Effect of Oral Alendronate on Bone Mineral Density and the Incidence of Fractures in Postmenopausal Osteoporosis
Uri A. Liberman, M.D., Ph.D., Stuart R. Weiss, M.D., Johann Bröll, M.D., Helmut W. Minne, M.D., Hui Quan, Ph.D., Norman H. Bell, M.D., Jose Rodriguez-Portales, M.D., Robert W. Downs, M.D., Jan Dequeker, M.D., Ph.D., Murray Favus, M.D., Ego Seeman, M.D., Robert R. Recker, M.D., Thomas Capizzi, Ph.D., Arthur C. Santora, M.D., Ph.D., Antonio Lombardi, M.D., Raksha V. Shah, M.A., R.d., Laurence J. Hirsch, M.D., David B. Karpf, M.D., for The Alendronate Phase III Osteoporosis Treatment Study Group
Background Postmenopausal osteoporosis is a serious health problem,and additional treatments are needed.
Methods We studied the effects of oral alendronate, an aminobisphosphonate,on bone mineral density and the incidence of fractures and heightloss in 994 women with postmenopausal osteoporosis. The womenwere treated with placebo or alendronate (5 or 10 mg daily forthree years, or 20 mg for two years followed by 5 mg for oneyear); all the women received 500 mg of calcium daily. Bonemineral density was measured by dual-energy x-ray absorptiometry.The occurrence of new vertebral fractures and the progressionof vertebral deformities were determined by an analysis of digitizedradiographs, and loss of height was determined by sequentialheight measurements.
Results The women receiving alendronate had significant, progressiveincreases in bone mineral density at all skeletal sites, whereasthose receiving placebo had decreases in bone mineral density.At three years, the mean (±SE) differences in bone mineraldensity between the women receiving 10 mg of alendronate dailyand those receiving placebo were 8.8±0.4 percent in thespine, 5.9±0.5 percent in the femoral neck, 7.8±0.6percent in the trochanter, and 2.5±0.3 percent in thetotal body (P<0.001 for all comparisons). The 5-mg dose wasless effective than the 10-mg dose, and the regimen of 20 mgfollowed by 5 mg was similar in efficacy to the 10-mg dose.Overall, treatment with alendronate was associated with a 48percent reduction in the proportion of women with new vertebralfractures (3.2 percent, vs. 6.2 percent in the placebo group;P = 0.03), a decreased progression of vertebral deformities(33 percent, vs. 41 percent in the placebo group; P = 0.028),and a reduced loss of height (P = 0.005) and was well tolerated.
Conclusions Daily treatment with alendronate progressively increasesthe bone mass in the spine, hip, and total body and reducesthe incidence of vertebral fractures, the progression of vertebraldeformities, and height loss in postmenopausal women with osteoporosis.
Postmenopausal osteoporosis is a common disorder characterizedby an increase in bone resorption relative to bone formation,generally in conjunction with an increased rate of bone turnover.1The progressive decrease in bone mass leads to an increasedsusceptibility to fractures, which result in substantial morbidityand mortality.2 Vertebral fractures are important not only becausethey can cause pain, kyphosis, and height loss but also becausethey predict subsequent, nonvertebral fractures independentlyof bone mineral density.3 Although there are several risk factorsfor fractures, reduced bone mineral density is the strongestpredictor.4 Thus, the ultimate goal of pharmacologic treatmentin women with postmenopausal osteoporosis is to reduce the riskof fractures by increasing bone mass of normal quality.
The clinically useful bisphosphonates are synthetic analoguesof inorganic pyrophosphate, an endogenous regulator of boneturnover that inhibits bone resorption and mineralization invitro.5 All bisphosphonates have a high affinity for hydroxyapatitebut, unlike pyrophosphate, are resistant to metabolism by endogenousphosphatases.5,6 Bisphosphonates are capable of inhibiting bonemineralization at roughly equivalent doses; however, their potenciesfor the inhibition of bone resorption depend on the unique chemicalstructure of their side chains.7 The four-carbon amino sidechain of alendronate conveys a very high potency, which in turnpermits effective inhibition of osteoclast-mediated bone resorptionat doses that do not impair bone mineralization,6 even withdaily doses, which is not the case with etidronate.8,9 Treatmentwith alendronate specifically inhibits increased bone resorptionand thereby normalizes the rate of bone turnover.10 Preclinicalevaluations of alendronate in animals with osteoporosis havedocumented greater bone strength in accordance with increasedbone mass,11,12 indicating the normal quality of alendronate-treatedbone. Iliac-crest biopsies in patients treated with alendronatefor up to three years show normal bone without evidence of mineralizationdefects.13
In 1990 two multicenter dose-ranging studies were initiatedin several countries to determine the efficacy of continuousoral alendronate therapy in postmenopausal women with osteoporosis.These randomized, double-blind, placebo-controlled studies hadidentical designs. Bone mineral density of the spine was chosenas the primary end point on the basis of epidemiologic evidencedemonstrating a strong and consistent relation between low bonemass and an increased risk of fracture.14,15 The studies alsoevaluated the incidence of vertebral fractures, the progressionof vertebral deformities, height loss, and the incidence ofadverse effects. We report the combined results of these twotrials.
