Proportion of osteoporotic women remaining at risk for fracture despite adherence to oral bisphosphonates.

BACKGROUND: Adherence to oral bisphosphonates is often low, but even adherent patients may remain at elevated fracture risk. The goal of this study was to estimate the proportion of bisphosphonate-adherent women remaining at high risk of fracture. METHODS: A retrospective cohort of women aged 50years and older, adherent to oral bisphosphonates for at least two years was identified, and data were extracted from a multi-system health information exchange. Adherence was defined as having a dispensed medication possession ratio≥0.8. The primary outcome was clinical occurrence of: low trauma fracture (months 7-36), persistent T-score≤-2.5 (months 13-36), decrease in bone mineral density (BMD) at any skeletal site≥5%, or the composite of any one of these outcomes. RESULTS: Of 7435 adherent women, 3110 had either pre- or post-adherent DXA data. In the full cohort, 7% had an incident osteoporotic fracture. In 601 women having both pre- and post-adherent DXA to evaluate BMD change, 6% had fractures, 22% had a post-treatment T-score≤-2.5, and 16% had BMD decrease by ≥5%. The composite outcomes occurred in 35%. Incident fracture was predicted by age, previous fracture, and a variety of co-morbidities, but not by race, glucocorticoid treatment or type of bisphosphonate. CONCLUSION: Despite bisphosphonate adherence, 7% had incident osteoporotic fractures and 35% had either fracture, decreases in BMD, or persistent osteoporotic BMD, representing a substantial proportion of treated patients in clinical practices remaining at risk for future fractures. Further studies are required to determine the best achievable goals for osteoporosis therapy, and which patients would benefit from alternate therapies.

Velocities of bone mineral accrual in black and white American children.

Black adults have higher bone mass than whites in the United States, but it is not clear when black children gain bone mineral faster than white children. We performed a cohort study to compare the growth velocity of total-body bone mineral content (TBMC) between black and white children of the same sex at different ages and stages of sexual maturity. TBMC and total-body area were measured in a cohort of 188 black and white boys and girls aged 5 to 15 years annually for up to 4 years. Rates of change in TBMC and area were found to vary with age and with Tanner stage. For both TBMC and area, growth velocities between black and white children differed significantly across Tanner stages. Age-specific velocities were higher in black children during prepuberty and initial entry into puberty but reversed in subsequent Tanner stages. Despite earlier entry into each Tanner stage, black children spent only an average of only 0.2 year longer in Tanner stages II through IV, and total gain in TBMC from age 5 to 15 was not higher in whites. In conclusion, the higher bone mass in black adults compared with whites cannot be attributed to faster accrual during puberty. It is due to black children's higher rate of bone mineral accrual in prepuberty and plausibly in postpuberty. Most of the racial difference in TBMC velocity can be explained by growth in size.

Heritability of changes in bone size and bone mass with age in premenopausal white sisters.

UNLABELLED: Femoral neck area expands and BMD decreases in premenopausal women. We used longitudinal DXA measurements on 388 premenopausal white sisters to show significant heritability of the rates of change in femoral neck area, BMC, and BMD. INTRODUCTION: Bone mass and structure are highly heritable. However, genetic effects on age-related changes in bone mass and structure in adults have been much less studied. MATERIALS AND METHODS: DXA measurements were made on 388 healthy white premenopausal sisters from 178 families. Rates of change in femoral neck area, BMC, and BMD, as well as body weight, were calculated from two measurements made an average of 5.7 years apart. Mixed models were used to test whether bone changes were related to age or weight change. Variance components models were used to estimate the heritability of the rates of change. A method was proposed to correct for the underestimation of heritabilities caused by measurement errors of the rates of change. RESULTS: Femoral neck area increased with age, whereas BMD decreased. All of the rates of change at the femoral neck were positively correlated with weight change, but the rates of femoral neck changes did not vary with age. Adjusted for weight change, change in femoral neck BMC became negative. Significant heritabilities (0.29-0.36) were detected for changes in femoral neck BMC, BMD, and area adjusted for weight changes. Correction for DXA measurement error in the rate estimates increased the heritability estimates (from 0.29-0.36 range to 0.37-0.64 range). CONCLUSIONS: Rates of change are heritable for femoral neck area, BMC, and BMD in premenopausal white women.

