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Preface
excellent concise reference source for the array of physical
science tools available to tackle biological problems.
In this book I focus specifically on the purpose, the
science, and the application of the physical science
tools. The chapters have been written to encapsulate all
tools active in current research labs, both experimental
and analytical/theoretical. Bulk ensemble methods as
well as single-molecule tools, and live-cell and test tube
methods, are discussed, as all are different components
available in the physical scientist’s toolbox for probing
biology. Importantly, this broad material is compre
hensively but concisely mapped into one single volume
without neglecting too much detail or any important
techniques. Theoretical sections have been written to
cover “intermediate” and “advanced” ability, allowing
levels of application for students with differing mathem
atical/computational abilities. The theory sections have
been designed to contrast the experimental sections in
terms of scale and focus. We need theories not only to
interpret experimental techniques but also to understand
more general questions around evolution, robustness,
nonequilibrium systems, etc., and these are not tied to
molecular scales.
Future innovators will need to be trained in multidis
ciplinary science to be successful, whether in industry,
academia, or government support agencies. This book
addresses such a need—to facilitate educating the future
leaders in the development and application of novel phys
ical science approaches to solve complex challenges linked
to biological questions. The importance of industrial
application at the physical/life sciences interface should
not be underestimated. For example, imaging, tracking,
and modeling chemical interactions and transport in
industrial biological/biomedical products is an emergent
science requiring a broad understanding and applica
tion of biophysical sciences. One of the great biopharma
challenges is the effective delivery of active compounds
to their targets and then monitoring their efficacy. This
is pivotal to delivering personalized healthcare, requiring
biological processes to be understood in depth. This is
also a good example of scales: the necessary molecular
scale of target, binding site, etc., and then the much
larger organismal scale at which most candidate drugs
fail—that of toxicology, side effects, etc. Physically based
methods to assess drug delivery and model systems facili
tating in vitro high-throughput screening with innovative
multilength scale modeling are needed to tackle these
challenges.
Also, the need for public health monitoring and iden
tifying environmental risks is highly relevant and are key
to preventative medicine. An example is exposure to
ionizing radiation due to medical imaging, travel, or the
workplace. Detecting, monitoring, and understanding
radiation damage to DNA, proteins, and cellular systems
during routine imaging procedures (such as dental x-
rays or cardiothoracic surgery) are key to understanding
noncancer effects (e.g., cataracts in the lens of the eye)
and the complications of radiation-based cancer therapy.
These are core global public health issues.
Understanding the science and application of new
instrumentation and analysis methods is vital not only
for core scientific understanding of biological process
in academia but also for application in many sectors
of the industry. Step changes in science and healthcare
sectors are always preceded by technological advances
in instrumentation. This requires the integration of spe
cialist knowledge with end-users’ requirements along
side an appreciation of the potential commercialization
process needed to exploit such innovation in both public
and private sectors via both multinational companies and
small- to medium-sized business enterprises (SMEs).
Such real-world challenges require individuals who are
skilled scientists and experts in their own field, but who
are also equipped to understand how to maximize impact
by utilizing the full investigative power of the biophysical
sciences. Specific advances are needed in advanced optical
microscopy and instrumentation, single-molecule detec
tion and interactions, atomic force microscopy (AFM),
image processing, polymer and synthetic chemistry, pro
tein crystallography, microfabrication, and mathematical
and finite element modeling to then interface with current
biological and healthcare problems.
This book is structured as nine concise chapters, navi
gating the reader through a historical background to the
concepts and motivation for a physical science toolbox in
understanding biology, and then dedicating a chapter to
orienting readers from a physical science area of expertise
to essential biological knowledge. Subsequent chapters
are then themed into sections involving experimental
biophysical techniques that primarily detect biological
components or measure/control biological forces. These
include descriptions of the science and application of the
key tools used in imaging, detection, general quantitation,
and biomolecular interaction studies, which span multiple
length and time scales of biological processes, ranging
from biological contexts both in the test tube and in the
living organism. I then dedicate a chapter to theoretical
biophysics tools, involving computational and analytical
mathematical methods for tackling challenging biological
questions, and end with a discussion of the future of this
exciting field.
Each chapter starts with a “General Idea,” which is a
broad-canvas description of the contents and import
ance of the chapter, followed by a nontechnical over
view of the general area and why it is relevant. Case
examples are used throughout for the most popular
physical science tools, involving full diagrams and a
précis of the science involved in the application of the
tool. “Key Points” are short sections used to reinforce
key concepts, and “Key Biological Applications” are used
to remind the reader of the general utility of different
biological questions for the different biophysical tools