Pharmacologic Treatment of Low Bone Density or Osteoporosis to Prevent Fractures: A Clinical Practice Guideline from the American College of Physicians

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	Qaseem, A.

CLINICAL GUIDELINES

Pharmacologic Treatment of Low Bone Density or Osteoporosis to Prevent Fractures: A Clinical Practice Guideline from the American College of Physicians

Amir Qaseem, MD, PhD, MHA; Vincenza Snow, MD; Paul Shekelle, MD, PhD; Robert Hopkins, Jr., MD; Mary Ann Forciea, MD; and Douglas K. Owens, MD, MS, for the Clinical Efficacy Assessment Subcommittee of the American College of Physicians^*

16 September 2008 | Volume 149 Issue 6 | Pages 404-415

Description: The American College of Physicians (ACP) developedthis guideline to present the available evidence on variouspharmacologic treatments to prevent fractures in men and womenwith low bone density or osteoporosis.

Methods: Published literature on this topic was identifiedby using MEDLINE (1966 to December 2006), the ACP Journal Clubdatabase, the Cochrane Central Register of Controlled Trials(no date limits), the Cochrane Database of Systematic Reviews(no date limits), Web sites of the United Kingdom National Instituteof Health and Clinical Excellence (no date limits), and theUnited Kingdom Health Technology Assessment Program (January1998 to December 2006). Searches were limited to English-languagepublications and human studies. Keywords for search includedterms for osteoporosis, osteopenia, low bone density, and thedrugs listed in the key questions. This guideline grades theevidence and recommendations according to the ACP's clinicalpractice guidelines grading system.

Recommendation 1: ACP recommends that clinicians offer pharmacologictreatment to men and women who have known osteoporosis and tothose who have experienced fragility fractures (Grade: strongrecommendation; high-quality evidence).

Recommendation 2: ACP recommends that clinicians consider pharmacologictreatment for men and women who are at risk for developing osteoporosis(Grade: weak recommendation; moderate-quality evidence).

Recommendation 3: ACP recommends that clinicians choose amongpharmacologic treatment options for osteoporosis in men andwomen on the basis of an assessment of risk and benefits inindividual patients (Grade: strong recommendation; moderate-qualityevidence).

Recommendation 4: ACP recommends further research to evaluatetreatment of osteoporosis in men and women.

The National Institutes of Health's consensus conference (1)defined osteoporosis as "a skeletal disorder characterized bycompromised bone strength predisposing to an increased riskfor fracture. Bone strength reflects the integration of twomain features: bone density and bone quality....Bone qualityrefers to architecture, turnover, damage accumulation (e.g.,microfractures), and mineralization." Although osteoporosiscan affect any bone, the hip, spine, and wrist are most likelyto be affected. Osteoporosis affects an estimated 44 millionAmericans or 55% of people 50 years of age or older. Another34 million Americans are estimated to have low bone mass, meaningthat they are at an increased risk for osteoporosis.

Osteoporosis can be diagnosed by the occurrence of fragilityfracture. In patients without fragility fracture, osteoporosisis often diagnosed by low bone density. Dual x-ray absorptiometry(DXA) is the current gold standard test for diagnosing osteoporosisin people without an osteoporotic fracture. Dual x-ray absorptiometryresults are scored as standard deviations (SDs) from a younghealthy norm (usually female) and reported as T-scores. Forexample, a T-score of –2 indicates a bone mineral densitythat is 2 SDs below the comparative norm. The internationalreference standard for the description of osteoporosis in postmenopausalwomen and in men age 50 years or older is a femoral neck bonemineral density of 2.5 SD or more below the young female adultmean (2). Low bone density, as measured by DXA, is an imperfectpredictor of fracture risk, identifying fewer than half thepeople who go on to have an osteoporotic fracture. Screeningguidelines for women are well established (3), and the AmericanCollege of Physicians (ACP) recently published guidelines onscreening for men (4).

