Practical approach to solution-based synthesis methods and mechanisms from a chemical engineering perspectives
Engineering Nanoparticles for Biomedical Applications provides an in-depth, hands-on overview of synthesis and formation mechanisms, characterization, and functionalization of nanoparticles (NPs) using solution-based methods developed from fundamental principles of nucleation and growth. Various experimental synthesis strategies are supported via simulation and modeling. The NPs studied in this book are designed to target an array of biomedical applications.
In this book, readers can practice reverse engineering by first choosing a specific biomedical application, upon which the reader will be exposed to a host of synthesis options. Based on desired properties of NPs, this book can then provide all the relevant information using modeling approaches for that specific biomedical application.
Sample topics covered in Engineering Nanoparticles for Biomedical Applications include: - Physico-chemical properties of NPs such as magnetic, plasmonic, and stimuli-sensitivity properties - Modeling approaches including Density Functional Theory (DFT), Molecular Dynamics (MD), Monte Carlo simulations, and Population Balance Model - Applications of NPs with emphasis on biomedical applications such as biosensing, diagnostics/imaging, and drug delivery - Optical, magnetic, thermal, electrochemical, and biological properties of multifunctional nanoparticles - Iron oxides in spherical magnetic NPs, detailing co-precipitation, thermal decomposition, and colloidal templating synthesis methods
Engineering Nanoparticles for Biomedical Applications is an essential reference on the subject for chemists and engineers at every level of academia and industry.
Engineering Nanoparticles for Biomedical Applications provides an in-depth, hands-on overview of synthesis and formation mechanisms, characterization, and functionalization of nanoparticles (NPs) using solution-based methods developed from fundamental principles of nucleation and growth. Various experimental synthesis strategies are supported via simulation and modeling. The NPs studied in this book are designed to target an array of biomedical applications.
In this book, readers can practice reverse engineering by first choosing a specific biomedical application, upon which the reader will be exposed to a host of synthesis options. Based on desired properties of NPs, this book can then provide all the relevant information using modeling approaches for that specific biomedical application.
Sample topics covered in Engineering Nanoparticles for Biomedical Applications include: - Physico-chemical properties of NPs such as magnetic, plasmonic, and stimuli-sensitivity properties - Modeling approaches including Density Functional Theory (DFT), Molecular Dynamics (MD), Monte Carlo simulations, and Population Balance Model - Applications of NPs with emphasis on biomedical applications such as biosensing, diagnostics/imaging, and drug delivery - Optical, magnetic, thermal, electrochemical, and biological properties of multifunctional nanoparticles - Iron oxides in spherical magnetic NPs, detailing co-precipitation, thermal decomposition, and colloidal templating synthesis methods
Engineering Nanoparticles for Biomedical Applications is an essential reference on the subject for chemists and engineers at every level of academia and industry.
Table of Contents
SECTION I: Synthesis and Formation Mechanisms of NPs1. Nucleation and Growth of NPs
2. Characterization of NPs
3. Spherical Magnetic NPs
4. Anisotropic Magnetic NPs
5. Spherical Plasmonic NPs
6. Anisotropic Plasmonic NPs
7. Polymeric NPs
8. Multifunctional NPs
SECTION II: Modelling Approaches for Understanding Formation Mechanisms of NPs
9. Overview of Modelling Approaches
10. Density Functional Theory (DFT)
11. Molecular Dynamics (MD)
12. Monte Carlo Simulation (MC)
13. Population Balance Model (PB)
SECTION III: Biomedical Applications of NPs
14. Biosensing
15. Diagnostics and Imaging
16. Drug Delivery
