This book explores innovative technological advancements contributing to sustainability and efficiency in biomedical applications. It examines how cutting-edge technologies in materials, bioprinting, and biotribology and biocorrosion address challenges in the biomedical field, enhance patient care, and promote environmental sustainability.
Advanced Technologies for Sustainable Biomedical Applications explores innovative technological advancements that contribute to the sustainability and efficiency of biomedical applications. This book provides a comprehensive overview of how cutting-edge technologies in materials, bioprinting, biotribology, and biocorrosion address current challenges in the biomedical field, enhance patient care, and promote environmental sustainability.
- Discusses the latest advances in materials and mechanics
- Probes the intricate relationship between biology and tribology in biological systems to enhance the longevity and performance of biomedical devices, reducing environmental impact
- Delves into principles, advancements, and applications of bioprinting, focusing on its transformative role in regenerative medicine, personalized healthcare, and sustainable organ transplantation
- Covers sustainable nanomanufacturing techniques
Emphasizing the integration of advanced technologies, this essential reference provides readers in materials engineering and biotechnology with the tools to create holistic and sustainable biomedical solutions.
1. Engagement of AI in Bioinformatics and Computational Biology. Section
I: Materials and Mechanics.
2. Nanomaterials and Their Challenges for
Biomedical Applications.
3. Functionally Graded Cellular Structures for
Biomaterials in Orthopedics.
4. Harnessing Nature: Sustainable Advancements
in Biomedical Applications.
5. Magnesium-Based Materials for Biomedical
Applications.
6. Soft Robotic Systems for Sustainable Biomedical
Applications. Section II: Bioprinting.
7. Sustainable Bioprinted
Tissue-Engineered Constructs Based on Biopolymers for Medical Applications
and Tissue Regeneration.
8. 3D Bioprinting of Biopolymer-Based Scaffolds for
Tissue Engineering.
9. Nanomanufacturing in the Biomedical Field.
10.
Biowaste-Derived Sustainable Biomaterials for Tissue Engineering
Applications: Opportunities and Challenges.
11. Materials and Processes Used
for Medical Devices Manufactured with 4D Printing.
12.
Nanohydroxyapatite-Reinforced UHMWPE Composites: A Sustainable Approach for
Next-Generation Dental Implants.
13. Medical Devices Made with 4D Printing:
From Manufacturing to Application.
14. Ti6Al4V 3D-Printed Lattice Structures
for Biomedical Applications. Section III: Biotribology and Biotribocorrosion.
15. Tribological Behaviour of Natural Fiber-Reinforced UHMWPE Composites for
Knee Prosthetics.
16. Mechanical Characterization of Kenaf, HDPE-Reinforced
UHMWPE Composite for Lower Knee Prosthetic Socket: A Review.
17. Future
Trends and Emerging Sustainable Technologies in Biomedical Field.
18. Machine
Learning in 3D Bioprinting: Enhancing Biomaterials for Regenerative Medicine.
Amit Aherwar is an Assistant Professor in the Department of Mechanical Engineering, Madhav Institute of Technology and Science, Deemed University, Gwalior, Madhya Pradesh, India.
Catalin I. Pruncu is an Associate Lecturer at Buckinghamshire New University, UK. He is a former Research Fellow of the Department of Design, Manufacturing and Engineering Management, University of Strathclyde, UK.
Binnur Sagbas is the head of the Surface Technologies Laboratory at Yildiz Technical University (YTU), Turkey, and the coordinator of the YTUAdditive Manufacturing Research group.
Luciano Lamberti is a Professor of Mechanical Design in the Dipartimento di Meccanica, Matematica and Management at the Politecnico di Bari, Italy.
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