Methods
Study Population
One multicenter study was conducted in the United States, andthe other in Australia, Canada, Europe, Israel, Mexico, NewZealand, and South America. Women who were 45 to 80 years oldand postmenopausal (>5 years since menopause) with osteoporosis(defined as a bone mineral density of the lumbar spine thatwas at least 2.5 SD below the mean value in premenopausal whitewomen) were eligible for participation. These enrollment criteriawere selected to represent the general population of women withosteoporosis (i.e., women with a low bone mass, with or withoutfractures). We excluded women with other causes of osteoporosis(e.g., treatment with glucocorticoids) or other disorders ofbone and mineral metabolism (e.g., vitamin D deficiency, Paget'sdisease, or hyperparathyroidism); active peptic ulcer disease,abnormal renal function (serum creatinine level, >1.5 mgper deciliter [130 µmol per liter]), or abnormal hepaticfunction; abnormalities of the lumbar spine precluding the assessmentof bone mineral density at a minimum of three lumbar vertebraeor a history of hip fracture; or any prior treatment with bisphosphonatesor treatment within the preceding 12 months with estrogen, progestin,calcitonin, fluoride, or an anabolic steroid. Women were notexcluded on the basis of race. All the women provided writteninformed consent, and the study protocols were approved by theinstitutional review board at each participating center.
Treatment
The women were randomly assigned to receive placebo (40 percentof the women) or 5, 10, or 20 mg of alendronate per day (20percent in each dose group) for two years, to be followed byopen-label therapy during the third year. Before any of thewomen had reached the 24-month visit, the protocol was modifiedto include a third year of double-blind therapy, and the womenreceiving 20 mg of alendronate per day were switched (blindly)to a dose of 5 mg per day for the third year. This change wasmade because the results of another study had demonstrated thata dose of 20 mg per day was more than necessary to obtain themaximal increase in bone mineral density.16 All the women receiveda daily supplement of calcium carbonate providing 500 mg ofelemental calcium.
End Points
The bone mineral density of the lumbar spine, femoral neck,trochanter, forearm, and total body was measured by dual-energyx-ray absorptiometry with the use of Hologic QDR-1000 or 1000/W(Hologic, Waltham, Mass.), Lunar DPX-L (Lunar, Madison, Wis.),or Norland XR-26 (Norland, Fort Atkinson, Wis.) densitometers.All scans were reviewed (without knowledge of the treatmentassignment) at a central facility, which provided factors tocorrect for calibration drift in the machines as necessary.
Lateral spine films were obtained at base line and after one,two, and three years of therapy to detect vertebral fracturesand the progression of vertebral deformities. Analysis of theseend points was based on the change from base line (or the firstavailable film) to the latest follow-up film. Films of the thoracicand lumbar spine were obtained with the standard values fortarget-to-film distance and centering used at each study center.The films were sent to the radiology center, where vertebralheights were determined by observers unaware of the treatmentassignment or film sequence. All films from each woman weredigitized at the same time. Three points were placed along thesuperior edge and three along the inferior edge of each vertebrafrom the fourth thoracic vertebra (T4) to the fifth lumbar vertebra(L5), demarcating the anterior, middle, and posterior heightsof each vertebral body. A computer mouse with cross-hairs anda commercially available digitization board were used to enterthe data as X and Y coordinates, and vertebral heights werecalculated to the nearest 0.1 mm with the use of computer software.Corrections for magnification errors were made when appropriate.
The presence of vertebral fractures at base line (previous fractures)was determined by comparing each woman's base-line vertebral-heightratios with those of a reference group.17 The ratios were calculatedas follows: the anterior and middle heights were compared withthe posterior height of the same vertebra, and the posteriorheight was compared with the posterior height of an adjacentvertebra. Any vertebral-height ratio more than 3 SD below thecorresponding reference ratio was considered to be a previousvertebral fracture.17 A new fracture was defined as a reductionof at least 20 percent, with an absolute decrease of at least4 mm, in the height of any vertebral body between base lineand follow-up.
Vertebral deformities were assessed with the Spine DeformityIndex, which was developed as a continuous measure of vertebraldeformities in patients with a history of vertebral fractures.The index sums deformations of multiple vertebrae into a singlenumerical value.18 Each vertebral height (T5 through L5) isdivided by the corresponding T4 height (anterior, middle, orposterior) to generate a maximum of 39 vertebral-height ratios,which are corrected for differences in stature. Each ratio isthen compared with population norms, and the absolute differencesfor ratios that fall below the minimal population norm are added,to arrive at the total Spine Deformity Index. We expected thata sizable proportion of the women with osteoporosis in our studywould have no measurable deformities initially (i.e., a SpineDeformity Index of zero) and that no deformities would developduring the study. Hence, the primary use of the Spine DeformityIndex was to compare the proportion of women in each group withincreased indexes during the study.
