Screening for Osteoporosis in Postmenopausal Women



Screening for Osteoporosis in Postmenopausal Women


David M. Slovik



One of the major concerns of postmenopausal women is the development of osteoporosis. Although much less appreciated, the problem is also an issue for elderly men (see Appendix 144-1-144-144). Osteoporotic fractures in aging women represent a major health problem in industrialized nations. In the United States, approximately 250,000 hip fractures occur annually in women older than the age of 65 years, with 15% to 25% of these women experiencing excess mortality or needing long-term nursing home care. Expenditures for osteoporotic fractures and their consequences are well in excess of $15 billion annually and rising with the aging of the population. The pathophysiologic mechanisms for postmenopausal osteoporosis are imperfectly understood, but the means to ensure maximal skeletal growth and strength, prevent loss of bone mass, and noninvasively evaluate bone mass are available (see Chapter 164).

The frequency and clinical significance of osteoporosis, combined with the capabilities to detect and treat it effectively so as to prevent fractures, argue strongly for screening. Many now recommend that osteoporosis screening become an essential part of the health maintenance program for women; however, data from prospective, long-term, randomized studies identifying those who are best served by screening have yet to emerge, so that clinical judgment is necessary in selecting candidates for osteoporosis screening. Effectively advising the perimenopausal woman requires knowledge of the epidemiology of osteoporosis and of the risk factors, screening tests, and treatment modalities for this disease.


EPIDEMIOLOGY AND RISK FACTORS (1, 2, 3, 4, 5, 6 and 7)


Epidemiology

As the life expectancy of women has reached the mid-80s, osteoporosis has taken on epidemic proportions, especially among white women in industrialized societies. In the United States, the prevalence of low bone density in older adults approaches 50%; a woman’s risk for an osteoporotic fracture by age 80 years is approximately 40% (several times greater than the risk for breast cancer). The risk for death after a hip fracture is nearly 25%. The disability and expense attributable to the consequences of osteoporosis are enormous and growing.


Risk Factors

More fractures occur in individuals in the low bone mass or osteopenic category (T-score between -1.0 and -2.5 on bone density measurement) than the osteoporosis category because there are many more individuals in that category. Thus, it is important to assess all risk factors and not rely just on bone mineral density (BMD) measurements.

The National Osteoporosis Risk Assessment Study examined risk factors of low BMD and the relationship of low BMD to fracture risk in a large population-based cohort of postmenopausal women (mean age 64 years). Age was the greatest risk factor. Women of ages 70 to 74 years, 75 to 79 years, and older than 80 years had a 9.5-fold, 14.3-fold, and 22.6-fold risk of osteoporosis, respectively. Other risk factors for osteoporosis included body mass index below the 25th percentile (<23 kg/m2), maternal history of fracture, and personal history of fracture during adulthood. Osteoporosis was associated with a fourfold increase in fracture rate (any site) at 1 year. After controlling for BMD, all of these risk factors were independently associated with fracture risk (Table 144-1).

In addition, a number of contributing risk factors have emerged. These include lifelong inadequate intake of calcium, white race, inadequate physical activity, early menopause (onset before the age of 45 years), cigarette smoking, and excessive intake of alcohol. All may predispose a woman to a lower bone mass and osteoporotic fractures with aging. Women in whom osteoporosis does not develop may have a larger skeletal mass, which can be increased through physical activity and calcium supplementation. Estrogen use and African American race are protective factors.

Medical conditions that are secondary causes of osteoporosis include Cushing syndrome, exogenous glucocorticoid administration, rheumatoid arthritis, prolonged heparin therapy, thyrotoxicosis (including excessive thyroid replacement therapy), hypogonadism, hyperprolactinemia, anorexia nervosa, and hyperparathyroidism. However, these diseases account for only a small percentage of cases of osteoporosis.


NATURAL HISTORY AND EFFECTIVENESS OF THERAPY (6,8, 9, 10, 11, 12, 13, 14 and 15)


Natural History

The resorption and formation of bone is a continuous process throughout life. Under physiologic circumstances, the rates of these processes are equal and coupled. Skeletal mass is usually maximal by age 35 years and declines in women after age 40 years and in men after age 50 years, when the rate of new bone formation no longer equals the rate of bone resorption. The rate of decline in skeletal mass is most rapid in women within 2 years of menopause and can average 2% to 4% a year during the first several years after menopause. Bone mineral content may decline by as much as 25% to 33% during this
period. Afterward, loss continues, but at a slower rate (1% or less a year). The areas of greatest loss include the femoral neck and lumbar vertebrae, sites rich in trabecular bone and subject to future fracture. Cortical bone, comprising 80% of skeletal bone, is lost less rapidly.








TABLE 144-1 Major Risk Factors for Osteoporosis-Related Fractures in Women





















Advanced age


History of low-trauma fracture during adulthood


Family history of osteoporosis in a first-degree relative


Low body weight or low body mass index


Low bone mineral density


Current cigarette smoking


Excess alcohol consumption


Glucocorticoid therapy


Secondary osteoporosis (e.g., rheumatoid arthritis, celiac disease)


The progressive decline in skeletal mass becomes clinically manifest when fractures are sustained spontaneously or after minimal trauma. Loss of height and developing kyphosis may indicate vertebral compression fractures have occurred. Fractures most commonly occur in the thoracic and lumbar vertebrae, hip, humerus, and wrist. The clinical course and frequency of fractures in individual patients are hard to predict.


Effectiveness of Therapy

There are now many therapies that have been shown to reduce bone loss, increase bone density, and reduce the risk of fracture. Estrogen replacement can prevent bone loss and even lead to skeletal accretion (see Chapter 164). Observational studies and the prospective Women’s Health Initiative have noted a 35% to 50% reduction in hip, wrist, and vertebral fractures in women who have used estrogen for at least 5 years after menopause. However, if estrogen is discontinued, bone loss rapidly ensues, and it is difficult to reverse the significant bone loss that occurs in the first few years of menopause. Bisphosphonates (e.g., alendronate, risedronate, ibandronate, and zoledronic acid) prevent bone loss, increase bone density, and reduce fracture risk in osteoporotic patients by up to 70%. Selective estrogen receptor modulators (e.g., raloxifene) also halt bone resorption, modestly increase BMD, and reduce spine fracture risk. Teriparatide, an anabolic agent, and denosumab, an antiresorptive agent and a human monoclonal antibody to RANKL, can prevent bone loss, increase bone density, and reduce fracture risk. Calcium supplementation with vitamin D helps to preserve cortical bone mass but does not prevent bone loss to the degree that estrogen or other therapies do.

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Aug 23, 2016 | Posted by in CRITICAL CARE | Comments Off on Screening for Osteoporosis in Postmenopausal Women

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