2019
DOI: 10.1002/inf2.12054
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3D electronic and photonic structures as active biological interfaces

Abstract: Biocompatible materials and structures with three-dimensional (3D) architectures establish an ideal platform for the integration of living cells and tissues, serving as desirable interfaces between biotic and abiotic systems. While conventional 3D bioscaffolds provide a mechanical support for biomatters, emerging developments of micro-, nano-, and mesoscale electronic and photonic devices offer new paradigms in analyzing and interrogating biosystems. In this review, we summarize recent advances in the developm… Show more

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Cited by 17 publications
(19 citation statements)
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References 164 publications
(222 reference statements)
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“…One of the unique characteristics of biological signals that occur inside an organism is that they can represent a biological signal of a specific region of complex organs, e.g., the brain, that have different roles and functions depending on the region, while these signals also can indicate an early stage of disease or pain, such as myocardial infarction, caused by partial necrosis inside the organ. [16][17][18][19] Thus, with 2D bioelectrodes, including flexible and stretchable bioelectronics, it is difficult to form a complete conformal biointerface and measure biological signals in the deep regions of organisms due to the limitation of the 2D planar structure. Therefore, in order to form an interface with the internal regions of 3D-structured organisms, bioelectronic engineers attempted to fabricate 3D electrodes, such as 3D MEA for intracellular-like in vitro and in vivo…”
Section: Doi: 101002/adma202005805mentioning
confidence: 99%
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“…One of the unique characteristics of biological signals that occur inside an organism is that they can represent a biological signal of a specific region of complex organs, e.g., the brain, that have different roles and functions depending on the region, while these signals also can indicate an early stage of disease or pain, such as myocardial infarction, caused by partial necrosis inside the organ. [16][17][18][19] Thus, with 2D bioelectrodes, including flexible and stretchable bioelectronics, it is difficult to form a complete conformal biointerface and measure biological signals in the deep regions of organisms due to the limitation of the 2D planar structure. Therefore, in order to form an interface with the internal regions of 3D-structured organisms, bioelectronic engineers attempted to fabricate 3D electrodes, such as 3D MEA for intracellular-like in vitro and in vivo…”
Section: Doi: 101002/adma202005805mentioning
confidence: 99%
“…Macroscopically, most living organisms and associated biomolecules, cells, tissues, and organs have inhomogeneous and irregular 3D structures with anisotropy. [16] This section discusses the advantages of macroscopic 3D-structured bioelectrodes and the microscopic properties of 3D electrodes at the electrode-tissue interface.…”
Section: Functionalities Of 3d Bioelectrodesmentioning
confidence: 99%
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