Height was measured at base line and at 3, 6, 9, 12, 18, 24,27, 30, and 36 months with a Harpenden stadiometer (Holtain,Crymmych, Pembrookshire, United Kingdom), which measures heightto the nearest millimeter. Three measurements were obtainedfor each woman at each time point, and two additional measurementswere made if any two values differed by more than 4 mm. Thevalue for height was the average of all three or five measurementsobtained at each visit.
All reported symptomatic nonvertebral fractures were recorded,with no attempt to exclude fractures on the basis of the degreeof trauma.
Statistical Analysis
From the outset, the plan was to pool the data from the two,identically designed studies and from the three alendronategroups in each study, since we anticipated that neither trialalone, nor any one dose group, would be sufficiently large toallow the detection of a significant effect of alendronate onthe incidence of new fractures.
Changes in bone mineral density at each site (expressed as thepercentage of increase or decrease from the base-line value)were calculated at 3, 6, 12, 18, 24, 30, and 36 months. Allanalyses reflect the correction factors calculated at the centralfacility, which were determined from standard phantom spinemeasurements made during the study.
For the analysis of the proportion of women with one or morenew vertebral fractures, the Breslow–Day test was usedto determine whether there was any interaction between treatmentgroup and study (since there were two studies). Because no interactionwas evident (P = 0.43), the study designs were identical, andthe data pooling was specified in advance, the pooling of datafrom the two studies was valid. After the data had been pooled,the Cochran–Mantel–Haenszel test was used to comparethe placebo group with the alendronate group. Estimates of therelative risk associated with alendronate as compared with placeboand 95 percent confidence intervals were computed.
A chi-square test was used to compare the proportions of womenwith progressive vertebral deformities (i.e., women with anincreased Spine Deformity Index) in the placebo and alendronategroups. For the analysis of changes in height from base line,we used an analysis-of-variance model that included terms forthe treatment group, center, and interaction between the treatmentand the center. This last term was removed from the analysis,since there was no statistical evidence of such an interaction.Slopes (for changes in height over time) were calculated forwomen who had at least three height measurements and were evaluatedin a fashion similar to that described above, except that aweighted analysis of variance was used, with the weights inverselyproportional to the variance of the estimated slope for eachwoman.19 Nonvertebral fractures were analyzed with the Cox proportional-hazardsmodel, with each of the two studies as a stratification factor.
All analyses of the efficacy of alendronate were based on theintention-to-treat principle; that is, all women who had atleast one measurement after randomization were included in theevaluation, irrespective of whether they were still taking thestudy drug. Treatment effects for certain prespecified patientcharacteristics (e.g., age and the presence or absence of avertebral fracture at base line) were summarized for all endpoints, but no P values were computed.
Results
The base-line characteristics of the women in the treatmentand placebo groups were similar (Table 1), and there were nodifferences between the two studies in the risk factors forfracture (data not shown). A total of 87.4 percent of the womenwere white, 0.4 percent were black, and 12.2 percent were ofother races. Of the 994 women randomly assigned to treatment,909 (91 percent) completed at least one year of the study. Pairedspine films were analyzed for 881 (97 percent) of these women.Of the other 28 women, 21 had films that could not be digitizedbecause of their poor quality, 4 had follow-up films that couldnot be found, and 3 declined follow-up radiography. The 113women not included in the analysis of vertebral fractures didnot differ from the other 881 women (data not shown). About20 percent of the women in each group had vertebral fracturesat base line (Table 1).
Table 1. Base-Line Characteristics of the 881 Women Included in the Analysis of Vertebral Fractures.
The Spine Deformity Index, which requires paired films withat least 13 vertebrae that can be fully evaluated, was calculatedfor 835 (95 percent) of the women included in the vertebral-fractureanalysis. A total of 921 women had height values recorded atbase line and at least one follow-up visit for the analysisof absolute loss of height; 902 women with values for at leastthree time points were included in the analysis of the rateof change in height. All women were included in the analysisof nonvertebral fractures.
Bone Mineral Density
There were significant increases in the bone mineral densityof the spine, femoral neck, trochanter, and total body at 36months in all three alendronate groups, and significant lossesat all sites in the placebo group (Figure 1). The 10-mg dosewas significantly more effective than the 5-mg dose at all skeletalsites and was as effective as 20 mg followed by 5 mg. The mean(±SE) differences in bone mineral density between thewomen receiving 10 mg of alendronate daily and those receivingplacebo were 8.8±0.4 percent in the spine, 5.9±0.5percent in the femoral neck, 7.8±0.6 percent in the trochanter,and 2.5±0.3 percent in the total body (P<0.001 forall comparisons). At two years, 10 mg was as effective as 20mg (Figure 1). As expected with an antiresorptive agent, thebone mineral density at each site increased most rapidly duringthe first six months of treatment.
