Over the past decade, there has been significant growth in the use of fibre-based products
and structures for biomedical applications, with new fibrous materials and manufacturing …

Wet‐spinning of polymeric materials has been widely investigated for various biomedical
applications, such as extracorporeal blood treatment, controlled drug release and tissue …

For successful material deployment in tissue engineering, the material itself, its mechanical
properties, and the microscopic geometry of the product are of particular interest. While silk …

Microscale fibrous materials with high surface areas and ordered structures have attracted
widespread attention recently. Microfluidic spinning technology that can effectively control …

Electrospinning and wet-spinning have been recognized as two of the most efficient and
promising techniques for producing polymeric fibrous constructs for a wide range of …

Microfibers, a type of long, thin, and flexible material, can be assembled into functional 3D
structures by folding, binding, and weaving. As a novel spinning method, combining …

Micro-or nanofiber-based materials have extensive applications in biomedical fields due to
their capability to mimic many aspects of physiological microenvironment in vivo. Fabricating …

Over the last decade, researchers have investigated the potential of nano and microfiber
scaffolds to promote wound healing, tissue regeneration, and skin protection. The centrifugal …

Functional polymeric micro-/nanofibers have emerged as promising materials for the
construction of structures potentially useful in biomedical fields. Among all kinds of …

Advancements in technology and material development in recent years has led to significant
breakthroughs in the remit of fiber engineering. Conventional methods such as wet spinning …