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

Cellular spheroids are aggregates of cells that are being explored to address fundamental
biological questions and as building blocks for engineered tissues. Spheroids possess …

Bone tissue engineering approaches have evolved towards addressing the challenges of
tissue mimetic requirements over the years. Different strategies have been combining …

Cell therapies offer a tailorable, personalized treatment for use in tissue engineering to
address defects arising from trauma, inefficient wound repair, or congenital malformation …

Modular biofabrication strategies using microtissues or organoids as biological building
blocks have great potential for engineering replacement tissues and organs at scale. Here …

Bioprinting of cellular aggregates, such as tissue spheroids, to form three-dimensional (3D)
complex-shaped arrangements, has posed a major challenge due to lack of robust …

3D bioprinting technology is evolving in complexity to enable human-scale, high-resolution,
and multi-cellular constructs to better mimic the native tissue microenvironment. The ultimate …

Background Tissue replacement is among the most important challenges in biotechnology
worldwide. Scope of review We aim to highlight the importance of the intricate feedback …

The modest clinical impact of musculoskeletal tissue engineering (TE) can be attributed, at
least in part, to a failure to recapitulate the structure, composition and functional properties of …

Biofabrication is a fast-evolving and multi-disciplinary field, harnessing the benefits and
capabilities of additive manufacturing and complementary bioassembly techniques at the …