Wiley - Encyclopedia of Medical Devices and Instrumentation - Vol. 1
PREFACE
This six-volume work is an alphabetically organized compilation
of almost 300 articles that describe critical aspects of
medical devices and instrumentation.
It is comprehensive. The articles emphasize the contributions
of engineering, physics, and computers to each of the
general areas of anesthesiology, biomaterials, burns, cardiology,
clinical chemistry, clinical engineering, communicative
disorders, computers in medicine, critical care
medicine, dermatology, dentistry, ear, nose, and throat,
emergency medicine, endocrinology, gastroenterology,
genetics, geriatrics, gynecology, hematology, heptology,
internal medicine, medical physics, microbiology, nephrology,
neurology, nutrition, obstetrics, oncology, ophthalmology,
orthopedics, pain, pediatrics, peripheral vascular
disease, pharmacology, physical therapy, psychiatry, pulmonary
medicine, radiology, rehabilitation, surgery, tissue
engineering, transducers, and urology.
The discipline is defined through the synthesis of the core
knowledge from all the fields encompassed by the application
of engineering, physics, and computers to problems in
medicine. The articles focus not only on what is now useful
but also on what is likely to be useful in future medical
applications.
These volumes answer the question, ‘‘What are the
branches of medicine and how does technology assist each
of them?’’ rather than ‘‘What are the branches of technology
and how could each be used in medicine?’’ To keep this work
to a manageable length, the practice of medicine that is
unassisted by devices, such as the use of drugs to treat
disease, has been excluded.
The articles are accessible to the user; each benefits from
brevity of condensation instead of what could easily have
been a book-length work. The articles are designed not for
peers, but rather for workers from related fields who wish to
take a first look at what is important in the subject.
The articles are readable. They do not presume a detailed
background in the subject, but are designed for any person
with a scientific background and an interest in technology.
Rather than attempting to teach the basics of physiology or
Ohm’s law, the articles build on such basic concepts to show
how the worlds of life science and physical science meld to
produce improved systems. While the ideal reader might be
a person with a Master’s degree in biomedical engineering or
medical physics or an M.D. with a physical science undergraduate
degree, much of the material will be of value to
others with an interest in this growing field. High school
students and hospital patients can skip over more technical
areas and still gain much fromthe descriptive presentations.
The Encyclopedia of Medical Devices and Instrumentation
is excellent for browsing and searching for those new
divergent associations that may advance work in a peripheral
field. While it can be used as a reference for facts, the
articles are long enough that they can serve as an educational
instrument and provide genuine understanding of a
subject.
One can use this work just as one would use a dictionary,
since the articles are arranged alphabetically by topic. Cross
references assist the reader looking for subjects listed under
slightly different names. The index at the end leads the
reader to all articles containing pertinent information on
any subject. Listed on pages xxi to xxx are all the abbreviations
and acronyms used in the Encyclopedia. Because of
the increasing use of SI units in all branches of science, these
units are provided throughout the Encyclopedia articles as
well as on pages xxxi to xxxv in the section on conversion
factors and unit symbols.
I owe a great debt to the many people who have contributed
to the creation of this work. At John Wiley & Sons,
Encyclopedia Editor George Telecki provided the idea and
guiding influence to launch the project. Sean Pidgeon was
Editorial Director of the project. Assistant Editors Roseann
Zappia, Sarah Harrington, and Surlan Murrell handled the
myriad details of communication between publisher, editor,
authors, and reviewers and stimulated authors and
reviewers to meet necessary deadlines.
My own background has been in the electrical aspects of
biomedical engineering. I was delighted to have the assisance
of the editorial board to develop a comprehensive
ncyclopedia. David J. Beebe suggested cellular topics such
as microfluidics. Jerry M. Calkins assisted in defining the
chemically related subjects, such as anesthesiology.
Michael R. Neuman suggested subjects related to sensors,
uch as in his own work—neonatology. Joon B. Park has
written extensively on biomaterials and suggested related
subjects. Edward S. Sternick provided many suggestions
from medical physics. The Editorial Board was instrumental
both in defining the list of subjects and in suggesting
authors.
This second edition brings the field up to date. It is
available on the web at *.
com/emdi, where articles can be searched simultaneously to
provide rapid and comprehensive information on all aspects
of medical devices and instrumentation.
