MARC details
000 -LEADER |
fixed length control field |
12733cam a22002894a 4500 |
003 - CONTROL NUMBER IDENTIFIER |
control field |
OSt |
005 - DATE AND TIME OF LATEST TRANSACTION |
control field |
20240220083106.0 |
008 - FIXED-LENGTH DATA ELEMENTS--GENERAL INFORMATION |
fixed length control field |
050422s2006 njua b 001 0 eng |
020 ## - INTERNATIONAL STANDARD BOOK NUMBER |
International Standard Book Number |
0130480363 (alk. paper) |
020 ## - INTERNATIONAL STANDARD BOOK NUMBER |
International Standard Book Number |
9780130480361 |
040 ## - CATALOGING SOURCE |
Original cataloging agency |
BUL |
Transcribing agency |
BUL |
Modifying agency |
BUL |
Language of cataloging |
eng |
Description conventions |
rda |
060 10 - NATIONAL LIBRARY OF MEDICINE CALL NUMBER |
Classification number |
WB 541 N995c 2006 |
100 1# - MAIN ENTRY--PERSONAL NAME |
Personal name |
Nyland, John. |
245 00 - TITLE STATEMENT |
Title |
Clinical decisions in therapeutic exercise : |
Remainder of title |
planning and implementation / |
Statement of responsibility, etc. |
John Nyland. |
260 ## - PUBLICATION, DISTRIBUTION, ETC. |
Place of publication, distribution, etc. |
Upper Saddle River, NJ : |
Name of publisher, distributor, etc. |
Pearson Education, |
Date of publication, distribution, etc. |
c2006. |
300 ## - PHYSICAL DESCRIPTION |
Extent |
xxiii, 695 p. : |
Other physical details |
ill. ; |
Dimensions |
29 cm. + |
Accompanying material |
1 CD-ROM (4 3/4 in.) |
504 ## - BIBLIOGRAPHY, ETC. NOTE |
Bibliography, etc. note |
Includes bibliographical references and index. |
505 ## - FORMATTED CONTENTS NOTE |
Formatted contents note |
Contents<br/><br/>Section I. Foundations of Therapeutic Exercise Program Planning<br/>Chapter 1. Effects of Immobilization and Disuse on Body System Function<br/>by Jerrad Zimmerman, Christine Price, and John Nyland<br/>Introduction<br/> Case Scenario<br/>Effects of Immobilization and Disuse on the Musculoskeletal System<br/>Muscular Consequences<br/>Bony Consequences<br/>Ligament and Tendon Effects of Immobilization and Disuse<br/>Articular Cartilage Effects of Immobilization and Disuse<br/>Neuromuscular Effects of Immobilization and Disuse<br/>Cardiovascular Effects of Immobilization and Disuse<br/>Pulmonary Effects of Immobilization and Disuse<br/>Hematological Effects of Immobilization and Disuse<br/>Integumentary Effects of Immobilization and Disuse<br/>Gastrointestinal Effects of Immobilization and Disuse<br/>Urinary Effects of Immobilization and Disuse<br/>Metabolic Effects of Immobilization and Disuse<br/>Psychosocial Considerations<br/>Disability and Quality of Life<br/> Definitions of Disability<br/> Prevention of Disability<br/>Therapeutic Exercise and Its Contraindications<br/>Summary<br/>Chapter 2. The Physiology of Muscle Activation<br/>by J. Timothy Noteboom<br/>Introduction<br/>Muscle Metabolism<br/>ATP-PC system<br/>Glycolysis<br/>The Oxidative System (Fat and Protein)<br/>Fat Oxidation<br/>Protein Oxidation<br/>Oxidative System Regulation<br/>Energy Production and Capacity<br/>Intensity and Duration of Exercise<br/>Nutrient Related Fatigue<br/>Oxygen Uptake During Recovery: The So-called "Oxygen Debt"<br/>Updated Theory to Explain EPOC<br/>Implications of EPOC for Exercise and Recovery<br/>Optimal Recovery from Exercise<br/>Intermittent Exercise: The Interval Training Approach<br/>Nutrition<br/>Protein<br/>Dietary Protein<br/>Protein Requirements<br/>Carbohydrates<br/>Dietary Carbohydrate<br/>Lipids<br/>Pharmacological Agents and Exercise<br/>Motor Units and Muscle Fibers<br/>Muscle Physiology, A Historical Perspective<br/>Actin Filaments<br/>Excitation-Contraction Coupling<br/>Muscle Fiber Type<br/>Motor units<br/>Contractile Properties<br/>Contractile Speed<br/>Motor Unit Force<br/>Fatigability<br/>Motor Unit Types<br/>Motor Unit Activation Patterns<br/>Motor Unit Recruitment Order<br/>Discharge Rate<br/>Fatigue<br/>Aging<br/>Spinal Reflexes<br/>Stretch Reflex<br/>Golgi tendon