Bioelectrical understanding and engineering of cell biology

Schofield, Zoe; Meloni, Gabriel N.; Tran, Peter; Zerfaß, Christian; Sena, Giovanni; Hayashi, Yoshikatsu; Grant, Murray; Contera, Sonia; Minteer, Shelley D.; Kim, Minsu; Prindle, Arthur; Rocha, Paulo R. F.; Djamgoz, Mustafa B.A.; Pilizota, Teuta; Unwin, Patrick R.; Asally, Munehiro; Soyer, Orkun S.

doi:10.1098/rsif.2020.0013

Cited by 44 publications

(47 citation statements)

References 75 publications

(114 reference statements)

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“…Living matter harnesses ionic power from the environment to sustain normal life process. [ 1,2 ] This strategy also inspires manmade energy devices that are implemented by migration and chemical reaction of ionic species, such as batteries and electrochemical capacitors. [ 3,4 ] In these natural or synthetic systems, ion transport under nanoscale confinement plays a crucial role, [ 5 ] and moreover, it is also fundamentally involved in a broad range of disciplines, such as bio‐inspired materials and membrane‐based technologies.…”

Section: Figurementioning

confidence: 99%

Harnessing Ionic Power from Equilibrium Electrolyte Solution via Photoinduced Active Ion Transport through van‐der‐Waals‐Like Heterostructures

et al. 2021

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Nanofluidic ion transport through van der Waals heterostructures, composed of two or more types of reconstructed 2D nanomaterials, gives rise to fascinating opportunities for light‐energy harvesting, due to coupling between the optoelectronic properties of the layered constituents and ion transport in between the atomic layers. Here, a photoinduced active ion transport phenomenon through transition metal dichalcogenides (TMDs)‐based van‐der‐Waals‐like multilayer heterostructures is reported for harnessing ionic power from equilibrium electrolyte solution. The binary heterostructure comprises sequentially stacked 2D‐WS2 and 2D‐MoS2 multilayers with sub‐1 nm interlayer spacing. Upon visible‐light illumination, a net ionic flow is initiated through the Janus membrane, suggesting a directional cationic transport from WS2 to MoS2 part. The transport mechanism is explained in terms of a photovoltaic effect due to type II band alignment of WS2/MoS2 heterostructures. The driving mechanism can be generally applied to a variety of heterogeneous TMD membranes with type II semiconductor heterojunctions. In equilibrium ionic solutions, the maximum ionic photoresponse approaches ≈21 µA cm–2 and ≈45 mV under one sun equivalent excitation. Under optimized conditions, the harvested power density reaches 2 mW m–2. The proof‐of‐concept demonstration of photonic‐to‐ionic power generation within angstrom‐scale confinement anticipates potential for light‐controlled ionic circuits, artificial photosynthesis, and biomimetic energy conversion.

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Section: Figurementioning

confidence: 99%

Harnessing Ionic Power from Equilibrium Electrolyte Solution via Photoinduced Active Ion Transport through van‐der‐Waals‐Like Heterostructures

et al. 2021

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“…More recently, electrical stimulation has been utilised to augment and influence cell behaviour in vitro. Cells and tissue within the human body are naturally bioelectric, responding to and generating electric fields for normal physiological development, function, maintenance, repair and regeneration [ 246 ]. Therein, bioelectric potentials control and regulate cell proliferation, differentiation, migration, gene expression, apoptosis and morphology.…”

Section: Electrical Stimulation For Tissue Engineeringmentioning

confidence: 99%

Bioengineering Clinically Relevant Cardiomyocytes and Cardiac Tissues from Pluripotent Stem Cells

James

Tomaskovic-Crook

Crook

2021

IJMS

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The regenerative capacity of cardiomyocytes is insufficient to functionally recover damaged tissue, and as such, ischaemic heart disease forms the largest proportion of cardiovascular associated deaths. Human-induced pluripotent stem cells (hiPSCs) have enormous potential for developing patient specific cardiomyocytes for modelling heart disease, patient-based cardiac toxicity testing and potentially replacement therapy. However, traditional protocols for hiPSC-derived cardiomyocytes yield mixed populations of atrial, ventricular and nodal-like cells with immature cardiac properties. New insights gleaned from embryonic heart development have progressed the precise production of subtype-specific hiPSC-derived cardiomyocytes; however, their physiological immaturity severely limits their utility as model systems and their use for drug screening and cell therapy. The long-entrenched challenges in this field are being addressed by innovative bioengingeering technologies that incorporate biophysical, biochemical and more recently biomimetic electrical cues, with the latter having the potential to be used to both direct hiPSC differentiation and augment maturation and the function of derived cardiomyocytes and cardiac tissues by mimicking endogenous electric fields.

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“…Optogenetics is a rapidly maturing field that enables precise control of gene expression in response to specific wavelengths of light 4 . Bioelectrical research is another sub-discipline disabling barriers to bio-informational engineering 5 . This field is opening up novel ways to control cell behaviours through electrical and electrochemical means.…”

Section: Introductionmentioning

confidence: 99%

“…Bioelectrochemistry is fundamental to all cells, which rely on ionic gradients to generate energy through ATP synthases, and reduction oxidation (redox) reactions to drive metabolism. Furthermore, there are naturally evolved specialized functions that harness electrochemistry, such as the neuronal action potentials that underlie brain function, bacteria that harness extracellular electrons, and ion and reactive oxygen species which mediate intercellular communication 5 .…”

Section: Introductionmentioning

confidence: 99%

Sensing the future of bio-informational engineering

2021

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The practices of synthetic biology are being integrated into ‘multiscale’ designs enabling two-way communication across organic and inorganic information substrates in biological, digital and cyber-physical system integrations. Novel applications of ‘bio-informational’ engineering will arise in environmental monitoring, precision agriculture, precision medicine and next-generation biomanufacturing. Potential developments include sentinel plants for environmental monitoring and autonomous bioreactors that respond to biosensor signaling. As bio-informational understanding progresses, both natural and engineered biological systems will need to be reimagined as cyber-physical architectures. We propose that a multiple length scale taxonomy will assist in rationalizing and enabling this transformative development in engineering biology.

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Bioelectrical understanding and engineering of cell biology

Cited by 44 publications

References 75 publications

Harnessing Ionic Power from Equilibrium Electrolyte Solution via Photoinduced Active Ion Transport through van‐der‐Waals‐Like Heterostructures

Harnessing Ionic Power from Equilibrium Electrolyte Solution via Photoinduced Active Ion Transport through van‐der‐Waals‐Like Heterostructures

Bioengineering Clinically Relevant Cardiomyocytes and Cardiac Tissues from Pluripotent Stem Cells

Sensing the future of bio-informational engineering

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