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Fabrication and biocompatibility evaluation of hydroxyapatite–polycaprolactone–gelatin composite nanofibers as a bone scaffold

Aminatun, Aisyah Sujak M. K., Djony Izak R., Sofijan Hadi, Yessie Widia Sari, Gunawarman Gunawarman, Nilam Cahyati, Yusril Yusuf, Che Azurahanim Che Abdullah

2024RSC Advances22 citationsDOIOpen Access PDF

Abstract

and C[double bond, length as m-dash]O stretching. Notably, an increase in PCL concentrations resulted in larger fiber diameters, ranging from 369-1403 nm with an average value of 929 ± 175 nm. The highest porosity percentage was (77.27 ± 11.57) %, and a sufficient degradation rate of up to 3.5 months facilitated the proliferation process of osteoblast cells. Tensile strength assessments revealed a significant increase in tensile strength with the addition of PCL, reaching a peak of 1.93 MPa. The MTT assay demonstrated a discernible increase in cell proliferation, as evidenced by increased cell viability percentages on days 1, 3, and 5. Concurrently, the fluorescence microscopy examination indicated an increase in cell numbers, which was especially noticeable on days 1 and 5. The SEM analysis confirmed the biocompatibility of the HA/PCL/gelatin nanofiber scaffold, as osteoblast cells attached and dispersed successfully five days after seeding. Based on these findings, the HA/PCL/gelatin nanofiber scaffold emerges as a very promising candidate for treating bone damage.

Topics & Concepts

BiocompatibilityGelatinPolycaprolactoneScaffoldNanofiberMTT assayViability assayComposite numberMaterials scienceBiomedical engineeringElectrospinningChemistryChemical engineeringNanotechnologyCell growthComposite materialCellMedicineOrganic chemistryPolymerBiochemistryMetallurgyEngineeringBone Tissue Engineering MaterialsElectrospun Nanofibers in Biomedical Applicationsbiodegradable polymer synthesis and properties
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