Abstract 3D bioprinting is a pioneering technology that enables fabrication of biomimetic,
multiscale, multi-cellular tissues with highly complex tissue microenvironment, intricate …

Tissue regeneration of damaged tissues or complete reconstruction of the organs is the
major concern in the human health-care-systems. The role of scaffold, cell, and growth …

Tissue engineering has progressed tremendously over recent decades through the
generation of functional tissue analogs. Traditional approaches based on seeding cells into …

Regenerative medicine offers the possibility of engineering patient-specific three-
dimensional (3D) tissue constructs for treating several tissue pathologies. Three …

There is a global clinical need for bone transplants due to defects caused by degeneration,
trauma, neoplasm, and congenital diseases. Bone is a highly complex tissue that has …

Tissue engineering and regenerative medicine research has utilized three-dimensional (3D)
bioprinting as a promising technique for fabricating complex functional biological constructs …

Purpose 3D bioprinting is capable of rapidly producing small-scale human-based tissue
models, or organoids, for pathology modeling, diagnostics, and drug development. With the …

Material Science, Medicine and Chemistry are research fields that turn us towards the field
of biomaterials and tissue engineering. The making of biomaterials for drug delivery, tissue …

Three-dimensional (3D) printing technology allows fabricating complex and precise
structures by stacking materials layer by layer. The fabrication method has a strong potential …

The utilization of biomedical nanotechnologies and nanomaterials has surged in the field of
3D bone printing and bioprinting. As such, it is possible to reproduce the hierarchical …