ultra-low cost MFCs to be innoculated with Shewanella Oneidensis MR-1 and then induced with a selected compound
Materials
Whatman Paper
Scissors
Razor
Aluminum Foil
8B Graphite Pencils
Carbon Cement
Crayon
Superglue (cyanoacrylate)
Parchment Paper
Procedure
Cut out 30mm x 30mm squares of whatman paper (6 per reactor) and one piece of parchment paper of the same size
Colour the sides of five pieces of whatman paper (5mm in from edges) with crayon (both sides). One piece can be set aside, this will be the blank.
Fully Colour one piece of whatman paper. This will be the cover.
Draw on the center of two pieces of paper with 8B graphite pencil for at least five repititions. These will be the anode and cathode.
Cut out 2cm long 1cm wide strips of aluminum foil.
Lightly superglue aluminum foil to wax part of both anode and cathode. Allow foil to extend 1cm onto anode/cathode.
Paint cement glue onto the anode and cathode. Ensure proper ventilation and safety. Allow to dry a minimum of five hours.
Cut the center out of two pieces of coloured whatman paper. These will be the chamber pieces.
Superglue the whatman paper together with small dabs of glue on only the corners of the paper in the order of cover, chamber, chamber, cathode (with foil facing up), blank, parchment paper, anode(with foil facing down).