This guideline presents the available evidence on various pharmacologictreatments to prevent fractures in men and women with low bonedensity or osteoporosis. Medications used to treat osteoporosismay affect different parts of the skeletal system differently,and efficacy for vertebral fractures does not necessarily implyefficacy for nonvertebral fractures. The target audience forthis guideline is all clinicians and the target patient populationis all adult men and women with low bone density or osteoporosis.These recommendations are based on the systematic evidence reviewby MacLean and colleagues (5) and the Agency for HealthcareResearch and Quality–sponsored Southern California Evidence-BasedPractice Center evidence report (6).

The drugs currently approved for prevention of osteoporosisinclude alendronate, ibandronate, risedronate, zoledronic acid,estrogen, and raloxifene. The drugs currently approved for treatmentof osteoporosis include alendronate, ibandronate, risedronate,calcitonin, teriparatide, zoledronic acid (in postmenopausalwomen), and raloxifene. Testosterone, pamidronate, and etidronateare not approved by the U.S. Food and Drug Administration forthe treatment or prevention of osteoporosis.

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The literature search done by MacLean and colleagues for thesystematic review (5) included studies from MEDLINE (1966 toDecember 2006), the ACP Journal Club database, the CochraneCentral Register of Controlled Trials (no date limits), theCochrane Database of Systematic Reviews (no date limits), Websites of the United Kingdom National Institute of Health andClinical Excellence (no date limits), and the United KingdomHealth Technology Assessment Program (January 1998 to December2006). The reviewers limited their search to English-languagepublications and human studies. They derived evidence for comparativebenefits of various treatments exclusively from randomized,controlled trials, whereas they included evidence from othertypes of studies for short- and long-term harms.

Two physicians independently abstracted data about study populations,interventions, follow-up, and outcome ascertainment by usinga structured form. For each group within a randomized trial,a statistician extracted the sample size and number of personsreporting fractures. Two reviewers, under the supervision ofthe statistician, independently abstracted information aboutadverse events. The statistician or the principal investigatorresolved disagreements.

This guideline is based on an evaluation of 76 randomized, controlledtrials, 4 of which were identified in the updated search, and24 meta-analyses that were included in the efficacy analyses.The analyses of adverse events included 491 articles, representing417 randomized trials, 25 other controlled clinical trials,11 open-label trials, 31 large observational studies, and 9case reports of osteonecrosis among bisphosphonate users. MacLeanand colleagues' background article (5) includes details aboutthe methods used for the systematic evidence review.

The ACP rates the evidence and recommendations by using theGrading of Recommendations, Assessment, Development, and Evaluation(GRADE) system with minor modifications (Table 1). In addition,the evidence reviewers used predefined criteria to assess thequality of systematic reviews and randomized trials, based oninternal and external validity assessments detailed in the Qualityof Reporting of Meta-Analyses (QUOROM) statement (7).

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Table 1. The American College of Physicians' Guideline Grading System

The objective of this guideline is to synthesize the evidencefor the following questions:

What are the comparative benefits in fracture reduction amongand also within the following treatments for low bone density:bisphosphonates, specifically alendronate, risedronate, etidronate,ibandronate, pamidronate, and zoledronic acid; calcitonin; estrogenfor women; teriparatide; selective estrogen receptor modulators(SERMs), specifically raloxifene and tamoxifen; testosteronefor men; vitamins and minerals, specifically vitamin D and calcium;and the combination of calcium plus vitamin D?
How does fracturereduction resulting from treatments vary amongindividuals withdifferent risks for fracture as determinedby bone mineral density(borderline, low, or severe), previousfractures (preventionvs. treatment), age, sex, glucocorticoiduse, and other factors(such as community-dwelling vs. institutionalizedor vitaminD–deficient vs. not)?
What are the short- and long-termharms (adverse effects) ofthese therapies, and do these varyby specific subpopulations?

