Calcitonin

Calcitonin is a 32-amino acid polypeptide secreted by the parafollicular cells of the thyroid. Effects on bone include inhibition of osteoclasts, thus preventing bone resorption, as well as increased renal calcium excretion. Salmon calcitonin is often used therapeutically because it is more potent and has a longer duration of action compared with human calcitonin. Calcitonin also possesses analgesic properties. The mechanism of its analgesic effect is unknown but is thought to involve inhibition of prostaglandins and stimulation of β-endorphins. Most of the clinical data in postmenopausal osteoporosis involves the use of salmon calciton in nasal spray. Clinical trials have demonstrated a reduction in the risk of vertebral fractures and increased bone mineral density. Studies examining nonvertebral fractures have shown mixed results, some indicating a nonsignificant risk In general, calcitonin is inferior to bisphosphonates (BPs) in reducing fracture risk. Calcitonin is effective in the treatment of osteopathic pain. It has also been used in glucocorticoid-induced osteoporosis. Parenteral calcitonin is generally associated with more frequent side effects compared with intranasal calcitonin. Injectable administration can cause flushing, tingling, nausea, and injection site and allergic reactions. Side effects with intranasal use are usually limited to local effects (nasal congestion and irritation). Recent phase I trials with a new oral dosage form show promise in terms of efficacy and tolerability for treating patients who prefer this route of administration. This review of pertinent literature on calcitonin indicates that this remains a viable, though second-or third-line, agent for osteoporotic patients who refuse or cannot tolerate other treatments (e.g., BPs, raloxifene, and estrogen).     

Calcitonin.

Calcitonin is FDA approved for the treatment of postmenopausal osteoporosis but not for prevention. The preferred delivery system is nasal. Nasal calcitonin is safe and well tolerated. The vertebral fracture efficacy of calcitonin is less robust than the two approved bisphosphonates (alendronate and risedronate) but is similar to raloxifene in the treatment of established osteoporosis. Calcitonin has not been demonstrated to reduce hip fracture risk, although a post-hoc pooled analysis suggests potential effectiveness of nasal calcitonin. Calcitonin produces small increments in bone mass of the spine and modestly reduces bone turnover in women with osteoporosis. Calcitonin may have analgesic benefit in patients with acute painful vertebral fractures. Treatment with calcitonin should be considered for older women with osteoporosis with painful vertebral fractures and for women who fail to respond to or cannot tolerate bisphosphonates. Calcitonin may also be indicated for women who are unable to take bisphosphonates because of impaired renal function.     

CALCITONIN AND POSTMENOPAUSAL OSTEOPOROSIS

Fasting serum calcitonin levels were measured in 54 postmenopausal women who had for 10 years been taking part in a double blind trial to assess the effect of the synthetic oestrogen, mestranol, on postmenopausal bone loss. There were no differences in calcitonin levels between mestranol treated and placebo groups. Fifteen of the women were challenged with a calcium infusion to measure the secretory reserve of calcitonin. Oestrogen treatment did not increase the calcitonin response to calcium infusion. The three patients who exhibited the greatest responses were placebo treated. Bone density was measured by gamma-ray absorptiometry over the ten year period and the annual rate of change of bone density calculated. No correlation could be found between basal calcitonin level or calcitonin reserve and change in bone density. Our results indicate that postmenopausal osteoporosis is not caused by a deficiency of calcitonin and that the action of oestrogen therapy to prevent bone loss does not involve calcitonin.     

Recommendations for the prevention and treatment of glucocorticoid-induced osteoporosis: 2001 update. American College of Rheumatology Ad Hoc Committee on Glucocorticoid-Induced Osteoporosis

