Mordecai P. Blaustein,
Mordecai P., MD (Professor & Chairman, Department of Physiology, University of Maryland School of Medicine, Baltimore, MD) Blaustein,
Joseph P. Y. Kao,
Joseph P. Y., PhD (Associate Professor, Department of Physiology, University of Maryland School of Medicine, Baltimore, MD) Kao,
Donald R. Matteson,
Donald R., PhD (Associate Professor, Department of Physiology, University of Maryland School of Medicine, Baltimore, MD) Matteson
e.a.
Elsevier Health Sciences
e druk, 2019
9780323596190
Cellular Physiology and Neurophysiology
Mosby Physiology Series
Specificaties
Paperback, blz.
|
Engels
Elsevier Health Sciences |
2019
ISBN13: 9780323596190
Rubricering
Onderdeel van serie
Mosby's Physiology Monograph
Levertijd ongeveer 9 werkdagen
Gratis verzonden
Samenvatting
Gain a foundational understanding of complex physiology concepts with this thoroughly revised text. Cellular Physiology and Neurophysiology, a volume in the Mosby Physiology Series, explains the fundamentals of these multi-faceted areas in a clear and concise manner. It helps bridge the gap between basic biochemistry, molecular and cell biology, and neuroscience, and organ and systems physiology, providing the rich, clinically oriented coverage needed to master the latest concepts in neuroscience and how cells function in health and disease. Helps you easily master the material in a systems-based curriculum with learning objectives, Clinical Concept boxes, highlighted key words and concepts, chapter summaries, self-study questions, and a comprehensive exam. Focuses on clinical implications with frequent examples from systems physiology, pharmacology, and pathophysiology. Provides a solid depiction of transport processes―an integral topic often treated superficially in other cell biology texts. Enhanced eBook version included with purchase. Your enhanced eBook allows you to access all of the text, figures, and references from the book on a variety of devices.
Complete the Mosby Physiology Series! Systems-based and portable, these titles are ideal for integrated programs.
White, Harrison, & Mehlmann: Endocrine and Reproductive Physiology Johnson: Gastrointestinal Physiology Koeppen & Stanton: Renal Physiology Cloutier: Respiratory Physiology Pappano & Weir: Cardiovascular Physiology Hudnall: Hematology: A Pathophysiologic Approach
Specificaties
Inhoudsopgave
<p>SECTION I, Fundamental Physicochemical Concepts</p> <p>CHAPTER 1, INTRODUCTION: HOMEOSTASIS AND CELLULAR PHYSIOLOGY</p> <p>Homeostasis Enables the Body to Survive in Diverse Environments</p> <p>The Body Is an Ensemble of Functionally and Spatially Distinct Compartments</p> <p>Transport Processes Are Essential to Physiological Function</p> <p>Cellular Physiology Focuses on Membrane-Mediated Processes and on Muscle Function</p> <p>Summary</p> <p>Key Words and Concepts</p> <p>CHAPTER 2, DIFFUSION AND PERMEABILITY</p> <p>Diffusion Is the Migration of Molecules down a Concentration Gradient</p> <p>Fick’s First Law of Diffusion Summarizes our Intuitive Understanding of Diffusion</p> <p>Essential Aspects of Diffusion Are Revealed by Quantitative Examination of Random, Microscopic Movements of Molecules</p> <p>Fick’s First Law Can Be Used to Describe Diffusion across a Membrane Barrier</p> <p>Summary</p> <p>Key Words