Comparative Benefits of Drugs versus Placebo in Fracture Reduction

Evidence from 24 meta-analyses (8–30) and 35 additionalrandomized trials published after the meta-analyses (31–65)described the effect of 9 of the 14 agents (alendronate, etidronate,risedronate, calcitonin, estrogen, teriparatide, raloxifene,calcium, and vitamin D) on fracture incidence. For 4 agents(ibandronate, pamidronate, zoledronic acid, and tamoxifen),the reviewers found no meta-analyses and instead gathered theevidence from 14 randomized trials (66–79). No studieswere found that reported fracture rates for testosterone. Threerandomized trials (35, 80, 81) and 1 meta-analysis (82) evaluatedthe combination of calcium plus vitamin D on fractures.

Bisphosphonates

Good-quality evidence showed that alendronate, etidronate, ibandronate,and risedronate prevent vertebral fractures. In addition, evidencefrom good-quality studies demonstrated that both alendronateand risedronate prevent nonvertebral and hip fractures. Twolarge randomized trials showed that zoledronic acid preventsvertebral and nonvertebral fractures in high-risk populationsand reduces the risk for hip fracture (67, 74). Ibandronatehas not been shown to reduce nonvertebral fractures (68). Ofthe 6 fairly small trials that looked at vertebral fractures,1 demonstrated a statistically significant reduction in fractureswith pamidronate relative to placebo (0.14 [95% CI, 0.03 to0.72]) (73). However, after these data were pooled, the pooledrisk estimate for fractures for pamidronate relative to placebowas not significant (0.52 [CI, 0.21 to 1.24]) (6).

Calcitonin

Fair-quality evidence shows that calcitonin reduces vertebralfractures (83, 84). Good-quality evidence indicates that calcitonindoes not reduce nonvertebral fractures (13, 16).

Estrogen

Good-quality evidence shows that estrogen reduces the incidenceof vertebral (29, 85), nonvertebral (86), and hip fractures(85).

Teriparatide

Good-quality evidence shows that teriparatide prevents vertebralfractures. The evidence related to teriparatide preventing nonvertebralfractures is mixed; 1 large randomized trial showed a reductionin nonvertebral fractures (34) but 2 small trials did not (87, 88).

SERMs

Good-quality evidence shows that raloxifene prevents vertebralfractures, but that tamoxifen has no effect on vertebral fractures(89–91). In addition, both raloxifene and tamoxifen hadno effect on hip fractures (91). Tamoxifen is not approved bythe U.S. Food and Drug Administration for the treatment or preventionof osteoporosis.

Testosterone

No studies reported fracture rates for testosterone.

Calcium and Vitamin D

In the studies evaluated by MacLean and colleagues (5), theevidence for the effect of calcium alone on reduction of fracturesis complex. Most studies of pharmacologic agents for osteoporosisinclude calcium and vitamin D as part of the treatment regimen.Evidence from 1 meta-analysis (27) and several randomized trials(35, 48, 51, 92) showed no significant difference between calciumand placebo in preventing vertebral, nonvertebral, and hip fracturesin postmenopausal women. However, nonadherence to therapy mayinfluence this result, and 1 trial with a prespecified analysisof adherent patients found a reduction in fracture risk (48).A recent meta-analysis (82) concluded that the relative risk(RR) for fracture with calcium alone was 0.90 (CI, 0.80 to 1.00),but it did not include a modestly large trial with negativeresults (35).

MacLean and colleagues (5) included 5 systematic reviews thatevaluated vitamin D. Four meta-analyses (8, 21, 24, 28) foundthat standard vitamin D (D₂, D₃, or 25-hydroxyvitamin [25(OH)]D)did not have any effect on risk for vertebral, nonvertebral,or hip fractures; a fifth (35) showed a statistically significantreduction in the pooled risk for nonvertebral and hip fracturesfor vitamin D₂ or D₃. In addition, MacLean and colleagues identified3 meta-analyses (21, 23, 24) that showed that vitamin D analogues[1,25(OH)D and 1(OH)D] significantly reduced the risk for vertebral,nonvertebral, and hip fractures. A meta-analysis published afterMacLean and colleagues' review concluded that vitamin D andcalcium reduced fractures by 13% (RR, 0.87 [CI, 0.77 to 0.97])(82).

