2017
DOI: 10.1016/j.biomaterials.2017.03.026
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Microfluidic-enhanced 3D bioprinting of aligned myoblast-laden hydrogels leads to functionally organized myofibers in vitro and in vivo

Abstract: We present a new strategy for the fabrication of artificial skeletal muscle tissue with functional morphologies based on an innovative 3D bioprinting approach. The methodology is based on a microfluidic printing head coupled to a co-axial needle extruder for high-resolution 3D bioprinting of hydrogel fibers laden with muscle precursor cells (C2C12). To promote myogenic differentiation, we formulated a tailored bioink with a photocurable semi-synthetic biopolymer (PEG-Fibrinogen) encapsulating cells into 3D con… Show more

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Cited by 275 publications
(296 citation statements)
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“…They observed high cell compartmentalization in each half of the extruded fiber. After 5 d of culture, good spatial organization with myotube formation in the C2C12 printed half and fibroblast compartmentalization in the opposite side was observed . To avoid cell deposition in the ink and to allow longer bioprinting, materials that act as surfactants have also been added into the inks.…”
Section: Skeletal Muscle Tissue Engineeringmentioning
confidence: 99%
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“…They observed high cell compartmentalization in each half of the extruded fiber. After 5 d of culture, good spatial organization with myotube formation in the C2C12 printed half and fibroblast compartmentalization in the opposite side was observed . To avoid cell deposition in the ink and to allow longer bioprinting, materials that act as surfactants have also been added into the inks.…”
Section: Skeletal Muscle Tissue Engineeringmentioning
confidence: 99%
“…Janus‐like compartmentalization of the two cell types remained after 5 d of culture. In vitro analysis at day 21 of culture showed aligned, multinucleated, fully striated myotubes with abundant MHC . Moreover, after 7 d in vitro culture the constructs were implanted subcutaneously in mice and were retrieved after 28 d. The analysis showed complete maturation of tightly packed fully striated myotubes.…”
Section: Skeletal Muscle Tissue Engineeringmentioning
confidence: 99%
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“…Fourth, the bioprinting of low‐viscosity cell‐laden bioinks via a microfluidic nozzle holds promise in forming thick 3D multicellular constructs for tissue engineering . Through microfluidic‐assisted bioprinting, multicellular constructs with well‐defined geometries and appropriately arranged cell organization resembling both the macroscopic shapes and complicated anatomy of human tissues/organs have been established . Equipped with microfluidic nozzles with multichannel or coaxial multichannel designs, bioinks with tunable compositions and multicellular incorporation could be printed in extrusion‐based methods (Figure e), which offer robust strategies for the rapid and continuous construction of thick tissue‐like structures with hierarchical and heterogeneous architectures .…”
Section: Biomedical Applicationsmentioning
confidence: 99%
“…Previous research into bioprinting of muscle tissues has demonstrated some advantages of 3D bioprinted tissues when compared to cast hydrogels, 34 namely induction of differentiation markers such as myosin heavy chain and sarcomere formation for skeletal muscle cells. Printed dECM-containing skeletal muscle constructs develop larger myotubes with a greater number of acetylcholine receptors compared to collagen printed muscle constructs.…”
Section: F I G U R Ementioning
confidence: 99%