Journal List > J Bone Metab > v.24(2) > 1090376

Shin, Cho, and Kim: Longitudinal Change in Trabecular Bone Score during and after Treatment of Osteoporosis in Postmenopausal Korean Women

Abstract

Background

The aim of this study was to evaluate the longitudinal changes of trabecular bone score (TBS) during and after bisphosphonate (BP) treatment in postmenopausal Korean women with osteoporosis.

Methods

We analyzed 191 patients who took BP and underwent bone mineral density (BMD) test for the period from January 2010 to December 2015. The mean follow up period during treatment and after treatment was 22.8 months and 18 months, respectively. The TBS and BMD values were evaluated by the percent changes relative to the baseline.

Results

In 191 patients, who treated with BPs, L-spine BMD increased 3.65±0.5% and TBS increased 0.26±0.4% from baseline during first 1 year. At 2 to 4 years, the changes of BMD and TBS from baseline gradually increased up to 9.3±3.25% and 2.69±0.98% and both results showed statistically significant correlation. In 86 patients who stopped BPs, L-spine BMD decreased -0.54±1.07% and TBS increased 0.33±1.96% from baseline during 3 years follow up period.

Conclusions

Lumbar spine TBS increase over time with BPs treatment although the changes were less than that of BMD. Also, it preserve for years after stopping treatment, as the changes of lumbar spine BMD. The results of BMD and TBS showed significant correlation during treatment but not during drug withdrawal.

INTRODUCTION

Osteoporosis is characterized by a low bone mass combined with a bone microarchitecture alteration increasing the overall bone fragility and consequently the fracture risk.[1] Multiple factors contribute to the structural integrity of the entire bones: total bone mass, bone geometry, and constituent tissue properties.[2] Despite the many contributors to bone strength, bone mineral density (BMD) measured by dual energy X-ray absorptiometry (DXA) remains the cornerstone for the assessment of fracture risk and drug treatment effect in the clinical setting.[34] However, BMD alone is insufficient to predict fracture risks because most individuals with a fragility fracture will have BMD values in the osteopenic or even normal range.[567] In addition, only a small part of the fracture risk reduction during drug treatment was linked to the BMD increase. Indeed, only up to 30% to 40% of the reduction of vertebral fracture risk was explained by the BMD increase at the spine with teriparatide treatment,[8] which dropped to 3% to 4% with raloxifene.[9] This suggests that factors other than BMD, such as bone microarchitecture, contribute to the reduction of the fracture risk.[10]
The trabecular bone score (TBS) is a novel gray-level texture metric, which is based on the analysis of two-dimensional spine DXA images. It is known that the TBS is highly correlated with trabecular bone microarchitecture independent of the BMD.[11] Recently, the spine TBS is a highly anticipated novel tool for osteoporosis diagnosis and fracture risk assessment.[121314] However, it is unclear whether the TBS is useful in evaluating the osteoporotic treatment effects. Several relatively small studies have examined the treatment-induced effects on spine microarchitectural texture as assessed by the TBS. Krieg et al. [15] reported that in women aged ≥50 years, the TBS is responsive to non-estrogen anti-resorptive drug therapy, and the treatmentrelated increase in the TBS is less than the increase in the BMD. These results confirmed the preservation effect of bisphosphonates (BPs) on microarchitecture at the iliac crest.[16] A sub-analysis of the Health Outcomes and Reduced Incidence with Zoledronic Acid Once Yearly (HORIZON) trial on 54 postmenopausal women [17] has demonstrated a significant increase in the BMD (+9.6% at 36 months) at the spine in a patient treated with zoledronic acid, whereas a slight but significant effect was observed in the TBS (+1.41% at 36 months) when compared to the placebo group (n=53). Finally, Senn et al. [18] reported that in postmenopausal women with osteoporosis, a 2-year treatment with teriparatide led to a significantly larger increase in the lumbar spine BMD and TBS (+7.6% and +4.3%, respectively) than that with ibandronate (+2.9% and +0.3%, respectively). The TBS tends to increase with treatments; however, the change in the TBS is less marked than that in the BMD.
BPs have been the most widely used agent in South Korea (about 80%) for the treatment of osteoporosis.[19] Robust data have demonstrated the efficacy of BPs in fracture risk reduction with a vertebral fracture risk reduction rate ranging from 40% to 70% and relative hip fracture reduction rate of 40% to 70% over 3 to 5 years of treatment.[20] BPs accumulate in the bone; therefore, their inhibitory effects on osteoclasts may persist for years after drug discontinuation.[2122] This mechanism has led to controversies regarding the ideal duration of the therapy and whether the drug provides protection after being discontinued.[23] Furthermore, the effect of BPs withdrawal on the spine TBS is still unclear. Therefore, we conducted a retrospective cohort study on postmenopausal Korean women who received BPs and evaluated the changes in the BMD and TBS during and after treatment.