Figure 1. Mean (±SE) Changes in Bone Mineral Density from Base-Line Values in Women with Postmenopausal Osteoporosis Receiving Alendronate or Placebo for Three Years.
Data are shown for bone mineral density (measured by dual-energy x-ray absorptiometry) of the spine, femoral neck, trochanter, and total body. Data for the alendronate group are shown according to the dose: 5 or 10 mg per day for three years or 20 mg per day for two years followed by 5 mg per day in year 3.
The 10-mg dose of alendronate resulted in increases in bonemineral density at all sites during all three years, althoughthe increase in total-body bone mineral density during year3 was not significant (Figure 1). In contrast, the bone mineraldensity in the spine, hip, and total body did not increase significantlyduring the third year in the patients treated with 5 mg of alendronateper day or 20 mg followed by 5 mg. Thus, the progressive increasesin bone mineral density at each site during the 36-month studyperiod were most marked in response to 10 mg of alendronateper day, with no plateau in the effect during the entire 3-yearstudy period at either the spine or the hip. In the mid-forearm,an almost entirely cortical site, the 10-mg dose also resultedin 2.2±0.4 percent greater bone mineral density thanplacebo (P<0.001).
The increases in bone mineral density in the spine were similarregardless of the bone mineral density, rate of bone turnover,age, or creatinine clearance at base line. Over 96 percent ofthe women treated with 10 mg of alendronate for three yearshad measurable increases in bone mineral density in the spine(data not shown).
Vertebral Fractures
During the study, 22 of the 355 women in the placebo group (6.2percent) had at least one new vertebral fracture, as comparedwith 17 of the 526 women in the combined alendronate groups(3.2 percent, P = 0.03) (Table 2). Only two women had new vertebralfractures only in vertebrae with previous fractures. The relativerisk of a new fracture among the women treated with alendronate,as compared with those receiving placebo, was 0.52 (95 percentconfidence interval, 0.28 to 0.95). This decreased risk amongthe women receiving alendronate was found in both studies andin women stratified according to age (less than 65 years or65 years or older) or the presence or absence of a previousvertebral fracture (Table 2). The risk of a vertebral fracturewas also decreased in all dose groups, with new vertebral fracturesin 2.9 percent of the women receiving 5 mg of alendronate, 2.8percent of those receiving 10 mg, and 4.1 percent of those receiving20 mg followed by 5 mg, as compared with 6.2 percent of thewomen in the placebo group.
Table 2. Women with New Vertebral Fractures during the Three-Year Study Period.
Among the women who had new vertebral fractures, the proportionwith two or more fractures was much lower in the combined alendronategroups (18 percent) than in the placebo group (68 percent).On an absolute basis, 4.2 percent of the women receiving placebo(15 of 355) had two or more vertebral fractures, as comparedwith 0.6 percent of those treated with alendronate (3 of 526).Because of the combination of fewer affected women and fewerfractures per woman, the number of vertebral fractures per 100women was substantially lower in the combined alendronate groupsthan in the placebo group (4.2 vs. 11.3). Among the women withvertebral fractures, the ratio of wedge or crush fractures toend-plate fractures was higher in the placebo group than inthe combined alendronate groups (data not shown).
Spine Deformity Index
The Spine Deformity Index increased in 33 percent of the womenreceiving alendronate but in 41 percent of those receiving placebo(P = 0.028). This beneficial effect of alendronate was consistentin both studies, in women younger than 65 or 65 or older, andin women with or without vertebral deformities at base line(data not shown). There was a difference of borderline significance(P = 0.054 by the Wilcoxon rank-sum test) in the distributionof the change from the base-line Spine Deformity Index in theplacebo and alendronate groups. The mean change in the SpineDeformity Index was 0.08±0.02 in the placebo group and0.04±0.01 in the alendronate group.
Height
The mean loss of height after three years of treatment was 35percent less in the alendronate group than in the placebo group(3.0 mm vs. 4.6 mm, P = 0.005). The effect of alendronate inpreventing loss of height was greater in the older women (>65years) and in the subgroup with previous fractures than in theyounger women or the subgroup without previous fractures (datanot shown). The annualized rate of height loss was about 40percent lower in the women treated with alendronate than inthose receiving placebo, resulting in a difference between thegroups of 0.7 mm per year (P<0.001).
Loss of height in the women without new vertebral fractureswas small and similar in the treatment and placebo groups (2.8and 3.3 mm, respectively) (Figure 2). Among the women with newvertebral fractures, however, those in the placebo group losta mean of 23.3 mm in height, whereas the mean loss of heightin the alendronate group (5.9 mm) was only slightly greaterthan the mean loss in the women without new fractures.
