ABSTRACT
Objective: To prepare and characterise keratin from chicken feathers (CF), collected from the slaughter house, and to blend with poly vinly alcohol (PVA) and biosynthesised silver nanoparticles (AgNPs) and to convert into nanofibers by an elctrospinning process. Methods: The extraction of keratin from chicken feathers was done by sodium m-bisulphite. The solution was subjected to ammonium sulphate precipitation to separate keratin. The nanoparticles was synthesised using tridax procumbens. The isolated keratin and PVA was mixed in the ration 0f 50:50 with 1 ml of biosynthesised nanoparticles was blended and made into nanofibres by electrospinning technique. Results: The precipitated protein was analysed using FT-IR analysis confirming the presence of β-keratin in the sample isolated from chicken feathers and the concentration of keratin was estimated to be 1.85 g/ml. PVA solution with 4% w/v had the best film forming ability. The solution containing keratin, PVA and silver nanoparticles was prepared in various proportions. These solutions when subjected to electrospinning, fibrous network was observed in 50:50 (PVA: Keratin) ratio with 1 ml of synthesised silver nanoparticle solution. Hydrogen bonding between keratin and PVA indicated in the XRD analysis showed successful film forming of the nanofiber, the DSC analysis also showed similar results as the obtained peak was at 214 °C which is in between the characteristic heat degradation temperature of both the keratin and PVA. The thermogravimetric analysis (TGA) showed high thermal stability as the complete degradation of the nanofiber was observed at 420 °C. Incorporation of metal nanoparticles by herbal approach using tridax procumbens in the nanofibers provided the antimicrobial properties. The nanofibres obtained by electrospinning process appeared stable and continous for solutions containing no more than 50% wt of CF. The average diameter of the nanofibres increased as the CF content increased. Conclusion: Keratin isolated from the waste chicken feathers impregnated with biosyntheised silver nanoparticles using tridax procumbens and PVA can be converted into nanofibers by electrospinning process. Thus, the biocomposite nano fibers are shown as a novel eco-friendly material that must be adequately applied in the development of green composites for the biomedical applications such as wound dressings.
ABSTRACT
ABSTRACT Objective: To investigate the mechanical properties of various mass fractions of Nylon 6 (N6), polymethyl-metacrylate (PMMA) and polyvinylidene-difluoride (PVDF) nanofibres reinforced bisphenol A-glycidyl methacrylate (Bis-GMA) and tri-ethylene glycol dimethacrylate (TEGDMA) based dental composite resins and to evaluate the penetration characteristics of the nanofibres into the resin. Methods: Nylon 6, PMMA and PVDF nanofibres were produced using the electrospinning method. The morphologies of the fabricated nanofibres were evaluated with a scanning electron microscope (SEM). The nanofibres were placed into the resin matrix at different mass fractions (3%, 5% and 7%). The three-point bending test was applied to nanofibre-reinforced dental composite resins and neat resin specimens. The flexural strength (Fs), flexural modulus (EY) and work of fracture (WOF) of the groups were found. The analysis of variance was used for the statistical analysis of the acquired data. Tukey 's multiple test was performed to compare the Fs, EY and WOF means. Fractured surfaces of the samples were observed by SEM, and fracture morphologies were evaluated. Results: Polymethyl-metacrylate nanofibres dissolved in the matrix, and a polymer alloy took place in the matrix. Fibre pull-out and fibre bridging mechanisms were observed by SEM images of the N6 and PVDF nanofibre-reinforced dental composites. The produced nanofibres enhanced the mechanical properties of the dental composite resins. Conclusion: Fibre pull-out and fibre bridging mechanisms on the fractured surfaces of samples may play a key role in the reinforcement of dental composite resins. However, polymer alloy of PMMA nanofibres increased the mechanical properties of the resin matrix.
RESUMEN Objetivo: Investigar las propiedades mecánicas de resinas compuestas dentales basadas en bisfenol A-diglicidildimetacrilato (Bis-GMA) y dimetacrilato trietilen-glicol (TEGDMA) reforzadas con nanofibras de fracciones de masa de Nylon 6 (N6), polimetilmetacrilato (PMMA) y fluoruro de polivinilideno (PVDF), y evaluar las características de la penetración de las nanofibras en la resina. Métodos: Se produjeron nanofibras de Nylon 6, PMMA y PVDF utilizando el método de electrohilado (electrospinning). Las morfologías de las nanofibras fabricadas fueron evaluadas con un microscopio electrónico de barrido (MEB). Las nanofibras fueron introducidas en la matriz de resina en diferentes fracciones de masa (3%, 5% y 7%). La prueba de flexión de tres puntos fue aplicada a las resinas compuestas dentales reforzadas por nanofibras y a las muestras de resina pura. La resistencia a la flexión (Rf), el módulo de flexión (EY) y el trabajo de fractura (WOF) de los grupos fueron halladas. El análisis de varianza se usó para el análisis estadístico de los datos adquiridos. Se realizó la prueba de comparaciones múltiples de Tukey con el propósito de comparar las medidas de Rf, EY y WOF. Las superficies fracturadas de las muestras fueron observadas mediante un MEB, y se evaluaron las morfologías de fractura. Resultados: Las nanofibras de polimetilmetacrilato se disolvieron en la matriz, y tuvo lugar una aleación de polímeros en la matriz. Los mecanismos de desprendimiento de fibras y puenteo de fibras fueron observados mediante imágenes de MEB de los compuestos dentales reforzados con nanofibras de N6 y PVDF. Las nanofibras producidas realzaron las propiedades mecánicas de las resinas compuestas dentales. Conclusión: Los mecanismos de desprendimiento de fibras y puenteo de fibras en las superficies fracturadas de las muestras pueden desempeñar un papel clave en el reforzamiento de las resinas de los compuestos dentales. Sin embargo, la aleación polimérica de las nanofibras de PMMA aumentó las propiedades mecánicas de la matriz de resina.