METHODS

1. Subjects

The present study enrolled 239 postmenopausal Korean women who visited the outpatient clinic of Kangwon National University Hospital between January 2010 and December 2015. The participants were treated with BP therapy (PO alendronate 70 mg/week, PO risedronate 35 mg/week, PO ibandronate 150 mg/monthly, or IV ibandronate 3 mg/3 months) or they took drug holidays during their follow-up period according to the physician's decision.
The main inclusion criteria were as follows: >70% of drug compliance throughout the study, >2 BMD tests, regular BMD tests per year, and drug initiated or finished at the time of the BMD tests. The exclusion criteria were as follows: abnormal laboratory evidence of renal, hepatic, and thyroid function and secondary causes of osteoporosis (i.e., any drugs that could affect bone metabolism, such as glucocorticoid or anticonvulsant therapy, and any diseases that might affect bone metabolism, such as malabsorption, cancer, hyperparathyroidism, and rheumatoid arthritis). Also, the patients with side effects to BPs were excluded. Ultimately, 191 subjects were deemed eligible and were included in the study. Eligible women underwent an additional evaluation, such as assessment of the history of clinical fractures. The weight, height, and body mass index (BMI; expressed in kg/m2) of all patients were recorded. The Institutional Review Board of Kangwon National University Hospital reviewed and approved this study.

2. BMD and TBS

The areal BMD of the anteroposterior lumbar spine (L1–L4) and proximal femur (femoral neck and total hip) was measured annually in all patients using DXA (Lunar Prodigy Advance, GE Lunar, Medison, WI, USA), software version 9.30.044. The results of BMD values were expressed in g/cm2 as well as in T-scores. The in vivo precision rate of the machine was 1.25% for the femoral neck and 0.67% for the lumbar spine. All TBS measurements were performed retrospectively using the TBS iNsight Software, ver. 2.0.0.1 (Med-Imaps, Needham, MA, USA) using spine DXA files from the database to ensure blinding of the investigators to all clinical parameters. The software uses the raw DXA images of the anteroposterior spine for the same region of interest as in the lumbar spine BMD measurement.

3. Statistical analyses

Descriptive analysis included mean±standard deviations or as numbers and percentages. Changes in the BMD and TBS from the baseline were calculated for each patient as the absolute changes divided by the baseline value and converted into percentages. The results were expressed as mean±standard error of the mean (SEM). Correlations between BMD and TBS were evaluated with Pearson correlation test. All statistical analyses were performed using the SPSS statistical software (SPSS Inc., Chicago, IL, USA), and P<0.05 was considered statistically significant.

RESULTS

1. Baseline characteristics of the study subjects

The mean age of the patients was 69.2 years (range, 48-92 years). Their mean BMI was 24.2±3.3 kg/m2 (range, 15.8-36.3 kg/m2), and only 6 (3.1%) patients had previous fractures. Among the 191 patients, 131 patients were treated with alendronate. The remaining patients were treated with risedronate (n=19) and ibandronate (n=59). Some of the patients' drug therapy was changed during follow-up. The baseline BMD and TBS of the patients are described in Table 1.