and Concepts</p> <p>Study Problems</p> <p>CHAPTER 3, OSMOTIC PRESSURE AND WATER MOVEMENT </p> <p>Osmosis Is the Transport of Solvent Driven by a Difference in Solute Concentration Across a Membrane That Is Impermeable to Solute</p> <p>Water Transport during Osmosis Leads to Changes in Volume</p> <p>Osmotic Pressure Drives the Net Transport of Water during Osmosis</p> <p>Osmotic Pressure and Hydrostatic Pressure Are Functionally Equivalent in Their Ability to Drive Water Movement Through a Membrane</p> <p>Only Impermeant Solutes Can Have Permanent Osmotic Effects</p> <p>Summary</p> <p>Key Words and Concepts</p> <p>Study Problems</p> <p>CHAPTER 4, ELECTRICAL CONSEQUENCES OF IONIC GRADIENTS </p> <p>Ions Are Typically Present at Different Concentrations on Opposite Sides of a Biomembrane</p> <p>Selective Ionic Permeability Through Membranes Has Electrical Consequences: The Nernst Equation</p> <p>The Stable Resting Membrane Potential in a Living Cell Is Established by Balancing Multiple Ionic Fluxes</p> <p>The Cell Can Change Its Membrane Potential by Selectively Changing Membrane Permeability to Certain Ions</p> <p>The Donnan Effect Is an Osmotic Threat to Living Cells</p> <p>Summary</p> <p>Key Words and Concepts</p> <p>Study Problems</p> <p>SECTION II, Ion Channels and Excitable Membranes</p> <p>CHAPTER 5, ION CHANNELS </p> <p>Ion Channels Are Critical Determinants of the Electrical Behavior of Membranes</p> <p>Distinct Types of Ion Channels Have Several Common Properties</p> <p>Ion Channels Share Structural Similarities and Can Be Grouped into Gene Families</p> <p>Summary</p> <p>Key Words and Concepts</p> <p>Study Problems</p> <p>CHAPTER 6, PASSIVE ELECTRICAL PROPERTIES OF MEMBRANES </p> <p>The Time Course and Spread of Membrane Potential Changes Are Predicted by the Passive Electrical Properties of the Membrane</p> <p>The Equivalent Circuit of a Membrane Has a Resistor in Parallel with a Capacitor</p> <p>Passive Membrane Properties Produce Linear Current-Voltage Relationships</p> <p>Membrane Capacitance Affects the Time Course of Voltage Changes</p> <p>Membrane and Axoplasmic Resistances Affect the Passive Spread of Subthreshold Electrical Signals</p> <p>Summary</p> <p>Key Words and Concepts</p> <p>Study Problems</p> <p>CHAPTER 7, GENERATION AND PROPAGATION OF THE ACTION POTENTIAL </p> <p>The Action Potential Is a Rapid and Transient Depolarization of the Membrane Potential in Electrically Excitable Cells</p> <p>Ion Channel Function Is Studied with a Voltage Clamp</p> <p>Individual Ion Channels Have Two Conductance Levels</p> <p>Na<SUP>+</SUP> Channels Inactivate during Maintained Depolarization</p> <p>Action Potentials Are Generated by Voltage-Gated Na<SUP>+</SUP> and K<SUP>+</SUP> Channels</p> <p>Action Potential Propagation Occurs as a Result of Local Circuit Currents</p> <p>Summary</p> <p>Key Words and Concepts</p> <p>Study Problems</p> <p>CHAPTER 8, ION CHANNEL DIVERSITY </p> <p>Various Types of Ion Channels Help to Regulate Cellular Processes</p> <p>Voltage-Gated Ca<SUP>2+</SUP> Channels Contribute to Electrical Activity and Mediate Ca<SUP>2+</SUP> Entry into Cells</p> <p>Many Members of the Transient Receptor Potential Superfamily of Channels Mediate Ca<SUP>2+</SUP> Entry</p> <p>K<SUP>+</SUP>-Selective Channels Are the Most Diverse