Electrospinning has gained much attention in the past decade as an effective means of
generating nano-to micro-scale polymer fibers that resemble native extracellular matrix …

Despite electrospinning having multiple advantages over other methods such as creating
materials with a superfine fiber diameter, high specific surface area, and good mechanical …

Electrospinning has been widely accepted for several decades by the tissue engineering
and regenerative medicine community as a technique for nanofiber production. Owing to the …

Electrospinning is one of the most effective approaches to fabricate tissue-engineered
scaffolds composed of nano-to sub-microscale fibers that simulate a native extracellular …

The ultimate goal of tissue engineering is to replace damaged tissues by applying
engineering technology and the principles of life sciences. To successfully engineer a …

Tissue engineering holds great promise to develop functional constructs resembling the
structural organization of native tissues to improve or replace biological functions, with the …

Porosity has been shown to be a key determinant of the success of tissue engineered
scaffolds. A high degree of porosity and an appropriate pore size are necessary to provide …

Tissue engineering involves fabrication of three-dimensional scaffolds to support cellular in-
growth and proliferation. The goal: generation of 'neotissues' that the body can adapt to carry …

Tissue engineering aims to develop artificial human tissues by culturing cells on a scaffold in
the presence of biochemical cues. Properties of scaffold such as architecture and …

Despite its long history and some preliminary work in tissue engineering nearly 30 years
ago, electrospinning has not gained widespread interest as a potential polymer processing …