Physical chemistry lies at the heart of the behaviour of those macromolecules and molecular assemblies that have vital roles in all living organisms. Physical principles determine the stability of proteins and nucleic acids, the rate at which biochemical reactions proceed, the transport of molecules across biological molecules; they allow us to describe structure and reactivity in complex biological systems, and make sense of how these systems operate.
Physical Chemistry for the Life Sciences provides a balanced presentation of the concepts of physical chemistry, and their extensive applications to biology and biochemistry. It is written to straddle the worlds of physical chemistry and the life sciences and to show students how the tools of physical chemistry can elucidate and illuminate biological questions.
Opening with a suite of chapters on Biochemical Thermodynamics, with a focus on energy conversion in biological cells and the factors that stabilize proteins, nucleic acids, and cell membranes, the book goes on to explore the Kinetics of Life Processes, examining the rates of chemical reactions, how rates can help characterise the mechanism of a reaction, and how enzymes affect reaction rates. A third section, Biomolecular Structure, looks at how concepts of physical chemistry can be used to
establish those 'rules' that govern the assembly of complex biological structures, while the final section, Biomolecular Spectroscopy, describes the major techniques in biochemistry that are being applied to help us to explore biochemical processes and systems ever further.
Physical Chemistry for the Life Sciences places emphasis on clear explanations of difficult concepts, with an eye toward building insight into biochemical phenomena. An extensive range of learning features, including worked examples, illustrations, self-tests, and case studies, support student learning throughout, while special attention is given to providing extensive help to students with those mathematical concepts and techniques that are so central to a sound understanding of
Balancing clarity and rigor of exposition of basic concepts with extensive discussion of biological techniques and processes, Physical Chemistry for the Life Sciences is the perfect resource for every life science student who seeks to master those essentials of physical chemistry that underpin life itself.
Online Resource Centre
- Web links for each chapter, pointing students to interesting sources of related information and data, to facilitate self-directed learning
- A list of key equations for each chapter, to help students revise and master the key mathematical concepts that underpin the subject
- Living graphs, which present graphs from the text in interactive format, and enable students to strengthen their learning by manipulating key variables and exploring the consequeneces
- Three-dimensional, interactive models of the biomolecules appearing in the end-of-book atlas of structures
For registered adopters of the book:
Figures in electronic format
Publisher: Oxford University Press
Number of pages: 624
Weight: 1279 g
Dimensions: 266 x 201 x 24 mm
Edition: 2nd Revised edition
Review from previous edition An excellent textbook - fun to read and crystal clear. * Dr Hans A. Heus, Radboud University Nijmegen *
The toolkits are great, the worked examples will be very useful and the 'in the laboratory' sections are very nice to read, and will provide great teaching material. As [in the first edition] the use of recently developed techniques is superb. * Dr Perdita Barran, University of Edinburgh *
The authors succeed brilliantly in their aim to show that deep insights into the behaviour of biological systems can be gained by applying the principles of physical chemistry. I enjoyed reading this book and would recommend it without reservation to teachers and students alike. * Chemistry World, January 2006 *
This book provides an excellent insight into the subject of physical chemistry, understandable and suitable for both beginners and experts of chemistry. * Internal Journal of Biological Macromolecules, August 2006 *