JOHN G. WEBSTER
University of Wisconsin, Madison
Download
*
PREFACE
This six-volume work is an alphabetically organized compilation
of almost 300 articles that describe critical aspects of
medical devices and instrumentation.
It is comprehensive. The articles emphasize the contributions
of engineering, physics, and computers to each of the
general areas of anesthesiology, biomaterials, burns, cardiology,
clinical chemistry, clinical engineering, communicative
disorders, computers in medicine, critical care
medicine, dermatology, dentistry, ear, nose, and throat,
emergency medicine, endocrinology, gastroenterology,
genetics, geriatrics, gynecology, hematology, heptology,
internal medicine, medical physics, microbiology, nephrology,
neurology, nutrition, obstetrics, oncology, ophthalmology,
orthopedics, pain, pediatrics, peripheral vascular
disease, pharmacology, physical therapy, psychiatry, pulmonary
medicine, radiology, rehabilitation, surgery, tissue
engineering, transducers, and urology.
The discipline is defined through the synthesis of the core
knowledge from all the fields encompassed by the application
of engineering, physics, and computers to problems in
medicine. The articles focus not only on what is now useful
but also on what is likely to be useful in future medical
applications.
These volumes answer the question, ‘‘What are the
branches of medicine and how does technology assist each
of them?’’ rather than ‘‘What are the branches of technology
and how could each be used in medicine?’’ To keep this work
to a manageable length, the practice of medicine that is
unassisted by devices, such as the use of drugs to treat
disease, has been excluded.
The articles are accessible to the user; each benefits from
brevity of condensation instead of what could easily have
been a book-length work. The articles are designed not for
peers, but rather for workers from related fields who wish to
take a first look at what is important in the subject.
The articles are readable. They do not presume a detailed
background in the subject, but are designed for any person
with a scientific background and an interest in technology.
Rather than attempting to teach the basics of physiology or
Ohm’s law, the articles build on such basic concepts to show
how the worlds of life science and physical science meld to
produce improved systems. While the ideal reader might be
a person with a Master’s degree in biomedical engineering or
medical physics or an M.D. with a physical science undergraduate
degree, much of the material will be of value to
others with an interest in this growing field. High school
students and hospital patients can skip over more technical
areas and still gain much fromthe descriptive presentations.
The Encyclopedia of Medical Devices and Instrumentation
is excellent for browsing and searching for those new
divergent associations that may advance work in a peripheral
field. While it can be used as a reference for facts, the
articles are long enough that they can serve as an educational
instrument and provide genuine understanding of a
subject.
One can use this work just as one would use a dictionary,
since the articles are arranged alphabetically by topic. Cross
references assist the reader looking for subjects listed under
slightly different names. The index at the end leads the
reader to all articles containing pertinent information on
any subject. Listed on pages xxi to xxx are all the abbreviations
and acronyms used in the Encyclopedia. Because of
the increasing use of SI units in all branches of science, these
units are provided throughout the Encyclopedia articles as
well as on pages xxxi to xxxv in the section on conversion
factors and unit symbols.
I owe a great debt to the many people who have contributed
to the creation of this work. At John Wiley & Sons,
Encyclopedia Editor George Telecki provided the idea and
guiding influence to launch the project. Sean Pidgeon was
Editorial Director of the project. Assistant Editors Roseann
Zappia, Sarah Harrington, and Surlan Murrell handled the
myriad details of communication between publisher, editor,
authors, and reviewers and stimulated authors and
reviewers to meet necessary deadlines.
My own background has been in the electrical aspects of
biomedical engineering. I was delighted to have the assisance
of the editorial board to develop a comprehensive
ncyclopedia. David J. Beebe suggested cellular topics such
as microfluidics. Jerry M. Calkins assisted in defining the
chemically related subjects, such as anesthesiology.
Michael R. Neuman suggested subjects related to sensors,
uch as in his own work—neonatology. Joon B. Park has
written extensively on biomaterials and suggested related
subjects. Edward S. Sternick provided many suggestions
from medical physics. The Editorial Board was instrumental
both in defining the list of subjects and in suggesting
authors.
This second edition brings the field up to date. It is
available on the web at *.
com/emdi, where articles can be searched simultaneously to
provide rapid and comprehensive information on all aspects
of medical devices and instrumentation.
JOHN G. WEBSTER
University of Wisconsin, Madison
Download
*