Application of bioinspired W/WO3 electrodes electrochemically constructed on microbial biofilm for the disinfection of dialysate contaminated by Candida parapsilosis

Barbara A. Souza , Maria José S.M. Giannini , Monica Yonashiro , Maria Valnice Boldrin Zanoni
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Abstract

The present work investigates the disinfection of dialysate water used in hemodialysis through the application of bioinspired W/WO3 electrodes constructed on microbial biofilm from C. parapsilosis by electrochemical anodization. The bioinspired electrode was photoactivated by UV/Vis or visible irradiation, and the photocurrent was found to be at least twice higher than that obtained for nanoporous W/WO3 electrode in the dialysate water. Under optimized conditions, the photo-electrocatalytic analysis conducted on the bioinspired electrode at Eapp = 1.5 V and under UV/Vis irradiation led to complete fungi inactivation (5 min) and up to 70% of total organic carbon removal monitored during cell lysis after 120 min of treatment. The results show the bioinspired electrode maintains the structural print of the fungi and works as fungus recognition material. The proposed electrode is also found to exhibit higher surface area, which improves adsorption of microorganisms, leading to faster and more efficient degradation compared to nanoporous W/WO3 electrode, with a 30% increase in the degradation of organic matter present in the medium. The findings show that the bioinspired electrode has outstanding advantages when compared with other materials investigated; these advantages include controlled morphology, good reproducibility, higher adsorption on the electrode surface, and higher efficiency in the disinfection of C. parapsilosis, an agent of several cases of contamination in dialysate.

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微生物生物膜电化学构建的仿生W/WO3电极在副假丝酵母污染透析液消毒中的应用
本文研究了利用电化学阳极氧化法在双歧杆菌微生物生物膜上构建仿生W/WO3电极对血液透析透析液的消毒效果。通过UV/Vis或可见光照射对生物激发电极进行光激活,发现光电流比在透析水中获得的纳米多孔W/WO3电极的光电流至少高两倍。在优化的条件下,在Eapp = 1.5 V和UV/Vis照射下,在生物激发电极上进行的光电催化分析导致真菌完全失活(5分钟),并且在120分钟的处理后,在细胞裂解过程中监测到高达70%的总有机碳去除。结果表明,仿生电极保持了真菌的结构特征,可作为真菌识别材料。研究还发现,该电极具有更高的表面积,这提高了微生物的吸附能力,与纳米多孔W/WO3电极相比,其降解速度更快,效率更高,对介质中有机物的降解能力提高了30%。研究结果表明,与其他研究材料相比,生物激发电极具有突出的优势;这些优点包括控制形态、良好的再现性、电极表面的高吸附性以及对双头孢菌(一种透析液中几种污染的病原体)的消毒效率更高。
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