Biomedical Applications of Magnetic Particles
Coordonnateurs : Anker Jeffrey N., Mefford O. Thompson
Biomedical Applications of Magnetic Particles discusses fundamental magnetic nanoparticle physics and chemistry and explores important biomedical applications and future challenges.
The first section presents the fundamentals of the field by explaining the theory of magnetism, describing techniques to synthesize magnetic particles, detailing methods to characterize magnetic particles, and quantitatively describing the applied magnetic forces, torques, and the resultant particle motions. The second section describes the wide range of biomedical applications, including chemical sensors, cellular actuators, drug delivery, magnetic hyperthermia, magnetic resonance imaging contrast enhancement, and toxicity.
Additional key features include:
- Covers both introduction to physics and characterization of magnetic nanoparticles and the state of the art in biomedical applications
- Authoritative reference for scientists and engineers for all new or old to the field
- Describes how the size of magnetic nanoparticles affects their magnetic properties, colloidal properties, and biological properties.
Written by a team of internationally respected experts, this book provides an up-to-date authoritative reference for scientists and engineers.
Table of Contents
Foreword..........................................................................................................................................vii
Preface...............................................................................................................................................ix
Editor Bios........................................................................................................................................xi
List of Contributors ........................................................................................................................xiii
Chapter 1 Introduction to Biomedical Applications of Magnetic Nanoparticles.......................1
SECTION I Magnetic Particle Fundamentals
Chapter 2 A Conceptual Introduction to the Fundamentals of Magnetic Fields,
Magnetic Materials, and Magnetic Particles
for Biomedical Applications.......................................................................................7
Chapter 3 Magnetic Forces and Torques: Separation, Tweezing, and Materials
Assembly in Biology ................................................................................................33
Chapter 4 Colloidal Interactions of Magnetic Nanoparticles ...................................................59
Chapter 5 Magnetic Characterization: Instruments and Methods ............................................83
SECTION II Magnetic Particle Applications
Chapter 6 Synthesis and Functionalization of Magnetic Particles .........................................121
Chapter 7 Nanomagnetic Actuation: Controlling Cell Behavior with Magnetic
Nanoparticles...........................................................................................................159
Chapter 8 Magnetic Nanoparticles: Challenges and Opportunities in Drug Delivery ..........177
Chapter 9 Magnetic Particle Biosensors .................................................................................197
Chapter 10 Magnetic Contrast Imaging: Magnetic Nanoparticles as Probes in
Living Systems .......................................................................................................241
Chapter 11 Energy Dissipation by Magnetic Nanoparticles: Basic Principles
for Biomedical Applications ..................................................................................275
Chapter 12 Toxicology of Magnetic Nanoparticles .................................................................305
Index..............................................................................................................................................345
Jeffrey N. Anker is a Wallace R. Roy Distinguished Professor of Chemistry
and BioEngineering at Clemson University. He earned his BS degree in
applied physics at Yale University in 1998. He earned his doctorate at The
University of Michigan in 2005, working for Professor Raoul Kopelman
to develop magnetically modulated optical nanoprobes (MagMOONs) to
measure chemical concentrations and mechanical properties of solutions. For
this work, he was awarded a grand prize at the 2002 National Inventor’s
Hall of Fame Collegiate Inventor’s Competition. From 2005 to 2008,
Dr. Anker worked as an NIH National Science Research Award (NSRA)
postdoctoral research fellow at Northwestern University under the guidance of Professor
Richard Van Duyne. His postdoctoral research focused on developing real-time high-resolution
plasmonic nanosensors. He joined the Clemson Chemistry Department in August 2008. Current
research focuses on imaging and spectroscopy using magnetic, plasmonic, x-ray excited microand
nanosensors, implantable sensors, orthopedic devices, and medical imaging. Along with
Thompson Mefford, he founded the Frontiers in BioMagnetic Particles Meeting Series. Awards
include: NSF CAREER award (2013); Clemson Faculty Collaboration Award (2014); Clemson
University School of Health Research (CUSHR), and Greenville Health System Embedded
Faculty Fellow (2018); University Research, Scholarship, and Artistic Achievement Award
(USRAAA) (2018); and senior member of the National Academy of Inventors (2019).
O. Thompson Mefford is an Associate Professor in the Department of
Materials Science Engineering where he holds a David and Mary Ann Bishop
Dean’s Professorship, along with an additional appointment in the Department
of Bioengineering at Clemson University. He earned his BS degree
in Polymer and Textile Che
Date de parution : 08-2022
17.8x25.4 cm
Date de parution : 12-2020
Ouvrage de 456 p.
17.8x25.4 cm
Thèmes de Biomedical Applications of Magnetic Particles :
Mots-clés :
Ferric Carboxymaltose; magnetic particles; Bone Sialoprotein; biomedicine; AC Susceptibility; drug delivery; DC Bias Field; Magnetophoresis; Magnetic Nanoparticles; Colloidal properties; Magnetization; Biomedical applications; Magnetic Force; Magnetic properties; Applied Field Amplitude; Applied Magnetic Field; Spin Valves; Mri Contrast Agent; Nanomagnetic Actuation; Van Der Waals; GMR Sensor; Magnetic Tweezers; MNP Suspension; RF Pulse; Single Domain Magnetic Particles; Van Der Waals Attractive Forces; Magnetic Moments; Atomic Magnetic Moments; Magnetite Nanoparticles; Single Domain MNPs; Contrast Agents