Bioprinting is a technology with the prospect to change the way many diseases are treated,
by replacing the damaged tissues with live de novo created biosimilar constructs. However …

Abstract Development of methods for scalable biofabrication of uniformly sized tissue
spheroids is essential for tissue spheroid-based bioprinting of large size tissue and organ …

Biofabricated tissues have found numerous applications in tissue engineering and
regenerative medicine in addition to the promotion of disease modeling and drug …

Organ printing, or the layer by layer additive robotic biofabrication of functional three-
dimensional tissue and organ constructs using self-assembling tissue spheroid building …

In recent years, scaffold‐free bio‐3D printing using cell aggregates (spheroids) as “bio‐inks”
has attracted increasing attention as a method for 3D cell construction. Bio‐3D printing uses …

Current tissue engineering techniques have various drawbacks: they often incorporate
uncontrolled and imprecise scaffold geometries, whereas the current conventional cell …

Bioprinting as an enabling technology for tissue engineering possesses the promises to
fabricate highly mimicked tissue or organs with digital control. As one of the biofabrication …

Bioprinting is the process of creating three-dimensional structures consisting of biomaterials,
cells, and biomolecules. The current additive manufacturing techniques, inkjet-, extrusion …

Over the past decades, many approaches have been developed to fabricate biomimetic
extracellular matrices of desired properties for engineering functional tissues. However, the …

An increasing demand for directed assembly of biomaterials has inspired the development
of bioprinting, which facilitates the assembling of both cellular and acellular inks into well …