Figure 2. Mean (±SE) Changes in Height from Base-Line Values among Women with or without New Vertebral Fractures in the Alendronate and Placebo Groups.
Changes in height were calculated as the mean of three to five measurements per woman, made with a Harpenden stadiometer. The data for the women in the three alendronate groups have been pooled.
Nonvertebral Fractures
Nonvertebral fractures occurred in 83 women, with a trend towarda reduced number of fractures in the alendronate group. Of the397 women in the placebo group, 38 had a total of 47 nonvertebralfractures during 1015 patient-years of follow-up, whereas 45of the 597 alendronate-treated women had a total of 46 nonvertebralfractures during 1525 patient-years of follow-up. In the placebogroup, the cumulative incidence of women with nonvertebral fracturesafter three years was 10.7 percent, with an overall rate of3.7 women with fractures per 100 patient-years at risk. In thealendronate group, the cumulative incidence was 8.5 percent,with an overall rate of 3.0 women with fractures per 100 patient-yearsat risk. The estimated risk of nonvertebral fractures in thewomen treated with alendronate was 0.79 (95 percent confidenceinterval, 0.52 to 1.22). The difference in the cumulative proportionsof women without nonvertebral fractures in the alendronate andplacebo groups appeared to increase in the third year (Figure 3).Table 3 shows the data for all nonvertebral fractures. Therewere no reports of stress fractures, fracture malunion, or delayedhealing of fractures.
Table 3. Women with New Nonvertebral Fractures and Sites of Fracture during the Three-Year Study Period.
Adverse Effects
Alendronate was generally well tolerated, with no greater clinicalor laboratory evidence of adverse effects than with placebo.Overall, 16.3 percent of the women discontinued therapy, withsimilar frequencies in the placebo group and all three alendronategroups (Table 4). Discontinuation was due to clinical adverseeffects in 6.0 percent of the women receiving placebo, 5.4 percentof those receiving 5 mg of alendronate, 4.1 percent of thosereceiving 10 mg, and 8.0 percent of those receiving 20 mg fortwo years followed by 5 mg in the third year. Dose-dependentupper gastrointestinal irritation is the primary side effectassociated with several other bisphosphonates, which are administeredat higher doses.20,21 The women in the placebo group and allthree alendronate groups had similar rates of adverse uppergastrointestinal effects, resulting in the discontinuation oftreatment in only 2.0 percent of the women receiving placebo,3.5 percent of those receiving 5 mg of alendronate, 1.0 percentof those receiving 10 mg, and 2.0 percent of those receiving20 mg followed by 5 mg. The most common adverse effects consideredto be drug-related by the blinded investigators were abdominalpain (in 6.6 percent of the women receiving 10 mg of alendronateand 4.8 percent of those receiving placebo), musculoskeletalpain (in 4.1 and 2.5 percent, respectively), nausea (in 3.6and 4.0 percent), dyspepsia (in 3.6 and 3.5 percent), constipation(in 3.1 and 1.8 percent), and diarrhea (in 3.1 and 1.8 percent).
Daily treatment with oral alendronate for three years resultedin increases in the bone mineral density of the spine, hip,and total body in women with postmenopausal osteoporosis, andthese effects were associated with reductions in the incidenceof vertebral fractures, vertebral deformities, and loss of height,as well as a trend toward a reduction in the incidence of fracturesat nonvertebral sites. The 10-mg dose produced progressive increasesin bone mineral density, which were larger than the increasesassociated with the 5-mg dose at all skeletal sites and at alltime points after six months. The efficacy of 10 mg of alendronateper day was similar to that of 20 mg per day for two years anddid not plateau during up to three years of therapy —a finding consistent with the reversal of a negative bone balanceat the level of individual remodeling units. Although 20 mgper day for two years followed by 5 mg per day in the thirdyear is a 50 percent greater cumulative dose than 10 mg perday for three years, the greater increase in bone mineral densityduring the third year in the 10-mg group indicates that thecurrent dose of alendronate, not the total or cumulative dose,results in the changes in bone mass. All three doses increasedthe bone mass at all sites, including the total body, whichis consistent with a systemic effect rather than a redistributionof the bone mass from cortical to trabecular bone. Continuoustherapy with 10 mg of alendronate per day provided maximal efficacy,was well tolerated, and is therefore the optimal dose for thetreatment of osteoporosis in postmenopausal women.
Most prospective, randomized trials with fractures as an endpoint have recruited women who had multiple vertebral fracturesat base line and were therefore at very high risk for subsequentfractures.22,23,24,25,26,27,28,29 Although these women had higherrates of fracture than the women in our study,14 the applicabilityof the results of these trials to the general population ofwomen with osteoporosis may be limited. A recent positive studyof the effects of vitamin D3 and calcium on hip fractures enrolledonly elderly institutionalized women, nearly half of whom hadbiochemical evidence of vitamin D deficiency.30 In contrast,the women in the two studies reported here were selected becauseof decreased bone mineral density in the lumbar spine but werenot required to have a history of vertebral or other fractures.Therefore, the results of these studies should be applicableto most women with postmenopausal osteoporosis.
