Functional rewiring across spinal injuries via biomimetic nanofiber scaffolds

Usmani, Sadaf; Biagioni, Audrey Franceschi; Medelin, Manuela; Scaini, Denis; Casani, Raffaele; Aurand, Emily R.; Padró, Daniel; Egimendia, Ander; Scarselli, Manuela; Crescenzi, M. De; Prato, Maurizio; Ballerini, Laura

doi:10.1073/pnas.2005708117

Cited by 28 publications

(22 citation statements)

References 48 publications

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“…In addition, functional biomaterials can carry a variety of biomolecules such as growth factors, drugs, antibodies, genes, enzymes, and exosomes through physical, chemical, and biological modifications and help tissue repair through different therapeutic targets, and at the same time, by adjusting the electrical conductivity, mechanical properties, structural morphology, etc. of the material, the optimal therapeutic effect can be achieved [ 176 – 179 , 185 , 187 , 188 ].…”

Section: Treatment Strategies For Scimentioning

confidence: 99%

“…According to reports, collagen is used as the main component of the bioactive scaffold, through the preparation process and method to make it have a certain appearance characteristics and then modify it with the stromal cell-derived factors, neurotrophic factors (NT-3 and BFGF), genes, antibodies (cetuximab), and drugs (paclitaxel) which can effectively promote the migration and survival of endogenous neural stem cells and induce them to differentiate into neurons, eventually forming complete neural circuits [ 76 , 221 , 222 ]. Nanomaterials also have their own unique functional properties, and studies have shown that the structure and morphology of nanofibers have an impact on the therapeutic effect [ 185 , 186 , 188 ]. Fibers with a diameter of 400 nanometers were more effective in promoting cell migration and growth of protrusions than nanofibers with diameters of 800 nanometers and 1200 nanometers [ 223 ].…”

Section: Treatment Strategies For Scimentioning

confidence: 99%

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Recent Advances in Cell and Functional Biomaterial Treatment for Spinal Cord Injury

Liu

Zhu

Zhang

et al. 2022

BioMed Research International

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Spinal cord injury (SCI) is a devastating central nervous system disease caused by accidental events, resulting in loss of sensory and motor function. Considering the multiple effects of primary and secondary injuries after spinal cord injury, including oxidative stress, tissue apoptosis, inflammatory response, and neuronal autophagy, it is crucial to understand the underlying pathophysiological mechanisms, local microenvironment changes, and neural tissue functional recovery for preparing novel treatment strategies. Treatment based on cell transplantation has become the forefront of spinal cord injury therapy. The transplanted cells provide physical and nutritional support for the damaged tissue. At the same time, the implantation of biomaterials with specific biological functions at the site of the SCI has also been proved to improve the local inhibitory microenvironment and promote axonal regeneration, etc. The combined transplantation of cells and functional biomaterials for SCI treatment can result in greater neuroprotective and regenerative effects by regulating cell differentiation, enhancing cell survival, and providing physical and directional support for axon regeneration and neural circuit remodeling. This article reviews the pathophysiology of the spinal cord, changes in the microenvironment after injury, and the mechanisms and strategies for spinal cord regeneration and repair. The article will focus on summarizing and discussing the latest intervention models based on cell and functional biomaterial transplantation and the latest progress in combinational therapies in SCI repair. Finally, we propose the future prospects and challenges of current treatment regimens for SCI repair, to provide references for scientists and clinicians to seek better SCI repair strategies in the future.

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Section: Treatment Strategies For Scimentioning

confidence: 99%

Section: Treatment Strategies For Scimentioning

confidence: 99%

Recent Advances in Cell and Functional Biomaterial Treatment for Spinal Cord Injury

Liu

Zhu

Zhang

et al. 2022

BioMed Research International

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“…[13][14][15] Furthermore, we have recently showed how fibrous scaffolds composed of CNT induced axonal growth in injured spinal cord, thus promoting neurogenesis. 16 For this reason, CNTs have been used as growth substrates, scaffolds for nerve tissue engineering, electrode coating, and long-term implants, as well as drug delivery carriers and molecular sensors. 17,18 In our previous works, we tried to answer why CNTs have such an excellent effect on neuronal cultures.…”