2. Changes in the BMD and TBS from the baseline during the BP treatment

In the 191 patients treated with BPs, the changes in the BMD and TBS from the baseline were monitored. As shown in Figure 1, the lumbar spine BMD increased (3.65±0.50%), and the TBS also increased (0.26±0.40%) from the baseline during the first year. The correlation between the changes in the BMD and TBS was statistically non-significant (r=0.047; P=0.514) during the first year. At the second to the fourth year, the changes in the BMD and TBS from the baseline gradually increased, and the correlation between both results was statistically significantly (r=0.318, 0.369, and 0.485, respectively; P<0.001, 0.002, and 0.004, respectively) (Table 2). There were slightly lesser changes in the femoral neck and total hip BMDs than in the lumbar spine BMD during the follow-up period. Although annual BMD tests were performed 2 to 6 times per patient, the fifth and sixth year follow-up findings were excluded owing to the small number of patients (10 and 1 patient[s], respectively).

3. Changes in the BMD and TBS from the baseline after the BP withdrawal

The changes in the BMD and TBS from the baseline during the drug holiday were evaluated in 86 patients (Table 3). After 1 year, the lumbar spine BMD decreased (-1.32±0.53%), and the TBS increased (0.09±0.59%). The correlation between the changes in the BMD and TBS was statistically non-significant (r=0.055; P=0.617). At the second year, both lumbar spine BMD and TBS decreased (-0.11±0.69% and -0.23±1.03%) from the baseline, without a statistically significant correlation (r=0.291; P=0.140). At the 3rd year, the TBS slightly increased again (0.33±1.96% from the baseline). Although annual BMD tests were performed for 5 years after BP withdrawal, the fourth and fifth year follow-up findings were excluded owing to the small number of patients (4 and 1 patient[s], respectively).
Taken together our results, the changes of lumbar spine BMD and TBS before and after administration of BP were graphically shown (Fig. 1). Also, BMD changes of femur neck and total hip before and after administration of BP were shown in the Figure 2.

