Litcius/Paper detail

Nanofibrous electrospun scaffold doped with hydroxyapatite derived from sand lobster shell ( <i>Panulirus homarus</i> ) for bone tissue engineering

I Kadek Hariscandra Dinatha, Arian Hermawan Diputra, Hevi Wihadmadyatami, Juliasih Partini, Yusril Yusuf

2024RSC Advances13 citationsDOIOpen Access PDF

Abstract

0, 1, 3, and 5% (w/v). Based on the morphological and physicochemical analysis, the addition of HAp into the nanofiber successfully showed incorporation into the nanofiber with small agglomeration at HAp concentrations of 1, 3, and 5% (w/v). This led to a smaller fiber diameter with higher concentration of Hap, and incorporating HAp into the nanofiber could improve the mechanical properties of the nanofiber closer to the trabecula bone. Moreover, in general, swelling due to water absorption increases due to higher hydrophilicity at higher HAp concentrations and leads to the improvement of the degradation process and protein adsorption of the nanofiber. Biomineralization in a simulated body fluid (SBF) solution confirms that the HAp in the nanofiber increases bioactivity, and it can be seen that more apatite is formed during longer immersion in the SBF solution. The nanofiber PVA/PVP/CS HAp 5% has the most potential for osteoblast (MC3T3E1) cell viability after being incubated for 24 h, and it allowed the cell to attach and proliferate. Additionally, the higher HAp concentration in the nanofiber scaffold membrane can significantly promote the osteogenic differentiation of MC3T3E1 cells. Overall, the PVA/PVP/CS/HAp 5% nanofiber scaffold membrane has the most potential for bone tissue engineering.

Topics & Concepts

ScaffoldShell (structure)ElectrospinningTissue engineeringBiomedical engineeringAnatomyMaterials scienceChemistryComposite materialMedicinePolymerElectrospun Nanofibers in Biomedical ApplicationsBone Tissue Engineering MaterialsGraphene and Nanomaterials Applications