Nanodynamic Therapies: Principles and Applications explores the innovative use of nanosensitizers to generate reactive oxygen species for the targeted treatment of cancer and bacterial infections. Covering a broad spectrum of ROS-based therapeutic strategies, including photodynamic, chemodynamic, sonodynamic, electrodynamic, radiodynamic, thermodynamic, piezoelectric dynamic, and pyroelectric dynamic therapies, this book provides comprehensive insights into their fundamental principles, biomedical applications, and emerging clinical perspectives. The book highlights the role of diverse nanomaterials, such as metal-based, polymer-based, carbon-based, lipid-based, and two-dimensional nanomaterials, in enhancing anticancer and antibacterial therapies. With a strong focus on translation research and therapeutic innovation, it presents the recent advances and future direction in nanodynamic approaches for combating cancer and microbial infections.
This volume serves as a valuable resource for researchers; postgraduate students in nanotechnology, materials science, biomaterials, and pharmaceutical sciences; and clinicians and cancer researchers seeking a comprehensive understanding of nanodynamic therapies and their impact on modern therapeutic strategies.
This volume serves as a valuable resource for researchers; postgraduate students in nanotechnology, materials science, biomaterials, and pharmaceutical sciences; and clinicians and cancer researchers seeking a comprehensive understanding of nanodynamic therapies and their impact on modern therapeutic strategies.
Table of Contents
Part I: Introduction to Nanodynamic therapies1. Nanodynamic therapies: Introduction and applications
2. The fundamental principles and biological aspects of ROS-based nanodynamic therapies for cancer and bacterial infections
3. Clinical and commercial trials of nanodynamic therapies for cancer and bacterial infections
Part II: Nano-based photodynamic cancer therapy
4. Metal-based nanomaterials in cancer photodynamic therapy
5. Polymer-based nanoparticles for photodynamic therapy
6. Emerging lipid-based nanomaterials for cancer photodynamic therapy
7. Application of two-dimensional nanomaterials for cancer photodynamic therapy
8. Rare earth-doped upconversion nanoparticles for photodynamic cancer therapy
9. Design of photosensitizers for photodynamic therapy of cancer and cancer stem cells
Part III: Nanomaterial-based chemodynamic cancer therapy
10. Smart nanocarrier-based hybrid catalysts for enhanced chemodynamic cancer therapy
11. Multifunctional nanozymes for cancer chemodynamic therapy
Part IV: Nanomaterial-based sonodynamic cancer therapy
12. Multifunctional sonosensitizer for sonodynamic cancer therapy
13. Nanozyme-augmented sonodynamic cancer therapy
Part V: Nanomaterial-based other dynamic cancer therapy
14. Nanoparticles to enable electrodynamic therapy for effective cancer treatment
15. Nanomaterials to enhance radiodynamic therapy of cancer
16. Targeting hypoxic tumor with hybrid nanomaterials for thermodynamic therapy and piezoelectric dynamic therapy
Part VI: Combination of nanodynamic therapy with other therapies
17. Nanoarchitectures for sonodynamic therapy-involved multimodal treatments
18. Nanosystems for chemo-/chemodynamic/sonodynamic cancer therapy
Part VII: Antibacterial nanophotodynamic therapy
19. Nanophotosensitizers for photodynamic antibacterial therapy
20. Emerging trends in polymer nanomaterials for antibacterial photodynamic therapy
Part VIII: Nanomaterial-based chemodynamic antibacterial therapy
21. Nanogel for chemodynamic antibacterial therapy
22. Nanomaterial-mediated antibacterial chemodynamic therapy
Part VIII: Nanomaterial-based antibacterial sonodynamic therapy
23. Multifunctional nanoparticles for antibacterial sonodynamic therapy
24. Nanomicelles for sonodynamic antibacterial therapy
Part IX: Nanomaterial-based other dynamic antibacterial therapy
25. Biomimetic electrodynamic nanoparticles for antibacterial therapy
26. Organic nanomaterials for thermodynamic, radiodynamic, piezoelectric antibacterial therapy
Part X: Combination of nanodynamic therapy with other therapies
27. Pyroelectric Janus nanomaterials for synergistic electrodynamic-photothermal antibacterial therapy
28. Nanozymes for synergistic chemodynamic/sonodynamic antibacterial therapy
Authors
Panchanathan Manivasagan Research Professor, Kumoh National Institute of Technology, South Korea.Dr. Panchanathan Manivasagan is a Research Professor in the Department of Chemistry & Bio-Science at Kumoh National Institute of Technology (KIT) in Gumi, South Korea. A primary focus of his current research is the development of multifunctional nanomaterials for multimodal imaging (in vivo fluorescence imaging, photoacoustic imaging, CT imaging, and MR imaging) and therapy (chemotherapy, phototherapy, chemodynamic therapy, electrodynamic therapy, sonodynamic therapy, immunotherapy, starvation therapy, and electrolytic ablation therapy) for cancer and microbial infections.
Jayachandran Venkatesan Assistant Professor, Yenepoya Research Centre, Mangaluru, Karnataka, India. Dr. Jayachandran Venkatesan M.Sc., M.Phil., Ph.D. is an assistant professor in Yenepoya Research Centre (YRC), Yenepoya (Deemed to be University), India. He worked as a postdoctoral researcher in the Division of Bioengineering, Incheon National University, and Hanyang University, South Korea. Previously, he worked as a Research Professor at the Department of Chemistry and Marine Bioprocess Research Center (MBPRC) at Pukyong National University, South Korea. He received his Master of Science in chemistry from Thiruvalluvar University in 2005. Further, He received his Ph.D. from Pukyong National University in 2011. His primary research interests are the investigation and development of naturally derived polymers, ceramics, and protein-based materials for biomedical applications. Furthermore, he works on natural biomaterials for tissue engineering and drug delivery applications. Eue-Soon Jang Professor, Kumoh National Institute of Technology, South Korea. Prof. Eue-Soon Jang is a Professor at the Department of Chemistry & Bio-Science at Kumoh National Institute of Technology (KIT) in Gumi, South Korea. He has held positions as a Post-Doctoral Fellow at Stanford University School of Medicine in Stanford, USA, and at the Department of Materials Science and Engineering at POSTECH in South Korea. Additionally, he worked as a Senior Researcher in the Department of Future Technology Research at Korea Telecom in South Korea. Prof. Jang obtained his B.Sc. degree from the Department of Chemistry at Chungnam National University in South Korea and his Master's and Ph.D. degrees from the Department of Chemistry at Seoul National University in Seoul, South Korea. His research program primarily revolves around the synthesis of various metal nanoparticles and the crystal engineering of solid nanoparticles.