Type of Channel</p> <p>Ion Channel Activity Can Be Regulated by Second-Messenger Pathways</p> <p>Summary</p> <p>Key Words and Concepts</p> <p>Study Problems</p> <p>SECTION III, Solute Transport</p> <p>CHAPTER 9, ELECTROCHEMICAL POTENTIAL ENERGY AND TRANSPORT PROCESSES </p> <p>Electrochemical Potential Energy Drives All Transport Processes</p> <p>Summary</p> <p>Key Words and Concepts</p> <p>Study Problems</p> <p>CHAPTER 10, PASSIVE SOLUTE TRANSPORT </p> <p>Diffusion across Biological Membranes Is Limited by Lipid Solubility</p> <p>Channel, Carrier, and Pump Proteins Mediate Transport across Biological Membranes</p> <p>Carriers Are Integral Membrane Proteins That Open to Only One Side of the Membrane at a Time</p> <p>Coupling the Transport of One Solute to the "Downhill" Transport of Another Solute Enables Carriers to Move the Cotransported or Countertransported Solute "Uphill" against an Electrochemical Gradient</p> <p>Net Transport of Some Solutes across Epithelia Is Effected by Coupling Two Transport Processes in Series</p> <p>Na<SUP>+</SUP> Is Exchanged for Solutes Such as Ca<SUP>2+</SUP> and H<SUP>+</SUP> by Countertransport Mechanisms </p> <p>Multiple Transport Systems Can Be Functionally Coupled</p> <p>Summary</p> <p>Key Words and Concepts</p> <p>Study Problems</p> <p>CHAPTER 11, ACTIVE TRANSPORT </p> <p>Primary Active Transport Converts the Chemical Energy from ATP into Electrochemical Potential Energy Stored in Solute Gradients</p> <p>The Plasma Membrane Na<SUP>+</SUP> Pump (Na<SUP>+</SUP>, K<SUP>+</SUP>-ATPase) Maintains the Low Na<SUP>+</SUP> and High K<SUP>+</SUP> Concentrations in the Cytosol</p> <p>Intracellular Ca<SUP>2+</SUP> Signaling Is Universal and Is Closely Tied to Ca<SUP>2+</SUP> Homeostasis</p> <p>Several Other Plasma Membrane Transport ATPases Are Physiologically Important </p> <p>Net Transport across Epithelial Cells Depends on the Coupling of Apical and Basolateral Membrane Transport Systems</p> <p>Summary</p> <p>Key Words and Concepts</p> <p>Study Problems</p> <p>SECTION IV, Physiology of Synaptic Transmission</p> <p>CHAPTER 12, SYNAPTIC PHYSIOLOGY I </p> <p>The Synapse Is a Junction Between Cells That Is Specialized for Cell-Cell Signaling</p> <p>Neurons Communicate with Other Neurons and with Muscle by Releasing Neurotransmitters</p> <p>The Synaptic Vesicle Cycle Is a Precisely Choreographed Process for Delivering Neurotransmitter into the Synaptic Cleft</p> <p>Short-Term Synaptic Plasticity Is a Transient, Use-Dependent Change in the Efficacy of Synaptic Transmission</p> <p>Summary</p> <p>Key Words and Concepts</p> <p>Study Problems</p> <p>CHAPTER 13, SYNAPTIC PHYSIOLOGY II</p> <p>Chemical Synapses Afford Specificity, Variety, and Fine Tuning of Neurotransmission </p> <p>Receptors Mediate the Actions of Neurotransmitters in Postsynaptic Cells</p> <p>Acetylcholine Receptors Can Be Ionotropic or Metabotropic</p> <p>Amino Acid Neurotransmitters Mediate Many Excitatory and Inhibitory Responses in the Brain</p> <p>Neurotransmitters That Bind to Ionotropic Receptors Cause Membrane Conductance Changes</p> <p>Biogenic Amines, Purines, and Neuropeptides Are Important Classes of Transmitters with a Wide Spectrum of Actions</p> <p>Unconventional Neurotransmitters Modulate Many Complex Physiological Responses</p> <p>Long-Term