In summary, for evaluating the comparative benefits of drugsversus placebo in fracture reduction, good-quality evidenceshows that alendronate, etidronate, ibandronate, risedronate,calcitonin, teriparatide, and raloxifene prevent vertebral fractures.The reviewers also found good-quality evidence that alendronateand risedronate prevent nonvertebral and hip fractures. No clearevidence demonstrates the appropriate duration of treatmentwith bisphosphonates; however, bisphosphonate trials rangedfrom 3 months to 60 months. Good evidence shows that estrogenreduced the incidence of vertebral, nonvertebral, and hip fractures.The effect of calcium alone is less certain. Systematic reviewsof the effectiveness of vitamin D and calcium have reached differentconclusions, with the most recent systematic review (82) findinga modest reduction in fracture risk.

Comparative Benefits of Drugs within and among Classes in Fracture Reduction

Evidence from 9 randomized trials comparing different bisphosphonates(41, 93–100), 1 study comparing different SERMs (101),and 16 studies with head-to-head comparisons of agents fromdifferent classes (31, 32, 35, 37, 42, 50, 64, 98, 100, 102–108)evaluated intermediate outcomes, such as bone mineral densityand changes in markers of bone turnover. These studies weretoo short to detect clinically important differences in fractureincidence. The 2 head-to-head trials that compared fractureincidence outcomes (risedronate vs. etidronate [97] and raloxifenevs. alendronate [107]) were underpowered and showed no statisticallysignificant differences.

In summary, evidence is insufficient to determine whether onebisphosphonate is superior to another, with the exception thatibandronate did not reduce nonvertebral fractures in a relativelylarge trial (68). Little evidence comparing drugs from differentclasses is available.

Benefits of Drugs in Different Risk Groups for Fracture Reduction

Low-Risk Populations

We defined "low risk" as a 10-year risk for osteoporotic fracture(vertebral, nonvertebral, or hip) of up to 2% and a lifetimerisk of up to 21%. The reviewers gathered evidence from 4 meta-analyses(14, 15, 28, 107). Summary estimates for alendronate showeda statistically nonsignificant reduction in the risk for vertebralfracture (RR, 0.45 [CI, 0.06 to 3.15]) and nonvertebral fracture(RR, 0.79 [CI, 0.28 to 2.24]) (15). Estrogen did not reducethe risk for vertebral fracture (28) but reduced nonvertebralfractures (28, 109). However, raloxifene and vitamin D did reducethe risk for vertebral fractures (raloxifene RR, 0.53 [CI, 0.35to 0.79]; vitamin D RR, 0.86 [CI, 0.72 to 1.02]) (28). Evidencefrom 2 randomized trials did not show any difference betweenraloxifene and tamoxifen for reducing fractures (63, 101).

Special Populations

Men

Studies showed that risedronate decreased the risk for hip fractures(RR, 0.25 [CI, 0.08 to 0.78]) (56), calcitonin decreased therisk for vertebral fractures (RR, 0.09 [CI, 0.01 to 0.96]) (61),and teriparatide decreased the risk for total fractures (RR,0.16 [CI, 0.01 to 0.96]) and possibly the risk for vertebralfractures (odds ratio [OR], 0.44 [CI, 0.18 to 1.09]) (44). Evidenceis insufficient to evaluate the effect of calcium alone in men(35).

Populations at Increased Risk for Falls

Populations studied included patients with stroke and hemiplegia,Alzheimer disease, a recent hip fracture, or Parkinson disease.Zoledronic acid reduced the risk for vertebral fractures (hazardratio, 0.54 [CI, 0.32 to 0.92]) and nonvertebral fractures (hazardratio, 0.73 [CI, 0.55 to 0.98]) in patients with a recent hipfracture (74). In patients with Alzheimer disease, risedronatereduced the risk for nonvertebral fracture (RR, 0.29 [CI, 0.15to 0.57]) (53) and hip fracture (RR, 0.29 [CI, 0.13 to 0.66])(58). Risedronate also reduced the risk for hip fracture inpatients with stroke (RR, 0.22 [CI, 0.05 to 0.88]) and hemiparesis(RR, 0.25 [CI, 0.08 to 0.78]) (55, 56). In patients with Parkinsondisease, alendronate (RR, 0.30 [CI, 0.12 to 0.78]) reduced therisk for hip fracture (57). Vitamin D also reduced the riskfor hip fracture in patients with stroke and hemiparesis (RR,0.12 [CI, 0.02 to 0.90]).

