Enzyme Fuel Cell for Cellulolytic Sugar Conversion Employing FAD Glucose Dehydrogenase and Carbon Cloth Electrode Based on Direct Electron Transfer Principle~!2010-01-09~!2010-02-04~!2010-05-17~!

Desriani, Takuya Hanashi, Tomohiko Yamazaki, W. Tsugawa, K. Sode
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引用次数: 8

Abstract

An enzyme fuel cell employing a carbon cloth electrode and bacterial FAD dependent glucose dehydrogenase (FADGDH) based on the direct electron transfer principle was constructed, and its scalability and cellulolytic sugar conversion were investigated. FADGDH was immobilized on the carbon cloth electrode together with carbon paste to form a multi-module type enzyme fuel cell by combining platinum-supported carbon immobilized carbon cloth as the cathode. The enzyme fuel cell was stable for more than 7 days of continuous operation. The 3 3 module (18 cm 2 ) enzyme fuel cell generated 68 μW (3.8 μW/cm 2 ) using glucose as the substrate, which was almost 9 times that of a single-module enzyme fuel cell. Thanks to the substrate specificity of bacterial FADGDH, cellulolytic sugars were revealed to be a good substrate for the enzyme fuel cell with cellobiose (9.3 μW/cm 2 ), cellotriose (9.2 μW/cm 2 ), or cellotetraose (6.3 μW/cm 2 ). These results demonstrated that together with the feasibility of using carbon cloth as the electrode material, FADGDH as the anode catalyst will become the norm in electrochemical biomass applications in the future.
利用FAD葡萄糖脱氢酶和基于直接电子转移原理的碳布电极进行纤维素解糖转化的酶燃料电池2010-01-09 2010-02-04 2010-05-17
采用碳布电极和细菌FAD依赖性葡萄糖脱氢酶(FADGDH)构建了基于直接电子转移原理的酶燃料电池,并对其可扩展性和纤维素解糖转化率进行了研究。将FADGDH与碳糊一起固定在碳布电极上,以铂负载碳固定碳布为阴极,形成多模块型酶燃料电池。酶燃料电池连续运行7天以上,性能稳定。33模块(18 cm 2)酶燃料电池以葡萄糖为底物产生68 μW (3.8 μW/cm 2),是单模块酶燃料电池的近9倍。由于细菌FADGDH的底物特异性,纤维素水解糖被证明是纤维素二糖(9.3 μW/cm 2)、纤维素三糖(9.2 μW/cm 2)或纤维素四糖(6.3 μW/cm 2)的酶燃料电池的良好底物。这些结果表明,加上碳布作为电极材料的可行性,FADGDH作为阳极催化剂将成为未来电化学生物质应用的常态。
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