Synaptic Potentiation and Depression Are Persistent Changes in the Efficacy of Synaptic Transmission Induced by Neural Activity</p> <p>Summary</p> <p>Key Words and Concepts</p> <p>Study Problems</p> <p>SECTION V, Molecular Motors and Muscle Contraction</p> <p>CHAPTER 14, MOLECULAR MOTORS AND THE MECHANISM OF MUSCLE CONTRACTION </p> <p>Molecular Motors Produce Movement by Converting Chemical Energy into Kinetic Energy</p> <p>Single Skeletal Muscle Fibers Are Composed of Many Myofibrils</p> <p>The Sarcomere Is the Basic Unit of Contraction in Skeletal Muscle</p> <p>Muscle Contraction Results from Thick and Thin Filaments Sliding Past Each Other (The "Sliding Filament" Mechanism)</p> <p>The Cross-Bridge Cycle Powers Muscle Contraction</p> <p>In Skeletal and Cardiac Muscles, Ca<SUP>2+</SUP> Activates Contraction by Binding to the Regulatory Protein Troponin C</p> <p>The Structure and Function of Cardiac Muscle and Smooth Muscle Are Distinctly Different from Those of Skeletal Muscle</p> <p>Summary</p> <p>Key Words and Concepts</p> <p>Study Problems</p> <p>CHAPTER 15, EXCITATION-CONTRACTION COUPLING IN MUSCLE </p> <p>Skeletal Muscle Contraction Is Initiated by a Depolarization of the Surface Membrane</p> <p>Direct Mechanical Interaction Between Sarcolemmal and Sarcoplasmic Reticulum Membrane Proteins Mediates Excitation-Contraction Coupling in Skeletal Muscle</p> <p>Ca<SUP>2+</SUP>-Induced Ca<SUP>2+</SUP> Release Is Central to Excitation-Contraction Coupling in Cardiac MuscleSmooth Muscle Excitation-Contraction Coupling Is Fundamentally Different from That in Skeletal and Cardiac Muscles</p> <p>Summary</p> <p>Key Words and Concepts</p> <p>Study Problems</p> <p>CHAPTER 16, MECHANICS OF MUSCLE CONTRACTION </p> <p>The Total Force Generated by a Skeletal Muscle Can Be Varied</p> <p>Skeletal Muscle Mechanics Is Characterized by Two Fundamental Relationships</p> <p>There Are Three Types of Skeletal Muscle Motor Units</p> <p>The Force Generated by Cardiac Muscle Is Regulated by Mechanisms That Control Intracellular Ca<SUP>2+</p></SUP> <p>Mechanical Properties of Cardiac and Skeletal Muscle Are Similar but Quantitatively Different</p> <p>Dynamics of Smooth Muscle Contraction Differ Markedly from Those of Skeletal and Cardiac Muscle</p> <p>The Relationships among Intracellular Ca<SUP>2+</SUP>, Myosin Light Chain Phosphorylation, and Force in Smooth Muscles Is Complex</p> <p>Summary</p> <p>Key Words and Concepts</p> <p>Study Problems</p> <p>SEction VI Epilogue and Appendicies</p> <p>EPILOGUE</p> <p>APPENDIX A, ABBREVIATIONS, SYMBOLS, AND NUMERICAL CONSTANTS</p> <p>Abbreviations</p> <p>Symbols</p> <p>Numerical Constants</p> <p>APPENDIX B, A MATHEMATICAL REFRESHER</p> <p>Exponents</p> <p>Logarithms</p> <p>Solving Quadratic Equations</p> <p>Differentiation and Derivatives</p> <p>Integration: The Antiderivative and the Definite Integral</p> <p>Differential Equations</p> <p>APPENDIX C, ROOT-MEAN-SQUARED DISPLACEMENT OF DIFFUSING MOLECULES</p> <p>APPENDIX D, SUMMARY OF ELEMENTARY CIRCUIT THEORY</p> <p>Cell Membranes Are Modeled with Electrical Circuits</p> <p>Definitions of Electrical Parameters</p> <p>Current Flow in Simple Circuits</p> <p>APPENDIX E, ANSWERS TO STUDY PROBLEMS</p> <p>APPENDIX F, REVIEW EXAMINATION</p> <p>Answers to Review Examination</p>