Populations with Renal Insufficiency

One trial (110) showed that alendronate reduced the risk forfractures to a similar degree in patients with and those withoutreduced renal function.

Populations with Long-Term Glucocorticoid Use

Evidence from 3 studies included in a systematic review (111)showed a possible reduction in vertebral fracture rate withbisphosphonate treatment (112–114). Six additional trialshave been published since this systematic review. Three of theserandomized trials (115–117) showed that bisphosphonatesreduced the fracture rate. Results from 2 studies also showedthat risedronate treatment led to a statistically significantreduction in the absolute risk (11%) and RR (70%) of incidentradiographic vertebral fractures after 1 year (117) and in vertebralfractures (116). In another trial (115), alendronate was associatedwith a reduction in the risk for incident radiographic vertebralfractures. However, 3 additional trials showed no significanteffect on fracture risk for etidronate (32, 53), from calcium(32), between calcium and a combination of etidronate and calcium(32), or between calcium and pamidronate (103).

To summarize the overall fracture reduction benefits of drugtreatments in special populations in different risk groups,a SERM (raloxifene) and vitamin D both reduced the risk forvertebral fracture in low-risk patients. Far fewer men thanwomen have been included in these trials, resulting in lessevidence about the effectiveness of treatment in men. In men,risedronate decreased hip fractures and calcitonin decreasedvertebral fractures. Teriparatide decreased total fracturesand possibly vertebral fractures. In patients with a previouship fracture, zoledronic acid reduced the risk for vertebraland nonvertebral fractures. Risedronate reduced the hip andnonvertebral fracture risk among patients with Alzheimer disease.Bisphosphonates (risedronate and alendronate) also reduced theclinical and radiographic fracture rate in patients receivingglucocorticoids.

Adverse Effects of Drugs

Bisphosphonates

The most common adverse effects of bisphosphonates are gastrointestinal.Trials reported esophageal ulcerations from all bisphosphonatesexcept zoledronic acid. One trial of etidronate versus placeboshowed a statistically significant increase in esophageal ulceration(OR, 1.33 [CI, 1.05 to 1.68]) (118). Mild upper gastrointestinalevents (acid reflux, esophageal irritation, nausea, vomiting,and heartburn) were more common with etidronate in a pooledanalysis (OR, 1.33 [CI, 1.21 to 1.46]) (32, 42, 53, 54, 64, 112, 118–128)and with pamidronate (OR, 3.14 [CI, 1.93 to 5.21]) (75, 79, 129–133).Pooled analysis showed no difference in occurrence of mild uppergastrointestinal events between alendronate, ibandronate, risedronate,or zoledronic acid and placebo. However, pooled analysis ofhead-to-head trials showed a higher risk for mild upper gastrointestinalevents with alendronate than with etidronate (OR, 5.89 [CI,1.61 to 32.7]), calcitonin (OR, 3.42 [CI, 1.79 to 7.00]), orestrogen (OR, 1.57 [CI, 1.00 to 2.46]). The pooled estimatefrom 3 studies showed that etidronate users were at increasedrisk for perforations, ulcerations, and gastrointestinal bleedingevents (OR, 1.32 [CI, 1.04 to 1.67]) (59, 118, 134), whereasthe pooled estimate from 2 studies showed that ibandronate hada lower risk for serious gastrointestinal adverse events (OR,0.33 [CI, 0.14 to 0.74]) (68, 135). Case reports and case serieshave documented increased osteonecrosis of the jaw in patientsreceiving bisphosphonates, but the most cases of osteonecrosishave occurred in patients with cancer who received high dosesof intravenous bisphosphonates (136). However, we could notcalculate the risk for this event from the available studies.Some studies showed a link between atrial fibrillation and eitherzoledronic acid or alendronate (5, 137).