DISCUSSION

In the present study, we have evaluated the effect of BPs treatment and withdrawal on the BMD and TBS. We observed that the lumbar spine, femoral neck, and total hip BMDs increased significantly during treatment and minimally decreased after drug withdrawal. The TBS showed the same tendency as the BMD, although the changes were lesser than those of the BMD. The results of the two tests showed a significant correlation during treatment but not during drug withdrawal.
It is well known that not only low bone mass but also microarchitectural deterioration of the bone tissues increases bone fragility and causes fractures. Although BP is known to increase bone mass, previous studies have shown that bone quality is also improved when the effects of BP are assessed using conventional tools, such as quantitative computed tomography (QCT) and femur geography to evaluate bone microstructure.[2425] Although the TBS is not a direct measurement tool in evaluating bone microarchitecture, it is known to be associated with the three-dimensional characteristics of the bone, such as trabecular volume, number, thickness, spacing, and connectivity density. [1226] In fact, a high TBS reflects a strong, fracture-resistant microarchitecture, whereas a low TBS reflects a weak, fracture-prone microarchitecture. Therefore, as with other tools, the TBS was expected to improve with BP treatment; however, the TBS change in our study was unexpectedly insignificant. Nevertheless, the results of our study are also consistent with those of other studies. Several studies have examined the role of the TBS in determining the efficacy of BP therapy in osteoporosis. After treatment with alendronate, risedronate, and ibandronate, the TBS increased by 1.4%, 1.4%, and 0.03% at the 2-year follow-up, respectively. [1827] When zoledronic acid was administered, the TBS increased by 1.4% during the 3-year follow-up.[17] In our study, the lumbar spine TBS increased by 1.4% at the 2-year follow-up and 1.89% at the 3-year follow-up, which are consistent with those of previous studies.
Theoretically, the recovery of trabecular bone tissue loss is considered impossible. New trabeculae will be difficult to be reproduced, and it is likely that the trabecular thickness will increase instead. However, the trabecular thickness would be thick enough to be reflected in the TBS; it must be very thin before the treatment.[15] In fact, in a previous study that evaluated bone microarchitecture with high resolution peripheral QCT (HR-pQCT), trabecular thickness and trabecular density changes were very low at 0.9% and 0.4%, respectively, at the 2-year follow-up after alendronate administration.[28] Nonetheless, the improvement in the TBS after BP administration may be due to the following reason. If BP is administered and the bone mass increases, the overall trabecular gap will also improve. Consequently, the trabecular regularity and TBS will also improve. Because the TBS is derived from the texture of DXA images, an increase in the bone mass may also affect the trabecular volume, number, spacing, and connectivity density; therefore, the TBS may also increase. In fact, among BPs, the agents with a high potency in increasing the bone mass also further increased the TBS (zoledronic acid>alendronate=risedronate>ibandronate), although they are not compared directly.[171827] Recent studies with denosumab and teriparatide also support this hypothesis. New agent denosumab increased the TBS by 2.8% during a 2-year follow-up period.[27] Two studies on teriparatide reported that the TBS increased by 3.6% and 4.3%, respectively, during a 2-year follow-up period.[1827] Taken together, all anti-osteoporosis medications appear to increase the TBS as well as the BMD, although the TBS changes are insignificant compared to the BMD changes. However, bone formation agents and high-potency agents for BMD showed greater increases in the TBS. If we included those with zoledronic acid, the change in the TBS would have been greater.
As the bone effect of BP is retained for several years after BP withdrawal,[222930] we expected that the TBS remains after drug withdrawal in the same vein. Indeed, the TBS increased by 0.33% after 3 years of drug withdrawal in our study, which is different from that of the study by Krieg et al. in which the TBS of untreated patients decreased by 0.3% over a mean follow-up period of 3.7 years.[15] Thus, this study suggests that BP may preserve the bone microarchitecture measured by the TBS for several years after drug withdrawal. If so, the TBS is expected to decrease significantly in the case of selective estrogen receptor modulator (SERM), which is known to decrease the BMD drastically after discontinuation of the drug.[3132] Unfortunately, it has not been evaluated in our study; however, it is expected to be interesting if additional research studies are conducted in the future.
Previous studies showed no significant correlation (r=0.01) [18] or a weak correlation (r=0.20-0.25) [151733] between the BMD and TBS during anti-osteoporosis medication administration, which suggests that the two indices are partly independent measures of the bone structure. In our study, the two indices showed a significant correlation (r=0.32-0.49) from the second to the fourth year, although they showed no correlation (r=0.047) during the first year. This finding is different from those of other studies; however, as previously discussed, such correlations are also possible because the BMD increases the TBS.
The present study has several limitations owing to the small number of patients and retrospective nature of the analysis. It is also limited, since the mean follow-up period was only 1.9 years during treatment and 1.5 years after treatment, although we followed up the patients for 6 years. Furthermore, the evaluation of the treated and drug withdrawal patients was not the same; some patients were only evaluated during the treatment and some patients only after drug withdrawal. Finally, the important concern is whether a treatment-related increase and preservation of the TBS provide a fracture risk reduction. Unfortunately, we did not evaluate how these changes correlate with the fracture risk in this study. Moreover, this study did not include laboratory data associated with osteoporosis. Nevertheless, the strength of our research is that we only included the patients whose follow-up interval was constant and who started or changed their drugs after undergoing the BMD tests.
In conclusion, this study is the first to evaluate the effects of BP withdrawal on the TBS. We observed that the lumbar spine TBS increases significantly over time with BPs treatment; such an increase is preserved for years after discontinuing the treatment as also observed in the lumbar spine BMD. Further large-scale studies including other anti-osteoporosis medications are needed.

Figures and Tables

Fig. 1

Lumbar spine bone mineral density and trabecular bone score changes during (A) and after bisphosphonate treatment (B).

jbm-24-117-g001
Fig. 2

Bone mineral density changes of femur neck (A) and total hip (B) during and after bisphosphonate treatment.

jbm-24-117-g002
Table 1

Baseline demographic and clinical characteristics

jbm-24-117-i001

The data is presented as mean±standard deviation or number (%).

BMI, body mass index; TBS, trabecular bone score; BMD, bone mineral density.

Table 2

Changes in BMD and TBS from baseline during bisphosphonate treatment

jbm-24-117-i002

The data is presented as n (mean±standard error of the mean).

a)The correlation coefficient is significant at 0.05 levels, both sides.

