Abstract Three-dimensional (3D) bioprinting strategies use computer-aided processes to
enable automated simultaneous spatial patterning of cells and/or biomaterials. These …

Manufacturing macroscale cell-laden architectures is one of the biggest challenges faced
nowadays in the domain of tissue engineering. Such living constructs, in fact, pose strict …

Three-dimensional (3D) bioprinting of vascular tissues that are mechanically and
functionally comparable to their native counterparts is an unmet challenge. Here, we …

Abstract Three-dimensional (3D) bioprinting has been extensively explored for tissue repair
and regeneration, while the insufficient nutrient and oxygen availability in the printed …

Digital light processing bioprinting favors biofabrication of tissues with improved structural
complexity. However, soft-tissue fabrication with this method remains a challenge to balance …

Complicated vessels pervade almost all body tissues and influence the pathophysiology of
the human body significantly. However, current fabrication strategies have limited success at …

Abstract 3D printing has emerged as an enabling approach in a variety of different fields.
However, the bulk volume of printing systems limits the expansion of their applications. In …

Nature fabricates organic/inorganic composites under benign conditions, yet, in many cases,
their mechanical properties exceed those of the individual building components it is made …

The field of engineered living materials lies at the intersection of materials science and
synthetic biology with the aim of developing materials that can sense and respond to the …

It is well‐known that tissue engineering scaffolds that feature highly interconnected and size‐
adjustable micropores are oftentimes desired to promote cellular viability, motility, and …