Calcitonin

Evidence from randomized trials showed no clinically importantserious adverse events associated with the use of calcitonin.

Estrogen

Estrogen was associated with an increased risk for thromboembolicevents versus placebo in pooled results from 4 studies (OR,1.36 [CI, 1.01 to 1.86]) (37, 85, 138, 139). In addition, pooledresults for estrogen–progestin also showed a higher riskfor thromboembolic events versus placebo (OR, 2.27 [CI, 1.72to 3.02]) (52, 140, 141). Pooled odds of stroke were increasedwith estrogen (OR, 1.28 [CI, 1.05 to 1.57]) (83, 138, 139) andcombined estrogen–progestin (OR, 1.28 [CI, 1.05 to 1.57])relative to placebo (52, 140). Women who received estrogen hada lower pooled risk for breast cancer than those who receivedplacebo (OR, 0.79 [CI, 0.66 to 0.93]) (83, 138, 142–144).However, pooled analysis showed that women who received an estrogen–progestincombination had an increased risk for breast cancer (OR, 1.28[CI, 1.03 to 1.60]) (52, 131, 140). One study showed a lowerrisk for colon cancer among women who received an estrogen–progestincombination (OR, 0.64 [CI, 0.43 to 0.95]) (85).

Teriparatide

Evidence from randomized trials showed no clinically importantserious adverse events associated with the use of teriparatide.

SERMs

Raloxifene increased the pooled risk for pulmonary embolism(OR, 6.26 [CI, 1.55 to 54.80]) (145, 146). In addition, pooledresults showed that raloxifene increased the risk for thromboembolicevents (OR, 2.08 [CI, 1.47 to 3.02) (145, 147–152) andmild cardiac events, including chest pain, palpitations, tachycardia,and vasodilatation (OR, 1.53 [CI, 1.01 to 2.35]) (147, 149, 152–155).

Testosterone

No trials of testosterone reported adverse events; however,testosterone has well-known side effects.

Calcium and Vitamin D

Evidence from randomized trials showed no clinically importantserious adverse events associated with the use of calcium andvitamin D.

To summarize the adverse effects of drugs, estrogen increasedthe risk for stroke and thromboembolic events; estrogen–progestinincreased the risk for stroke and breast cancer; and raloxifeneincreased the risk for pulmonary embolism, thromboembolic events,and mild cardiac events. Etidronate was associated with increasedrisk for esophageal ulcerations and, in addition to mild uppergastrointestinal events, increased the risk for perforations,ulcerations, and bleeding events. Alendronate was associatedwith a higher risk for mild upper gastrointestinal events thanwere etidronate, calcitonin, and estrogen.

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Good evidence shows that bisphosphonates (alendronate, etidronate,and risedronate) reduce the risk for vertebral, nonvertebral,and hip fractures. Ibandronate reduces vertebral fractures.No clear evidence indicates the appropriate duration of treatmentwith bisphosphonates; however, bisphosphonate trials rangedfrom 3 months to 60 months. Estrogen reduces the risk for vertebral,nonvertebral, and hip fractures. Whereas evidence for fracturerisk reduction from calcium alone is less clear, it is strongerfor vitamin D and calcium in combination (82). Evidence showeda statistically significant reduction in the risk for vertebralfractures from vitamin D analogues [1,25(OH)D and 1(OH)D] butmixed results for nonvertebral and hip fractures.

Oral bisphosphonates increase the risk for such gastrointestinaladverse events as acid reflux. However, pooled analyses showedno differences in occurrence of mild upper gastrointestinalevents among alendronate, ibandronate, risedronate, or zoledronicacid versus placebo; however, pooled analyses of 18 trials ofetidronate versus placebo indicated an increased risk for mildgastrointestinal events. The evidence linking zoledronic acidinfusion with atrial fibrillation is contradictory. Raloxifeneincreased the pooled risk for pulmonary embolism and thromboembolicevents. Estrogen was linked to an increased risk for cerebrovascularand thromboembolic events.

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Recommendation 1: ACP recommends that clinicians offer pharmacologictreatment to men and women who have known osteoporosis and tothose who have experienced fragility fractures (Grade: strongrecommendation; high-quality evidence).