Glucocorticoid-induced bone loss should be prevented, and if present, should be treated (Table 2). Supplementation with calcium and vitamin D at a dosage of 800 IU/day, or an activated form of vitamin D (e.g., alfacalcidiol at 1 microg/day or calcitriol at 0.5 microg/day), should be offered to all patients receiving glucocorticoids, to restore normal calcium balance. This combination has been shown to maintain bone mass in patients receiving long-term low-to-medium-dose glucocorticoid therapy who have normal levels of gonadal hormones. However, while supplementation with calcium and vitamin D alone generally will not prevent bone loss in patients in whom medium-to-high-dose glucocorticoid therapy is being initiated, supplementation with calcium and an activated form of vitamin D will prevent bone loss. There are no data available to support any conclusion about the antifracture efficacy of the combination of calcium supplementation plus an activated form of vitamin D. Antiresorptive agents are effective in the treatment of glucocorticoid-induced bone loss. All of these agents either prevent bone loss or modestly increase lumbar spine bone mass and maintain hip bone mass. While there are no randomized controlled trials of prevention of glucocorticoid-induced bone loss or radiographic vertebral fracture outcomes with HRT or testosterone, patients receiving long-term glucocorticoid therapy who are hypogonadal should be offered HRT. The bisphosphonates are effective for both the prevention and the treatment of glucocorticoid-induced bone loss. Large studies have demonstrated that bisphosphonates also reduce the incidence of radiographic vertebral fractures in postmenopausal women with glucocorticoid-induced osteoporosis. Treatment with a bisphosphonate is recommended to prevent bone loss in all men and postmenopausal women in whom long-term glucocorticoid treatment at > or =5 mg/day is being initiated, as well as in men and postmenopausal women receiving long-term glucocorticoids in whom the BMD T-score at either the lumbar spine or the hip is below normal. While there is little information on the prevention or treatment of bone loss in premenopausal women, these women, too, may lose bone mass if they are being treated with glucocorticoids, so prevention of bone loss with antiresorptive agents should be considered. If bisphosphonate therapy is being considered for a premenopausal woman, she must be counseled regarding use of appropriate contraception. The therapies to prevent or treat glucocorticoid-induced bone loss should be continued as long as the patient is receiving glucocorticoids. Data from large studies of anabolic agents (e.g., PTH) and further studies of combination therapy in patients receiving glucocorticoids are eagerly awaited so additional options will be available for the prevention of this serious complication of glucocorticoid treatment.     

The role of bisphosphonates in breast and prostate cancers

Bisphosphonate drugs are a group of pyrophosphate analogues which bind avidly to hydroxyapatite bone mineral surfaces and their major action is to inhibit osteoclast activity and thus bone resorption. In oncology, their role in metastatic bone disease is well established, but there is increasing interest in their potential role in preventing and treating cancer-induced bone loss and their possible anti-tumour effects. Metastatic bone disease is associated with a variety of skeletal complications, including pathologic fractures, bone pain, impaired mobility, spinal cord compression and hypercalcaemia. Intravenous bisphosphonates, particularly zoledronic acid, in conjunction with rehydration, are now established as the treatment of choice for hypercalcaemia. For treatment of bone pain, it has also been shown that bisphosphonates can be an effective supplementary approach to radiotherapy. In breast cancer and myeloma, bisphosphonates have now become part of standard therapy to treat and prevent skeletal-related events (SRE) and, until recently, treatment was largely with intravenous pamidronate or oral clodronate. However, large, randomised, multicentre trials using intravenous administration of the highly potent bisphosphonate zoledronic acid every 3-4 weeks have recently demonstrated a reduction of 20% in the risk of developing an SRE compared with pamidronate for patients with breast cancer. Moreover, these trials have demonstrated, for the first time, that a bisphosphonate significantly reduces the occurrence of skeletal events in hormone-refractory prostate cancer and in non-small cell lung cancer and a range of other solid tumours. Investigations into the potential of the relatively low potency bisphosphonate, clodronate, for the prevention of bone metastases in breast cancer have produced conflicting data. Further large, randomised studies with clodronate and zoledronic acid are planned and until the results are available it is not possible to identify a definite adjuvant role for bisphosphonates. Evidence is accumulating in vitro that bisphosphonates are also able to directly affect tumour cells, in addition to their effects on osteoclasts, with zoledronic acid being particularly potent. Over recent decades there has been a significant improvement in cure rates and survival times in certain cancers and the use of chemotherapy and hormone therapy has expanded greatly, leading to increasing numbers of long-term survivors who have received these treatments. Management of treatment-induced bone loss is therefore assuming a greater importance and bisphosphonates represent an attractive treatment option in such patients. Several placebo-controlled trials using oral clodronate, oral risedronate, intravenous pamidronate and intravenous zoledronic acid have all now demonstrated benefits in reducing the loss in bone mineral density.     

