Plan for Week 3 First day Second day Center of Mass calculation method Bone growth and integrity (Ch 4) Stress-strain curves (pp 77-79) Second day Complete Bone growth and integrity unit Review problems from p 105 that you don’t understand Introduce unit on joints and flexibility
Objectives Explain bone and other tissue loading modes Explain and interpret stress/strain curves as a descriptor of mechanical properties of materials Explain how material constituents and structural organization of bone affect its ability to withstand mechanical loads. Describe the processes involved in the normal growth and maturation of bone. Describe factors affecting bone mineral content. Explain the significance of osteoporosis and discuss current theories on its prevention. Explain the relationship between different forms of mechanical loading and common bone injuries.
Bone Structure and Integrity Architecture and dev - Microstructure of bone How bones grow? Adaptability - Wolff’s law Mechanical properties of bone stress-strain relationship strength (density, mineral content, or BMC) elasticity energy absorption resistance to fatigue Loading modes - tension, compression, torsion, shear
Bone Gross Structure, Architecture and Development
Long Bone Structure
Bone Micro-Structure, cont’d Projections of osteocytes are thought to be cite of strain sensing, which stimulates bone to form
Bone Composition & Structure Material Constituents: Calcium carbonate and Calcium phosphate 60-70% bone weight Adds stiffness Primary determinant for compressive strength. Collagen Adds flexibility Contributes to tensile strength Material Constituents Water 25-30% bone weight Contributes to bone strength Provides transportation for nutrients and wastes.
Bone Composition & Structure Structural Organization Bone mineralization ratio specific to bone Two categories of porous bone: Cortical bone(70-95% mineral content) Trabecular bone (10-70% mineral content) More porous bones have: Less calcium phosphate More calcium carbonate Greater proportion of non-mineralized tissue
Bone Composition & Structure Cortical Bone Low porosity 5-30% bone volume is non-mineralized tissue Withstand greater stress but less strain before fracturing
Bone Composition & Structure Trabecular Bone High porosity 30 - >90% bone volume is non-mineralized tissue Trabeculae filled with marrow and fat Withstand more strain (but less stress) before fracturing
Bone Composition & Structure Both cortical and trabecular bone are anisotropic – stress/strain response is directional Bone function determines structure Strongest at resisting compressive stress Weakest at resisting shear stress
Bone Growth & Development Longitudinal Growth at epiphyses or epiphyseal plates Stops at 18 yrs of age (approx.) can be seen up to 25 yrs of age Circumferential Growth Diameter increases throughout lifespan Most rapid growth before adulthood Periosteum build-up in concentric layers
Bone Growth & Development Osteoblasts Osteoclasts Adult Bone Development Balance between oseoblast and osetoclast activity Increase in age yields progressive decrease in collagen and increase in bone brittleness. Greater in women
lamella
Bone Growth & Development Women Peak bone mineral content: 25-28 yrs. 0.5%-1.0% loss per year following age 50 or menopause 6.5% loss per year post-menopause for first 5-8 years. Youth – bones are vulnerabe during peak growing years Bone mineral density (BMD) is least during peak growing years Growth plates are thickest during peak growing years
Bone Growth & Development Aging Bone density loss as soon as early 20’s Decrease in mechanical properties and general toughness of bone Increasing loss of bone substance Increasing porosity Disconnection and disintegration of trabeculae leads to weakness
Mechanical Loading Modes on the Human Body Compression Tension Shear Torsion
Bone loading modes: Compression – pushing together Tension – pulling apart Torsion – twisting Shear – cutting across
Cutting across
The Effects of Loading Deformation When an external force is applied to the human body, several factors influence whether an injury occurs Magnitude and direction of force Area over which force is distributed Load-deformation curve Yield point (elastic limit) Failure
Load-deformation relationship: Stress-strain curve: Load-deformation relationship:
Repetitive vs. Acute Loads Repetitive loading Acute loading Macrotrauma Microtrauma
I: bone vs glass and metal II: Anisotropic behavior of bone
Comparison of tendon and ligament
Bone Response to Stress Wolf’s Law Indicates that bone strength increases and decreases as the functional forces on the bone increase and decrease. Bone Modeling and Remodeling Mechanical loading causes strain Bone Modeling If Strain > modeling threshold, then bone modeling occurs.
