Biofabrication holds the potential to generate constructs that more closely recapitulate the
complexity and heterogeneity of tissues and organs than do currently available regenerative …

The combined potential of hydrogels and rapid prototy** technologies has been an
exciting route in develo** tissue engineering scaffolds for the past decade. Hydrogels …

The rapid prototy** has been developed from the 1980s to produce models and
prototypes until the technologies evolution today. Nowadays, these technologies have other …

One of the milestones in tissue engineering has been the development of 3D scaffolds that
guide cells to form functional tissue. Recently, mouldless manufacturing techniques, known …

We report the first investigation into the bioprinting of human induced pluripotent stem cells
(hiPSCs), their response to a valve-based printing process as well as their post-printing …

As a technique of producing fabric engineering scaffolds, three‐dimensional (3D) printing
has tremendous possibilities. 3D printing applications are restricted to a wide range of …

The ability to pattern functional polymers at different length scales is important for research
fields including cell biology, tissue engineering and medicinal science and the development …

Tissue engineering aims to produce patient-specific biological substitutes in an attempt to
circumvent the limitations of existing clinical treatments for damaged tissue or organs. The …

Recent advances in regenerative medicine have confirmed the potential to manufacture
viable and effective tissue engineering 3D constructs comprising living cells for tissue repair …

The tremendous interest received by additive manufacturing (AM) within the biomedical
community is a consequence of the great versatility offered in terms of processing approach …