Scientists have worked long to develop biomaterials for repara-tive, regenerative, and
reconstructive surgery. Biomaterials were first passive in their rule (inert, eg, metals), then …

Three‐dimensional bioprinting shows great potential for autologous vascular grafts due to its
simplicity, accuracy, and flexibility. The 6‐mm‐diameter vascular grafts are used in clinic …

Tumors are complex three-dimensional (3D) tissues that form in a microenvironment
consisting of a heterogeneous mixture of cellular and non-cellular components. Due to the …

Microextrusion bioprinting has been used to recreate the complex architecture and
composition of a physiological system through the quick and accurate handling of various …

Purpose of Review 3D bioprinting of cardiovascular tissues for in vitro and in vivo
applications is currently investigated as a potential solution to better mimic the …

Extrusion-based cell deposition has become a prominent technique for expanding
bioprinting applications. However, the associated print resolution in the order of nanolitre or …

Abstract Three-dimensional (3D)-printed scaffolds are widely used in tissue engineering to
help regenerate critical-sized bone defects. However, conventional scaffolds possess …

Self-healing hydrogels are the most promising hydrogel-ink materials, especially for
extrusion-based 3D-bioprinting, because, unlike traditional hydrogels, the bonds as well as …

In cultured meat (CM) production, Scaffolding plays an important role by aiding cell
adhesion, growth, differentiation, and alignment. The existence of fibrous microstructure in …

The progress of three-dimensional (3D) bioprinting techniques has driven several advances
in tissue engineering (TE), which allow the obtention of biological constructs analogous to …