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KIN 330 Structural and Functional Analysis of Human Movement
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Structure of Class H divided into three parts –tissue –movement patterns and analyses –application of physics to movement
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What is Kinesiology? H Components of Kinesiology
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What is Biomechanics? H...the application of physics and engineering principles to the study of motion.
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Components of Biomechanics H Kinematics - the description of motion H Kinetics - the study of forces on motion
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Who can use biomechanics?
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Biomechanics of Bone H Purposes of skeletal system –protection –provides rigid links and attachments for muscles –facilitates muscle action and body movement
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Bone H metabolically active H highly vascular H responds to mechanical demands H among the body’s hardest structures
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Distinguishing Features H Organic component H Inorganic component H Interface of two components
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Mechanical Properties H Functionally speaking: –strength –stiffness
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Load/Deformation Curve H Regions –A - B: Elastic Region: –B: Yield Point –B - C: Plastic Region: –C: Ultimate Failure Point
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Parameters displayed on curve H load H deformation H energy
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Usefulness of L-D Curve H determines the mechanical properties of the entire structure of the bone. H Strength H Stiffness
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Classification of Bone H Depends on the extent of deformation before failure –reflected in the fracture surfaces H Brittle - H Ductile -
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Bone’s behavior H more brittle or more ductile behavior depending on: –age of bone –rate at which bone is loaded
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Characteristic Unique to Bone H Anisotropy –bone exhibits different mechanical properties when loaded along different axes
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Types of Loading Types of Loading H Forces are applied to bone using Newton’s 3rd Law of Motion. H These loads are equal in magnitude and oppositely directed.
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Types of Loading H Tension –loads applied outward along longitudinal axis of bone. H Compression –loads applied inward along longitudinal axis of bone. H Shear –loads applied parallel to cross-sectional surface of structure.
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Bone loads cont. H Bending –loads applied that cause bone to bend. H Torsion –loads applied that cause bone to twist about longitudinal axis. H Combination –two or more loads are applied to bone.
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Behavior of bone varies H Rate of bone loading is important H When loaded at higher rates: –bone is stiffer, sustaining higher load to failure, and –bone stores more energy before failure.
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Clinical Importance of Loading Rate H Influences the fracture pattern and amount of soft tissue damage at the fracture site. H Three general categories of bone fracture. –Low energy fracture –High energy fracture –Very high energy fracture
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Fractures caused by: H a single load that exceeds the ultimate strength of the bone, or H repeated applications of a load of lower magnitude.
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Fatigue Fractures H Produced by: –few repetitions of a high load, or –by many repetitions of a relatively normal load.
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Factors affecting the fatiguing process H Amount of Load H Number of repetitions H Frequency of Loading
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When do fatigue fractures occur? H When remodeling process is outpaced by the fatigue process. H Examples? H Affect of muscle fatigue? –Implications?
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Bone Remodeling H bone remodels by altering its size, shape and structure to meet the mechanical demands placed on it. H Wolff’s Law:
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Degenerative changes H reduction in amount of cancellous bone, H thinning of cortical bone, H decrease in total amount of bone tissue, and H slight decrease in the size of bone. H Direct implications?
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Bone Summary H Identify eight major points presented.
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