Bone Response to Stress Bone Remodeling If Strain < lower remodeling threshold, then bone remodeling occurs. at bone that is close to marrow “conservation mode”: no change in bone mass “disuse mode”: net loss of bone mass Osteocytes
Bone Response to Stress Bone mineral density generally parallels body weight Body weight provides most constant mechanical stress Determined by stresses that produce strain on skeleton Think: weight gain or loss and its effect on bone density
Bone Hypertrophy An increase in bone mass due to predominance of osteoblast activity. Seen in response to regular physical activity Ex: tennis players have muscular and bone hypertrophy in playing arm. The greater the habitual load, the more mineralization of the bone. Also relates to amount of impact of activity/sport
Bone Atrophy A decrease in bone mass resulting form a predominance of osteoclast activity Accomplished via remodeling Decreases in: Bone calcium Bone weight and strength Seen in bed-ridden patients, sedentary elderly, and astronauts
Bone Atrophy Affect on Astronauts Overall cause is unknown Tend to have negative calcium loss Decrease of intestinal Ca2+ absorption Increase in Ca2+ excretion Hypotheses: Less strain on bone results in less osteoblastic activity Changes in bone blood flow due to difference in gravitational field
Osteoporosis Website on osteporosis: http://www.nof.org National Osteoporosis Foundation A disorder involving decreased bone mass and strength with one or more resulting fractures. Found in elderly Mostly in postmenopausal and elderly women Causes more than 1/2 of fractures in women, and 1/3 in men. Begins as osteopenia
Osteoporosis Type I Osteoporosis = Post-menopausal Osteoporosis Affects about 40% of women over 50 Gender differences Men reach higher peak bone mass and strength in young adulthood Type II Osteoporosis = Age-Associated Osteoporosis Affects most women and men over 70
Osteoporosis Symptoms: Painful, deforming and debilitating crush fractures of vertebrae Usually of lumbar vertebrae from weight bearing activity, which leads to height loss Estimated 26% of women over 50 suffer from these fractures
Osteoporosis Men have an increase in vertebral diameter with aging Reduces compressive stress during weight bearing activities Structural strength not reduced Not known why same compensatory changes do not occur in women
Female Athlete Triad 1) Eating Disorders affect 1-10% of all adolescent and college-age women. Displayed in 62% female athletes Mostly in endurance or appearance-related sports 2) Amenorrhea is the cessation of the menses. 3) Osteoporosis is the decrease in bone mass and strength.
Amenorrhea & Osteoporosis Primary Amenorrhea Secondary Amenorrhea Prevention ACSM Position Statement:
Position Statement of ACSM on Osteoporosis Weightbearing physical activity is essential for developing and maintaining a healthy skeleton Strength exercises may also be beneficial, particularly for non-weightbearing bones An increase in physical activity for sedentary women can prevent further inactivity-related bone loss and can even improve bone mass Exercise is not an adequate substitute for postmenopausal hormone replacement Ex programs for older women should include activities for improving strength, flexibility, and coordination, to lessen the likelihood of falls
Osteoporosis Treatment Hormone replacement therapy Estrogen deficiency damages bone Increased dietary calcium Lifestyle factors affect bone mineralization Risk factors for osteoporosis:
Osteoporosis Treatment Future use of pharmacologic agents May stimulate bone formation Low doses of growth factors to stimulate osteoblast recruitment and promote bone formation. Best Bet: Engaging in regular physical activity Avoiding the lifestyle (risk) factors that negatively affect bone mass.
Types of Fractures
Common Bone Injuries Bone stronger in resisting compression than tension, so the side loaded with tension will fracture first. Acute compression fractures (in absence of osteoporosis) is rare Stress Fractures occur when there is no time for repair process (osteoblast activity) Begin as small disruption in continuity of outer layers of cortical bone.
Epiphyseal Injuries Include injuries to: Cartilaginous epiphyseal plate Articular cartilage Apophysis Acute and repetitive loading can injure growth plate Leads to premature closing of epiphyseal junction and termination of bone growth.
Epiphyseal Injuries Osteochondrosis Apophysitis Disruption of blood supply to epiphyses Associated with tissue necrosis and potential deformation of the epiphyses. Apophysitis Osteochondrosis of the apophysis Associated with traumatic avulsions.
Summary Bone is an important living tissue that is continuously being remodeled. Bone Strength and Resistance to fracture depend on its material composition and organizational structure. Bones continue to change in density. Osteoporosis is extremely prevalent among the elderly.
Assignment for Week 4 Review problems on p. 105 Introductory problems 1,2,3,8,9,10 Additional problems 1,2,3,8,10 Read pp 125-136 of text (Flexibility and proprioception)