Hormone replacement therapy and fractures in older adults

Estrogen deficiency in women is associated with accelerated bone loss, and estrogen replacement therapy has been proven to be effective in preventing osteoporosis and fractures in postmenopausal women. The introduction of selective estrogen receptor modulators that have an estrogen-like effect on the skeleton but have a different pattern of effects on other tissues may have an important role in the management of osteoporosis in women in the near future. In men, androgen deficiency has been shown to be associated with osteoporosis. Although androgen replacement in hypogonadal men may decrease bone resorption and increase bone mass, long-term placebo-controlled trials are needed to better define the benefits and risks of such therapy before it can be recommended. Sex hormone deficiency is linked to the development of osteoporosis in both women and men. In women, hormonal replacement by estrogen or the newly developed selective estrogen receptor modulators may prevent the development of osteoporosis and its related fractures. In men, there is early evidence that testosterone replacement therapy may enhance bone mass in hypogonadal men.     

Role of estrogens in the management of postmenopausal bone loss

It is well known that estrogen deficiency is the major determinant of bone loss in postmenopausal women. Estrogen is important to the bone remodeling process through direct and indirect actions on bone cells. The largest clinical experience exists with estrogen therapy, demonstrating its successful prevention of osteoporosis as well as its positive influence on oral bone health, vasomotor and urogenital symptoms, and cardiovascular risk factors, which may not occur with other nonestrogen-based treatments. Compliance with HRT, however, is typically poor because of the potential side effects and possible increased risk of breast or endometrial cancer. Nevertheless, there is now evidence that lower doses of estrogens in elderly women may prevent bone loss while minimizing the side effects seen with higher doses of estrogen. Additionally, when adequate calcium, vitamin D, and exercise are used in combination with estrogen-based treatments, more positive increases occur in bone density. The benefits and risks of HRT must be assessed on a case-by-case basis, and the decision to use HRT is a matter for each patient in consultation with her physician. Estrogen-based therapy remains the treatment of choice for the prevention of osteoporosis in most postmenopausal women, and there may be a role for estrogen to play in the prevention of corticosteroid osteoporosis. Combination therapies using estrogen should probably be reserved for patients who continue to fracture on single therapy or should be used in patients who present initially with severe osteoporosis.     

Osteoporosis. Pathogenesis, diagnosis, and treatment in older adults

Osteoporosis is a major cause of disability and excess mortality in older men and women. Hip fracture incidence accelerates approximately 10 years after menopause in women and after age 70 in men. Approximately 1 million Americans suffer fragility fractures each year at a cost of over 14 billion dollars. The disability, mortality, and cost of hip and vertebral fractures are substantial in the rapidly growing, aging population so that prevention of osteoporosis is a major public health concern. BMD is used to make the diagnosis of osteoporosis before incident fracture and predict fracture risk. Recommendations for treatment and prevention of osteoporosis based on BMD score have been published by the World Health Organization and the National Osteoporosis Foundation. In a process that continues throughout life, bone repairs itself by the coupled action of bone resorption followed by bone formation, sometimes referred to as bone turnover. Osteoblasts and osteoclasts are the primary cells involved in bone formation and resorption, respectively. The process of bone turnover is regulated by hormones, such as PIH and local factors such as IL-1 and prostaglandins. Following attainment of peak bone mass at age 25, bone loss begins, accelerates in women at menopause and slows again but continues into advanced years at a rate of 1% to 2% per year, similar to premenopausal bone loss rate. The leading theories of the mechanism of bone loss in older individuals is calcium deficiency leading to secondary hyperparathyroidism and sex hormone deficiency. Risk factors such as age, gender, ethnic background, smoking, exercise, and nutrition, and medical conditions associated with osteoporosis should be evaluated and modified when possible to prevent further bone loss. Osteoporosis treatment and prevention include weight-bearing exercise, calcium and vitamin D supplementation, estrogen replacement, bisphosphonates, selective estrogen receptor antagonists, and calcitonin. Although there is no currently approved treatment for osteoporosis in men, many of the treatments approved for osteoporosis in women hold promise to be beneficial in men.     