organs<br/>Withdrawal Reflex<br/>Automatic Responses<br/>The Effects of Arousal on Motor Performance<br/>Summary<br/>Chapter 3. Stretching for Musculotendinous Extensibility, Joint Flexibility<br/>by Harvey Wallmann and J. Timothy Noteboom<br/>Introduction<br/>Viscoelastic Tissue Properties<br/>Stress and Strain<br/>Viscoelasticity and Tissue Function<br/>Structure, Viscoelastic Properties, and Function of Tissue<br/>Tendons and Ligaments<br/>Muscle<br/>Articular Cartilage<br/>Bone<br/>Influence of Training, Disuse, Aging, and Gender on Tissues of the Musculoskeletal System<br/>Bone<br/>Ligaments/Joint Capsule<br/>Tendon<br/>Muscle<br/>Influence of Sensory and Motor Systems on Flexibility<br/>Stretching and Musculotendinous Flexibility<br/>What is Stretching?<br/>What is Flexibility?<br/>Flexibility and Associated Topics<br/>Limitations to Flexibility<br/>Aging and Flexibility<br/>Gender Differences<br/>Pathology and Joint Laxity<br/>Flexibility Assessment<br/>Principles Of Stretching<br/>General Effects of Stretching<br/>Types of Stretching<br/>Stretching Comparisons<br/>Proposed Stretching Benefits<br/>Performance Enhancement<br/>Long-Term Flexibility Effects<br/>Short-Term Effects<br/>Rationale for Stretching Affecting Performance<br/>Stretching Precautions<br/>Stretching Aids<br/>Essentials of a Stretching Program<br/>When to Stretch<br/>Program<br/>Summary<br/>Chapter 4. Training for Cardiovascular Power and Endurance<br/>by Mark Reinking and Harvey Wallmann<br/>Introduction<br/>Metabolic Pathways<br/>Blood Lactate Accumulation<br/>Response to Exercise<br/>Aerobic Capacity and Endurance<br/>Maximal Oxygen Uptake (VO2max)<br/>Factors Affecting VO2max<br/>Training for Maximal Aerobic Capacity<br/>Exercise Economy and Aerobic Capacity<br/>Effects of Endurance Training<br/>Oxygen Uptake Adaptations<br/>Cardiovascular Adaptations<br/>Cardiopulmonary Adaptations<br/>Metabolic Adaptations<br/>Blood Lactate Adaptations<br/>Thermoregulation<br/>Temperature Regulatory Control<br/>Hyperthermia<br/>Hypothermia<br/>Clinical Exercise Testing<br/>Screening<br/>Graded Exercise Testing<br/>Maximal Graded Exercise Testing<br/>Submaximal Graded Exercise Testing<br/>Laboratory Testing<br/>Treadmill<br/>Cycle Ergometer<br/>Step<br/>Field Testing<br/>Lifespan Changes<br/>Introduction To Aerobic Exercise Prescription<br/>Considerations in Aerobic Exercise Prescription<br/>Exercise Program Adherence<br/>Components of Aerobic Power Exercise Prescription<br/>Overload Principle<br/>Reversibility Principle<br/>Aerobic Exercise Intensity<br/>Aerobic Exercise Duration<br/>Aerobic Exercise Frequency <br/>Aerobic Exercise Preparation<br/>Aerobic Exercise Mode<br/>Cross-Training <br/>Continuous vs. Interval Training<br/>Exercise Modes to Improve Aerobic Power<br/>Walking<br/>Running<br/>Inline Skating<br/>Step Aerobics<br/>Aerobic Dance<br/>Stair-Stepping<br/>Elliptical Trainers<br/>Cross-country skiing<br/>Bicycling<br/>Rowing<br/>Arm Ergometry<br/>Aquatic Exercise<br/>Aerobic Exercise Progression<br/>Aerobic Exercise Initiation (Phase I)<br/>Aerobic Exercise Advancement (Phase II) <br/>Aerobic Exercise Maintenance (Phase III)<br/>Special Considerations In Aerobic Exercise<br/>Exercise-related Cardiac Events<br/>Pregnancy<br/>Diabetes Mellitus<br/>Age: Children and Elderly<br/>Summary<br/>Chapter 5. Training for Muscular Strength, Power and Endurance<br/>by J.A. Brosky, Jr. and Glenn A. Wright<br/>Introduction<br/>Resistance Training Considerations<br/>Existing Health and Fitness Status<br/>Client Goals<br/>Performance Vs. Health-Related Fitness and Training<br/>Types of Muscular Actions<br/>Resistance Training Principles<br/>Overload<br/>Progression<br/>Specificity<br/>Reversibility<br/>Fundamentals of Muscular Fitness<br/>Training for Muscular Strength<br/>Training for Muscle Hypertrophy<br/>Training for Muscular Endurance<br/>Muscular Power<br/>Resistance Training Program Design<br/> Other Resistance Training Methods<br/>Therapeutic Exercise Program Applications of Cross Training and Circuit Training<br/>Cross Training and Crossover Effect<br/>Circuit Training<br/>Pyramids, Split Routines, Super Sets, and Compound Sets<br/>Exercise, Therapeutic Exercise, or Rehabilitation?