EC Number | Application | Comment | Organism |
---|---|---|---|
1.1.3.4 | energy production | design of a bioanode that directly utilizes starch as a fuel in an enzymatic biofuel cell. The enzymatic fuel cell is based on three enzymes (alpha-amylase, glucoamylase and glucose oxidase). The carbon paste electrode containing these three enzymes and tetrathiafulvalene can both saccharize and oxidize starchy biomass. In cyclic voltammetry, catalytic currents are successfully observed with both glucose and starchy white rice used as a substrate. A membraneless white rice/O2 biofuel cell is assembled and the electrochemical performance is evaluated. The three enzyme based electrode is used as a bioanode and an immobilized bilirubin oxidase (derived from Myrothecium verrucaria) electrode is used as a biocathode. The biofuel cell deliveres an open circuit voltage of 0.522 V and power density of up to 0.099 mW/cm | Aspergillus niger |
1.3.3.5 | energy production | design of a bioanode that directly utilizes starch as a fuel in an enzymatic biofuel cell. The enzymatic fuel cell is based on three enzymes (alpha-amylase, glucoamylase and glucose oxidase). The carbon paste electrode containing these three enzymes and tetrathiafulvalene can both saccharize and oxidize starchy biomass. In cyclic voltammetry, catalytic currents are successfully observed with both glucose and starchy white rice used as a substrate. A membraneless white rice/O2 biofuel cell is assembled and the electrochemical performance is evaluated. The three enzyme based electrode is used as a bioanode and an immobilized bilirubin oxidase (derived from Myrothecium verrucaria) electrode is used as a biocathode. The biofuel cell delivers an open circuit voltage of 0.522 V and power density of up to 0.099 mW/cm | Albifimbria verrucaria |
3.2.1.1 | energy production | design of a bioanode that directly utilizes starch as a fuel in an enzymatic biofuel cell. The enzymatic fuel cell is based on three enzymes (alpha-amylase, glucoamylase and glucose oxidase). The carbon paste electrode containing these three enzymes and tetrathiafulvalene can both saccharize and oxidize starchy biomass. In cyclic voltammetry, catalytic currents are successfully observed with both glucose and starchy white rice used as a substrate. A membraneless white rice/O2 biofuel cell is assembled and the electrochemical performance is evaluated. The three enzyme based electrode is used as a bioanode and an immobilized bilirubin oxidase (derived from Myrothecium verrucaria) electrode is used as a biocathode. The biofuel cell deliveres an open circuit voltage of 0.522 V and power density of up to 0.099 mW/cm | Streptococcus equinus |
3.2.1.3 | energy production | design of a bioanode that directly utilizes starch as a fuel in an enzymatic biofuel cell. The enzymatic fuel cell is based on three enzymes (alpha-amylase, glucoamylase and glucose oxidase). The carbon paste electrode containing these three enzymes and tetrathiafulvalene can both saccharize and oxidize starchy biomass. In cyclic voltammetry, catalytic currents are successfully observed with both glucose and starchy white rice used as a substrate. A membraneless white rice/O2 biofuel cell is assembled and the electrochemical performance is evaluated. The three-enzyme-based electrode is used as a bioanode and an immobilized bilirubin oxidase (derived from Myrothecium verrucaria) electrode is used as a biocathode. The biofuel cell deliveres an open circuit voltage of 0.522 V and power density of up to 0.099 mW/cm | Rhizopus arrhizus |
EC Number | Organism | UniProt | Comment | Textmining |
---|---|---|---|---|
1.1.3.4 | Aspergillus niger | P13006 | - |
- |
1.3.3.5 | Albifimbria verrucaria | Q12737 | - |
- |
3.2.1.1 | Streptococcus equinus | - |
- |
- |
3.2.1.1 | Streptococcus equinus 148 | - |
- |
- |
3.2.1.3 | Rhizopus arrhizus | - |
- |
- |
EC Number | Synonyms | Comment | Organism |
---|---|---|---|
3.2.1.1 | AmyA | - |
Streptococcus equinus |
3.2.1.3 | glucoamylase | - |
Rhizopus arrhizus |
3.2.1.3 | GluR | - |
Rhizopus arrhizus |