COPD and osteoporosis

Osteoporosis, with resulting fractures, is a significant problem in patients with advanced COPD. The etiology for the bone loss is diverse but includes smoking, vitamin D deficiency, low body mass index, hypogonadism, sedentary lifestyle, and use of glucocorticoids. Effective strategies to prevent bone loss and/or to treat osteoporosis include calcium and vitamin D, hormone replacement when indicated, calcitonin, and bisphosphonate administration. However, many patients remain undiagnosed until their first fracture because of the lack of recognition of the disease. With an increased awareness by pulmonologists and the increased use of preventive strategies, the impact of osteoporosis on those patients with COPD should decrease.     

Zoledronic acid protects against local and systemic bone loss in tumor necrosis factor-mediated arthritis

OBJECTIVE: Increased osteoclast activity is a key factor in bone loss in rheumatoid arthritis (RA). This suggests that osteoclast-targeted therapies could effectively prevent skeletal damage in patients with RA. Zoledronic acid (ZA) is one of the most potent agents for blocking osteoclast function. We therefore investigated whether ZA can inhibit the bone loss associated with chronic inflammatory conditions. METHODS: Human tumor necrosis factor (TNF)-transgenic (hTNFtg) mice, which develop severe destructive arthritis as well as osteoporosis, were treated with phosphate buffered saline, single or repeated doses of ZA, calcitonin, or anti-TNF, at the onset of arthritis. RESULTS: Synovial inflammation was not affected by ZA. In contrast, bone erosion was retarded by a single dose of ZA (-60%) and was almost completely blocked by repeated administration of ZA (-95%). Cartilage damage was partly inhibited, and synovial osteoclast counts were significantly reduced with ZA treatment. Systemic bone mass dramatically increased in hTNFtg mice after administration of ZA, which was attributable to an increase in trabecular number and connectivity. In addition, bone resorption parameters were significantly lowered after administration of ZA. Calcitonin had no effect on synovial inflammation, bone erosion, cartilage damage, or systemic bone mass. Anti-TNF entirely blocked synovial inflammation, bone erosion, synovial osteoclast formation, and cartilage damage but had only minor effects on systemic bone mass. CONCLUSION: ZA appears to be an effective tool for protecting bone from arthritic damage. In addition to their role in antiinflammatory drug therapy, modern bisphosphonates are promising candidates for maintaining joint integrity and reversing systemic bone loss in patients with arthritis.     

Down-regulation of rat kidney calcitonin receptors by salmon calcitonin infusion evidenced by autoradiography.

In treating age-related osteoporosis and Paget disease of bone, it is of major importance to avoid an escape phenomenon that would reduce effectiveness of the treatment. The factors involved in the loss of therapeutic efficacy with administration of large pharmacological doses of the hormone require special consideration. Down-regulation of the hormone receptors could account for the escape phenomenon. Specific binding sites for salmon calcitonin (sCT) were characterized and localized by autoradiography on rat kidney sections incubated with 125I-labeled sCT. Autoradiograms demonstrated a heterogenous distribution of 125I-labeled sCT binding sites in the kidney, with high densities in both the superficial layer of the cortex and the outer medulla. Infusion of different doses of unlabeled sCT by means of Alzet minipumps for 7 days produced rapid changes in plasma calcium, phosphate, and magnesium levels, which were no longer observed after 2 or 6 days of treatment. Besides, infusion of high doses of sCT induced down-regulation of renal sCT binding sites located mainly in the medulla, where calcitonin (CT) has been shown to exert its physiological effects on water and ion reabsorption. These data suggest that the resistance to high doses of sCT often observed during long-term treatment of patients may be the consequence of not only bone-cell desensitization but also down-regulation of CT-sensitive kidney receptor sites.     

Prevention of osteoporosis in cardiac transplant recipients

Osteoporosis is a leading cause of pretransplant and posttransplant morbidity. The need for early detection by measuring bone mineral density, even before transplant, must be emphasized. Preventive measures are not comparable. The use of calcium and vitamin D supplements, although recommended, is inadequate for the prevention of bone loss and complications such as vertebral fractures. Bisphosphonates have been shown to attenuate the bone loss and reduce fractures associated with steroid-induced osteoporosis. Small studies in transplant recipients suggest similar results. Other preventive measures such as hormone replacement therapy are also helpful. There are limited data on the administration of nasal calcitonin in transplant recipients.     