Polymorphisms in the estrogen receptor beta (ESR2) gene are associated with bone mineral density in Caucasian men and women.

CONTEXT: A major determinant of osteoporotic fractures is peak bone mineral density (BMD), which is a highly heritable trait. Recently, we identified significant linkage for hip BMD in premenopausal sister pairs at chromosome 14q (LOD score = 3.5), where the estrogen receptor beta gene (ESR2) is located. OBJECTIVE: The objective of the study was to determine whether ESR2 polymorphisms are associated with normal BMD variation. DESIGN: This was a population-based genetic association study, using 11 single nucleotide polymorphisms (SNPs) distributed across the ESR2 gene. SETTING: The study was conducted at an academic research laboratory and medical center. PATIENTS AND OTHER PARTICIPANTS: A total of 411 healthy men (aged 18-61 yr) and 1291 healthy premenopausal women (aged 20-50 yr) living in Indiana participated in the study. INTERVENTION(S): There were no interventions. MAIN OUTCOME MEASURE(S): The main outcome measures were SNP genotype distributions and their association with BMD at the femoral neck and lumbar spine. RESULTS: Significant association of spine BMD was found with three SNPs in men and one SNP in women (P < or = 0.05). The conditional linkage analysis using the ESR2 haplotypes showed that the ESR2 gene accounts for, at most, 18% of the original linkage. CONCLUSIONS: ESR2 polymorphisms are significantly associated with bone mass in both men and women. However, the ESR2 gene is not entirely responsible for our original linkage, and an additional gene(s) in chromosome 14q contributes to the determination of BMD.

Sex-specific and non-sex-specific quantitative trait loci contribute to normal variation in bone mineral density in men.

INTRODUCTION: A major determinant of osteoporotic fracture is peak bone mineral density (BMD). In women peak BMD is highly heritable and several quantitative trait loci (QTL) have been reported. There are few comparable data in men. This study in men aimed to establish the heritability of peak BMD, identify QTL contributing to normal variation in BMD, and determine which QTL might be sex specific. METHODS: BMD at the spine and hip were measured in 323 pairs of brothers aged 18-61 yr (264 white pairs; 59 black pairs). Heritability was calculated and linkage analysis performed with spine and hip BMD phenotypes. RESULTS: Heritability estimates ranged from 0.61 to 0.87 and were not significantly different between white and black men. A 9-cM genome-wide scan followed by genotyping with more closely spaced markers identified suggestive QTL (logarithm of the odds > 2.2) for BMD on chromosomes 1q (spine), 2p (spine), 2q (hip), 14p (spine), 18 (hip), and 21 (hip). Comparison with published data in 774 pairs of premenopausal sisters suggested that the QTL on 1q (spine), 2q (hip), 14p (spine), and 21q (hip) were male specific, whereas those on 2p (spine) and 18 (hip) were not sex specific. CONCLUSIONS: This study demonstrates that BMD in healthy men is highly heritable with similar estimates of the genetic contribution to BMD in both whites and blacks. Of the six QTL identified, three were specific for spine BMD and three were specific for hip BMD. When compared with published QTL for peak BMD in women from the same geographical region, four of the QTL appeared to be male specific. The occurrence of sex-specific genes in humans for BMD has potentially important implications for the pathogenesis and treatment of osteoporosis.

Contribution of the LRP5 gene to normal variation in peak BMD in women.