<br/>General Principles of Therapeutic Exercise Intervention<br/>Creation of a Functional Therapeutic Exercise Environment<br/>Planes of Motion<br/>Posture and the "Ready Position"<br/>The Dosage Dilemma: How Much Is Enough, Too Much, or Not Enough?<br/>"Physical Stress Theory", Overload, and Neural Adaptation<br/>Overload vs. Overtraining<br/>Closed and Open Kinematic or Kinetic Chains<br/>Considerations of the Squat and its Variations as Cornerstones of Lower Extremity Exercise<br/>The Spinal Engine<br/>Axial-Appendicular Relationship and Anatomical Rationale for Core Stability<br/>The Serape Effect<br/>Kinesiological Monitors<br/>Examples of Dynamic Stabilization Exercises<br/>Total Gym<br/>Plyometrics: Training for Power<br/> Screening for Plyometric Training Readiness<br/>Functional Performance Testing<br/>Common Methods of Resistance Training<br/>Resistance Machines<br/>Free Weights, Dumbbells and Medicine Balls<br/>Elastic Resistance Devices<br/>Manual Resistance and Body Weight Resistance<br/>Isokinetics<br/>Other Resistance Training Environments<br/>The Aquatic Environment<br/>Friction: Lower Extremity Sliding Boards (Inertial/Isoinertial)<br/>Swiss Ball<br/>Common Denominators of Successful Knee Injury Prevention Programs<br/>Summary<br/>Chapter 6. Training For Joint Stability<br/>by Timothy F. Tyler and Michael Mullaney<br/>Introduction<br/>The Structure Of Joint Stability<br/>Joint Structure and Design <br/>Diarthrodial Joint Designs<br/>Non-Contractile Stability<br/>Contractile Stability<br/>Dynamic Joint Stability<br/>Neuromuscular Control<br/>Generalized Joint Hypomobility vs. Hypermobility<br/>Inherent Vs. Acquired Joint Laxity<br/>Spinal Stability<br/>Increased Joint Laxity in Females: Fact or Fiction?<br/>Joint Stability Changes Across the Lifespan<br/>Treatment Techniques<br/>Neuromuscular Training<br/>Proprioceptive Neuromuscular Facilitation<br/>Biofeedback<br/>Lumbar Stabilization Training<br/>Swiss Ball Therapy for Lumbar Stabilization<br/>Taping for Joint Stability<br/>Post-Operative Joint Stabilization Training<br/>Functional, Prophylactic, and Post-Operative Orthoses<br/>Summary<br/>Chapter 7. Training for Proprioception and Kinesthesia<br/>by William Ogard<br/>Introduction<br/>What is Proprioception?<br/>Neuroanatomic and Neurophysiologic Basis for Proprioception<br/>Muscle Receptors: Muscle Spindle and Golgi Tendon Organ (GTO)<br/>Articular Receptors: Capsular and Ligamentous Mechanoreceptors<br/>Evidence for a Primary Source of Afferent Information for Proprioception<br/>Testing Proprioception<br/>Knee Joint Proprioception Studies<br/>Shoulder Joint Proprioception<br/>Ankle Proprioception<br/>The Spine and Proprioception<br/>Effects of Training/Exercise on Proprioception<br/>Aspects of Rehabilitation Exercise and Training with Utilization of Proprioceptive Input<br/>Exercise and Training Guidelines<br/>Summary<br/>Chapter 8. Training for Neuromuscular Coordination and Re-Education<br/>by Timothy Brindle<br/>Introduction<br/>Movement<br/>Movement Accuracy<br/>Movement Errors<br/>Pointing or Reaching with the Upper Extremity<br/>Locomotion<br/>Input to the CNS<br/>Visual Feedback<br/>Mechanoreceptors<br/>Central Nervous System - Motor Processing<br/>Spinal Cord<br/>Brain Stem<br/>Cerebral Cortex<br/>CNS Output<br/>Background of Movement Control and Motor Learning<br/>Equilibrium Point Hypothesis<br/>The Alpha Model<br/>The Lambda Model <br/>Amplitude and Duration Control<br/>CNS Control of Movement<br/>Motor Planning- Input<br/>Closed Loop Control<br/>The Stretch Reflex and its Contribution to Motor Control<br/>Motor Planning- Central Processing<br/>Open Loop Control<br/> Motor Programs<br/>Motor Program- Output <br/>Invariant Movement Parameters<br/>Variable Movement Parameters<br/>Muscle Output -- Characteristics<br/> Synchronization<br/> Muscle Macro- and Microscopic Architecture<br/>Motor Learning<br/>Motor Program Errors<br/>Age and Training<br/>Neuromuscular Training /Evaluation and Techniques<br/>Critical Tracking Tasks<br/>Medicine Ball or Plyometric Exercises from a Motor Control Perspective<br/>Summary<br/>Chapter 9. Training for Agility and Balance<br/>by Claudia Angeli<br/>Introduction<br/>Components of Agility<br/>Changes Across the Lifespan<br/>Biomechanics of Agility<br/>Walking<br/>Ground Reaction Forces<br/>Base of Support<br/>Running<br/>Cutting<br/>Joint Moments<br/>Reaching and Grasping<br/>Agility Training Progressions<br/>Agility Drill Examples<br/>Balance<br/>Summary<br/>Chapter 10 Complementary and Alternative Approaches to Movement and Exercise<br/>by Theresa J. Kraemer<br/>Introduction<br/>Recent Events<br/>Terminology<br/>Classification System<br/>Basic Concepts Behind Complementary and Alternative Movement Approaches<br/>Mind-Body-Energy Connection<br/>Universal Life Force<br/>Chakras or Energy Centers<br/>Meridians or Channels<br/>Energy Systems and Healing<br/>Mind-Body-Energy-Movement Relationship<br/>Energy Balance and Movement<br/>Ten Principles of Movement Quality<br/>Healing Through Movement<br/>Dance Therapy<br/>Background<br/>Therapeutic Indications<br/>Contraindications<br/>Evidence<br/>Technique<br/>Practitioner Training<br/>The Feldenkrais Method<br/>Background<br/>Therapeutic Indications<br/>Contraindications<br/>Techniques<br/>Evidence<br/>Equipment<br/>Example: A Spinal ATM Lesson<br/>Practitioner Training<br/>Nickolaus Technique<br/>Background<br/>Therapeutic Indications<br/>Contraindications<br/>Equipment<br/>Technique<br/>Evidence and Practitioner Requirements<br/>Pilates<br/>Background<br/>Pilates Eight Basic Principles of Body Conditioning<br/>Therapeutic Indications<br/>Contraindications and Special Precautions<br/>Evidence<br/>Equipment<br/>Technique<br/>Practitioner Training<br/>Qigong<br/>Background<br/>Principles<br/>Technique<br/>Therapeutic Indications<br/>Contraindications<br/>Evidence<br/>Equipment<br/>Basic Techniques<br/>Practitioner Requirements<br/>Tai Chi<br/>Background<br/> Basic Technique<br/>Therapeutic Indications<br/>Contraindications<br/>Evidence<br/>Equipment<br/>Technique<br/>Beginning Tai Chi Exercise Program<br/>Practitioner Training<br/>Yoga<br/>Background<br/>Posture (Asana) and Breathing (Pranayama)<br/>Therapeutic Indications<br/>Contraindications<br/>Evidence<br/>Equipment<br/>Technique<br/>Example Yoga Program<br/>Practitioner Requirements |
650 #0 - SUBJECT ADDED ENTRY--TOPICAL TERM |
Topical term or geographic name entry element |
Exercise therapy. |
650 12 - SUBJECT ADDED ENTRY--TOPICAL TERM |
Topical term or geographic name entry element |
Exercise Therapy. |
650 22 - SUBJECT ADDED ENTRY--TOPICAL TERM |
Topical term or geographic name entry element |
Biomechanics. |
650 22 - SUBJECT ADDED ENTRY--TOPICAL TERM |
Topical term or geographic name entry element |
Planning Techniques. |
856 41 - ELECTRONIC LOCATION AND ACCESS |
Materials specified |
Table of contents |
Uniform Resource Identifier |
<a href="http://www.loc.gov/catdir/toc/ecip0511/2005011757.html">http://www.loc.gov/catdir/toc/ecip0511/2005011757.html</a> |
906 ## - LOCAL DATA ELEMENT F, LDF (RLIN) |
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7 |
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orignew |
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1 |
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20 |
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y-gencatlg |
942 ## - ADDED ENTRY ELEMENTS (KOHA) |
Source of classification or shelving scheme |
Dewey Decimal Classification |
Koha item type |
Book Open Access |
Classification part |
WB 541 |
Item part |
1 |
Call number prefix |
N995c 2006 |
Call number suffix |
WB 541 N995c 2006 |