Tsuyonobu Hatazawa

A high-power glucose /oxygen biofuel cell operating under quiescent conditions

Biofuel cells are a next-generation energy device because they use renewable fuels with high energy density and safety. We have developed passive-type biofuel cell units, which generate a power over 100 mW (80 cm3, 39.7 g). Our biofuel cell, in which two-electron oxidation of glucose and four-electron reduction of O2 occurs at pH 7 in mediated bioelectrochemical processes under quiescent conditions, accomplished the maximum power density of 1.45 ± 0.24 mW cm−2 at 0.3 V. This performance was achieved by introducing three technologies: (1) Enzymes and mediator are densely entrapped on carbon-fiber electrodes with the enzymatic activity retained, (2) the concentration of buffer in electrolyte solution was optimized for the immobilized enzymes, and (3) the cathode structure was designed to supply O2 efficiently. The cell units with a multi-stacked structure successfully operate a radio-controlled car (16.5 g), which demonstrates the potential of biofuel cells in practical applications.

Room temperature observation of negative differential resistance effect using ZnO nanocrystal structure with double Schottky barriers

A varistic nonlinear I-V characteristic caused by a tunneling effect was observed in two-dimensional nanopolycrystal ZnO (NPC-ZnO) with double Schottky barriers (DSBs). Id-Vd characteristic of a NPC-ZnO field effect transistor showed a negative differential resistance characteristic at room temperature. The Id-Vg showed clear current peaks and valleys although this characteristic has an asymmetric hysteresis. An ultraviolet irradiation on the Id-Vg showed the increase of current peaks and disappearance of the hysteresis. These results could be related to the tunneling effect via DSBs and quasibound states that were caused by the internal defect of ZnO dots or the grain boundary.

A mediator-adapted diaphorase variant for a glucose dehydrogenase–diaphorase biocatalytic system

Biofuel cell is an energy conversion device of the next generation which enables use of safer and higher energy-density fuels such as glucose. We have been developing a biofuel cell that comprises the three enzymes: glucose dehydrogenase (GDH) and diaphorase (DI) on anode, and bilirubin oxidase (BOD) on cathode. In this work, we have developed a DI variant suitable for our biofuel cell by using directed molecular evolution method. A gene library of DI variants was constructed by using error-prone PCR and the variant proteins were expressed in an Escherichia coli system. 8000 isolated variants have been screened with activity against 2-amino-1,4-naphthoquinone (ANQ), and 10 of them have been qualified which were then purified and examined their activities against ANQ. A highest activity was observed in G122D variant of which glycine residue at position 122 is substituted to aspartate. Enzymatic kinetic analyses show that KM for ANQ in G122D is 1/3 of that in wild type (G122D: 356 μM, wild type: 1.08 mM), whereas kcat and KM for NADH is almost the same, clearly showing that G122D mutation has given DI an improvement in enzymatic activity at lower ANQ concentration. The effect of this mutation was considered electrochemically in solution and in immobilized layer. The results show that G122D variant DI gave a higher current at lower ANQ concentration in solution, as well as in immobilized condition where GDH is co-immobilized within.

Micro-coulometric study of bioelectrochemical reaction coupled with TCA cycle

The mediated electro-enzymatic electrolysis systems based on the tricarboxylic acid (TCA) cycle reaction were examined on a micro-bulk electrolytic system. A series of the enzyme-catalyzed reactions in the TCA cycle was coupled with electrode reaction. Electrochemical oxidation of NADH was catalyzed by diaphorase with an aid of a redox mediator with a formal potential of -0.15 V vs. Ag|AgCl. The mediator was also able to shuttle electrons between succinate dehydrogenase and electrode. The charge during the electrolysis increased on each addition of dehydrogenase reaction in a cascade of the TCA cycle. However, the electrolysis efficiencies were close to or less than 90% because of the product inhibition. Lactate oxidation to acetyl-CoA catalyzed by two NAD-dependent dehydrogenases was coupled with the bioelectrochemical TCA cycle reaction to achieve the 12-electron oxidation of lactate to CO(2). The charge passed in the bioelectrocatalytic oxidation of 5 nmol of lactate was 4 mC, which corresponds to 70% of the electrolysis efficiency.