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Advancing Hemostasis: Innovations in Hybrid Polymeric Biomaterials provides an in-depth review of hybrid polymeric biomaterials and their applications in hemostasis, particularly at the interface where polymers and nanomaterials meet. This advanced guide explores the transformative potential of these materials in bleeding management, infection control, and wound healing. Chapters cover a range of hybrid polymeric biomaterials, including polysaccharide-based hemostatic biomaterials, peptide and protein hybrid biomaterials, nanostructured hemostatic hybrid biomaterials and more; in addition, a selection of key clinical case studies is detailed, bridging the gap between research and clinics to enhance patient care outcomes.
Advancing Hemostasis: Innovations in Hybrid Polymeric Biomaterials is an invaluable resource for academic and industrial researchers, professionals, and students in the fields of biomaterials, nanotechnology, and tissue engineering, as well as clinicians interested in the development of novel biomaterials for hemostasis.
List of contents
1. Introduction of Hybrid Biomaterials
2. Polyscaccharide based hemostatic biomaterials
3. Peptide and Protein Hybrid Biomaterials for Hemostasis
4. Supramolecular, Thermoresposive and Self-Healing Polymers/Hydrogels for Hemostasis
5. FDA-Approved Polymers and Nanomaterials for Hemostatic Applications
6. Synthetic polymer based hemostatic biomaterials
7. Nanostructured Hemostatic hybrid biomaterials
8. Hybrid Polymeric Biomaterial Composites and Combinations
9. 3D printed hybrid Hemostatic Biomaterials
10. Microfabrication Techniques for Hemostatic Biomaterials
11. Regenerative Medicine and Hemostatic Biomaterials
12. Biomimetic Approaches in Hemostatic Biomaterials Design
13. Biocompatibility and Safety Assessment of Hemostatic Biomaterials
14.Clinical Applications and Case Studies in Hemostasis
15.Regulatory Considerations and Commercialization
About the author
Dr. Kokkarachedu Varaprasad is an Associate Professor in the Faculty of Engineering, Architecture and Design, San Sebastián University, Chile. He received PhD (2011) in biocidal temperature-sensitive hydrogels from the Department of Polymer Science and Technology, India. He worked as an Investigator at the Advanced Polymer Research Center (CIPA), Chile. He received 3 International Postdoctoral Fellowships at Creighton University, USA, Tshwane University of Technology, South Africa, and Concepcion University, Chile. He developed the bioactivity of hybrid nanomaterials for advanced biomedical applications. He has published numerous articles, books, book chapters, and has 2 patents. His name has been listed in the Top 2% of scientists in the world under biomaterials, nanoscience, and nanotechnology in a recent survey conducted by Stanford University. His primary objective is to translate primary nano and polymer technology research results for the next generation of biomedical applications.