Calcitonin Therapy in Osteoporosis

Osteoporosis is the most prevalent metabolic bone disease and is characterized by diminished bone strength predisposing to an increased risk of fracture. Its incidence is particularly high in postmenopausal women but it can also affect other groups, such as men and patients receiving corticosteroid therapy. Calcitonin is a naturally occurring peptide which acts via specific receptors to strongly inhibit osteoclast function. It has been used in the treatment of osteoporosis for many years. Historically, calcitonin was administered as a parenteral injection, but the intranasal formulation is now the most widely used because of its improved tolerability. New approaches are currently being investigated to enhance the bioavailability and effects of calcitonin, including oral, pulmonary, and transdermal routes of administration, and novel allosteric activators of the calcitonin receptor. Several controlled trials have reported that calcitonin stabilizes and in some cases produces a short-term increase in bone density at the lumbar spine level. The most relevant clinical trial to evaluate the effect of calcitonin in the prevention of fractures was the Prevent Recurrence of Osteoporotic Fractures (PROOF) study, a 5-year double-blind, randomized, placebo-controlled trial showing that salmon calcitonin nasal spray at a dosage of 200 IU/day can reduce the risk of vertebral osteoporotic fractures by 33% (relative risk [RR] = 0.67; 95% CI 0.47, 0.97; p = 0.03). However, the 100 and 400 IU/day dosages did not significantly reduce vertebral fracture risk. Effects on nonvertebral fractures were not significant (RR = 0.80; 95% CI 0.59, 1.09; p = 0.16). There is mounting evidence to show that calcitonin diminishes bone pain in osteoporotic vertebral fractures, which may have clinical utility in vertebral crush fracture syndrome. A recent study suggests that nasal salmon calcitonin appears to be a promising therapeutic approach for the treatment of men with idiopathic osteoporosis, although long-term trials are necessary to confirm these results and evaluate fracture rate as an endpoint in men. The role of calcitonin in corticosteroid-induced osteoporosis remains controversial, hence it can only be considered a second-line agent for the treatment of patients with low bone mineral density who are receiving long-term corticosteroid therapy.     

Acute effects of calcitonin on bone formation in man

Intravenous administration of porcine calcitonin or salmon calcitonin to a normal subject or to patients with Paget's disease of bone produces a marked decrease in the urinary excretion of hydroxyproline-containing peptides. The excretion of both polypeptides (retentate after dialysis) and oligopeptides (diffusate after dialysis) decreases after calcitonin. Since it has been shown previously in patients with Paget's disease that the retentate hydroxyproline reflects predominantly (bone) collagen synthesis, it is likely that bone collagen synthesis decreases acutely, accompanying the decrease in degradation of bone produced by calcitonin.     

Antiresorptive treatment of postmenopausal osteoporosis: comparison of study designs and outcomes in large clinical trials with fracture as an endpoint

Antiresorptive treatments for postmenopausal osteoporosis have been studied extensively, but due to the volume of published data and lack of head-to-head trials, it is difficult to evaluate and compare their fracture reduction efficacy. The objective of this review is to summarize the results from clinical trials that have fracture as an endpoint and to discuss the factors in study design and populations that can affect the interpretation of the results. Although there are numerous observational studies suggesting that estrogen and hormone replacement therapies may reduce the risk of vertebral and nonvertebral fractures, there is no large, prospective, randomized, placebo-controlled, double-blind clinical trial demonstrating fracture efficacy. The effects of raloxifene, alendronate, risedronate, and salmon calcitonin on increasing bone mineral density (BMD) and decreasing fracture risk have been shown in randomized, placebo-controlled, double-blind clinical trials of postmenopausal women with osteoporosis. Although the increases in lumbar spine BMD vary greatly in these trials, the decrease in relative risk of vertebral fractures is similar among therapies. However, nonvertebral fracture efficacy has not been consistently demonstrated. Combined administration of two antiresorptive therapies results in greater BMD increases, but the effects on fracture risk are unknown. Direct comparisons of clinical trial results should be considered carefully, given the differences in study design and populations. Differences in study design that may influence the efficacy of fracture risk reduction include calcium and vitamin D supplementation, primary fracture endpoints, definition of vertebral deformity or fracture, discontinuation rates, and statistical power. Factors in the study population that may influence fracture efficacy include the age of the population and the proportion of subjects with prevalent fractures. The use of surrogate endpoints such as BMD to predict fracture risk should be approached with caution, as the relationship between BMD changes and fracture risk reduction with antiresorptive therapies is uncertain. Consideration of these results from clinical trials can contribute to clinical judgment in selecting the best treatment option for postmenopausal osteoporosis.     

