Pre-clinical medicine: basic sciences Books

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Book SynopsisBiomechanics of Human Motion: Applications in the Martial Arts, Second Edition, explores the biomechanical principles of nine different forms of martial arts, with specific attention paid to their anatomical features. Within this examination, Professor Arus highlights the use of energy and force especially in Kyusho-Jutsu. Whereas the first edition provided an in-depth explanation of the Aikido techniques of Kokyu-ryoku, the second edition focusses specifically on the grabbing and liberation techniques used in Kyusho-Jutsu. Such an examination stresses the importance of vital points, finger manipulation, and their co rresponding emphasis on energy usage. As Professor Arus details throughout Biomechanics of Human Motion, Second Edition, knowledge of this form of pressure point maneuvering is useful in both attack and counterattack situations, especially since the martial artist's anatomo-physiological adaptation to effort represenTable of ContentsSection I: The Anatomical Foundations of Biomechanics 1. Introduction 2. The Anatomy of Human Motion 3. Functional Anatomy and Biomechanics Section II: The Biomechanical and Physiological Foundations of Human Motion 4. The Concept of Muscular Mechanics 5. Movement Control (Muscular Physiology) Section III: The Fundamentals of Biomechanics 6. Kinematics in Linear Motion 7. Kinematics in Angular Motion 8. Kinetics in Linear Motion 9. Kinetics in Angular Motion Section IV: Martial Arts Biomechanics 10. The Biomechanics of Throwing Arts 11. The Biomechanics of Striking, Kicking Arts 12. The Defense and Attack on Vital Points (Kyusho): Finger(s) Manipulation 13. The Biomechanics of the Sword Art

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Book SynopsisClaudia Neuhauser, PhD, is Associate Vice President for Research and Director of Research Computing in the Office of the Vice President for Research at University of Minnesota. In her role as Director of Research Computing she oversees the University of Minnesota Informatics Institute (UMII), the Minnesota Supercomputing Institute (MSI), and U-Spatial. UMII fosters and accelerates data-intensive research across all disciplines in the University and develops partnership with industry.  Neuhauser's research is at the interface of mathematics and biology, and focuses on the analysis of ecological and evolutionary models and the development of statistical methods in biomedical applications. She received her Diplom in mathematics from the Universität Heidelberg (Germany) in 1988, and a Ph.D. in mathematics from Cornell University in 1990. She is a fellow of the American Association for the Advancement of Science (AAAS) and a fellow of the American MathematicTable of Contents(NOTE: Each chapter concludes with Key Terms and Review Problems.) 1. Preview and Review 1.1 Precalculus Skills Diagnostic Test 1.2 Preliminaries 1.3 Elementary Functions 1.4 Graphing 2. Discrete-Time Models, Sequences, and Difference Equations 2.1 Exponential Growth and Decay 2.2 Sequences 2.3 Modeling with Recurrence Equations 3. Limits and Continuity 3.1 Limits 3.2 Continuity 3.3 Limits at Infinity 3.4 Trigonometric Limits and the Sandwich Theorem 3.5 Properties of Continuous Functions 3.6 A Formal Definition of Limits (Optional) 4. Differentiation 4.1 Formal Definition of the Derivative 4.2 Properties of the Derivative 4.3 Power Rules and Basic Rules 4.4 The Product and Quotient Rules, and the Derivatives of Rational and Power Functions 4.5 Chain Rule 4.6 Implicit Functions and Implicit Differentiation 4.7 Higher Derivatives 4.8 Derivatives of Trigonometric Functions 4.9 Derivatives of Exponential Functions 4.10 Inverse Functions and Logarithms 4.11 Linear Approximation and Error Propagation 5. Applications of Differentiation 5.1 Extrema and the Mean-Value Theorem 5.2 Monotonicity and Concavity 5.3 Extrema and Inflection Points 5.4 Optimization 5.5 L'Hôpital's Rule 5.6 Graphing and Asymptotes 5.7 Recurrence Equations: Stability (Optional) 5.8 Numerical Methods: The Newton - Raphson Method (Optional) 5.9 Modeling Biological Systems Using Differential Equations (Optional) 5.10 Antiderivatives 6. Integration 6.1 The Definite Integral 6.2 The Fundamental Theorem of Calculus 6.3 Applications of Integration 7. Integration Techniques and Computational Methods 7.1 The Substitution Rule 7.2 Integration by Parts and Practicing Integration 7.3 Rational Functions and Partial Fractions 7.4 Improper Integrals (Optional) 7.5 Numerical Integration 7.6 The Taylor Approximation (optional) 7.7 Tables of Integrals (Optional) 8. Differential Equations 8.1 Solving Separable Differential Equations 8.2 Equilibria and Their Stability 8.3 Differential Equation Models 8.4 Integrating Factors and Two-Compartment Models 9. Linear Algebra and Analytic Geometry 9.1 Linear Systems 9.2 Matrices 9.3 Linear Maps, Eigenvectors, and Eigenvalues 9.4 Demographic Modeling 9.5 Analytic Geometry 10. Multivariable Calculus 10.1 Two or More Independent Variables 10.2 Limits and Continuity (optional) 10.3 Partial Derivatives 10.4 Tangent Planes, Differentiability, and Linearization 10.5 The Chain Rule and Implicit Differentiation (Optional) 10.6 Directional Derivatives and Gradient Vectors (Optional) 10.7 Maximization and Minimization of Functions (Optional) 10.8 Diffusion (Optional) 10.9 Systems of Difference Equations (Optional) 11. Systems of Differential Equations 11.1 Linear Systems: Theory 11.2 Linear Systems: Applications 11.3 Nonlinear Autonomous Systems: Theory 11.4 Nonlinear Systems: Lotka - Volterra Model of Interspecific Interactions 11.5 More Mathematical Models (Optional) 12. Probability and Statistics 12.1 Counting 12.2 What Is Probability? 12.3 Conditional Probability and Independence 12.4 Discrete Random Variables and Discrete Distributions 12.5 Continuous Distributions 12.6 Limit Theorems 12.7 Statistical Tools Appendices A: Frequently Used Symbols B: Table of the Standard Normal Distribution Answers to Odd-Numbered Problems References Photo Credits Index

