Stretchable and Flexible Buckypaper‐Based Lactate Biofuel Cell for Wearable Electronics

Chen, Xiaohong; Yin, Lu; Lv, Jian; Gross, Andrew J.; Le, Minh Thuy; Gutierrez, Nathaniel Georg; Li, Yang; Jeerapan, Itthipon; Giroud, Françoise; Berezovska, Anastasiia; O’Reilly, Rachel K.; Xu, Sheng; Cosnier, Serge; Wang, Joseph

doi:10.1002/adfm.201905785

Cited by 139 publications

(144 citation statements)

References 35 publications

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“…In solution, mvBOD is active in a wide pH range from pH 5 to pH 8 [45,50,51]. Also it has been proven that mvBOD is very stable in the presence and in the absence of Os polymer or other mediator, losing around 10% of activity during one day under operating conditions [45,[50][51][52]. The effect of pH on the MCO catalytic mechanism has only been partly elucidated, but it is well resumed in [45,53].…”

Section: Effect Of Phmentioning

confidence: 99%

Comparison of Direct and Mediated Electron Transfer for Bilirubin Oxidase from Myrothecium Verrucaria. Effects of Inhibitors and Temperature on the Oxygen Reduction Reaction

et al. 2019

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One of the processes most studied in bioenergetic systems in recent years is the oxygen reduction reaction (ORR). An important challenge in bioelectrochemistry is to achieve this reaction under physiological conditions. In this study, we used bilirubin oxidase (BOD) from Myrothecium verrucaria, a subclass of multicopper oxidases (MCOs), to catalyse the ORR to water via four electrons in physiological conditions. The active site of BOD, the T2/T3 cluster, contains three Cu atoms classified as T2, T3α, and T3β depending on their spectroscopic characteristics. A fourth Cu atom; the T1 cluster acts as a relay of electrons to the T2/T3 cluster. Graphite electrodes were modified with BOD and the direct electron transfer (DET) to the enzyme, and the mediated electron transfer (MET) using an osmium polymer (OsP) as a redox mediator, were compared. As a result, an alternative resting (AR) form was observed in the catalytic cycle of BOD. In the absence and presence of the redox mediator, the AR direct reduction occurs through the trinuclear site (TNC) via T1, specifically activated at low potentials in which T2 and T3α of the TNC are reduced and T3β is oxidized. A comparative study between the DET and MET was conducted at various pH and temperatures, considering the influence of inhibitors like H2O2, F−, and Cl−. In the presence of H2O2 and F−, these bind to the TNC in a non-competitive reversible inhibition of O2. Instead; Cl− acts as a competitive inhibitor for the electron donor substrate and binds to the T1 site.

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Section: Effect Of Phmentioning

confidence: 99%

Comparison of Direct and Mediated Electron Transfer for Bilirubin Oxidase from Myrothecium Verrucaria. Effects of Inhibitors and Temperature on the Oxygen Reduction Reaction

et al. 2019

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“…[759,760] Conformal and intimate contact with the human body are necessary for biofuel cells, which could realize the power extraction from biofluids continuously and efficiently. [745] To this end, biofuel cells built on the tattoo platform and fabric platform using printing methods have been demonstrated. [754] For example, Jeerapan et al developed a stretchable textile-based printed biofuel cell [743] (Figure 8f-h).…”

Section: Energy-harvesting Devicesmentioning

confidence: 99%

Ink‐Based Additive Nanomanufacturing of Functional Materials for Human‐Integrated Smart Wearables

2020

Advanced Intelligent Systems

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Human-integrated devices include wearable and implantable devices for monitoring vital human signals or interacting with the human body. [1-3] The human-integrated devices needed to be tethered to the organs or the human skin for implementing their functions such as sensing and energy harvesting. [4-18] The economical, agile, customizable manufacturing, and integration of multifunctional device modules into networked systems with mechanical compliance and robustness will enable unprecedented human-integrated smart wearables [19-23] and usher in exciting opportunities in emerging technologies such as electronics, [24-29] wearable computation, [30-36] human-machine interface, [37-42] robotics, [43-48] and advanced healthcare. [49-54] The fabrication of stateof-the-art microelectronics involves hightemperature processing steps, which are generally incompatible with the flexible substrates (e.g., paper, polymer, fiber, etc.) [55-61] widely used in the wearable devices. Moreover, the current microfabrication technologies are not well positioned to process the emerging functional nanomaterials (e.g., nanowires [NWs] and 2D materials). [62-65] Such incomparability severely limits the pace of deploying these emerging materials (despite their unprecedented properties) in wearable and flexible device technologies. The additive manufacturing (AM) processes have emerged as potential candidates for addressing the earlier limitations of the current microfabrication technologies in fabricating flexible/wearable printed devices with diversified functionalities, e.g., energy harvesting/storage, sensing, actuation, and computation, leveraging advantages such as maskless processing, versatile ink formulation, low cost, low processing temperature, and scalability. [66-71] Researchers have devoted tremendous efforts to develop the related technologies, and several reviews have provided excellent discussions on the material formulation and process aspects of AM techniques. [63,72-79] However, to our best knowledge, there are few review reports about the ink-based additive nanomanufacturing of functional materials for human-integrated smart wearables. To fill this gap, here we review the recent progress in ink-based

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“…See Supplementary Note 1 and In the wearable microgrid system, BFCs offer the feature of harvesting biochemical energy continuously from metabolites present in biofluids via enzymatic reactions. Due to the high lactate concentrations in human sweat, a variety of sweat-based BFCs has been developed as wearable energy harvesters [45][46][47][48][49] . The wearable BFC modules were also screen-printed using various ink composites onto textile substrates.…”

Section: Characterization Of the Microgrid Modulesmentioning

confidence: 99%

A Self-Sustainable Wearable Multi-Modular E-Textile Bioenergy Microgrid System

Yin

Kim

Lyu

et al. 2020

Preprint

Self Cite

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Despite the fast development of various energy harvesting and storage devices, their judicious integration into efficient, autonomous, and sustainable wearable systems has not been widely explored. Here, we introduce the concept and design principles of e-textile microgrids to the world of wearable electronics by demonstrating the operation of a multi-module bioenergy microgrid system. Unlike earlier hybrid wearable energy systems, the presented e-textile microgrid relies solely on human movements to work synergistically, harvesting biochemical and biomechanical energy using sweat-based biofuel cells and triboelectric generators, and regulating the harvested energy via supercapacitor modules for high-power output. Through careful energy budgeting, the versatile e-textile system offers fast-booting and extended-harvesting to efficiently power liquid crystal displays continuously or a sweat sensor-electrochromic display system in pulsed sessions. Implementing the “compatible form factors, commensurate performance and complementary functionality” design principles, the flexible, textile-based bioenergy microgrid offers attractive prospects for the design and operation of efficient, sustainable, and autonomous wearable systems.

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Stretchable and Flexible Buckypaper‐Based Lactate Biofuel Cell for Wearable Electronics

Cited by 139 publications

References 35 publications

Comparison of Direct and Mediated Electron Transfer for Bilirubin Oxidase from Myrothecium Verrucaria. Effects of Inhibitors and Temperature on the Oxygen Reduction Reaction

Comparison of Direct and Mediated Electron Transfer for Bilirubin Oxidase from Myrothecium Verrucaria. Effects of Inhibitors and Temperature on the Oxygen Reduction Reaction

Ink‐Based Additive Nanomanufacturing of Functional Materials for Human‐Integrated Smart Wearables

A Self-Sustainable Wearable Multi-Modular E-Textile Bioenergy Microgrid System

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