Biophysics An Introduction
Today, courses on biophysics are taught in almost all universities in the world, often in separate biophysics departments or divisions. This reflects the enormous growth of the field, even though the problem of its formal definition remains unsettled. In spite of this lack of definition, biophysics,...
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| Format: | eBook |
| Language: | English |
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Dordrecht
Springer Netherlands
1989, 1989
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| Edition: | 1st ed. 1989 |
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| Online Access: | |
| Collection: | Springer Book Archives -2004 - Collection details see MPG.ReNa |
Table of Contents:
- 10.4 The energetics of contraction
- 11. Biophysics of sensory systems
- 11.1 The transmission of information
- 11.2 The visual receptor
- 11.3 The otic receptors
- 11.4 The chemical, somatic, and visceral receptors
- 12. Theoretical biology
- 12.1 Physical concepts and biology
- 12.2 Nonequilibrium thermodynamics
- 12.3 Modeling
- 12.4 Cybernetics
- 12.5 Generalizations in biology
- Appendix I. Some elements of quantum mechanics
- AI.1 The principle of quantization and the uncertainty principle
- Appendix II. Elements of equilibrium thermodynamics
- AII.l Definitions
- AII.2 First and second laws of thermodynamics
- AII.3 Entropy
- AII.4 Thermodynamic potentials
- AII.5 The chemical and the electrochemical potentials
- AII.6 The standard free energy of a chemical reaction
- AII.7 Oxidation-reduction potentials
- 1. Introduction
- 1.1 What is biophysics
- 1.2 The fundamental principles of biology
- 2. Biological structures
- 2.1 The structures of life
- 2.2 The morphology of cells
- 2.3 The biological macromolecules
- 2.4 Membranes
- 2.5 Cell evolution
- 3. Physical principles and methods in biology
- 3.1 The electronic structure of atoms
- 3.2 The structure of molecules and molecular complexes
- 3.3 Absorption and emission spectroscopy
- 3.4 Infrared and Raman spectroscopy
- 3.5 Magnetic resonances
- 3.6 Size and shape of biological macromolecules
- 3.7 X-ray crystal structure analysis
- 4. Structure and function of proteins and nucleic acids
- 4.1 The structure of proteins
- 4.2 Enzymes
- 4.3 Recognition proteins
- 4.4 The genetic systyem
- 4.5 Regulation and control
- 4.6 Recombinant DNA
- 5. Biological energy conversion
- 5.1 The biological energy flow
- 5.2 Adenosine triphosphate in coupled reactions; pyridine nucleotides
- 5.3 Fermentation and glycolysis
- 5.4 The citric acid cycle
- 5.5 Respiration
- 6. Photosynthesis
- 6.1 Photosynthetic structures
- 6.2 Transfer and trapping of excitation energy
- 6.3 Photosynthetic electron transport in higher plants and algae
- 6.4 Photosynthetic electron transport in prokaryotes
- 6.5 Reaction centers
- 6.6 Carbon fixation
- 7. Biological transport processes
- 7.1 Passive and active transport
- 7.2 Osmotic equilibrium
- 7.3 Ionic equilibrium
- 7.4 Flow across membranes
- 7.5 Transport mechanisms
- 8. Membrane-bound energy transduction
- 8.1 The high-energy intermediate
- 8.2 The chemiosmotic model
- 8.3 Proton translocation
- 8.4 pH gradient and membrane potential
- 8.5 The proton-translocating ATPase
- 9. Biophysics of nerves
- 9.1 Nerves
- 9.2 The action potential
- 9.3 Synapses
- 9.4 Information processing in neuronal systems
- 10. Biophysics of contractility
- 10.1 Intracellular motion
- 10.2 Cellular motion
- 10.3 Muscular contraction