Good evidence supports the treatment of patients who have osteoporosisto prevent further loss of bone and to reduce the risk for initialor subsequent fracture. Randomized, controlled trials offergood evidence that, compared with placebo, alendronate, ibandronate,risedronate, calcitonin, teriparatide, and raloxifene preventvertebral fractures. Evidence is also good that teriparatideprevents nonvertebral fractures compared with placebo and thatrisedronate and alendronate prevent both nonvertebral and hipfractures compared with placebo. Estrogen has been shown tobe associated with reduced vertebral, nonvertebral, and hipfractures. The evidence on use of calcium with or without vitaminD is mixed, and the effectiveness is modest. Because most trialsof other pharmacologic therapy included their use, we recommendadding calcium and vitamin D to osteoporosis treatment regimens.Evidence is insufficient to determine the appropriate durationof therapy.

Recommendation 2: ACP recommends that clinicians consider pharmacologictreatment for men and women who are at risk for developing osteoporosis(Grade: weak recommendation; moderate-quality evidence).

Evidence supports the treatment of selected patients who areat risk for osteoporosis but who do not have a T-score on DXAless than –2.5. Evidence supporting preventive treatmentis stronger for patients who are at moderate risk for osteoporosis,which includes patients who have a T-score from –1.5 to–2.5, are receiving glucocorticoids, or are older than62 years of age.

Factors that increase the risk for osteoporosis in men includeage (>70 years), low body weight (body mass index <20to 25 kg/m²), weight loss (>10% [compared with the usualyoung or adult weight or weight loss in recent years]), physicalinactivity (no physical activities performed regularly, suchas walking, climbing stairs, carrying weights, housework, orgardening), corticosteroid use, and androgen deprivation therapy(4). Risk factors for women include lower body weight, the singlebest predictor of low bone mineral density; smoking; weightloss; family history; decreased physical activity; alcohol orcaffeine use; and low calcium and vitamin D intake (3). In certaincircumstances, a single risk factor (for example, androgen deprivationtherapy in men) is enough for clinicians to consider pharmacologictreatment.

Research groups are developing calculators, such as the WorldHealth Organization's Fracture Risk Assessment Tool (availableat http://www.shef.ac.uk/FRAX/), to predict the risk for osteoporoticfracture. Such tools will help guide both clinician and patientdecisions.

Recommendation 3: ACP recommends that clinicians choose amongpharmacologic treatment options for osteoporosis in men andwomen on the basis of an assessment of the risk and benefitsto individual patients (Grade: strong recommendation; moderate-qualityevidence).

We recommend that the choice of therapy for patients who arecandidates for pharmacologic treatment be guided by judgmentof the risks, benefits, and adverse effects of drug optionsfor each individual patient. Table 2 summarizes the benefitsand harms of pharmacologic agents for fracture risk. Becausegood-quality evidence shows that bisphosphonates reduce therisk for vertebral, nonvertebral, and hip fractures, they arereasonable options to consider as first-line therapy, particularlyfor patients who have a high risk for hip fracture. Evidencefrom head-to-head trials is insufficient to demonstrate thesuperiority of one bisphosphonate over another. Alendronateand risedronate have been studied more than other bisphosphonates(Table 2). Ibandronate has not been shown to reduce nonvertebralor hip fractures, which may be an important consideration forsome patients. In a recent trial, zoledronic acid administeredto patients with a recent hip fracture reduced subsequent fractureand improved survival (74). Of the other agents available fortreatment of osteoporosis, estrogen has efficacy for vertebral,nonvertebral, and hip fractures but is associated with otherserious risks; calcitonin has not been demonstrated to reducenonvertebral and hip fractures; and calcium and vitamin D arepart of the treatment regimen in most studies of pharmacologicagents for osteoporosis.

