As a cutting-edge technology, three-dimensional (3D) printing technology is currently widely
used in many fields, and hydrogel as an emerging material is also more and more widely …

A 3D cell culture has developed rapidly in recent years, as cells growing on a flat substrate
in a static environment are far from achieving an in vivo status. Currently, researchers have …

Bioprinting has seen significant progress in recent years for the fabrication of bionic tissues
with high complexity. However, it remains challenging to develop cell‐laden bioinks …

Electroactive hydrogels can be used to influence cell response and maturation by electrical
stimulation. However, hydrogel formulations which are 3D printable, electroactive …

Biofabrication can be a tool to three-dimensionally (3D) print muscle cells embedded inside
hydrogel biomaterials, ultimately aiming to mimic the complexity of the native muscle tissue …

Three-dimensional bioprinting of cell-laden hydrogels in a sacrificial support-bath has
recently emerged as a potential solution for fabricating complex biological structures …

The mechanical behavior of cartilage tissue plays a crucial role in physiological
mechanotransduction processes of chondrocytes and pathological changes like …

Mimicking the mechanical properties of native human tissues is one key route in tissue
engineering. However, the successful creation of functional tissue equivalents requires the …

Biodegradable hydrogels that promote stem cell differentiation into neurons in three
dimensions (3D) are highly desired in biomedical research to study drug neurotoxicity or to …

Alginate dialdehyde–gelatin (ADA–GEL) hydrogels have been reported to be suitable
matrices for cell encapsulation. In general, application of ADA–GEL as bioink has been …