UNLABELLED: The role of the LRP5 gene in rare BMD-related traits has recently been shown. We tested whether variation in this gene might play a role in normal variation in peak BMD. Association between SNPs in LRP5 and hip and spine BMD was measured in 1301 premenopausal women. Only a small proportion of the BMD variation was attributable to LRP5 in our sample. INTRODUCTION: Mutations in the low-density lipoprotein receptor-related protein 5 (LRP5) gene have been implicated as the cause of multiple distinct BMD-related rare Mendelian phenotypes. We sought to examine whether the LRP5 gene contributes to the observed variation in peak BMD in the normal population. MATERIALS AND METHODS: We genotyped 12 single nucleotide polymorphisms (SNPs) in LRP5 using allele-specific PCR and mass spectrometry methods. Linkage disequilibrium between the genotyped LRP5 SNPs was measured. We tested for association between these SNPs and both hip and spine BMD (adjusted for age and body weight) in 1301 healthy premenopausal women who took part in a sibling pair study aimed at identifying the genes underlying peak bone mass. Our study used both population-based (ANOVA) and family-based (quantitative transmission disequilibrium test) association methodology. RESULTS AND CONCLUSIONS: The linkage disequilibrium pattern and haplotype block structure within the LRP5 gene were consistent with that observed in other studies. Although significant evidence of association was found between LRP5 SNPs and both hip and spine BMD, only a small proportion of the total variation in these phenotypes was accounted for. The genotyped SNPs accounted for approximately 0.8% of the variation in femoral neck BMD and 1.1% of the variation in spine BMD. Results from our sample suggest that natural variation in and around LRP5 is not a major contributor to the observed variability in peak BMD at either the femoral neck or lumbar spine in white women.

Peak bone mineral density at the hip is linked to chromosomes 14q and 15q.

A major determinant of osteoporotic hip fracture is peak hip BMD which is a highly heritable trait. Caucasian American women have lower BMD and higher hip fracture rates than African American women. This study examines linkage of hip BMD in 570 Caucasian sister pairs and 204 African American sister pairs. It compares the results with our published study in a smaller overlapping sample of Caucasian sisters. Hip BMD was measured at neck, trochanter, Ward's, shaft, and total hip. Principal component analysis provided a novel BMD phenotype comprising neck and trochanter, common sites of fracture, and Ward's, site of lowest BMD. A 9 cM genome scan was performed for these phenotypes. Significant linkage was found at chromosomes 14q and 15q. At 14q, the 774 African American and Caucasian sister pairs together yielded the highest LOD score for trochanter (3.5) and at 15q the highest LOD score for femoral neck (4.3). This linkage study in Caucasian and African American healthy premenopausal sisters demonstrates that chromosomes 14q and 15q harbor genes that affect peak bone mass at the hip in women. Principal component had comparable LOD scores with those of the component phenotypes suggesting pleiotropic effects of these genes on hip phenotypes.

Confirmation of linkage to chromosome 1q for peak vertebral bone mineral density in premenopausal white women.

Peak bone mineral density (BMD) is a highly heritable trait and is a good predictor of the risk of osteoporosis and fracture in later life. Recent studies have sought to identify the genes underlying peak BMD. Linkage analysis in a sample of 464 premenopausal white sister pairs detected linkage of spine BMD to chromosome 1q (LOD 3.6). An independent sample of 254 white sister pairs has now been genotyped, and it also provides evidence of linkage to chromosome 1q (LOD 2.5) for spine BMD. Microsatellite markers were subsequently genotyped for a 4-cM map in the chromosome 1q region in all available white sister pairs (n=938), and a LOD score of 4.3 was obtained near the marker D1S445. Studies in the mouse have also detected evidence of linkage to BMD phenotypes in the region syntenic to our linkage finding on chromosome 1q. Thus, we have replicated a locus on 1q contributing to BMD at the spine and have found further support for the region in analyses employing an enlarged sample. Studies are now ongoing to identify the gene(s) contributing to peak spine BMD in women.

Tissue mineralization is increased following 1-year treatment with high doses of bisphosphonates in dogs.