The selection of the optimal dose of alendronate for the treatmentof osteoporosis was based on bone mineral density, rather thanfractures, as the primary end point, since dose-ranging studiesthat used fractures as the primary end point would require manymore women. To verify the hypothesis that increases in bonemass induced by alendronate would reduce the incidence of fractures,we compared all three alendronate groups with the placebo group.Because the regimen of 10 mg of alendronate per day for threeyears produced a greater increase in bone mineral density thanthe other doses (the women in the 10-mg group had 8.8 percentgreater density at the spine than those in the placebo group),as well as a larger decrease in the incidence of vertebral fractures(55 percent), the pooling of the dose groups may underestimatethe efficacy of the 10-mg dose in preventing fractures.
A number of previous trials have used fracture rates as theprimary unit of analysis in determining the efficacy of treatment.22,23,24,25,28,31In contrast, we used the number of women with new vertebralfractures, since multiple fractures in the same woman are notindependent events.32 Nevertheless, fracture rates are of interest.Treatment with alendronate, as compared with placebo, decreasedthe average number of vertebral fractures per woman by 63 percent.The decrease in the number of fractures and the smaller proportionsof crush and wedge fractures account for the much smaller lossof height among the women with new fractures in the alendronategroup than among the women with new fractures in the placebogroup.
We found a trend toward a decreased proportion of women withnew nonvertebral fractures in the alendronate group, with a21 percent reduction in absolute risk among the women treatedwith alendronate, as compared with those receiving placebo.The use of pooled data on nonvertebral fractures as an indicationof the efficacy of treatment represents a post hoc analysisand should be viewed with some caution. Nevertheless, the reductionin new nonvertebral fractures in the alendronate group is consistentwith the progressive increases in the bone mineral density ofthe hip and total body induced by treatment with alendronate,as well as with the reduction in vertebral fractures. Theseresults suggest that alendronate increases bone strength atappendicular sites, as well as in the axial skeleton.
The results of these trials are consistent both internally andwith prospective epidemiologic studies of the relation betweenbone mineral density of the lumbar spine and the risk of vertebralfracture.14,15 The women in the placebo group with the lowestbase-line bone mineral density of the lumbar spine had the highestincidence of new vertebral fractures, the highest rate of progressionof vertebral deformities, and the greatest loss in height duringthe study, whereas the women with the highest base-line bonemineral density of the spine had the lowest values for thesethree end points (data not shown). In addition, the overallincrease in spine bone mineral density in the alendronate group(approximately 8 percent, as compared with a decrease in theplacebo group) was associated with an almost 50 percent decreasein the proportion of women with new vertebral fractures. Thesefindings confirm the results of other studies indicating thatthe relative risk of a vertebral fracture approximately doublesfor each reduction in spine bone mineral density equivalentto 1 SD (approximately 10 percent).14,15
In summary, daily treatment with oral alendronate progressivelyincreases the bone mass of the spine, hip, and total body andreduces the risk of vertebral fractures, the progression ofvertebral deformities, and height loss in postmenopausal womenwith osteoporosis.
Supported by a grant from Merck Research Laboratories.
We are indebted to Ms. Ann Barash for assistance in the preparationof the manuscript and to the study nurses and technicians forassistance in conducting the studies.
* The other members of the Alendronate Phase III OsteoporosisTreatment Study Group are listed in the Appendix.
Source Information
From the Department of Metabolic Disease, Beilinson Medical Center, Tel Aviv University, Petah-Tikva, Israel (U.A.L.); the San Diego Endocrine and Medical Clinic, San Diego, Calif. (S.R.W.); the Department of Medicine, Kaiser Franz Josef Hospital, Vienna, Austria (J.B.); Klinik der Fürstenhof, Bad Pyrmont, Germany (H.W.M.); Merck Research Laboratories, Rahway, N.J. (H.Q., T.C., A.C.S., A.L., R.V.S., L.J.H., D.B.K.); the Department of Research Services, Veterans Affairs Medical Center, Charleston, S.C. (N.H.B.); the Department of Endocrinology, School of Medicine, Catholic University of Chile, Santiago (J.R.-P.); the Department of Medicine, Medical College of Virginia, Richmond (R.W.D.); the Department of Rheumatology, Catholic University Leuven, Leuven, Belgium (J.D.); the Department of Medicine, University of Chicago, Chicago (M.F.); the Department of Endocrinology, Austin Hospital, Heidelberg, Australia (E.S.); and the Center for Osteoporosis Research, Creighton University, Omaha, Nebr. (R.R.R.). Presented in part at the 77th Annual Meeting of the Endocrine Society, Washington, D.C., June 14–17, 1995.
