Biomanufacturing of functional tissue analogues is of great importance in regenerative
medicine. However, this is still highly challenging due to extreme difficulties in recreating …

Nanofibrous scaffolds hold great promise in tissue engineering owing to their extracellular
matrix (ECM)-mimicking architectures. Electrospinning, with its ease for producing …

Aim: Biomaterials that mimic the nanofibrous architecture of the natural extracellular matrix
(ECM) are in the focus for stem cell hosting or delivery in tissue engineering of multilayered …

The development of three-dimensional (3D) scaffolds with physical and chemical topological
cues at the macro-, micro-, and nanometer scale is urgently needed for successful tissue …

Electrospun fibrous scaffolds attract great attention in tissue engineering owing to their high
similarity in architecture to the extracellular matrix (ECM) that support cell attachment and …

Compared with traditional in-vitro cell culture materials, three-dimensional nanofibrous
scaffolds provide a superior environment for promoting cell functions. Since nanofibrous …

With the ability to form nano-fibrous structures, a drive to mimic the extracellular matrix
(ECM) and form scaffolds that are an artificial extracellular matrix suitable for tissue …

Novel clinical grade electrospinning methods could provide three‐dimensional (3D)
nanostructured biomaterials comprising of synthetic or natural biopolymer nanofibers. Such …

Engineered tissue constructs rely on biomaterials as support structures for tissue repair and
regeneration. Among these biomaterials, polyester biomaterials have been widely used for …

Although regenerative medicine necessitates advanced three-dimensional (3D) scaffolds for
organ and tissue applications, creating intricate structures across scales, from nano-to meso …