Biomimicking dual drug eluting twisted electrospun nanofiber yarns for post-operative wound healing

Singh, Pragya; Pandey, Prashant; Arya, Dilip Kumar; Anjum, Md Meraj; Poonguzhali, Subramaniam; Kumar, Abhishek; Gupta, Ravi; Rajamanickam, Vijayakumar Mahalingam; Singh, Sanjay; Chaurasia, Sundeep; Dantuluri, Ajay Kumar; McMahon, Sean M.; Rajinikanth, Paruvathanahalli Siddalingam

doi:10.1088/1748-605x/acc4a1

Cited by 8 publications

(1 citation statement)

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“…The electrospun nanofibers possess a distinctive hierarchical micro/nanofiber architecture, which incorporates a highly porous structure. This configuration facilitates exceptional transmission of essential elements such as nutrients, oxygen, growth factors, and waste materials (Pandey et al, 2023;Singh et al, 2023). Their effectiveness in supporting bone regeneration hinges on their pivotal contributions to cell recruitment, cytokine release, and the transport of oxygen, nutrients, and metabolic waste.…”

Section: Graphical Abstract 1 Introductionmentioning

confidence: 99%

Multifunctional electrospun nanofibrous scaffold enriched with alendronate and hydroxyapatite for balancing osteogenic and osteoclast activity to promote bone regeneration

Anjum,

Arya,

Saeed

et al. 2023

Front. Bioeng. Biotechnol.

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Electrospun composite nanofiber scaffolds are well known for their bone and tissue regeneration applications. This research is focused on the development of PVP and PVA nanofiber composite scaffolds enriched with hydroxyapatite (HA) nanoparticles and alendronate (ALN) using the electrospinning technique. The developed nanofiber scaffolds were investigated for their physicochemical as well as bone regeneration potential. The results obtained from particle size, zeta potential, SEM and EDX analysis of HA nanoparticles confirmed their successful fabrication. Further, SEM analysis verified nanofiber’s diameters within 200–250 nm, while EDX analysis confirmed the successful incorporation of HA and ALN into the scaffolds. XRD and TGA analysis revealed the amorphous and thermally stable nature of the nanofiber composite scaffolds. Contact angle, FTIR analysis, Swelling and biodegradability studies revealed the hydrophilicity, chemical compatibility, suitable water uptake capacity and increased in-vitro degradation making it appropriate for tissue regeneration. The addition of HA into nanofiber scaffolds enhanced the physiochemical properties. Additionally, hemolysis cell viability, cell adhesion and proliferation by SEM as well as confocal microscopy and live/dead assay results demonstrated the non-toxic and biocompatibility behavior of nanofiber scaffolds. Alkaline phosphatase (ALP) and tartrate-resistant acid phosphatase (TRAP) assays demonstrated osteoblast promotion and osteoclast inhibition, respectively. These findings suggest that developed HA and ALN-loaded PVP/PVA-ALN-HA nanofiber composite scaffolds hold significant promise for bone regeneration applications.

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Section: Graphical Abstract 1 Introductionmentioning

confidence: 99%