Three-dimensional (3D) printing techniques
for scaffold fabrication
have shown promising advancements in recent years owing to the ability
of the latest high-performance printers to mimic the native tissue
down to submicron scales. Nevertheless, host integration and performance
of scaffolds in vivo have been severely limited owing to the lack
of robust strategies to promote vascularization in 3D printed scaffolds.
As a result, researchers over the past decade have been exploring
strategies that can promote vascularization in 3D printed scaffolds
toward enhancing scaffold functionality and ensuring host integration.
Various emerging strategies to enhance vascularization in 3D printed
scaffolds are discussed. These approaches include simple strategies
such as the enhancement of vascular in-growth from the host upon implantation
by scaffold modifications to complex approaches wherein scaffolds
are fabricated with their own vasculature that can be directly anastomosed
or microsurgically connected to the host vasculature, thereby ensuring
optimal integration. The key differences among the techniques, their
pros and cons, and the future opportunities for utilizing each technique
are highlighted here. The Review concludes with the current limitations
and future directions that can help 3D printing emerge as an effective
biofabrication technique to realize tissues with physiologically relevant
vasculatures to ultimately accelerate clinical translation.
There are only a few reports of implantable 4D printed biomaterials, most of which exhibit slow deformations rendering them unsuitable for in situ surgical deployment. In this study, a hydrogel system is engineered with defined swelling behaviors, which demonstrated excellent printability in extrusion‐based 3D printing and programmed shape deformations post‐printing. Shape deformations of the spatially patterned hydrogels with defined infill angles are computationally predicted for a variety of 3D printed structures, which are subsequently validated experimentally. The gels are coated with gelatin‐rich nanofibers to augment cell growth. 3D‐printed hydrogel sheets with pre‐programmed infill patterns rapidly self‐rolled into tubes in vivo to serve as nerve‐guiding conduits for repairing sciatic nerve defects in a rat model. These 4D‐printed hydrogels minimized the complexity of surgeries by tightly clamping the resected ends of the nerves to assist in the healing of peripheral nerve damage, as revealed by histological evaluation and functional assessments for up to 45 days. This work demonstrates that 3D‐printed hydrogels can be designed for programmed shape changes by swelling in vivo to yield 4D‐printed tissue constructs for the repair of peripheral nerve damage with the potential to be extended in other areas of regenerative medicine.
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