Osteoporosis: an age-related and gender-specific disease--a mini-review

Osteoporosis, a classical age-related disease and known to be more common in women than in men, has been reported increasingly often in men during the past few years. Although men at all ages after puberty have larger bones than women, resulting in greater bending strength, mortality after a hip fracture, one of the major complications of osteoporosis, is more common in men than in women. Sex hormone deficiency is associated with unrestrained osteoclast activity and bone loss. Even though estrogen deficiency is more pronounced in women, it appears to be a major factor in the pathogenesis of osteoporosis in both genders. In contrast to osteoporosis in postmenopausal women, the treatment of osteoporosis in men has been scarcely reported. Nevertheless, some drugs commonly used for the treatment of osteoporosis in women also appear to be effective in men. The aim of this study is to review primary osteoporosis in the elderly with particular emphasis on gender-related aspects.     

The role of selective estrogen receptor modulators in the prevention and treatment of osteoporosis

Osteoporosis can affect almost everyone in the population, and although clinical outcome of fracture is manifested in late life, the disease process begins in the early postmenopausal years in women. The pharmacologic agents currently available for osteoporosis prevention and treatment act by inhibiting bone resorption, and include estrogen or hormone replacement therapy (estrogen with progestin), bisphosphonates, salmon calcitonin nasal spray, and selective estrogen receptor modulators (SERMs). Raloxifene is a benzothiophene SERM that has estrogen against effects in bone and on serum lipid metabolism and estrogen antagonist effects on breast and uterine tissue. This article summarizes the effects of these antiresorptive agents, as measured by changes in bone mineral density, biochemical markers of bone turnover, and incident fractures in postmenopausal osteoporosis.     

The role of calcitonin in the development and treatment of osteoporosis

CT is a peptide hormone produced predominantly by thyroid C cells and probably to a lesser extent by extrathyroidal tissues. Although its physiological function has not yet been established, it is a pharmacological inhibitor of osteoclastic bone resorption. There is currently no convincing evidence that naturally occurring or iatrogenic CT deficiency is involved in the pathogenesis of osteoporosis; however, a selective examination of patients with various rates of bone turnover would help to resolve this issue. As a pharmacological inhibitor of bone resorption, CT has potential usefulness in the therapy of osteoporosis. CT has been shown to stabilize or modestly increase indices of cortical and trabecular bone mass and total body calcium when administered to patients with established osteoporosis for periods of 1-2 yr. The increments in bone mass seen in some studies appear to be transient and are likely due to reductions in bone resorption with bone formation remaining unaffected until remodeling spaces are filled. The duration and magnitude of these increases are probably limited by the eventual decline in bone formation as remodeling equilibrium is reestablished. Therefore, reduction in the rate of bone loss with maintenance of the existing skeletal mass, rather than significant sustained increases in bone mass, should be considered the most realistic therapeutic goal with this agent. Whether or not a reduction in the rate of bone loss persists for longer periods needs further evaluation as does the important issue of subsequent fracture rates. The identification of patients with increased bone resorption rates (high turnover osteoporosis) should help provide a basis for more selective treatment of those patients who would be most likely to respond to this form of therapy. Whether there is additional benefit to using intermittent CT concurrently or sequentially with bone formation stimulating agents (coherence therapy) also needs to be explored. CT may also be of benefit in the prevention of osteoporosis, particularly in postmenopausal women who are unable or unwilling to take estrogen replacement. These potential benefits must be weighed carefully against the current cost of CT and the inconvenience of it having to be given by injection, problems which should be solved by future research.     

Background for studies on the treatment of male osteoporosis: state of the art

Male osteoporosis represents an important, although long underestimated, public health problem. Both in men and in women aging is accompanied by continuous bone loss and by an exponential increase in the incidence of osteoporotic fracture, with a female to male incidence ratio of about 2 to 3 to 1 in the elderly for hip and vertebral fractures. Morbidity after osteoporotic fractures appears to be more serious and mortality more common in men than in women. To date, no single treatment has been proved to be effective and safe in published prospective studies. The present report, based on a systematic search of the literature on male osteoporosis, summarises the state of the art on the clinical consequences of male osteoporosis and its risk factors, in relation to the present state of knowledge about female osteoporosis. This constitutes the background for the design of rational clinical development strategies for therapeutic interventions in male osteoporosis. From this review of the literature it is apparent that notwithstanding the existing sex differences in pathophysiology of osteoporosis and the difference in age-specific incidence of osteoporotic fractures, there are also important similarities between osteoporosis in women and men. The higher incidence of fracture in women than in men results from quantitative differences in risk factors rather than from different risk factors. Even though there are sex differences in bone geometry, incidence of fracture seems to be similar in men and women for a same absolute areal bone mineral density. However, the lack of data on the changes in fracture rates in men resulting from pharmacological intervention, leading to changes in bone mineral density or bone turnover, remains the main limitation for extrapolation of established treatment outcomes from women to men.     

