2019
DOI: 10.1002/wnan.1568
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Electroconductive hydrogels for biomedical applications

Abstract: Electroconductive hydrogels (EHs), combining both the biomimetic features of hydrogels and the electrochemical properties of conductive polymers and carbon‐based materials, have received immense considerations over the past decade. The three‐dimensional porous structure, hydrophilic properties, and regulatable chemical and physical properties of EH resemble the extracellular matrix in tissues, enable EHs a good matrix for cell growth, proliferation, and migration. Different from nonconductive hydrogels, EHs po… Show more

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Cited by 62 publications
(55 citation statements)
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References 100 publications
(190 reference statements)
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“…Wearable or implantable devices are in direct contact with the human body and are expected not to cause damage to human health . Due to the unique hydrated environment and adjustable physicochemical properties, CPHs as a good candidate of biocompatible material have been widely used in a large number of biological devices such as biosensor, tissue engineering, controlled drug delivery, and cell culture …”
Section: Properties Of Cphsmentioning
confidence: 99%
See 1 more Smart Citation
“…Wearable or implantable devices are in direct contact with the human body and are expected not to cause damage to human health . Due to the unique hydrated environment and adjustable physicochemical properties, CPHs as a good candidate of biocompatible material have been widely used in a large number of biological devices such as biosensor, tissue engineering, controlled drug delivery, and cell culture …”
Section: Properties Of Cphsmentioning
confidence: 99%
“…[65][66][67][68] Due to the unique hydrated environment and adjustable physicochemical properties, CPHs as a good candidate of biocompatible material have been widely used in a large number of biological devices such as biosensor, tissue engineering, controlled drug delivery, and cell culture. [69][70][71] With the organic composition similar to extracellular matrix of biological tissues, CPHs have become a candidate for the next-generation bioelectronic interfaces as a bridge between biology and electronics. 72 In a rabbit model experiments, the phytic acid-doped PAni hydrogel-coated scaffolds showed enhanced biocompatibility, as manifested by the fact that the cell morphology was plumper and the cell diameter was larger than the counterpart in scaffolds without PAni hydrogel.…”
Section: Biocompatibilitymentioning
confidence: 99%
“…In human tissues, the extracellular matrix (ECM), mainly composed of collagen, elastin, and fibronectin, provides a favorable environment for the growth, repair, support, and connection of tissues [64]. In order to enhance tissue-chip integration, some studies have used conductive hydrogels that form a soft interface on the electrode surface that provides a medium for cellular attachment [65][66][67][68][69]. This modification, in addition to facilitating cellular attachment, overcomes electrode limitations in mechanical properties, charge transfer, and charge storage.…”
Section: Coating Materials For the Biochip Interfacementioning
confidence: 99%
“…Currently, conductive hydrogels have emerged as a promising class of hydrogel scaffolds combining a hydrophilic matrix with conducting components such as conductive polymers (CPs), metallic nanoparticles, or carbon materials [12]. Due to its tissue-like softness and the inherent presence of electrical fields similar to the innate nervous system, the conductive hydrogel can provide mechanical and electrical cues for enhancing neuronal differentiation of neural stem cells (NSCs) and controlling neurite extension [11,13].…”
Section: Introductionmentioning
confidence: 99%