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Book SynopsisWolinsky.Trade ReviewAs a model for viral evolution, this book is a gold mine. [It] should be used as a starting point for those who want to browse the huge literature on the subject... [and] to those who devise policies for the containment of the epidemic. European Molecular Biology Organization ReportsTable of ContentsContributorsPrefacePart I: Introduction to HIVChapter 1. Molecular Biology of HIVChapter 2. Global Diversity in HIVPart II: Molecular Methods For Studying HIV DiversityChapter 3. Phylogenetics and the Study of HIVChapter 4. Modeling the Molecular Evolution of HIV SequeuencesChapter 5. Statistical Approaches to Detecting Recombination Chapter 6. The Molecular Population Dynamics of HIV-1Chapter 7. Use of Phylogenetic Inference to Test an HIV Transmission HypothesisChapter 8. Coalescent Approaches to HIV Population GeneticsPart III: Case Studies of HIV EvolutionChapter 9. Levels of Diversity Within and Among Host Individuals Chapter 10. The Phylogenetics of Known Transmission HistoriesChapter 11. HIV Evolution and Disease Progression Via Longitudinal Studies Chapter 12. Perinatal HIV InfectionChapter 13. Determinants of HIV-1 Protein EvolutionChapter 14. Evolution of HIV-1 Resistance to Antiviral AgentsIndex

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Book SynopsisTable of ContentsPreface III Laboratory Safety and Guidelines 1 Data Documentation 7 Data Analysis 11 Laboratory Techniques and Safety Practices 23 Experiments Unit Opener 1 Introduction Dry Lab 1 The Laboratory and SI Experiment 1 Basic Laboratory Operations Unit Opener 2 Chemical and Physical Properties Experiment 2 Identification of a Compound: Chemical Properties Experiment 3 Water Analysis: Solids Experiment 4 Percent Water in a Hydrated Salt Dry Lab 2A Inorganic Nomenclature I. Oxidation Numbers Dry Lab 2B Inorganic Nomenclature II. Binary Compounds Dry Lab 2C Inorganic Nomenclature III. Ternary Compounds Experiment 5 Acids, Bases, and Salts Unit Opener 3 Atomic and Molecular Structure Experiment 6 Periodic Table and Periodic Law Dry Lab 3 Atomic and Molecular Structure Unit Opener 4 Mole Concept Experiment 7 Empirical Formulas Experiment 8 Limiting Reactant Experiment 9 A Volumetric Analysis Experiment 10 Vinegar Analysis Unit Opener 5 Molar Mass of Gases and Solute Experiment 11 Molar Mass of a Volatile Liquid Experiment 12 A Carbonate Analysis; Molar Volume of Carbon Dioxide Experiment 13 Molar Mass of a Solid Unit Opener 6 Kinetics and Equilibrium Constant Experiment 14 Factors Affecting Reaction Rates Experiment 15 A Rate Law and Activation Energy Experiment 16 An Equilibrium Constant Unit Opener 7 Acid-Base Equilibrium and Analysis Experiment 17 LeChâtelier’s Principle; Buffers Experiment 18 Antacid Analysis Experiment 19 Potentiometric Analyses Experiment 20 Alkalinity of a Water Resource Experiment 21 Hard Water Analysis Experiment 22 Molar Solubility, Common-Ion Effect Unit Opener 8 Thermodynamics Experiment 23 Calorimetry Experiment 24 Thermodynamics of the Dissolution of Borax Unit Opener 9 Oxidation-Reduction Systems and Analysis Experiment 25 Oxidation–Reduction Reactions Experiment 26 Chemistry of Copper Experiment 27 Bleach Analysis Experiment 28 Vitamin C Analysis Experiment 29 Dissolved Oxygen Levels in Natural Waters Experiment 30 Galvanic Cells, the Nernst Equation Experiment 31 Electrolytic Cells, Avogadro’s Number Unit Opener 10 Metal Double Salts and Complexes Experiment 32 Synthesis of Potassium Alum Experiment 33 Transition Metal Complexes Unit Opener 11 Qualitative Analysis Experiment 34 Aspirin Synthesis and Analysis Experiment 35 Paper Chromatography Experiment 36 Spectrophotometric Metal Ion Analysis Dry Lab 4 Preface to Qualitative Analysis Experiment 37 Qual: Common Anions Experiment 38 Qual I. Na+, K+, NH4+, Mg2+, Ca2+, Cu2+ Experiment 39 Qual II. Ni2+, Fe3+, Al3+, Zn2+ Appendixes Appendix A Conversion Factors Appendix B Familiar Names of Common Chemicals Appendix C Vapor Pressure of Water Appendix D Concentrations of Acids and Bases Appendix E Water Solubility of Inorganic Salts

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