In the last decade, nerve tissue engineering has attracted much attention due to the
incapability of self-regeneration. Nerve tissue regeneration is mainly based on scaffold …

Nerve tissue engineering aims to create scaffolds that promote nerve regeneration in the
damaged peripheral nervous system. However, there remain some challenges in the …

Bridging of nerve gaps after injury is a major problem in peripheral nerve regeneration.
Considering the potential application of a bio-artificial nerve guide material …

Nanofibers are used in a wide range of applications, including scaffolds for tissue
engineering. Electrospinning is a promising technique to fabricate nanofibrous scaffolds …

Nerve regeneration and functional recovery have been a major issue following injury of
nerve tissues. Electrospun nanofibers are known to be suitable scaffolds for neural tissue …

The repairing process in the nervous system is complicated and brings great challenges to
researchers. Tissue engineering scaffolds provide an alternative approach for neural …

Recent advances in regenerative medicine have given hope in overcoming and
rehabilitating complex medical conditions. In this regard, the biopolymer poly-ε-caprolactone …

Attributed to the excellent biocompatibility and desirable mechanical properties to natural
tissue, natural polymer-based electrospun nanofibers have drawn extensive research …

Nerve tissue engineering is one of the most promising methods to restore nerve systems in
human health care. Scaffold design has pivotal role in nerve tissue engineering. Polymer …

Biomaterial bridges constructed from electrospun fibers offer a promising alternative to
traditional nerve tissue regeneration substrates. Aligned and unaligned polycaprolactone …