BMD, bone mineral density; TBS, trabecular bone score.

Table 3

Changes in BMD and TBS from baseline after bisphosphonate withdrawal

jbm-24-117-i003

The data is presented as n (mean±standard error of the mean).

BMD, bone mineral density; TBS, trabecular bone score.

ACKNOWLEDGEMENT

This study was supported by Wonkwang University in 2016. We also thank the Korean Society for Bone and Mineral Research for providing the software program of TBS for this study.

Notes

No potential conflict of interest relevant to this article was reported.

References

1. NIH Consensus Development Panel on Osteoporosis Prevention, Diagnosis, and Therapy. Osteoporosis prevention, diagnosis, and therapy. JAMA. 2001; 285:785–795.
2. van der Meulen MC, Jepsen KJ, Mikić B. Understanding bone strength: size isn't everything. Bone. 2001; 29:101–104.
crossref
3. Johnell O, Kanis JA, Oden A, et al. Predictive value of BMD for hip and other fractures. J Bone Miner Res. 2005; 20:1185–1194.
crossref
4. Cummings SR, Bates D, Black DM. Clinical use of bone densitometry: scientific review. JAMA. 2002; 288:1889–1897.
5. Miller PD, Siris ES, Barrett-Connor E, et al. Prediction of fracture risk in postmenopausal white women with peripheral bone densitometry: evidence from the National Osteoporosis Risk Assessment. J Bone Miner Res. 2002; 17:2222–2230.
crossref
6. Pasco JA, Seeman E, Henry MJ, et al. The population burden of fractures originates in women with osteopenia, not osteoporosis. Osteoporos Int. 2006; 17:1404–1409.
crossref
7. WHO Study Group. Assessment of fracture risk and its application to screening for postmenopausal osteoporosis. Report of a WHO Study Group. World Health Organ Tech Rep Ser. 1994; 843:1–129.
8. Chen P, Miller PD, Delmas PD, et al. Change in lumbar spine BMD and vertebral fracture risk reduction in teriparatide-treated postmenopausal women with osteoporosis. J Bone Miner Res. 2006; 21:1785–1790.
crossref
9. Sarkar S, Mitlak BH, Wong M, et al. Relationships between bone mineral density and incident vertebral fracture risk with raloxifene therapy. J Bone Miner Res. 2002; 17:1–10.
crossref
10. Seeman E, Delmas PD. Bone quality-the material and structural basis of bone strength and fragility. N Engl J Med. 2006; 354:2250–2261.
crossref
11. Silva BC, Leslie WD, Resch H, et al. Trabecular bone score: a noninvasive analytical method based upon the DXA image. J Bone Miner Res. 2014; 29:518–530.
crossref
12. Hans D, Goertzen AL, Krieg MA, et al. Bone microarchitecture assessed by TBS predicts osteoporotic fractures independent of bone density: the Manitoba study. J Bone Miner Res. 2011; 26:2762–2769.
crossref
13. Briot K, Paternotte S, Kolta S, et al. Added value of trabecular bone score to bone mineral density for prediction of osteoporotic fractures in postmenopausal women: the OPUS study. Bone. 2013; 57:232–236.
crossref
14. Krueger D, Fidler E, Libber J, et al. Spine trabecular bone score subsequent to bone mineral density improves fracture discrimination in women. J Clin Densitom. 2014; 17:60–65.
crossref
15. Krieg MA, Aubry-Rozier B, Hans D, et al. Effects of anti-resorptive agents on trabecular bone score (TBS) in older women. Osteoporos Int. 2013; 24:1073–1078.
crossref
16. Dufresne TE, Chmielewski PA, Manhart MD, et al. Risedronate preserves bone architecture in early postmenopausal women in 1 year as measured by three-dimensional microcomputed tomography. Calcif Tissue Int. 2003; 73:423–432.
crossref
17. Popp AW, Guler S, Lamy O, et al. Effects of zoledronate versus placebo on spine bone mineral density and microarchitecture assessed by the trabecular bone score in postmenopausal women with osteoporosis: a three-year study. J Bone Miner Res. 2013; 28:449–454.
crossref
