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Chapter 42: Exercise Prescription for Patients with Osteoporosis

Copyright © 2014 American College of Sports Medicine

EpidemiologyEpidemiology

• Osteoporosis is a skeletal disorder characterized by compromised bone strength that results in an increased susceptibility to fracture.

• 200 million women worldwide currently have osteoporosis.

• Osteoporotic fractures are low-trauma fractures that occur with forces generated by a fall from a standing height or lower and are most common at the spine, hip, and wrist.

– Hip fractures are considered to be the most devastating consequences of osteoporosis.

• Costs $17 billion per year in United States

• Osteoporosis among men and women

– Although women are more susceptible, men also can have osteoporosis and often go undiagnosed.

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Basic Bone Physiology Basic Bone Physiology

• Bone is a biphasic material with crystals of hydroxyapatite (calcium phosphate) and an organic collagen matrix.

– Cortical bone

– Trabecular bone

• Modeling and remodeling: affect the quantity, quality, and structure of the bone; regulated by hormonal and mechanical environments

– Osteoblasts: bone-forming cells

– Osteoclasts: bone-reabsorbing cells

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FIGURE 42-1. Bone is a dynamic tissue that is vascularized and innervated. Cortical bone is dense and stiff and makes up the shaft of long bones. Cortical bone also provides a shell of protection around trabecular bone, which is more porous and flexible and is found at the ends of long bones and in vertebrae.

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FIGURE 42-2. Bone remodeling is the coupled actions of osteoclasts and osteoblasts whereby a portion of older bone is resorbed by osteoclasts and replaced with newly formed bone by osteoblasts. The new bone begins as osteoid (unmineralized matrix). Eventually, the osteoid incorporates mineral.

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Osteoporosis Pathophysiology Osteoporosis Pathophysiology • Skeletal fragility

– Bone quantity: amount of bone material present

• Rapid accumulation during adolescence

• Peak in second to third decade of life

• Negative bone balance: decline over time with aging where reabsorption is greater than formation rate

– Bone material quality: ability to withstand stressors

• Amount of bone in human skeleton decreases with menopause and advancing age.

• Increased mean tissue mineralization and changes in collagen properties increase fracture risk with age.

• Increased microdamage accumulation

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FIGURE 42-3. Normal pattern of bone mineral accretion and loss throughout the lifespan in men and women.

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Osteoporosis PathophysiologyOsteoporosis Pathophysiology

• Skeletal fragility

– Bone structure: distribution of bone material in bone space

• Structural differences in cortical bone geometry may explain some of the differences in fracture rates between men and women.

• During growth, long bones of boys have greater gains in periosteal (outer) diameter, resulting in greater overall bone size in boys that remains throughout life.

• Increased porous bone results in loss of bone strength and increased fracture risk.

– Falls

• Falls significantly increase the risk of fracture, especially when skeletal fragility exists.

• Most hip fractures occur after a sideways fall and landing on the hip.

• Hip fractures are a common occurrence because of falling.

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FIGURE 42-4. Slice of trabecular bone in a normal (A) and an individual with osteoporosis (B) showing loss of trabecular connectivity and increased microdamage with ageing.

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Diagnosis of Osteoporosis Diagnosis of Osteoporosis

• Measurement of bone mineral density (BMD) by dual-energy X-ray absorptiometry (DEXA) is the primary method of diagnosis.

• World Health Organization (WHO) criteria

– Osteopenia (low bone mass): site-specific bone density between 1.0 and 2.5 standard deviations below the mean for young white adult women

– Osteoporosis: bone density that is 2.5 standard deviations or more below the mean for young white adult women

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Risk Factors for Osteoporotic FractureRisk Factors for Osteoporotic Fracture• BMD

• Age

– Risk of hip fractures increases three to six times from 50 to 80 yr of age, independent of BMD status.

• Family history of fracture

• Previous fracture

• Physical inactivity

• Medication use

• Hypogonadism

• Menopause

• Hyperthyroidism and bariatric surgery risk for secondary osteoporosis

Copyright © 2014 American College of Sports Medicine

Copyright © 2014 American College of Sports Medicine

Bariatric Surgery: A Risk Factor for Osteoporosis?

Bariatric Surgery: A Risk Factor for Osteoporosis?

• With rapid and dramatic weight loss, there is an increasing concern that bariatric surgery may negatively affect the skeleton by accelerating bone loss and increasing bone fragility.

• Recent review showed that BMD loss may be as high as 15% at the hip 1 yr following gastric bypass procedures.

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Clinical Management Clinical Management

• Pharmacologic therapy

– Several categories are FDA approved.

• Antiresorptive agents: act by suppressing bone resorption.

• Bisphosphonates, salmon calcitonin, hormone replacement therapy (HRT), selective estrogen receptor modulators (SERMs), and receptor activator of nuclear factor kappa-B ligand (RANKL) inhibitors

• Anabolic agents: promote bone formation

• Regulation of calcium homeostasis: parathyroid hormone (PTH)

Copyright © 2014 American College of Sports Medicine

Copyright © 2014 American College of Sports Medicine

Antiresorptive Agents and Increased Risk of Fracture

Antiresorptive Agents and Increased Risk of Fracture

• With long-term use, antiresorptive medications may lose value in preventing fracture and, in some cases, may lead to fracture.

