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4D Printed Nerve Conduit with <i>In Situ</i> Neurogenic Guidance for Nerve Regeneration

Haitao Cui, Wei Zhu, Shida Miao, Kausik Sarkar, Lijie Grace Zhang

2023Tissue Engineering Part A14 citationsDOI

Abstract

Nerve repair poses a significant challenge in the field of tissue regeneration. As a bioengineered therapeutic method, nerve conduits have been developed to address damaged nerve repair. However, despite their remarkable potential, it is still challenging to encompass complex physiologically microenvironmental cues (both biophysical and biochemical factors) to synergistically regulate stem cell differentiation within the implanted nerve conduits, especially in a facile manner. In this study, a neurogenic nerve conduit with self-actuated ability has been developed by in situ immobilization of neurogenic factors onto printed architectures with aligned microgrooves. One objective was to facilitate self-entubulation, ultimately enhancing nerve repairs. Our results demonstrated that the integration of topographical and in situ biological cues could accurately mimic native microenvironments, leading to a significant improvement in neural alignment and enhanced neural differentiation within the conduit. This innovative approach offers a revolutionary method for fabricating multifunctional nerve conduits, capable of modulating neural regeneration efficiently. It has the potential to accelerate the functional recovery of injured neural tissues, providing a promising avenue for advancing nerve repair therapies.

Topics & Concepts

Regeneration (biology)Nerve guidance conduitNeuroscienceBiomedical engineeringNeural tissue engineeringTissue engineeringAnatomyMedicineBiologyCell biologyNeuroscience and Neural Engineering3D Printing in Biomedical ResearchNerve injury and regeneration
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