Suppression of bone turnover using anti-resorptive agents such as bisphosphonates prevents bone loss but also may increase tissue mineralization. This may make the bone more prone to initiate microcracks. The objective of this study was to determine whether suppression of remodeling caused by treatment of dogs for 1 year with five times the clinical dose of either alendronate or risedronate is associated with increased tissue mineralization and whether it changes the nature of the mineral crystal. Thirty-five dogs were divided into three weight-matched groups and treated daily for 1 year with a subcutaneous injection of saline (CON, n = 12), oral risedronate (RIS, 0.5 mg/kg/day, n = 11), or oral alendronate (ALN, 1.0 mg/kg/day, n = 12). Density fractionation, peripheral quantitative computerized tomography (pQCT), and quantitative backscattered electron microscopy (qBSE) were used to evaluate changes in mineral content of bone tissue from the vertebrae or ribs. Infrared microspectroscopy (IR) and X-ray diffraction were used to assess the quality of the mineral and some aspects of collagen structure in the thoracic vertebrae and iliac crest. Following 12 months of treatment, there was a significant shift toward higher density bone in both ALN (P = 0.04) and RIS (P = 0.002) by density fractionation methods. IR, pQCT, and qBSE did not detect any significant differences in mineralization, probably because of their lower sensitivity and/or because of the smaller region of interest they sample. No significant differences were found in the maturity of the mineral crystals or in their length or size. We conclude that treatment for 1 year with high doses of bisphosphonates which suppress bone remodeling up to 90% increases tissue mineralization, but does not change the nature of the mineral crystal.

Prevention of osteoporosis and uterine effects in postmenopausal women taking raloxifene for 5 years.

OBJECTIVE: Raloxifene hydrochloride (60 mg/day) is a selective estrogen receptor modulator indicated for the prevention and treatment of postmenopausal osteoporosis. Raloxifene treatment for 3 years increases bone mineral density (BMD) and, unlike tamoxifen (a triphenylethylene selective estrogen receptor modulator), does not stimulate the endometrium in healthy postmenopausal women. The effect of longer duration of treatment with raloxifene is not known. Therefore, the main objectives of these analyses are (1) to compare the effect of 5 years of treatment with raloxifene (60 mg/day) with placebo in terms of the likelihood of developing osteoporosis and (2) to evaluate the effect of 5 years of raloxifene treatment on the endometrium and incidence of vaginal bleeding. DESIGN: The current analyses include integrated data from two identically designed, prospective, double-blinded trials including postmenopausal women (mean age, 55 years) randomly assigned to either placebo (n = 143) or raloxifene (60 mg/day; n = 185). Osteoporosis and osteopenia were diagnosed according to World Health Organization criteria, using the manufacturer's database for the lumbar spine and the National Health and Nutrition Examination Survey's 1998 reference base for the hip. Endometrial thickness was determined using transvaginal ultrasonography. Clinical diagnoses of endometrial hyperplasia or endometrial cancer were confirmed by blinded review of histopathology reports. RESULTS: Compared with the case of placebo, raloxifene treatment for 5 years reduced bone turnover markers (osteocalcin: -10.9%, P < 0.001; bone-specific alkaline phosphatase: -7.2%, P = 0.042; urinary C-telopeptide: -11.1%, P = 0.034) and was associated with increased BMD in the lumbar spine (2.8%; P < 0.001) and total hip BMD (2.6%; P < 0.001). Women taking raloxifene were less likely to develop osteoporosis (relative risk [RR] for raloxifene v placebo: 0.13; 95% CI: 0.00, 0.37; P = 0.001) or osteopenia (RR: 0.23; 95% CI: 0.00, 0.81; P = 0.038) at the lumbar spine and were more likely to convert to normal BMD status at the lumbar spine (RR: 4.01; 95% CI: 1.34, 11.23; P = 0.043) and total hip (RR: 3.92; 95% CI: 1.12,14.27; P = 0.011) at 5 years, compared with the case of placebo. Raloxifene also significantly reduced total cholesterol (-5.5%; P < 0.001) and low-density lipoprotein cholesterol (-8.7%; P < 0.001), compared with the case of placebo. No significant changes in high-density lipoprotein cholesterol (P = 0.257) or triglycerides (P = 0.620) were detected. Incidence of hot flashes was higher among women taking raloxifene compared with those taking placebo [raloxifene, 47 (28.8%); placebo, 21 (16.8%); P = 0.017]. Women taking placebo or raloxifene reported a similar incidence of vaginal bleeding (P = 0.999) or of mean endometrial thickness of more than 5 mm at baseline and at each visit, up to the 5-year endpoint (P >/= 0.349). No diagnoses of endometrial hyperplasia or endometrial cancer were made in either treatment group. CONCLUSIONS: Five years of raloxifene treatment in healthy postmenopausal women preserves BMD, significantly reduces the likelihood of development of osteoporosis, and was not associated with an increased rate of vaginal bleeding, endometrial hyperplasia, or endometrial carcinoma, compared with the case of placebo.