Role of insulin-like growth factor-I in primary osteoporosis: a correlative study

Osteoporosis is characterized by impairment of bone mass and deterioration of bone microscopic structure, resulting in increased bone fragility and susceptibility to fracture. Recent reports have indicated that reduced plasma levels of IGF-I are associated with osteoporosis in both males and females. Moreover, there is accumulating clinical evidence that treatment with GH or IGF-I has beneficial effects on bone mass and bone remodeling in men with idiopathic osteoporosis, in the elderly and in hypopituitary patients. As correlative studies on IGF-I, IGF-BP3 and bone mass in the elderly are lacking, we studied the relationships between serum IGF-I, IGF-BP3, bone mineral density (BMD), body mass index (BMI), calciotropic hormones and age in 102 premenopausal and postmenopausal women. Our study indicates that the reduction of the anabolic processes mediated by IGF-I may account for the slow and progressive loss of bone mass that take place after the age of 40-50 years. In addition, nutritional caloric or proteic deficit may add to the effects of GH, age and other factors in decreasing IGF-I synthesis and therefore further contribute to the development of primary osteoporosis.     

Osteoporosis and osteoporotic fractures in men: a clinical perspective.

The lifetime risk of any fracture of the hip, spine or distal forearm in men aged 50 years has been estimated to be 13%, compared with 40% in women. Although the overall incidence of osteoporosis is less in men than in women, the disease still represents an important public health problem. In particular, hip fractures are associated with substantial mortality and morbidity, even more so than in women. In male patients presenting with osteoporotic fractures, major causes of skeletal fragility, such as hypogonadism, glucocorticoid excess, primary hyperparathyroidism and alcohol abuse, can often be identified. In as many as 50% of osteoporotic men, however, no aetiology can be found: these men suffer from a syndrome commonly referred to as idiopathic osteoporosis, which is presumably related to some type of osteoblast dysfunction. Recent evidence indicates that the loss of skeletal integrity in ageing men may be partially related to endocrine deficiencies, including vitamin D, androgen and/or oestrogen deficiency. While the consequences of vitamin D or oestrogen deficiency in women have been well established, the skeletal impact of these (partial) age-related deficiencies in men remains to be clarified. Osteoporosis in elderly men is a multifactorial disease, as it is in women. The prevention of osteoporosis should therefore focus not only on increasing the bone strength, but also on decreasing the risk of falls. However, the prevention and therapy of osteoporotic disorders in men are virtually unexplored. To date, the use of specific osteoporotic drugs in osteoporotic men is still based on reasonable but untested assumptions.     

Bone responsiveness to parathyroid hormone in normal and osteoporotic postmenopausal women

Increased bone loss in estrogen-deficient normal and osteoporotic postmenopausal women may be due mainly to increased sensitivity of bone-resorbing cells to circulating PTH, but this is supported only by indirect data. Therefore, we tested the responsiveness of bone to PTH directly by using a 3-day iv infusion of bovine PTH-(1-34) at 400 U/day in 9 normal premenopausal women, 10 normal postmenopausal women, and 12 osteoporotic postmenopausal women. Serum calcium and urinary hydroxyproline concentrations increased (P less than 0.001) over baseline values during infusion, but the mean increases in both variables did not differ among groups. The data do not support the hypothesis that estrogen deficiency increases the sensitivity of bone to PTH or that the sensitivity in osteoporotic women is greater than that in normal postmenopausal women. Within the constraints imposed by the method of testing, we conclude that the additional bone resorption induced by menopause and by osteoporosis may be due to mechanisms that are not due to enhanced responsiveness of bone to PTH.     

Testosterone and Male Osteoporosis

Male osteoporosis is not a rare public health issue. The prevalence of hypogonadism increases with aging, and the gradual onset of moderate hypogonadism is the most common cause of male osteoporosis. Decreased testosterone levels with aging can directly or indirectly increase the risk of male osteoporosis and fractures. However, testosterone deficiency is not a universal feature of elderly men, and the association of testosterone with osteoporosis is not as strong as that of estrogen with osteoporosis in females; the effect of testosterone on male osteoporosis and treatment of osteoporosis is still controversial. Although many data and results have been released, the mechanism by which testosterone affects bone formation and resorption is not fully understood yet. Therefore, this review aims to present current knowledge about testosterone and male osteoporosis.     

