An irreversible loss of subcutaneous adipose tissue in patients after tumor removal or deep
dermal burns makes soft tissue engineering one of the most important challenges in …

The development of biomimetic highly-porous scaffolds is essential for successful tissue
engineering. Segmented poly (ester urethane) s and poly (ester urethane urea) s have been …

For skin tissue engineering, an ideal scaffold should mimic the natural extracellular matrix of
the native skin. In this study, we reported a novel elastic sub-micron fiber scaffold blending …

It is important to control the degradation rate of a tissue‐engineered scaffold so that the
scaffold will degrade in an appropriate matching rate as the tissue cells grow in. A set of …

We synthesized a biodegradable, elastomeric, and functionalizable polyurethane (PU) that
can be electrospun for use as a scaffold in soft tissue engineering. The PU was synthesized …

Basement membrane‐rich extracellular matrices, particularly murine sarcoma‐derived
Matrigel, play important roles in regenerative medicine research, exhibiting marked cellular …

Extracellular matrix (ECM) has been utilized as a biological scaffold for tissue engineering
applications in a variety of body systems, due to its bioactivity and biocompatibility. In the …

Biocompatible polymeric scaffolds are crucial for successful tissue engineering. Biomedical
segmented polyurethanes (SPUs) are an important and versatile class of polymers …

Electrospinning from a melt, in contrast to from a solution, is an attractive tissue engineering
scaffold manufacturing process as it allows for the formation of small diameter fibers while …

The novel biomaterial poly (glycerol sebacate)(PGS) holds great promise for tissue
engineering and regenerative medicine. PGS is a rubbery, degradable polymer much like …