1. Electrospun Polycaprolactone/lignin-based Nanocomposite as a Novel Tissue Scaffold for Biomedical Applications
- Author
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Saeed Saber-Samandari, Faranak Kaveian, Mohammad Rafienia, Amirsalar Khandan, Mitra Naeimi, and Mohammad Ali Salami
- Subjects
Scaffold ,Materials science ,lcsh:Medical technology ,Biomedical Engineering ,Nanoparticle ,lignin ,Health Informatics ,02 engineering and technology ,engineering.material ,scaffold ,010402 general chemistry ,01 natural sciences ,chemistry.chemical_compound ,Tissue engineering ,polycaprolactone ,Ultimate tensile strength ,Computer Science (miscellaneous) ,Radiology, Nuclear Medicine and imaging ,Nanocomposite ,Radiological and Ultrasound Technology ,Electrospinning ,nanocomposite ,technology, industry, and agriculture ,021001 nanoscience & nanotechnology ,0104 chemical sciences ,chemistry ,Chemical engineering ,lcsh:R855-855.5 ,tissue engineering ,Polycaprolactone ,engineering ,Original Article ,Biopolymer ,0210 nano-technology - Abstract
Biopolymer scaffolds have received great interest in academic and industrial environment because of their supreme characteristics like biological, mechanical, chemical, and cost saving in the biomedical science. There are various attempts for incorporation of biopolymers with cheap natural micro- or nanoparticles like lignin (Lig), alginate, and gums to prepare new materials with enhanced properties. Materials and Methods: In this work, the electrospinning (ELS) technique as a promising cost-effective method for producing polymeric scaffold fibers was used, which mimics extracellular matrix structure for soft tissue engineering applications. Nanocomposites of Lig and polycaprolactone (PCL) scaffold produced with ELS technique. Nanocomposite containings (0, 5, 10, and 15 wt.%) of Lig were prepared with addition of Lig powder into the PCL solution while stirring at the room temperature. The bioactivity, swelling properties, morphological and mechanical tests were conducted for all the samples to investigate the nanocomposite scaffold features. Results: The results showed that scaffold with 10 wt.% Lig have appropriate porosity, biodegradation, minimum fiber diameter, optimum pore size as well as enhanced tensile strength, and young modulus compared with pure PCL. Degradation test performed through immersion of samples in the phosphate-buffer saline showed that degradation of PCL nanocomposites could accelerate up to 10% due to the addition of Lig. Conclusions: Electrospun PCLLig scaffold enhanced the biological response of the cells with the mechanical signals. The prepared nanocomposite scaffold can choose for potential candidate in the biomedical science
- Published
- 2017