BE REU @ SLU Department of Chemistry Dr. Shelley D. Minteer
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Transcript BE REU @ SLU Department of Chemistry Dr. Shelley D. Minteer
Enzymatic Glucose Biofuel Cell:
Concentration Studies
and Biocompatibility
Joe Fazio
BE REU @ SLU
Dr. Shelley D. Minteer
Kyle Sjöholm
SLU Department of Chemistry
Background
Enzymatic Biofuel cell:
Enzymes
Power biomedical
devices
High power and current
density
Incomplete oxidation
www.nano-biokit.com
Biofuel Cell Process
Reaction at anode produces
protons
Electrons create current
Protons diffuse to cathode
Protons at cathode react
with oxygen
Mediated Electron Transfer (MET)
Electrocatalyst
Commonly used to
reduce overpotential
2e-
Glucose
NADH
Facilitates ion
transfer to electrode
Gluconolactone
NAD+
Glucose
Dehydrogenase
Entrapped in
Polymer
060 Toray
Paper
Electrode
Modified Polymers
Immobilize enzymes
Extend functional lifetime
Microencapsulation:
Support enzyme structure
Neutral pH
Micellar environment
Geometry
Ion exchange
properties
Polymer encapsulation
Project Goals
Power Densities
Hypoglycemic (3mM)
Normal (5mM)
Hyperglycemic (8mM)
Biocompatibility
Bulk electrolysis
Live/dead assay
•
Biofilm formation
Basic Components
Anode: 060 Toray Paper electrodes
Fuel: Glucose
Enzyme: Glucose Dehydrogenase
Cofactor: NAD+
Electrocatalyst: Poly(methylene green) (PMG)
Modified polymer:
Nafion®
Chitosan
Electrode Preparation
Polymer modification
Nafion®: Tetrabutylammonium bromide (TBAB)
Chitosan
Hydrophobic
Deacylation
Chitosan
http://www.global-b2b-network.com/
Co-cast polymer and enzyme onto electrode
Soak electrodes in solution of glucose overnight
Experimental Set-up
3, 5, 8mM glucose fuel
NAD+, pH 7.4 phosphate buffer
Bioanode
V
Glass tube
Fuel Solution
Open circuit potential
(~1000secs)
Linear sweep voltammetry
(<1mV/sec)
Power density equation
P=I*V
+
O-ring
Nafion PEM
4.5cm 2 20% Pt
GDE Cathode
O-ring
Glass tube
Diagram of Icell
Air
Potentiostat
Power Density Test Results
5mM Averages
7e-6
7e-6
6e-6
6e-6
Power Density, Watts/cm2
Power Density, Watts/cm2
3mM Averages
5e-6
4e-6
3e-6
2e-6
1e-6
4e-6
3e-6
2e-6
1e-6
0
0
0
1e-5
2e-5
3e-5
Current Density, Amps/cm
4e-5
2
0
1e-5
Deacylated Chitosan
Chitosan
Nafion
8mM Averages
8e-6
Power Density, Watts/cm2
5e-6
2e-5
3e-5
Current Density, Amps/cm
4e-5
5e-5
2
Average Maximum Power Density* µW/cm2
6e-6
4e-6
2e-6
0
0
1e-5
2e-5
3e-5
Current Density, Amps/cm2
4e-5
5e-5
3mM
5mM
8mM
Chitosan
2.87(±0.21)
2.82(±0.52)
3.32(±0.46)
Deacylated
chitosan
6.04(±3.23)
6.15(±3.51)
7.52(±4.31)
Nafion®
0.28(±0.02)
0.29(±0.02)
0.33(±0.04)
*errors are equal to one standard deviation
Biocompatibility, Bulk Electrolysis
Decreasing current
Possible biofilm
formation
6e-6
5e-6
Current, Amps
Testing
Bacteria culture
injected
Hold fuel cell at 0.3V
and monitor current (3
days)
4e-6
3e-6
2e-6
1e-6
0
0.0
5.0e+4
1.0e+5
1.5e+5
Time, seconds
2.0e+5
2.5e+5
Biocompatibility, Live/dead Assay
Live/Dead assay
Cast polymer with bacteria
Gluconobacter SP33
Origami C4-AW genetically modified E. Coli
Fluorescent nucleic acid stains
FITC filter- live bacteria
TRITC filter- dead bacteria
Live/Dead Assay
Assay showed
biocompatibility
for all polymers.
FITC filter
Chitosan E. coli
Deacylated chitosan
Gluconobacter
Nafion® E. coli
Nafion® Gluconobacter
TRITC filter image
Olympus IX71 fluorescence microscope
Conclusions
Chitosan and Nafion® can immobilize GDH
Chitosan provides higher power and current
densities
Chitosan and Nafion® provide biocompatible
surface material
Future work
Temperature and pH studies
Biocompatible modifications
Impact on current densities
Acknowledgements
National Science Foundation
Saint Louis University
Dr. Minteer
Minteer group
Kyle Sjöholm
Dr. Waheed
Rob Arechederra
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