Bone metabolism alterations after kidney transplantation

Early after renal transplantation (RT) a rapid decrease in bone mineral density at the lumbar spine, femoral neck, and femoral shaft has been documented. In addition, an appreciable proportion of patients still remain losing bone late after RT. As a consequence, RT patients are at a high risk of bone fractures as compared to general population. Most fractures involve appendicular skeleton, particularly the feet and ankles, and the diabetic patient is at increased risk of fractures. Thus, early institution of preventive measures and treatment of established osteoporosis are central. The major cause of post-transplantation bone loss is corticosteroid treatment, and this should be used at the lower dose compatible with graft survival. Preexisting hyperparathyroidism also affects the early cancellous bone loss at the spine, and post-transplantation bone loss reflects variable individual susceptibility, resembling the polygenic determination of bone mineral density in general. Clinical trials have demonstrated that bisphosphonates or vitamin D plus calcium supplementation, prevent post-transplantation bone loss during the first 6-12 months. However, their role in preventing bone fractures has not been proven. Finally, recommendations for management, prevention and treatment, are summarized.     

Vitamin K2 as a protector of bone health and beyond

Several lives of evidence indicate a protective effect of vitamin K against osteoporosis. Epidemiological studies showed that low vitamin K intake is associated with the increased risk of osteoporosis. Vitamin K2 (menatetrenone, MK-4) has been clinically used in the treatment of patients with osteoporosis in Japan, Korea and Thailand. Previous studies demonstrated the efficacy of vitamin K2 (45 mg/day) to prevent bone loss and reduce the rate of vertebral fractures, although a large, randomized intervention study is anticipated to provide more detailed evidence. Recently, vitamin K2 has been shown to reduce the progression of hepatocarcinoma. Moreover, it has been proposed that vitamin K may also have beneficial effects to prevent atherogenesis. The clarification of molecular mechanisms by which vitamin K2 exerts these salutary effects deserve further investigations.     

Use of Bone Turnover Markers in Osteoporosis

Bone metabolism can be assessed by measuring bone turnover markers in serum or urine. Bone turnover markers are substances released from bone during bone turnover. They can be skeletal tissue proteins, collagen fragments, peptides, or enzymes released from bone cells. Bone turnover markers are extensively used in research applications but also as tools for the management of skeletal disorders in clinical practice. Osteoporosis-related applications may include assessment of response to, or deciding on osteoporosis therapy; identification of individuals with increased bone loss, and prediction of risk for fragility fractures. Advancements in the development of assays to measure bone markers has made the measurements available also for clinical practice. The possibility to use them in various aspects of clinical practice has been tested in the recent years and given promising results. Monitoring the efficacy of bone-active drugs is currently the most promising application for bone turnover markers. Some markers, particularly resorption markers may also be useful in identifying individuals who are at high risk for bone loss and future fracture. In this article we discuss some potential applications of currently available bone turnover markers in postmenopausal osteoporosis.     

Management of metabolic bone disease in kidney transplant recipients

Bone disease after kidney transplantation has a complex pathophysiology and heterogeneous histology. Pre-existing renal osteodystrophy may not resolve completely, but continue or evolve into a different osteodystrophy. Rapid bone loss immediately after transplant can persist, at a lower rate, for years to come. These greatly increase the risk of bone fracture and vertebral collapse. Hypovitaminosis D, hyperparathyroidism and hyperaluminemia may resolve after kidney transplant, but many patients have other risk factors of bone loss, such as steroids usage, hypogonadism, persistent hyperparathyroidism, poor allograft function, aging, and chronic diseases. Clinical management requires a comprehensive approach to address the underlying and ongoing disease processes. Successful prevention of bone loss has been shown with vitamin D analogues, bisphosphonates and calcitonin. Novel approaches to restore the normal bone remodeling and improve the bone quality may be needed in order to effectively decrease bone fractures in kidney transplant recipients.     