18. Senn C, Günther B, Popp AW, et al. Comparative effects of teriparatide and ibandronate on spine bone mineral density (BMD) and microarchitecture (TBS) in postmenopausal women with osteoporosis: a 2-year open-label study. Osteoporos Int. 2014; 25:1945–1951.
crossref
19. Korean Endocrine Society. Osteoporosis fact sheet 2014. 2014. cited by 2016 December 1. Available from: http://www.endocrinology.or.kr/image/main/kor_Osteoporosis_Fact_Sheet2014.pdf.
20. Eastell R, Walsh JS, Watts NB, et al. Bisphosphonates for postmenopausal osteoporosis. Bone. 2011; 49:82–88.
crossref
21. Russell RG, Watts NB, Ebetino FH, et al. Mechanisms of action of bisphosphonates: similarities and differences and their potential influence on clinical efficacy. Osteoporos Int. 2008; 19:733–759.
crossref
22. Eastell R, Hannon RA, Wenderoth D, et al. Effect of stopping risedronate after long-term treatment on bone turnover. J Clin Endocrinol Metab. 2011; 96:3367–3373.
crossref
23. Gedmintas L, Solomon DH, Kim SC. Bisphosphonates and risk of subtrochanteric, femoral shaft, and atypical femur fracture: a systematic review and meta-analysis. J Bone Miner Res. 2013; 28:1729–1737.
crossref
24. Imai K, Ohnishi I, Matsumoto T, et al. Assessment of vertebral fracture risk and therapeutic effects of alendronate in postmenopausal women using a quantitative computed tomography-based nonlinear finite element method. Osteoporos Int. 2009; 20:801–810.
crossref
25. Burghardt AJ, Kazakia GJ, Sode M, et al. A longitudinal HR-pQCT study of alendronate treatment in postmenopausal women with low bone density: Relations among density, cortical and trabecular microarchitecture, biomechanics, and bone turnover. J Bone Miner Res. 2010; 25:2558–2571.
crossref
26. Winzenrieth R, Michelet F, Hans D. Three-dimensional (3D) microarchitecture correlations with 2D projection image gray-level variations assessed by trabecular bone score using high-resolution computed tomographic acquisitions: effects of resolution and noise. J Clin Densitom. 2013; 16:287–296.
crossref
27. Di Gregorio S, Del Rio L, Rodriguez-Tolra J, et al. Comparison between different bone treatments on areal bone mineral density (aBMD) and bone microarchitectural texture as assessed by the trabecular bone score (TBS). Bone. 2015; 75:138–143.
crossref
28. Rizzoli R, Chapurlat RD, Laroche JM, et al. Effects of strontium ranelate and alendronate on bone microstructure in women with osteoporosis. Results of a 2-year study. Osteoporos Int. 2012; 23:305–315.
crossref
29. Black DM, Schwartz AV, Ensrud KE, et al. Effects of continuing or stopping alendronate after 5 years of treatment: the Fracture Intervention Trial Long-term Extension (FLEX): a randomized trial. JAMA. 2006; 296:2927–2938.
crossref
30. Black DM, Reid IR, Cauley JA, et al. The effect of 6 versus 9 years of zoledronic acid treatment in osteoporosis: a randomized second extension to the HORIZON-Pivotal Fracture Trial (PFT). J Bone Miner Res. 2015; 30:934–944.
crossref
31. Neele SJ, Evertz R, De Valk-De Roo G, et al. Effect of 1 year of discontinuation of raloxifene or estrogen therapy on bone mineral density after 5 years of treatment in healthy postmenopausal women. Bone. 2002; 30:599–603.
crossref
32. Bone HG, Bolognese MA, Yuen CK, et al. Effects of denosumab treatment and discontinuation on bone mineral density and bone turnover markers in postmenopausal women with low bone mass. J Clin Endocrinol Metab. 2011; 96:972–980.
crossref
33. Kalder M, Hans D, Kyvernitakis I, et al. Effects of exemestane and tamoxifen treatment on bone texture analysis assessed by TBS in comparison with bone mineral density assessed by DXA in women with breast cancer. J Clin Densitom. 2014; 17:66–71.
crossref
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