Description
Book SynopsisRecent advances in nanomedicine offer ground-breaking methods for the prevention, diagnosis and treatment of some fatal diseases. Amongst the most promising nanomaterials being developed are magnetic nanomaterials, including magnetic nanoparticles and magnetic nanosensors. Some nanomagnetic medical applications are already commercially available with more set to be released over the coming years.
Nanomedicine, Design and Applications of Magnetic Nanomaterials, Nanosensors and Nanosystems presents a comprehensive overview of the biomedical applications of various types of functional magnetic materials. The book provides an introduction to magnetic nanomaterials before systematically discussing the individual materials, their physical and chemical principles, fabrication techniques and biomedical applications. This methodical approach allows this book to be used both as a textbook for beginners to the subject and as a convenient reference for professionals in the field.
Table of Contents
CONTENTS Preface
About the Authors Introduction
1.1 What is nanoscience and nanotechnology
1.2 Magnets and nanometers: mutual attraction
1.3 Typical magnetic nanomaterials
1.4 Nanomedicine and magnetic nanomedicine
1.5 Typical biomedical applications of functional magnetic nanomaterials
Physical background for the biomedical applications of functional magnetic nanomaterials
2.1 Requirements for biomedical applications
2.2 Fundamentals of nanomagnetism
2.3 Magnetic relaxation of ferrofluids
2.4 Magnetorheology of ferrofluids
2.5 Manipulation of magnetic particles in fluids
2.6 Interactions between biological nanomaterials and functionalized magnetic nanoparticles
Magnetic nanoparticles
3.1 Introduction
3.2 Basics of nanomagnetics
3.3 Synthesis techniques
3.4 Synthesis of magnetic nanoparticles
3.5 Bio-inspired magnetic nanoparticles
3.6 Functionalization of magnetic nanoparticles
3.7 Future prospects
Biomedical applications of magnetic nanoparticles
4.1 Introduction
4.2 Diagnostic applications
4.3 Therapeutic applications
4.4 Physiological aspects
4.5 Toxic effects
Magnetosomes and their biomedical applications
5.1 Introduction
5.2 Magnetosome formation
5.3 Cultivation of magnetotactic bacteria
5.4 Characterization of magnetosomes
5.5 Biomedical applications of magnetosomes
Magnetic nanowires and their biomedical applications
6.1 Introduction
6.2 Magnetism of magnetic nanowires
6.3 Template-based synthesis of magnetic nanowires
6.4 Characterization of magnetic nanowires
6.5 Functionalization of magnetic nanowires
6.6 Magnetic nanowires in suspension
6.7 Biomedical applications of magnetic nanowires
Magnetic nanotubes and their biomedical applications
7.1 Introduction
7.2 Magnetism of nanotubes
7.3 Multifunctionality of magnetic nanotubes
7.4 Synthesis and characterization of magnetic nanotubes
7.5 Biomedical applications of magnetic nanotubes
Magnetic biosensors
8.1 Introduction
8.2 Magnetoresistance-based sensors
8.3 Hall effect sensors
8.4 Other sensors detecting stray magnetic fields
8.5 Sensors detecting magnetic relaxations
8.6 Sensors detecting ferrofluid susceptibility
Magnetic biochips: basic principles
9.1 Introduction
9.2 Biochips based on giant magnetoresistance sensors
9.3 Biochips based on spin valve sensors
9.4 Biochips based on magnetic tunnel junctions
9.5 Fully integrated biochips
Biomedical applications of magnetic biosensors and biochips
10.1 Introduction
10.2 DNA analysis
10.3 Protein analysis and protein biochips
10.4 Virus detection and cell analysis
10.5 Study of the interactions between biomolecules
10.6 Detection of biological warfare agents
10.7 Environmental monitoring and cleanup
10.8 Outlook
Appendix
A1. Units for magnetic properties