Geriatrics grand rounds: Eve's rib, or a revisionist view of osteoporosis in men

It is widely accepted that estrogen withdrawal following menopause predisposes women to accelerated bone loss and increased risk of developing osteoporosis. Although osteoporosis is a significant public health problem for aging men as well as women, the cause of osteoporosis in men remains largely unknown. A substantial number of men with osteoporosis present with bone loss secondary to conditions associated with reduced gonadal steroid hormone levels. Although hypogonadism is related to bone loss in men, and androgen levels decline with age in men, it is not at all clear that reduced androgen levels are related to bone loss in older men. What, then, is the role of gonadal steroids in osteoporosis in men? This review focuses on recent research--including clinical investigations of men with genetic disorders of estrogen action, basic biomedical studies of estrogen receptor "knockout" mice, and population-based comparisons of bone density with gonadal steroids in older men--leading to the surprising conclusion that estrogen plays a vital role in maintenance of bone in men as well as in women. Possible mechanisms whereby reduced estrogen levels might result in bone loss in both sexes are also reviewed, as are potential therapeutic implications of a role for estrogen in osteoporosis in men.     

Calcium requirement for the maintenance of bone mass

The bone mineral density of middle-aged and elderly people is determined by the peak bone mass obtained in the adolescent period and the bone loss in the later stage of life. The rapid bone loss observed in the postmenopausal women is largely explained by estrogen deficiency. On the other hand, aging-dependent decrease of bone mass commonly seen in women and men may be attributed to the change in calcium metabolism. In Japan, the calcium intake would be less than the amount sufficient to keep positive calcium balance and to maintain bone mass.     

Osteoporosis in the elderly man

Elderly men are at substantial risk for fracture. Morbidity after osteoporotic fractures appears to be more serious and mortality more common in men than in women. Risk factors for osteoporotic fractures in men appear to be qualitatively similar to those in women. Low bone mineral density (BMD) is an important risk factor for fracture in men; however, further clarification of the relationship between BMD, bone geometry and fracture risk is needed. Our understanding of the mechanisms underlying senile bone loss and the pathogenesis of senile osteoporosis in men remains fragmentary with, in particular, the need for further clarification regarding the precise impact of hormonal status in elderly men on skeletal homeostasis. Nevertheless, the available evidence indicates a role for both testosterone and estrogens in the regulation of bone metabolism in elderly men. Recommendations concerning prevention and treatment of senile osteoporosis in men should focus on the minimization of known risk factors for bone loss and falls. Testosterone treatment may be useful only in those men with initially low serum testosterone. As to other pharmacological treatment modalities, prospective trials specifically in elderly men, and preferably with fracture incidence as the primary clinical endpoint, are required.     

Selective estrogen receptors modulators in the prevention and treatment of postmenopausal osteoporosis.

Raloxifene, the first of the second-generation of SERMs to be widely available, represents a significant improvement over tamoxifen. It prevents postmenopausal bone loss and reduces the incidence of vertebral fractures and of new breast cancer cases in osteoporotic patients without stimulating the endometrium. The suggestion that raloxifene could have a beneficial effect on cardiovascular disease in high-risk patients needs to be confirmed in prospective study. Selective estrogen receptors modulators represent a new and promising class of agents for the management of postmenopausal women with a scope that goes far beyond the prevention and treatment of osteoporosis. The observations that estrogens may play a role in bone metabolism of men and that SERMs prevent bone loss and induce a decrease in total serum cholesterol without affecting the prostate in orchidectomized male rats raises the possibility that they also may be of interest for the treatment of elderly men.     

Response of biochemical markers of bone turnover to estrogen treatment in post-menopausal women: evidence against an early anabolic effect on bone formation.

Bone loss following menopause can be prevented or reduced by estrogen replacement therapy (ERT). The primary action of estrogen on bone is generally considered to be antiresorptive, but some evidence would also suggest a stimulatory effect on bone formation. The aim of this study was to assess the effect of ERT on biochemical markers of bone resorption (urinary pyridinoline and deoxypyridinoline), and of bone formation (bone-specific alkaline phosphatase--B-ALP, and the C-terminal propeptide of type I collagen--CICP) in a group of 25 postmenopausal women with no evidence of osteoporosis. Since the suggested anabolic effect of estrogen seems to take place in the early period of ERT, we measured the response of markers immediately before and after the start of treatment (30, 60, 120 and 180 days). The markers of bone resorption started to decrease at 30 days and remained low thereafter. We also observed a similar decrease in serum levels of B-ALP and CICP, reflecting a reduction of bone formation rate. Our data would indicate that ERT at the given dose does not have early anabolic effects on bone, in addition to its recognized suppressive effect on bone resorption.     

