Bridging the gap in peripheral nerve repair with 3D printed and bioprinted conduits

Bridging the gap in peripheral nerve repair with 3D printed and bioprinted conduits

Over the past two decades, a number of fabrication methods, including 3D printing and bioprinting, have emerged as promising technologies to bioengineer nerve conduits that closely replicate features of the native peripheral nerve, with the aim of augmenting or supplanting autologous nerve grafts. 3...

Full description

Saved in:
Bibliographic Details
Published in:Biomaterials Vol. 186; pp. 44 - 63
Main Authors: Dixon, Angela R., Jariwala, Shailly H., Bilis, Zoe, Loverde, Joseph R., Pasquina, Paul F., Alvarez, Luis M.
Format: Journal Article
Language:English
Published: Netherlands Elsevier Ltd 01-12-2018
Subjects:
Animals
Biocompatible Materials - chemistry
Bioprinting - methods
Electric Conductivity
Humans
Nerve conduit
Nerve Regeneration
Peripheral nerve repair
Peripheral Nerves - transplantation
Polymers - chemistry
Printing, Three-Dimensional
Regenerative medicine
Three-dimensional (3D) bioprinting
Three-dimensional (3D) printing
Tissue Engineering - methods
Tissue Scaffolds - chemistry
Peripheral nerve repair
Nerve conduit
Three-dimensional (3D) bioprinting
Regenerative medicine
Three-dimensional (3D) printing
Nerve regeneration
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Over the past two decades, a number of fabrication methods, including 3D printing and bioprinting, have emerged as promising technologies to bioengineer nerve conduits that closely replicate features of the native peripheral nerve, with the aim of augmenting or supplanting autologous nerve grafts. 3D printing and bioprinting offer the added advantage of rapidly creating composite peripheral nerve matrices from micron-scaled units, using an assortment of synthetic, natural and biologic materials. In this review, we explore the evolution of automated 3D manufacturing technologies for the development of peripheral nerve conduits and discuss aspects of conduit design, based on microarchitecture, material selection, cell and protein inclusion, and mechanical properties, as they are adaptable to 3D printing. Additionally, we highlight advancements in the application of bio-imaging modalities toward the fabrication of patient-specific nerve conduits. Lastly, we outline regulatory as well as clinical challenges that must be surmounted for the translation of 3D printing and bioprinting technology to the clinic. As a whole, this review addresses topics that may situate 3D manufacturing at the forefront of fabrication technologies that are exploited for the generation of future revolutionary therapies like in situ printing of peripheral nerves.
Bibliography:ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-3
content type line 23
ObjectType-Review-2
ISSN:0142-9612
1878-5905
DOI:10.1016/j.biomaterials.2018.09.010