Conductive Collagen-Based Hydrogel Combined With Electrical Stimulation to Promote Neural Stem Cell Proliferation and Differentiation

Xu, Xin; Wang, Lin; Jing, Juehua; Zhan, Junfeng; Xu, Chungui; Xie, Wukun; Ye, Shuming; Zhao, Yong; Zhang, Chi; Huang, Fei

doi:10.3389/fbioe.2022.912497

Cited by 17 publications

(18 citation statements)

References 48 publications

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“…Davaa et al [57] transplanted NSCs through a collagen hydrogel to the SCI site in SCI model rats, and the results indicated that the collagen hydrogel protected the NSCs from a severe inflammatory environment, allowing the differentiation of NSCs and recovery of the spinal cord (Figure 3a). Xu et al [89] and Yang et al [86] demonstrated that a collagen hydrogel induces in situ NSCs to form neurons and reduces the accumulation of astrocytes, leading to the recovery of damaged spinal cord tissues. In addition, collagen hydrogels are used to deliver drugs to injury sites.…”

Section: Protein Hydrogelsmentioning

confidence: 99%

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Hydrogel and Nanomedicine‐Based Multimodal Therapeutic Strategies for Spinal Cord Injury

Yin,

Liang,

Han

et al. 2023

Small Methods

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Spinal cord injury (SCI) is a severe neurodegenerative disease caused by mechanical and biological factors, manifesting as a loss of motor and sensory functions. Inhibition of injury expansion and even reversal of injury in the acute damage stage of SCI are important strategies for treating this disease. Hydrogels and nanoparticle (NP)‐based drugs are the most effective, widely studied, and clinically valuable therapeutic strategies in the field of repair and regeneration. Hydrogels are 3D flow structures that fill the pathological gaps in SCI and provide a microenvironment similar to that of the spinal cord extracellular matrix for nerve cell regeneration. NP‐based drugs can easily penetrate the blood‐spinal cord barrier, target SCI lesions, and are noninvasive. Hydrogels and NPs as drug carriers can be loaded with various drugs and biological therapeutic factors for slow release in SCI lesions. They help drugs function more efficiently by exerting anti‐inflammatory, antioxidant, and nerve regeneration effects to promote the recovery of neurological function. In this review, the use of hydrogels and NPs as drug carriers and the role of both in the repair of SCI are discussed to provide a multimodal strategic reference for nerve repair and regeneration after SCI.

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Section: Protein Hydrogelsmentioning

confidence: 99%

“…Xu et al. [ 89 ] and Yang et al [ 86 ] demonstrated that a collagen hydrogel induces in situ NSCs to form neurons and reduces the accumulation of astrocytes, leading to the recovery of damaged spinal cord tissues. In addition, collagen hydrogels are used to deliver drugs to injury sites.…”

Section: Hydrogel‐based Multimodal Strategy For Treating Scimentioning

confidence: 99%

Hydrogel and Nanomedicine‐Based Multimodal Therapeutic Strategies for Spinal Cord Injury

Yin,

Liang,

Han

et al. 2023

Small Methods

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“…[ 12 ] While collagen is normally not conductive, the combination with PPy increased the conductivity to 17.6 S m −1 , which demonstrates advantages of hybrid copolymer formulations. [ 124 ] While the porcine tissue model provides a highly complex environment that properly mimics in vivo sensing conditions, many uncontrollable metabolic mechanisms that can be otherwise readily tuned in cell culture are left unmonitored in tissue samples. As such, the presence of aerobic metabolizing microorganisms that consume glucose in the porcine tissue can alter the readouts, which was indeed confirmed by standard glucose assays, resulting in a sensor viability lifetime of under 5 days.…”