• Long-term bisphosphonate use remains controversial.

– Fractures appear to occur infrequently

– Lack of strong evidence

– FDA has issued warning regarding possible risk

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Lifestyle ModificationsLifestyle Modifications

• Adequate calcium (1,000–1,500 mg · d–1) intake

• Adequate vitamin D (600-800 IU · d–1) intake

• Regular exercise

– Exercise is the only lifestyle modification that can simultaneously ameliorate low BMD, augment muscle mass, promote strength gain, and improve dynamic balance — all of which are independent risk factors for fracture.

• Smoking cessation

• Avoidance of excessive alcohol intake

• Visual correction to decrease fall risk

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Exercise and Osteoporosis Exercise and Osteoporosis

• Physiologic response of bone to exercise

– Acute physiologic response

• Exercise causes compression, tension, or torsion of bone tissue and ultimately deformation, which is the basis for chronic adaptations.

– Chronic physiologic response

• Changes via modeling/remodeling take up to several months.

• Maintenance of bone tissue quality through targeted remodeling

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Exercise and OsteoporosisExercise and Osteoporosis

• Osteogenic activities

– Response is site specific.

– Loading/stress should be designed to affect the location in which osteoporosis is identified (e.g., spine, hip).

– Rest is important for proper bone adaptation or response.

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Exercise and OsteoporosisExercise and Osteoporosis• Exercise during youth: building a strong skeleton

– Exercise in youth is deemed very important for adult bone health.

– Period of maximal velocity of height growth may be most important period of bone mineral accumulation.

– Studies suggest that the bone response to loading is optimized in prepuberty and early puberty.

• Exercise prescription for optimizing bone development in youth

– ACSM Position Stand on Physical Activity and Bone Health: 10–20 min, 3 d · wk–1 of impact activities such as plyometrics, jumping, moderate-intensity resistance training, and participation in sports that involve running and jumping (soccer, basketball)

– Ten jumps, three times per day has also been shown to significantly increase bone mineral density in the proximal femur and intertrochanteric regions.

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Exercise and OsteoporosisExercise and Osteoporosis

• Exercise during adulthood: maintaining a strong skeleton

– Goal of exercise in adulthood is to gain bone strength and to offset bone loss observed during this time in life.

– Not as much research in men as women but appears men can also retard the BMD loss associated with aging.

• Exercise prescription to preserve bone health during adulthood

– ACSM Position Stand on Physical Activity and Bone Health: 30–60 min · d–1 of a combination of moderate-to-high intensity weight-bearing endurance activities (three to five times per week), resistance exercise (two to three times per week), and jumping activities

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Exercise for the Elderly and Individuals with Osteoporosis

Exercise for the Elderly and Individuals with Osteoporosis

• Exercise testing for those with osteoporosis

– Not contraindicated

– Use of cycle ergometry may be indicated in patients with severe vertebral osteoporosis if walking is painful.

– Vertebral compression fractures compromise ventilatory capacity and may affect balance during treadmill walking.

– May have increased false-negative test rate because of inability to exercise to significant level of stress

– Maximal muscle strength testing may be contraindicated in those with severe osteoporosis because of risk for fracture.

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Exercise Prescription for Individuals with Osteoporosis

Exercise Prescription for Individuals with Osteoporosis

• Should consult with patient’s physician first

• Pain may limit exercise program options

• Pain management may be an important part of the care

• ACSM position statement on physical activity and bone health: “Exercise programs for elderly men and women should include not only weight-bearing endurance and resistance activities aimed at preserving bone mass but also activities designed to improve balance and prevent falls.”

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Exercise Prescription for Individuals with Osteoporosis

Exercise Prescription for Individuals with Osteoporosis

• Contraindicated exercise for individuals with osteroporosis

– Contraindicated because they can generate large forces on relatively weak bone

• Twisting movements (e.g., golf swing)

• Dynamic abdominal exercises (e.g., sit-ups)

• Excessive trunk flexion

• Exercises that involve abrupt or explosive loading

• High-impact loading

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Exercise Prescription for Individuals with Osteoporosis

Exercise Prescription for Individuals with Osteoporosis

• Flexibility training for individuals with osteoporosis

– Increased flexibility can be of benefit (especially with posture).

– Many commonly prescribed exercises for increasing flexibility involve spinal flexion and should be avoided.

– Slow and controlled movements should be the rule.

– Avoid ballistic-type stretching.

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Exercise Prescription for Individuals with Osteoporosis

Exercise Prescription for Individuals with Osteoporosis

• Aerobic training for individuals with osteoporosis

– Goals

• Increase aerobic fitness

• Decrease cardiovascular disease risk factors

• Help maintain bone strength

• Improve balance

– Perform 3-5 d · wk–1 at an intensity of 40%–59% of VO2 reserve or heart rate reserve (HRR)

– Initial goal of 20–30 min per session with slow increase to 30–60 min once tolerated.

– When possible, exercise mode should be weight bearing.

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Exercise Prescription for Individuals with Osteoporosis

Exercise Prescription for Individuals with Osteoporosis

• Resistance training for individuals with osteoporosis

– Goals

• Improve bone health

• Improve balance to lower risk of falling

– Perform 2–3 d · wk–1, 8–12 repetitions at a moderate intensity (60%–80%)

– Those with osteoporosis should avoid any ballistic or jumping activities.