Materials for Biomedical Engineering: Hydrogels and Polymer-based Scaffolds

<p>1. Interactions between tissues, cells, and biomaterials: an advanced evaluation by synchrotron radiation-based high-resolution tomography<br>2. Bioprinted scaffolds<br>3. Fundamentals of chitosan-based hydrogels: elaboration and characterization techniques<br>4. Bioreabsorbable polymers for tissue engineering: PLA, PGA, and their copolymers<br>5. Technological challenges and advances: from lactic acid to polylactate and copolymers<br>6. PLGA scaffolds: building blocks for new age therapeutics<br>7. Electrospun biomimetic scaffolds of biosynthesized poly(β-hydroxybutyrate) from Azotobacter vinelandii strains. cell viability and bone tissue engineering<br>8. Polyurethane-based structures obtained by additive manufacturing technologies<br>9.  Composites based on bioderived polymers: potential role in tissue engineering: Vol VI: resorbable polymer fibers<br>10. Composite scaffolds for bone and osteochondral defects<br>11. Plasma treated and untreated thermoplastic biopolymers/biocomposites in tissue engineering and biodegradable implants<br>12. The design of two different structural scaffolds using β-tricalcium phosphate (β-TCP) and collagen for bone tissue engineering.<br>13. Composite materials based on hydroxyapatite embedded in biopolymer matrices: ways of synthesis and application<br>14. Study of microstructural, structural, mechanical, and vibrational properties of defatted trabecular bovine bones: natural sponges<br>15. Laser processing of biopolymers for development of medical and high-tech devices</p>