Difference in bone mass between black and white American children: attributable to body build, sex hormone levels, or bone turnover?

A cross-sectional study of 232 healthy children, with about equal numbers of boys and girls and blacks and whites, aged 4 to 16 yr, was conducted to investigate the racial differences in bone mineral. Bone mineral content (BMC) by dual x-ray absorptiometry was found to be similar between blacks and whites at the spine after controlling for age and Tanner stage. However, total body BMC was higher in blacks, compared with whites of the same age and Tanner stage. Height and weight alone reduced the racial difference in BMC from 152 g to 66 g in girls and from 163 g to 105 g in boys, in whom the difference was further reduced to 66 g after accounting for lean and fat body mass and subscapular skinfold. The only significant sex hormone was androstenedione, which explained another 4-5 g of the racial difference in total body BMC for both boys and girls. Among the biochemical variables, only 25OH vitamin D reduced the residual racial difference in total body BMC to 39 g in girls, whereas serum PTH, urine free deoxypyridinoline ratio, and 1,25(OH)(2) vitamin D reduced the residual difference to 25 g in boys. The residual racial differences in bone mass were not statistically significant.

Sibling pair linkage and association studies between peak bone mineral density and the gene locus for the osteoclast-specific subunit (OC116) of the vacuolar proton pump on chromosome 11p12-13.

A major determinant of the risk of osteoporosis is peak bone mineral density (BMD), which has been shown to have substantial heritability. The genes for 3 BMD-related phenotypes (autosomal dominant high bone mass, autosomal recessive osteoporosis-pseudoglioma, and autosomal recessives osteopetrosis) are all in the chromosome 11q12-13 region. We reported linkage of peak BMD in a large sample of healthy premenopausal sister pairs to this same chromosomal region, suggesting that the genes underlying these 3 disorders may also play a role in determining peak BMD within the normal population. To test this hypothesis, we examined the gene responsible for 1 form of autosomal recessive osteopetrosis, TCIRG1, which encodes an osteoclast-specific subunit (OC116) of the vacuolar proton pump. We identified 3 variants in the sequence of TCIRG1, but only one, single nuclear polymorphism 906713, had sufficient heterozygosity for use in genetic analyses. Our findings were consistent with linkage to femoral neck BMD, but not to spine BMD, in a sample of 995 healthy premenopausal sister pairs. However, further analysis, using both population and family-based disequilibrium approaches, did not demonstrate any evidence of association between TCIRG1 and the spine or femoral neck BMD. Therefore, our linkage data suggest that the chromosomal region that contains OC116 harbors a gene that affects peak BMD, but our association results indicate that polymorphisms in the OC116 gene do not affect peak BMD.

Bone loss at the femoral neck in premenopausal white women: effects of weight change and sex-hormone levels.

To investigate whether bone loss occurs in the premenopause, we measured the bone mineral content (BMC), bone mineral density (BMD), and bone area in the spine (L2-L4), femoral neck, and total hip, as well as the sex hormone levels of 130 healthy premenopausal white women (age, 31-50 yr) at least three times over 1-9 yr. We found an increase in all three bone measurements at the spine but no change in volumetric density. Neither could we detect any age-related changes in any of the three measurements in the total hip. In contrast, we detected a significant decrease in femoral neck BMD over time, due to a decrease in BMC and increase in bone area. Greater loss in femoral neck BMD was associated independently with weight loss and lower levels of estrone sulfate or E2. Separating the women into those with FSH spikes (>20 IU/liter) and women with consistently low FSH, we found the latter group had smaller decrease in BMD and that the decrease was due less to a decline in BMC and more to an increase in bone area. In summary, femoral neck BMD decreases in premenopausal women, particularly those with lower levels of estrogens resulting from slowing ovarian function despite regular menses. This decrease can be offset by more rapid weight gain.