Address reprint requests to Dr. Liberman at Metabolic Diseases, Beilinson Medical Center, 49100, Petah-Tikva, Israel.
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Appendix
In addition to the authors, the following investigators weremembers of the Alendronate Phase III Osteoporosis TreatmentStudy Group: M.Z. Baker, Oklahoma City; M. Bliziotes, Portland,Oreg.; H.G. Bone III, Detroit; R. Correa-Rotter and J.C. Peña,Mexico City; D.C. Cumming, Edmonton, Alta., Canada; J.P. Devogelaerand C. Nagant de Deuxchaisnes, Brussels, Belgium; R.D. Emkey,Reading, Pa.; P. Geusens, Diepenbeek, Belgium; D. Hosking, Nottingham,United Kingdom; P. Jaeger, Bern, Switzerland; C.C. Johnston,Jr., Indianapolis; J.M. Kaufman and A. Vermeulen, Ghent, Belgium;M.O. Leite, São Paulo, Brazil; J. León, Bogotá,Colombia; R. Samuel, Tel Aviv, Israel; R. Marcus and M.L. Villa,Palo Alto, Calif.; H. McIlwain, J.C. Silverfield, and J.L. Miller,Tampa, Fla.; C.J. Menkes, Paris; P.J. Meunier, Lyon, France;I.R. Reid, Auckland, New Zealand; A. Romanowicz, Buenos Aires,Argentina; R.D. Tonino, Burlington, Vt.; J. Tucci, Providence,R.I.; R.D. Wasnich, Honolulu; N.B. Watts, Atlanta; and R.S.Weinstein and A.L. Mulloy, Augusta, Ga. Radiology Center, BadPyrmont, Germany: T. Bruckner and W. Pollähne. Bone DensitometryCenter, Portland, Oreg.: E.S. Orwoll, S. Oviatt-Orwoll, andK. Linton. Merck Research Laboratories, Rahway, N.J.: C. Arena,K. Plezia, C. Peverly, C.D. Maibach, D.R. Shapiro, D.E. Thompson,and R. Tierney.
Injury Prevention
Barach P., Richter E., Leistikow B. N., Karpf D. B., Rivara F. P., Grossman D. C., Cummings P.
Extract |
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N Engl J Med 1998;
338:132-133, Jan 8, 1998.
Correspondence
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[Abstract][Full Text]
Koo, W. W. K., Hammami, M., Margeson, D. P., Nwaesei, C., Montalto, M. B., Lasekan, J. B.
(2003). Reduced Bone Mineralization in Infants Fed Palm Olein-Containing Formula: A Randomized, Double-Blinded, Prospective Trial. Pediatrics
111: 1017-1023
[Abstract][Full Text]
Ascott-Evans, B. H., Guanabens, N., Kivinen, S., Stuckey, B. G. A., Magaril, C. H., Vandormael, K., Stych, B., Melton, M. E.
(2003). Alendronate Prevents Loss of Bone Density Associated With Discontinuation of Hormone Replacement Therapy: A Randomized Controlled Trial. Arch Intern Med
163: 789-794
[Abstract][Full Text]
Brown, J. P., Josse, R. G.
(2003). Lignes directrices de pratique clinique 2002 pour le diagnostic et le traitement de l'osteoporose au Canada. CMAJ
168: SF1-38
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Riggs, B. L., Hartmann, L. C.
(2003). Selective Estrogen-Receptor Modulators -- Mechanisms of Action and Application to Clinical Practice. NEJM
348: 618-629
[Full Text]
Watts, N. B., Josse, R. G., Hamdy, R. C., Hughes, R. A., Manhart, M. D., Barton, I., Calligeros, D., Felsenberg, D.
(2003). Risedronate Prevents New Vertebral Fractures in Postmenopausal Women at High Risk. J. Clin. Endocrinol. Metab.
88: 542-549
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Horwitz, M. J., Tedesco, M. B., Gundberg, C., Garcia-Ocana, A., Stewart, A. F.
(2003). Short-Term, High-Dose Parathyroid Hormone-Related Protein as a Skeletal Anabolic Agent for the Treatment of Postmenopausal Osteoporosis. J. Clin. Endocrinol. Metab.
88: 569-575
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Chow, C. C., Chan, W. B., Li, J. K. Y., Chan, N. N., Chan, M. H. M., Ko, G. T. C., Lo, K. W., Cockram, C. S.
(2003). Oral Alendronate Increases Bone Mineral Density in Postmenopausal Women with Primary Hyperparathyroidism. J. Clin. Endocrinol. Metab.
88: 581-587
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Chellaiah, M. A., Kizer, N., Biswas, R., Alvarez, U., Strauss-Schoenberger, J., Rifas, L., Rittling, S. R., Denhardt, D. T., Hruska, K. A.