Section: In Situ Sensorsmentioning

confidence: 99%

Advances in the Translation of Electrochemical Hydrogel‐Based Sensors

Shafique

Vries

Strauss

et al. 2022

Adv Healthcare Materials

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Novel biomaterials for bio‐ and chemical sensing applications have gained considerable traction in the diagnostic community with rising trends of using biocompatible and lowly cytotoxic material. Hydrogel‐based electrochemical sensors have become a promising candidate for their swellable, nano‐/microporous, and aqueous 3D structures capable of immobilizing catalytic enzymes, electroactive species, whole cells, and complex tissue models, while maintaining tunable mechanical properties in wearable and implantable applications. With advances in highly controllable fabrication and processability of these novel biomaterials, the possibility of bio‐nanocomposite hydrogel‐based electrochemical sensing presents a paradigm shift in the development of biocompatible, “smart,” and sensitive health monitoring point‐of‐care devices. Here, recent advances in electrochemical hydrogels for the detection of biomarkers in vitro, in situ, and in vivo are briefly reviewed to demonstrate their applicability in ideal conditions, in complex cellular environments, and in live animal models, respectively, to provide a comprehensive assessment of whether these biomaterials are ready for point‐of‐care translation and biointegration. Sensors based on conductive and nonconductive polymers are presented, with highlights of nano‐/microstructured electrodes that provide enhanced sensitivity and selectivity in biocompatible matrices. An outlook on current challenges that shall be addressed for the realization of truly continuous real‐time sensing platforms is also presented.

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“…[ 4,5 ] The 3D bioprinted hydrogels with customized structures, intrinsic bioactivity, and biocompatibility provide extracellular matrix (ECM)‐mimetic microenvironments for cell proliferation, migration, and maturation, which have attracted tremendous attention in tissue engineering, disease modeling, drug screening, etc. [ 6–9 ]…”

Section: Introductionmentioning

confidence: 99%

“…[4,5] The 3D bioprinted hydrogels with customized structures, intrinsic bioactivity, and biocompatibility provide extracellular matrix (ECM)-mimetic microenvironments for cell proliferation, migration, and maturation, which have attracted tremendous attention in tissue engineering, disease modeling, drug screening, etc. [6][7][8][9] Recent studies have further revealed the importance of providing electrical cues to the living cells within 3D bioprinted constructs, which can mediate the growth and differentiation of cells for various electroactive tissue repairing applications, e.g., cardiac, skeletal, smooth muscles, and neural tissues. [10][11][12][13] And, electro-conductive biomaterials have been demonstrated to promote the proliferation and differentiation behavior of electrical stimuli-responsive cells, such as neuron cells, [14] bone cells, [15] and muscle cells.…”

Section: Introductionmentioning

confidence: 99%

Development of Electro‐Conductive Composite Bioinks for Electrohydrodynamic Bioprinting with Microscale Resolution

et al. 2023

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Bioprinting has attracted extensive attention in the field of tissue engineering due to its unique capability in constructing biomimetic tissue constructs in a highly controlled manner. However, it is still challenging to reproduce the physical and structural properties of native electroactive tissues due to the poor electroconductivity of current bioink systems as well as the limited printing resolution of conventional bioprinting techniques. In this work, an electro‐conductive hydrogel is prepared by introducing poly (3,4‐ethylene dioxythiophene): poly (styrene sulfonate) (PEDOT: PSS) into an RGD (GGGGRGDSP)‐functionalized alginate and fibrin system (RAF), and then electrohydrodynamic (EHD)‐bioprinted to form living tissue constructs with microscale resolution. The addition of 0.1 (w/v%) PEDOT: PSS increases the electroconductivity to 1.95 ± 0.21 S m−1 and simultaneously has little effect on cell viability. Compared with pure RAF bioink, the presence of PEDOT: PSS expands the printable parameters for EHD‐bioprinting, and hydrogel filaments with the smallest feature size of 48.91 ± 3.44 µm can be obtained by further optimizing process parameters. Furthermore, the EHD‐bioprinted electro‐conductive living tissue constructs with improved resolution show good viability (>85%). The synergy of the advanced electro‐conductive hydrogel and EHD‐bioprinting presented here may provide a promising approach for engineering electro‐conductive and cell‐laden constructs for electroactive tissue engineering.

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Conductive Collagen-Based Hydrogel Combined With Electrical Stimulation to Promote Neural Stem Cell Proliferation and Differentiation

Cited by 17 publications

References 48 publications

Hydrogel and Nanomedicine‐Based Multimodal Therapeutic Strategies for Spinal Cord Injury

Hydrogel and Nanomedicine‐Based Multimodal Therapeutic Strategies for Spinal Cord Injury

Advances in the Translation of Electrochemical Hydrogel‐Based Sensors

Development of Electro‐Conductive Composite Bioinks for Electrohydrodynamic Bioprinting with Microscale Resolution

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