Male osteoporosis-what are the causes,diagnostic challenges,and management

Osteoporosis is underrecognized and undertreated in men, even though up to 25% of fractures in patients over the age of 50 years occur in men. Men develop osteoporosis with normal aging and accumulation of comorbidities that cause bone loss. Secondary causes of bone loss may be found in up to 60% of men with osteoporosis. Mortality in men who experience major fragility fracture is greater than in women. Diagnosis of osteoporosis in men is similar to women, based on low-trauma or fragility fractures, and/or bone mineral density dual-energy X-ray absorptiometry (DXA) T-scores at or below ?2.5. Because most clinical trials with osteoporosis drugs in men were based on bone density endpoints, not fracture reduction, the antifracture efficacy of approved treatments in men is not as well documented as that in women. Men at a high risk of fracture should be offered treatment to reduce future fractures.     

Exercise considerations for postmenopausal women with osteoporosis

Individuals with osteoporosis are at an increased risk of fracture due to a net loss of bone mass. The cellular mechanisms causing decreased bone mass are increased osteoclast-mediated bone resorption and/or decreased osteoblast-mediated bone formation. Clinical studies have shown that bone loss can be prevented by estrogen replacement therapy and calcium supplementation. Weight-bearing and strengthening exercise may also play a role in retarding bone loss in the postmenopausal woman, and it may even increase bone mass. The essential components of an exercise program include intensity, duration, frequency, and type of activity. Additional goals of a therapeutic exercise program are to improve flexibility and balance, and to prevent falls. Structure-function relationships in normal and osteoporotic bone and the effects of exercise on bone are reviewed. A rational approach for exercise strategies is discussed.     

Osteoporosebehandlung: Bisphosphonate, SERM’s, Teriparatide und Strontium

The therapy of osteoporosis is mostly based upon the use of drugs which inhibit bone resorption. Among these, the bisphosphonate family is the best known and mostly used by clinicians. Both second and third generation bisphosphonates, like alendronate and risedronate, are now available as weekly tablets which have facilitated the patient compliance to treatment together with a decreased occurrence of gastrointestinal side effects. These compounds are used efficiently to treat postmenopausal osteoporosis and osteoporosis of men as well. Their use did provide good evidence of increased bone mineral density (BMD) and a reduction in fracture rates. The use of intravenous bisphosphonates such as Zoledronate, Ibandronate and Pamidronate remains in most of the cases limited to special indications such as intolerance to the oral formulations and treatment of patients with bone metastases. The selective estrogen modulators (SERM's) family is limited to a single product on the market as of now, Raloxifene, which does inhibit bone resorption and is well documented by postmenopausal women to increase BMD and reduce vertebral fractures. In addition, a large range of positive nonosseous effects have been documented such as the reduction of the incidence of breast cancer. Other substances do have a strong anabolic effect such as Teriparatide, a recombinant human formulation of PTH 1-34. This compound has demonstrated good efficacy in postmenopausal women, increasing vertebral and hip BMD and reducing the incidence of fractures at both sites. The exact role of Teriparatide in the clinical setting is still open but its overall impact in the therapy of osteoporosis could be major due to its major efficiency over shorter periods of time. Strontium ranelate, a new divalent Strontium salt taken orally, acts both as an anti-catabolic and anabolic agent. The first results provided with strontium ranelate are very promising due to its major effect on the increase in BMD both at the vertebral and hip sites and its ability to reduce the incidence of fractures at both locations. Additional data are awaited to confirm these initial positive results.     

Managing osteoporosis: current trends, future possibilities

The management of osteoporosis after fracture has occurred is currently difficult. The most effective approach is clearly prevention. Reduction in risk factors, adequate calcium nutrition, and physical activity are all important features, but the mainstay is estrogen therapy. Although this treatment early in the postmenopausal period has been shown to reduce bone and fracture, it must not be forgotten that other biochemical abnormalities in calcium homeostasis may also cause bone loss with aging. Despite the difficulties in treating established disease, newer strategies are being developed in the hope that increments in bone mass may reduce the frequency of fracture recurrence.