(2003). Osteopontin Deficiency Produces Osteoclast Dysfunction Due to Reduced CD44 Surface Expression. Mol. Biol. Cell
14: 173-189
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Malik, A R, Campbell, S H, Toma, N M G
(2002). Bilateral acute anterior uveitis after alendronate. Br. J. Ophthalmol.
86: 1443-1443
[Full Text]
Khan, A. A., Brown, J. P., Kendler, D. L., Leslie, W. D., Lentle, B. C., Lewiecki, E. M., Miller, P. D., Nicholson, R. L., Olszynski, W. P., Watts, N. B.
(2002). The 2002 Canadian bone densitometry recommendations: take-home messages. CMAJ
167: 1141-1145
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Brown, J. P., Josse, R. G.
(2002). 2002 clinical practice guidelines for the diagnosis and management of osteoporosis in Canada. CMAJ
167: s1-34
[Abstract][Full Text]
Galbiati, E., Caruso, P. L., Amari, G., Armani, E., Ghirardi, S., Delcanale, M., Civelli, M.
(2002). Pharmacological Actions of a Novel, Potent, Tissue-Selective Benzopyran Estrogen. J. Pharmacol. Exp. Ther.
303: 196-203
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Parker, C. R., Blackwell, P. J., Fairbairn, K. J., Hosking, D. J.
(2002). Alendronate in the Treatment of Primary Hyperparathyroid-Related Osteoporosis: A 2-Year Study. J. Clin. Endocrinol. Metab.
87: 4482-4489
[Abstract][Full Text]
Body, J.-J., Gaich, G. A., Scheele, W. H., Kulkarni, P. M., Miller, P. D., Peretz, A., Dore, R. K., Correa-Rotter, R., Papaioannou, A., Cumming, D. C., Hodsman, A. B.
(2002). A Randomized Double-Blind Trial to Compare the Efficacy of Teriparatide [Recombinant Human Parathyroid Hormone (1-34)] with Alendronate in Postmenopausal Women with Osteoporosis. J. Clin. Endocrinol. Metab.
87: 4528-4535
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Cryer, B., Bauer, D. C.
(2002). Oral Bisphosphonates and Upper Gastrointestinal Tract Problems: What Is the Evidence?. Mayo Clin Proc.
77: 1031-1043
[Abstract]
Greenspan, S., Field-Munves, E., Tonino, R., Smith, M., Petruschke, R., Wang, L., Yates, J., de Papp, A. E., Palmisano, J.
(2002). Tolerability of Once-Weekly Alendronate in Patients With Osteoporosis: A Randomized, Double-Blind, Placebo-Controlled Study. Mayo Clin Proc.
77: 1044-1052
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Nelson, H. D., Helfand, M., Woolf, S. H., Allan, J. D.
(2002). Screening for Postmenopausal Osteoporosis: A Review of the Evidence for the U.S. Preventive Services Task Force. ANN INTERN MED
137: 529-541
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Dobrucali, A., Tobey, N. A., Awayda, M. S., Argote, C., Abdulnour-Nakhoul, S., Shao, W., Orlando, R. C.
(2002). Physiological and morphological effects of alendronate on rabbit esophageal epithelium. Am. J. Physiol. Gastrointest. Liver Physiol.
283: G576-G586
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Tuck, S P, Francis, R M
(2002). Osteoporosis. Postgrad. Med. J.
78: 526-532
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Gardner, M. J., Flik, K. R., Mooar, P., Lane, J. M.
(2002). Improvement in the Undertreatment of Osteoporosis Following Hip Fracture. JBJS
84: 1342-1348
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Cranney, A., Wells, G., Willan, A., Griffith, L., Zytaruk, N., Robinson, V., Black, D., Adachi, J., Shea, B., Tugwell, P., Guyatt, G.
(2002). II. Meta-Analysis of Alendronate for the Treatment of Postmenopausal Women. Endocr. Rev.
23: 508-516
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Johnell, O., Pauwels, R., Lofdahl, C-G., Laitinen, L.A., Postma, D.S., Pride, N.B., Ohlsson, S.V.
(2002). Bone mineral density in patients with chronic obstructive pulmonary disease treated with budesonide Turbuhaler(R). Eur Respir J
19: 1058-1063
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Bell, N. H., Bilezikian, J. P., Bone III, H. G., Kaur, A., Maragoto, A., Santora, A. C.
(2002). Alendronate Increases Bone Mass and Reduces Bone Markers in Postmenopausal African-American Women. J. Clin. Endocrinol. Metab.
87: 2792-2797
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Lehmann, H J, Mouritzen, U, Christgau, S, Cloos, P A C, Christiansen, C
(2002). Effect of bisphosphonates on cartilage turnover assessed with a newly developed assay for collagen type II degradation products. Ann Rheum Dis
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A correction has been published: N Engl J Med 1996;334(11):733.
