Chapter 1 Amino acids functionalized inorganic metal nanoparticles: Synthetic nanozymes for target specific binding, sensing and catalytic applications; Selvakannan Periasamy, Deepa Dumbre, Libitha Babu, Srinivasan Madapusi, Sarvesh Kumar Soni, Hemant Kumar Daima, Suresh Kumar Bhargava
Chapter 2 Thermal decomposition routes for magnetic nanoparticles: development of next-generation artificial enzymes, their phase transfer and biological applications; Mandeep Singh, Hemant Kumar Daima
Chapter 7 Metal-based nanozyme: Strategies to modulate the catalytic activity to realize environment application; Stuti Bhagata, Juhi Shaha, Sanjay Singh
Chapter 8 Nanozymes in Environmental Protection; Sheng Zhang, Yihui Hu
Dr. Hemant Kumar Daima, is nano-biotechnology expert at Amity University Rajasthan, India and visiting scientist at RMIT University, Australia. His research findings have revealed guiding principles involved in rational nanoparticle design strategies for biomedical applications. He is editorial member of leading scientific publishers, member of numerous scientific/professional bodies, and recipient of international fellowships/awards.
Navya PN is assistant professor at the Bannari Amman Institute of Technology, India. She is cofounder of Nano-Bio Interfacial Research Laboratory (NBIRL). Her research works are at the interface between nanotechnology and biology. She is recipient of several international fellowships.
Dr. Eric Lichtfouse is professor of environmental chemistry and scientific communication at Aix-Marseille University, France and Xi’an Jiaoting University, China. He has invented carbon-13 dating based on the discovery of temporal pools of organic molecules in soils. He is Chief Editor and co-founder of the journal Environmental Chemistry Letters, and the book series Sustainable Agriculture Reviews and Environmental Chemistry for a Sustainable World. He has published the book Scientific Writing for Impact Factor Journals.
Protection of the environment is essential because pollution has become a global problem with many adverse effects on life and ecosystems. For that, remediation strategies and techniques have been designed, yet they are limited. Here, the recent development of nanotechnology opens a new vista for environmental remediation. In particular, nanomaterials displaying enzyme-like activities, named ‘nanozymes’, appear very promising for environmental monitoring, contaminant detection, microbial management, and degradation of organic pollutants. Nanomaterials including metallic, metal oxides and carbon-based nanoparticles with nanozymes activities have been synthesized. These nanozymes have similar activities as natural peroxidase, oxidase, superoxide dismutase and catalase enzymes. Nanozymes have several advantages, yet they suffer from several limitations such as low catalytic efficiency, less substrate selectivity, biocompatibility, and lack of engineering of the active sites. This book reviews the latest developments and applications of nanozymes in environmental science.