Biomedical EPR Part-B Methodology Instrumentation and Dynamics - Sandra R. Eaton
PREFACE
There has not been an attempt to cover the full scope of biological EPR in
a single volume since Biological Applications of Electron Spin Resonance
edited by Swartz, Bolton, and Borg in 1972. In three decades there have
been enormous changes in the field. Our original plan for one volume
expanded into two. A stimulus for an updated book at this time was the
birthday of James S. Hyde (May 20, 2002), one of the leaders in the
development of EPR instrumentation and methodology applied to biological
problems. To symbolically tie this book to Jim Hyde’s efforts, we choose
the title “Biomedical EPR”, which is the name of the NIH-funded National
Biomedical EPR Center founded by Harold Swartz and James Hyde at the
Medical College of Wisconsin in 1975. This Center has been funded
continuously since then, and has been a focal point of new developments and
applications in biomedical research. Many of the authors of chapters in this
book have been close associates of Jim Hyde, and several have been longterm
members of the Advisory Committee of the Center.
There is a long history underlying most of the topics in these books.
Some of this history was surveyed in Foundations of Modern EPR, edited by
Eaton, Eaton, and Salikhov (1998). It is helpful to keep in mind that
theoretical and experimental studies of spin relaxation preceded the
development of EPR and NMR. The early work of Waller and of Gorter, for
example, focused on spin relaxation (see Foundations of Modern EPR).
Long development periods, and indirect paths from initial concept to
biomedical application are the norm. Even new instrumentation or
methodology developments, with few exceptions, require of the order of 10
to 15 years from “invention” to general application. No one could have
predicted that the attempt to make a better measurement of the deuterium
magnetic moment would lead to functional magnetic resonance imaging
(fMRI), and if such a prediction had been made, it would have been
dismissed as ridiculous. Those who sponsor research, and nurture
researchers, enrich humanity by not demanding proof of relevance. We each
pursue goals that inspire us, and hope that they will be of benefit. This book
is part of a story as it unfolds.
Contributors were asked to make this book more “pedagogical” than
“review.” The goal is a multi-author introduction to biomedical EPR with
up-to-date examples, explanations, and applications, pointing toward the
future. Thus, the book is aimed not just at readers who are EPR experts, but
at biomedical researchers seeking to learn whether EPR technology and
methodology will be useful to solve their biomedical problems. The
derivation and explanation of the underlying theory and methodology for
many of the topics presented would require separate books. The authors
were asked to keep the background and theory to a minimum, referring
whenever possible to other texts and reviews to lead the reader to additional
information. The referencing in most chapters is thus to be tutorial and
helpful, rather than to be comprehensive or to reflect priority of discovery.
There is a focus on papers with a biological orientation. Thus, for example,
although the fact that oxygen in solution broadens CW EPR spectra has been
known since 1959 (see the chapter by Hauser and Brunner in Foundations of
Modern EPR ), the citations in the oxymetry chapter in this book to
biologically relevant literature about oxygen broadening start about twenty
years later. The perspective in each chapter is presented from the viewpoint
of people involved in cutting-edge research.
Download
*
PREFACE
There has not been an attempt to cover the full scope of biological EPR in
a single volume since Biological Applications of Electron Spin Resonance
edited by Swartz, Bolton, and Borg in 1972. In three decades there have
been enormous changes in the field. Our original plan for one volume
expanded into two. A stimulus for an updated book at this time was the
birthday of James S. Hyde (May 20, 2002), one of the leaders in the
development of EPR instrumentation and methodology applied to biological
problems. To symbolically tie this book to Jim Hyde’s efforts, we choose
the title “Biomedical EPR”, which is the name of the NIH-funded National
Biomedical EPR Center founded by Harold Swartz and James Hyde at the
Medical College of Wisconsin in 1975. This Center has been funded
continuously since then, and has been a focal point of new developments and
applications in biomedical research. Many of the authors of chapters in this
book have been close associates of Jim Hyde, and several have been longterm
members of the Advisory Committee of the Center.
There is a long history underlying most of the topics in these books.
Some of this history was surveyed in Foundations of Modern EPR, edited by
Eaton, Eaton, and Salikhov (1998). It is helpful to keep in mind that
theoretical and experimental studies of spin relaxation preceded the
development of EPR and NMR. The early work of Waller and of Gorter, for
example, focused on spin relaxation (see Foundations of Modern EPR).
Long development periods, and indirect paths from initial concept to
biomedical application are the norm. Even new instrumentation or
methodology developments, with few exceptions, require of the order of 10
to 15 years from “invention” to general application. No one could have
predicted that the attempt to make a better measurement of the deuterium
magnetic moment would lead to functional magnetic resonance imaging
(fMRI), and if such a prediction had been made, it would have been
dismissed as ridiculous. Those who sponsor research, and nurture
researchers, enrich humanity by not demanding proof of relevance. We each
pursue goals that inspire us, and hope that they will be of benefit. This book
is part of a story as it unfolds.
Contributors were asked to make this book more “pedagogical” than
“review.” The goal is a multi-author introduction to biomedical EPR with
up-to-date examples, explanations, and applications, pointing toward the
future. Thus, the book is aimed not just at readers who are EPR experts, but
at biomedical researchers seeking to learn whether EPR technology and
methodology will be useful to solve their biomedical problems. The
derivation and explanation of the underlying theory and methodology for
many of the topics presented would require separate books. The authors
were asked to keep the background and theory to a minimum, referring
whenever possible to other texts and reviews to lead the reader to additional
information. The referencing in most chapters is thus to be tutorial and
helpful, rather than to be comprehensive or to reflect priority of discovery.
There is a focus on papers with a biological orientation. Thus, for example,
although the fact that oxygen in solution broadens CW EPR spectra has been
known since 1959 (see the chapter by Hauser and Brunner in Foundations of
Modern EPR ), the citations in the oxymetry chapter in this book to
biologically relevant literature about oxygen broadening start about twenty
years later. The perspective in each chapter is presented from the viewpoint
of people involved in cutting-edge research.
Download
*