Management of Paget's disease of bone

Paget's disease of bone is a common condition with a strong genetic component, characterized by focal increases in bone turnover, affecting one or more bones throughout the skeleton. Paget's disease can be asymptomatic but is frequently associated with bone pain, bone deformity, pathological fracture, secondary osteoarthritis and deafness. Inhibitors of osteoclastic bone resorption, such as bisphosphonates and calcitonin, suppress bone turnover and improve bone pain in Paget's disease. Many patients also require therapy with analgesics and anti-inflammatory agents, since pain in Paget's disease can arise not only from increased bone turnover but also from complications such as osteoarthritis and nerve compression syndromes, which do not respond well to antiresorptive therapy. Comparative studies have shown that second- and third-generation bisphosphonates, such as tiludronate, alendronate and risedronate, are more effective than etidronate at inhibiting bone turnover in Paget's disease but they have not been found to be significantly more effective in controlling bone pain. Importantly, none of the treatments that are currently available for Paget's disease have been shown to prevent complications such as deafness, fracture or bone deformity, or to alter the natural history of the disease. More research is required to define the long-term effects of antiresorptive treatment on clinical outcomes in Paget's disease, so that clinicians and their patients can make better-informed choices about the risks and benefits of treatment.     

Glucocorticoid-induced osteoporosis: mechanisms for bone loss; evaluation of strategies for prevention

Osteoporosis is a common complication of chronic glucocorticoid therapy, especially in older patients who already are at risk of having a reduced bone mass. Glucocorticoids cause bone loss by altering the bone remodeling sequence: bone resorption by osteoclasts is increased, and bone formation by osteoblasts is decreased. Serum levels of osteocalcin, a protein made by osteoblasts, are decreased with glucocorticoid therapy, further evidence of decreased osteoblast function. Glucocorticoids decrease calcium absorption by the gastrointestinal tract and increase renal calcium excretion. Several recent studies suggest that low-dose glucocorticoid therapy is not associated with bone loss. Calcium supplementation with vitamin D is recommended. Several short-term studies have shown prevention of glucocorticoid-induced bone loss with bisphosphonates, calcitonin, and progesterone. Long-term clinical trials should be undertaken to determine strategies to prevent this type of osteoporosis.     

Selection of antiresorptive or anabolic treatments for postmenopausal osteoporosis

Osteoporosis is a common, chronic disease that can be treated effectively by pharmacological interventions. Antiosteoporotic drugs reduce fracture risk via different mechanisms of action. Available therapies are broadly distinguished into inhibitors of bone turnover, stimulators of bone formation, and therapies with as-yet unclear mechanisms of action. No direct comparison studies with fracture end points have yet been done, which makes selection of one drug over another difficult. Identification of individuals who might derive particular benefit from a specific therapy has been explored in post-hoc analyses of clinical studies with bisphosphonates and recombinant parathyroid hormone (PTH). Their findings showed that the efficacy of these therapies in reducing fracture risk was largely independent of the prevalent rates of bone turnover. Selection of a specific antiosteoporotic therapy should, therefore, be made according to the results of trials specifically designed to assess fracture risk, safety, tolerability, patient preference and cost-effectiveness rather than on characteristics specific to patients or the disease. Studies of sequential administration of PTH and bisphosphonates suggest advantages over single-therapy regimens, particularly in patients with severe disease. However, the optimum duration of PTH administration, as well as the efficacy of such regimens in reducing the risk of fractures, remain to be determined.     

Treatment of Paget's Disease with the Calcitonins*

Summary: Calcitonin has been used in the treatment of Paget's Disease of bone because of its ability to inhibit osteoclastic bone resorption. This results in a return of bone turnover towards normal, as reflected by urinary hydroxyproline and serum alkaline phosphatase. A plateau is reached with these parameters, at about 50% of the pre-treatment level. The cause of this plateau is unknown, but does not indicate resistance to treatment, since it occurs with all forms of calcitonin. Most treated patients experience pain relief, and there is radiological and histological evidence of arrested progression of Paget's Disease in patients treated with calcitonin. Both primary and secondary resistance to calcitonin occur with all calcitonins, including homologous hormone. Antibodies develop commonly in patients treated with pig or salmon calcitonin, but antibody-based clinical resistance has been demonstrated only in a few patients. Methods of selection of patients for treatment and of assessment of response are discussed, and treatment schedules summarized.