Electroconductive PEDOT Nanoparticle Integrated Scaffolds for Spinal Cord Tissue Repair

Author:

Serafin Aleksandra1ORCID,Rubio Mario Culebras2,Carsi Marta3,Ortiz-Serna Pilar3,Sanchis Maria J.3,Garg Atul K.4,Oliveira J. Miguel5,Koffler Jacob6,Collins Maurice NORCID

Affiliation:

1. University of Limerick

2. University of Valencia: Universitat de Valencia

3. Universitat Politècnica de València: Universitat Politecnica de Valencia

4. Johnson and Johnson

5. University of Minho: Universidade do Minho

6. University of California San Diego Department of Neurosciences

Abstract

Abstract Background Hostile environment around the lesion site following spinal cord injury (SCI) prevents the re-establishment of neuronal tracks, thus significantly limiting the regenerative capability. Electroconductive scaffolds are emerging as a promising option for SCI repair, though currently available conductive polymers such as polymer poly(3,4-ethylenedioxythiophene) polystyrene sulfonate (PEDOT:PSS) present poor biofunctionality and biocompatibility, thus limiting their effective use in SCI tissue engineering (TE) treatment strategies. Methods PEDOT NPs were synthesized via chemical oxidation polymerization in miniemulsion. The conductive PEDOT NPs were incorporated with gelatin and hyaluronic acid (HA) to create gel:HA:PEDOT-NPs. Morphological analysis of both PEDOT NPs and scaffolds was conducted via SEM. Further characterisation included dielectric constant and permittivity variances mapped against morphological changes after crosslinking, Young’s modulus, FTIR, DLS, swelling studies, rheology, in-vitro, and in-vivo biocompatibility studies were also conducted. Results Incorporation of PEDOT NPs increased the conductivity to 8.3×10− 4±8.1×10− 5 S/cm. The compressive modulus of the scaffold was tailored to match the native spinal cord at 1.2 ± 0.2 MPa, along with controlled porosity. Rheological studies of the hydrogel showed excellent 3D shear-thinning printing capabilities and shape fidelity post-printing. In-vitro studies showed the scaffolds are cytocompatible and an in-vivo assessment in a rat SCI lesion model shows glial fibrillary acidic protein (GFAP) upregulation not directly in contact with the lesion/implantation site, with diminished astrocyte reactivity. Decreased levels of macrophage and microglia reactivity at the implant site is also observed. This positively influences the re-establishment of signals and initiation of healing mechanisms. Observation of axon migration towards the scaffold can be attributed to immunomodulatory properties of HA in the scaffold caused by a controlled inflammatory response. HA limits astrocyte activation through its CD44 receptors and therefore limits scar formation. This allows for a superior axonal migration and growth towards the targeted implantation site through the provision of a stimulating microenvironment for regeneration. Conclusions Based on these results, the incorporation of PEDOT NPs into Gel:HA biomaterial scaffolds enhances not only the conductive capabilities of the material, but also the provision of a healing environment around lesions in SCI. Hence, gel:HA:PEDOT-NPs scaffolds are a promising TE option for stimulating regeneration for SCI.

Publisher

Research Square Platform LLC

Reference65 articles.

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3. Manipulating the extracellular matrix and its role in brain and spinal cord plasticity and repair;Burnside ER;Neuropathol Appl Neurobiol,2014

4. Dissecting the Dual Role of the Glial Scar and Scar-Forming Astrocytes in Spinal Cord Injury;Yang T;Frontiers in Cellular Neuroscience,2020

5. Moving beyond the glial scar for spinal cord repair;Bradbury EJ;Nat Commun,2019

Cited by 1 articles. 订阅此论文施引文献 订阅此论文施引文献,注册后可以免费订阅5篇论文的施引文献,订阅后可以查看论文全部施引文献

1. Application of Conductive Hydrogels on Spinal Cord Injury Repair: A Review;ACS Biomaterials Science & Engineering;2023-06-26

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