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Table 2. Summary of Evidence about Drugs and Fracture Risk

Gastrointestinal events are the most common adverse effectsassociated with bisphosphonate therapy. No evidence was foundthat bisphosphonates, calcium, vitamin D, calcitonin, or teriparatidediffer regarding risk for serious cardiac events. Etidronateis associated with an increased risk for esophageal ulcers,bleeding events, and mild upper gastrointestinal events (acidreflux, esophageal irritation, nausea, vomiting, and heartburn).Raloxifene is associated with a higher risk for pulmonary embolism,thromboembolic events, and mild cardiac events (including chestpain, palpitations, tachycardia, and vasodilatation). Estrogenis associated with a greater risk for stroke, and the estrogen–progestincombination is associated with a greater probability of strokeand higher odds of breast cancer. In trials, perforations, ulcerations,and bleeding events occurred with all of the bisphosphonatesexcept zoledronic acid.

Recommendation 4: ACP recommends further research to evaluatetreatment of osteoporosis in men and women.

Current evidence is mostly concentrated on postmenopausal women;more research on other patient populations, including men, isneeded. Comparative effectiveness data on preventing fracturesfrom head-to-head studies with sufficient power to detect differenceswould be helpful. The association between bisphosphonates andosteonecrosis of the jaw also needs to be studied. Finally,further research is needed on prevention strategies in bothmen and women and on the appropriate duration of treatment forosteoporosis.

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From the American College of Physicians and University of Pennsylvania, Philadelphia, Pennsylvania; Veterans Affairs Greater Los Angeles Healthcare System and RAND, Santa Monica, California; University of Arkansas, Little Rock, Arkansas; and Veterans Affairs Palo Alto Health Care System and Stanford University, Stanford, California.

Note: Clinical practice guidelines are "guides" only and maynot apply to all patients and all clinical situations. Thus,they are not intended to override clinicians' judgment. AllACP clinical practice guidelines are considered automaticallywithdrawn or invalid 5 years after publication, or once an updatehas been issued.

Disclaimer: The authors of this article are responsible forits contents, including any clinical or treatment recommendations.No statement in this article should be construed as an officialposition of the Agency for Healthcare Research and Quality orthe U.S. Department of Health and Human Services.

Grant Support: Financial support for the development of thisguideline comes exclusively from the American College of Physicians'operating budget.

Potential Financial Conflicts of Interest: Employment: R. Hopkins(University of Arkansas). Consultancies: D.K. Owens (GE Healthcare).Grants received: V. Snow (Novo Nordisk, United Healthcare Foundation,Centers for Disease Control and Prevention, Atlantic Philanthropies).Any conflict of interest of the Guideline Development Committeegroup members was declared, discussed, and resolved.

Requests for Single Reprints: Amir Qaseem, MD, PhD, MHA, AmericanCollege of Physicians, 190 N. Independence Mall West, Philadelphia,PA 19106; e-mail, aqaseem{at}acponline.org.

Current Author Addresses: Drs. Qaseem and Snow: 190 N. IndependenceMall West, Philadelphia, PA 19106.

Dr. Shekelle: 1776 Main Street, Santa Monica, CA 90401.

Dr. Hopkins: 4301 West Markham Street, Little Rock, AR 72205.

Dr. Forciea: 3615 Chestnut Street, Philadelphia, PA 19104.

Dr. Owens: 117 Encina Commons, Stanford, CA 94305.

^* This paper, written by Amir Qaseem, MD, PhD, MHA; VincenzaSnow, MD; Paul Shekelle, MD, PhD; Robert Hopkins Jr., MD; MaryAnn Forciea, MD; and Douglas K. Owens, MD, MS, was developedfor the Clinical Efficacy Assessment Subcommittee of the AmericanCollege of Physicians (ACP): Douglas K. Owens, MD, MS (Chair);Donald E. Casey Jr., MD, MPH, MBA; Paul Dallas, MD; Thomas D.Denberg, MD, PhD; Mary Ann Forciea, MD; Lakshmi Halasyamani,MD; Robert H. Hopkins Jr., MD; William Rodriguez-Cintron, MD;and Paul Shekelle, MD, PhD. Approved by the ACP Board of Regentson 12 May 2008.

See related article in 5 February 2008 issue (volume 148, pages197-213).

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References

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