Recent developments in the use of centrifugal spinning and pressurized gyration for biomedical applications

Centrifugal spinning is a technology used to generate small diameter fibers and has been extensively studied for its vast applications in biomedical engineering. Centrifugal spinning is known for its rapid production rate and has inspired the creation of other technologies which leverage the high-speed rotation, namely Pressurized Gyration. Pressurized gyration incorporates a unique applied gas pressure which serves to provide additional control over the fiber production process. The resulting fibers are uniquely suitable for a range of healthcare-related applications that are thoroughly discussed in this work, which involve scaffolds for tissue engineering, solid dispersions for drug delivery, antimicrobial meshes for filtration and bandage-like fibrous coverings for wound healing. In this review, the notable recent developments in centrifugal spinning and pressurized gyration are presented and how these technologies are being used to further the range of uses of biomaterials engineering, for example the development of core-sheath fabrication techniques for multi-layered fibers and the combination with electrospinning to produce advanced fiber mats. The enormous potential of these technologies and their future advancements highlights how important they are in the biomedical discipline.This article is categorized under:Implantable Materials and Surgical Technologies > Nanotechnology in Tissue Repair and ReplacementNanotechnology Approaches to Biology > Nanoscale Systems in BiologyBiology-Inspired Nanomaterials > Lipid-Based Structures

Automated summary

Centrifugal spinning is a technology known for generating small diameter fibers and has been extensively studied in biomedical engineering. Pressurized gyration, which incorporates gas pressure for fiber production, is an innovative technology inspired by centrifugal spinning. This review highlights the recent developments and applications of these technologies in biomedical engineering, including core-sheath fabrication and combination with electrospinning.