Application of conductive polymers, scaffolds and electrical stimulation for nerve tissue engineering

Ghasemi‐Mobarakeh, Laleh; Prabhakaran, Molamma P.; Morshed, Mohammad; Nasr-Esfahani, Mohammad Hossein; Baharvand, Hossein; Kiani, Sahar; Al‐Deyab, Salem S.; Ramakrishna, Seeram

doi:10.1002/term.383

Cited by 587 publications

(392 citation statements)

References 161 publications

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“…7) also revealed similar conclusion because greater number of long neurites were presented. This increase is significantly greater than not only the values (20-60%) typically reported on hybrid and functionalized conducting organic materials 20,[27][28][29][30] but also the largest increase (90%) previously reported on polypyrrole 24 . We attribute this behaviour to the integrated stimulation of surface biochemical ligands and applied electrical pulses.…”

Section: Articlecontrasting

confidence: 51%

“…4e). This stimulation time was significantly longer than those reported from most previously conducted cell-based electrical stimulation experiments 20,24,[27][28][29][30] . In contrast, greater than 40% of the cells detached from unfunctionalized PEDOTs after only 1 day of electrical stimulation at an even lower voltage (20 mV).…”

Section: Articlementioning

confidence: 72%

“…Pioneering studies have demonstrated the efficiency of using ECPs for electrical interfacing with neural cells and tissues [18][19][20][21][22][23][24][25][26] .…”

mentioning

confidence: 99%

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Large enhancement in neurite outgrowth on a cell membrane-mimicking conducting polymer

et al. 2014

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Although electrically stimulated neurite outgrowth on bioelectronic devices is a promising means of nerve regeneration, immunogenic scar formation can insulate electrodes from targeted cells and tissues, thereby reducing the lifetime of the device. Ideally, an electrode material capable of electrically interfacing with neurons selectively and efficiently would be integrated without being recognized by the immune system and minimize its response. Here we develop a cell membrane-mimicking conducting polymer possessing several attractive features. This polymer displays high resistance towards nonspecific enzyme/cell binding and recognizes targeted cells specifically to allow intimate electrical communication over long periods of time. Its low electrical impedance relays electrical signals efficiently. This material is capable to integrate biochemical and electrical stimulation to promote neural cellular behaviour. Neurite outgrowth is enhanced greatly on this new conducting polymer; in addition, electrically stimulated secretion of proteins from primary Schwann cells can also occur on it.

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Section: Articlecontrasting

confidence: 51%

Section: Articlementioning

confidence: 72%

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Large enhancement in neurite outgrowth on a cell membrane-mimicking conducting polymer

et al. 2014

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“…Since pi-electrons move freely, they can form electrical pathways of mobility charge carriers [54,55]. The usage of conducting polymers allows a hydrogel to provide electrical stimulation locally and enhance the physical properties of the hydrogel as a template to accurately control the extent and duration of external stimulation [56][57][58]. Conductive materials like, polypyrrole (PPy), polyaniline (PANi), polythiophene (PT), and poly (3, 4-ethylene dioxythiophene) (PEDOT), have been widely used in conductive hydrogels (Figure 3).…”

Section: Conductive Polymersmentioning

confidence: 99%

Incorporation of Conductive Materials into Hydrogels for Tissue Engineering Applications

Min¹,

Koh²

2018

Preprint

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In the field of tissue engineering, conductive hydrogels have been the most effective biomaterials to mimic the biological and electrical properties of tissues in the human body. The main advantages of conductive hydrogel include not only its physical properties, but also its adequate electrical properties, thus providing electrical signals to cells efficiently. However, when introducing a conductive material into a non-conductive hydrogel, a conflicting relationship between the electrical and mechanical properties may develop. This review examines the strengths and weaknesses of the generation of conductive hydrogels using various conductive materials and introduces the use of these conductive hydrogels in tissue engineering applications.

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“…The most commonly studied OCPs for biomedical applications are polypyrrole (PPy) and the functionalised thiophene, Poly(3,4-ethylenedioxythiophene) (PEDOT) [58]. These OCPs have been studied in a wide range of cell types and are considered to be chemically stable and non-cytotoxic.…”

Section: Electrically On-demand Delivery Systems Based On Ocpsmentioning

confidence: 99%

Controlled delivery for neuro-bionic devices

Yue

Moulton

Cook

et al. 2013

Advanced Drug Delivery Reviews

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Implantable electrodes interface with the human body for a range of therapeutic as well as diagnostic applications. Here we provide an overview of controlled delivery strategies used in neuro-bionics. Controlled delivery of bioactive molecules has been used to minimise reactive cellular and tissue responses and/or promote nerve preservation and neurite outgrowth toward the implanted electrode. These effects are integral to establishing a chronically stable and effective electrode-neural communication. Drug-eluting bioactive coatings, organic conductive polymers, or integrated microfabricated drug delivery channels are strategies commonly used.

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Application of conductive polymers, scaffolds and electrical stimulation for nerve tissue engineering

Cited by 587 publications

References 161 publications

Large enhancement in neurite outgrowth on a cell membrane-mimicking conducting polymer

Large enhancement in neurite outgrowth on a cell membrane-mimicking conducting polymer

Incorporation of Conductive Materials into Hydrogels for Tissue Engineering Applications

Controlled delivery for neuro-bionic devices

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