Section: Introductionmentioning

confidence: 99%

“…More specifically, carbon nanotubes (CNTs) are one of the most promising materials to interface with the central nervous system (CNS), and they have shown excellent interaction with neuronal cells and ability to efficiently modulate the neuronal behavior at either the structural or functional level: CNTs boost the neuronal function, improve spontaneous synapses, and promote growth and extension of their axonal processes. − Furthermore, we have recently shown how fibrous scaffolds composed of CNTs induced axonal growth in injured spinal cord, thus promoting neurogenesis . For this reason, CNTs have been used as growth substrates, scaffolds for nerve tissue engineering, electrode coating, and long-term implants, and drug delivery carriers and molecular sensors. , In our previous works, we tried to answer why CNTs have such an excellent effect on neuronal cultures.…”

Section: Introductionmentioning

confidence: 99%

Toward Spontaneous Neuronal Differentiation of SH-SY5Y Cells Using Novel Three-Dimensional Electropolymerized Conductive Scaffolds

Dominguez‐Alfaro

Alegret

Arnáiz

et al. 2020

ACS Appl. Mater. Interfaces

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Neuroblastoma-derived SH-SY5Y cells have become an excellent model for nervous system regeneration to treat neurodegenerative disorders. Many approaches achieved a mature population of derived neurons in in vitro plates. However, the importance of the third dimension in tissue regeneration has become indispensable to achieve a potential implant to replace the damaged tissue. Therefore, we have prepared porous 3D structures composed uniquely of carbon nanotubes (CNT) and poly(3,4ethylenedioxythiophene) (PEDOT) that show great potential in the tridimensional differentiation of SH-SY5Y cells into mature neurons. The scaffolds have been manufactured through electropolymerization by applying 1.2 V in a three-electrode cell using a template of sucrose/CNT as a working electrode. By this method, PEDOT/CNT 3D scaffolds were obtained with homogeneous porosities and high conductivity. In vitro analyses showed that an excellent biocompatibility of the scaffold and the presence of high amount of β-tubulin class III and MAP-II target proteins that mainly expresses in neurons, suggesting the differentiation into neuronal cells already after a week of incubation.

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“…Aiming to rewire the injured spinal cord (SC), researchers have suggested a variety of approaches including transplantation of different cell types or biomaterials into the injury site in the acute phase. [ 5–8 ] The implantation of Schwann cells, [ 9 ] neural stem cells (NSCs) or neural progenitor cells (NPCs), [ 10,11 ] or mesenchymal stem cells [ 12 ] has been investigated as a potential therapy for SC injury. However, two issues may jeopardize the success of the treatment, namely the immune response to allogenic or xenogeneic cells, which may promote cell rejection, and implantation of dissociated cells, not organized into a functional network.…”

Section: Introductionmentioning

confidence: 99%

Regenerating the Injured Spinal Cord at the Chronic Phase by Engineered iPSCs‐Derived 3D Neuronal Networks

et al. 2022

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Cell therapy using induced pluripotent stem cell-derived neurons is considered a promising approach to regenerate the injured spinal cord (SC). However, the scar formed at the chronic phase is not a permissive microenvironment for cell or biomaterial engraftment or for tissue assembly. Engineering of a functional human neuronal network is now reported by mimicking the embryonic development of the SC in a 3D dynamic biomaterial-based microenvironment. Throughout the in vitro cultivation stage, the system's components have a synergistic effect, providing appropriate cues for SC neurogenesis. While the initial biomaterial supported efficient cell differentiation in 3D, the cells remodeled it to provide an inductive microenvironment for the assembly of functional SC implants. The engineered tissues are characterized for morphology and function, and their therapeutic potential is investigated, revealing improved structural and functional outcomes after acute and chronic SC injuries. Such technology is envisioned to be translated to the clinic to rewire human injured SC.

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Functional rewiring across spinal injuries via biomimetic nanofiber scaffolds

Cited by 28 publications

References 48 publications

Recent Advances in Cell and Functional Biomaterial Treatment for Spinal Cord Injury

Recent Advances in Cell and Functional Biomaterial Treatment for Spinal Cord Injury

Toward Spontaneous Neuronal Differentiation of SH-SY5Y Cells Using Novel Three-Dimensional Electropolymerized Conductive Scaffolds

Regenerating the Injured Spinal Cord at the Chronic Phase by Engineered iPSCs‐Derived 3D Neuronal Networks

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