Moving polyvinyl pyrrolidone electrospun nanofibers and bioprinted scaffolds toward multidisciplinary biomedical applications

[Display omitted] •Scrutiny of recent advances and trends of PVP in multidisciplinary biomedical applications.•Futuristic 3D and 4D printing based PVP biomedical uses are covered.•Assessments on the PVP based implants developed by electrospinning, electrospraying, 3D/4D printing.•Discussion on broad...

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Bibliographic Details
Published in:European polymer journal 2020-08, Vol.136, p.109919, Article 109919
Main Authors: Kurakula, Mallesh, Koteswara Rao, G.S.N.
Format: Article
Language:English
Subjects:
3D/4D printing
Biocompatibility
Biodegradability
Biological properties
Biomedical
Biomedical engineering
Biomedical materials
Dental materials
Electrospinning
Literature reviews
Nanofibers
Nanoscaffolds
Orthopedics
Polymers
Polyvinyl pyrrolidone
Regeneration
Regenerative tissue engineering
Surgical implants
Three dimensional printing
Tissue engineering
Wound healing
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Summary:[Display omitted] •Scrutiny of recent advances and trends of PVP in multidisciplinary biomedical applications.•Futuristic 3D and 4D printing based PVP biomedical uses are covered.•Assessments on the PVP based implants developed by electrospinning, electrospraying, 3D/4D printing.•Discussion on broad PVP utilization in regenerative tissue engineering. With emerging technological advances in biomedicine, the scope of futuristic biomaterials has been limited and existing polymers are gaining momentum. Unlike other synthetic polymers, polyvinyl pyrrolidone (PVP) is bioactive, water-soluble, non-toxic, temperature-resistant, pH-stable, biodegradable, and biocompatible. Due to its versatile properties, PVP is explored and widely used in the fabrication of wide biomedical products via electrospinning, 3D/4D printing, and other technologies. PVP owes intrinsic biological and tunable properties with next-generation biomaterials as nanoscaffolds delivering wide therapeutics, supporting material in implants, as a bone spacer, in tissue regeneration, wound healing materials, in diagnostics and many more. Several modifications of PVP are reported to achieve the additional criteria for special functions and additive with other clinically approvedpolymersto obtain new biomedical products. This article is a literature review on the PVP use in designing multidisciplinary biomedical products via advanced approaches. The review details key research aspects and promising potentials of PVP based nanoscaffolds utilized in several biomedical implants (orthopedic, dental, vaginal, breast), regenerative engineering (neural, cardiac, and pancreatic tissue), ophthalmic, wound healing materials, theranostics and miscellaneous. A special focus on novel PVP biomedical products by emerging, sustainable, cost-effective 3D and 4D printing are highlighted. From a biomedical scientist’s viewpoint, this review presents, the current challenges, outlook, and future prospective of PVP in designing bioresorbable devices.
ISSN:0014-3057
1873-1945
DOI:10.1016/j.eurpolymj.2020.109919