Performance of Osteoporosis Self-Assessment Tool (OST) in Predicting Osteoporosis—A Review
Department of Pharmacology, Faculty of Medicine, Universiti Kebangsaan Malaysia, Jalan Yaacob Latif, Bandar Tun Razak, Cheras, Kuala Lumpur 56000, Malaysia
*
Author to whom correspondence should be addressed.
Int. J. Environ. Res. Public Health 2018, 15(7), 1445; https://doi.org/10.3390/ijerph15071445
Submission received: 6 June 2018
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Revised: 28 June 2018
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Accepted: 4 July 2018
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Published: 9 July 2018
(This article belongs to the Section Health Economics)
Abstract
:Bone health screening plays a vital role in the early diagnosis and treatment of osteoporosis to prevent fragility fractures among the elderly and high-risk individuals. Dual-energy X-ray absorptiometry (DXA), which detects bone mineral density, is the gold standard in diagnosing osteoporosis but is not suitable for screening. Therefore, many screening tools have been developed to identify individuals at risk for osteoporosis and prioritize them for DXA scanning. The Osteoporosis Self-assessment Tool (OST) is among the first tools established to predict osteoporosis in postmenopausal women. It can identify the population at risk for osteoporosis, but its performance varies according to ethnicity, gender, and age. Thus, these factors should be considered to ensure the optimal use of OST worldwide. Overall, OST is a simple and economical screening tool to predict osteoporosis and it can help to optimize the use of DXA.
1. Introduction
Osteoporosis is a progressive bone metabolic disease. It is undetectable until a bone fracture occurs. Once osteoporosis has developed, then it is less likely to completely restore the bone strength of the patients [1]. The prevalence of osteoporosis is increasing as the global population ages rapidly. In Asia, the number of osteoporotic hip fractures is expected to rise from 1,124,060 in 2018 to 2,563,488 in 2050 [2]. The Asians also encompassed 55% of the population at risk for fragility fractures worldwide [3]. The escalating morbidity and mortality rates due to osteoporotic fractures have distressed the patients, families, and society [4]. In addition, fragility fractures also contribute to a tremendous healthcare and economic burden. A recent meta-analysis of studies in Asia indicated that the median medical cost for hip fracture was USD 2943, representing around 19% of the gross domestic product of the countries studied in 2014 [5]. Thus, it is crucial to identify individuals at risk for osteoporosis to enable early intervention for fracture prevention.
Dual-energy X-ray absorptiometry (DXA) is the gold standard technique used to detect osteoporosis. According to the World Health Organization (WHO), a bone mineral density (BMD) ≤ −2.5 standard deviations (SD) below the young adult mean (or a T-score ≤ −2.5) indicates osteoporosis, while a T-score value at any site between ≤−1.0 and >−2.5 indicates a low bone mass or osteopenia [6]. Dual-energy X-ray absorptiometry cannot be widely used for osteoporosis screening due to its high cost and limited availability in most developing countries [7]. Quantitative ultrasound (QUS) has been developed as an alternative to DXA for osteoporosis screening [7]. Although QUS is portable and more economical than DXA, it may be unavailable in all primary medical settings.
Various clinical risk assessment tools have been developed to evaluate the risk of osteoporosis [8]. These screening tools help physicians to prioritize high-risk patients for a DXA scan. Some of the screening algorithms are the Fracture Risk Assessment Tool (FRAX), Qfracture algorithm, and Garvan Fracture Risk Calculator (Garvan) [9]. The Osteoporosis Self-assessment Tool (OST) is another predictive algorithm currently in use to predict the risk for osteoporosis [10]. It was first established by Koh et al. (2001) using data of postmenopausal women from eight Asian countries. The screening algorithm was only based on age (years) and body weight (kg): OSTA score = (body weight − age) × 0.2, with three osteoporosis risk categories: low risk (>−1), moderate risk (−1 to −4), and high risk (<−4). It performed well to determine women at risk of osteoporosis [11]. The performance of OST among Asian men was first assessed by Kung et al. (2004) and it demonstrated a moderate performance in predicting osteoporosis [12]. OST has been known as OSTA (OST for Asians) when it is applied to Asian women. The establishment of OSTA only involved postmenopausal women and men from East and Southeast Asia. A recent article by Chin (2017) reviewed the performance of OSTA among various Asian populations, but the performance of OST in non-Asian countries was not examined [13]. Thus, the present review summarized and compared the performance of OST in determining osteoporosis risk among the Asian and non-Asian population.
2. Literature Search
A literature search was performed from 15 January 2018 to 4 April 2018 using two databases: PubMed and Scopus. Only original articles written in English were included in this review. The search term used was “osteoporosis self-assessment tool”. The search revealed 84 articles from PubMed and 65 articles from Scopus, which resulted in a total of 149 articles. After removing 16 duplicated articles, 133 articles were screened based on title and abstract. Only studies investigating the performance of OST against DXA were considered. The present review included 44 relevant articles (Figure 1).
3. Performance of OST among Asians
3.1. Performance of OST among Asian Women
The osteoporosis self-assessment tool for Asians (OSTA) was first developed by Koh et al. (2001) using data of postmenopausal women from eight Asian countries. The final algorithm only selected age and body weight as the predictors, creating the formula: OSTA score = (body weight in kg − age in years) × 0.2. Based on the truncated product of this formula, the women could be divided into three risk categories: low-risk (>−1), moderate-risk (−1 to −4), and high-risk (<−4). The predictive values of these scores were good, as indicated by the fact that 61% women categorized as high-risk were osteoporotic compared to 3% in the low-risk group in their study [11]. Its performance (cutoff = −1; sensitivity = 91%; specificity = 45%; AUC = 0.79) was superior than the reported values of the SOFSURF index [14], Osteoporosis Risk Assessment Index (ORAI), and Simple Calculated Osteoporosis Risk Estimation (SCORE) [15]. The performance of OSTA was subsequently validated in other East Asian populations, such as Chinese [16] and Korean women [17], and comparable results were obtained. This is not surprising, considering that a majority of the subjects in the development phase were East Asians [11]. In addition, the validation study by Huang et al. (2015) showed that OSTA performed better when BMD at the femoral neck was used as the reference, and when the women tested were older [16]. The site difference is probably due to the presence of osteophyte at the lumbar spine, which distorts its BMD. This finding was validated in similar studies conducted among Thai women [18,19]. The age difference coincides with the development population, which was elderly women (mean age: 62.3 ± 6.2 years) [11]. The limitation of OSTA in predicting osteoporosis among younger women was also observed in Thai women [19].
3.2. Performance of OST among Asian Men
Men also suffer from osteoporosis and their post-fracture mortality rate is higher than women [20]. Therefore, OSTA was developed for men by Kung et al. in 2004 based on data of community-dwelling Chinese men (age range: 50–93 years) in Hong Kong. The algorithm and cutoff values were the same as reported by Koh et al. (2001), but its performance in the development and validation cohort was not as good as in postmenopausal women (cutoff = −1; sensitivity = 71–73%, specificity = 68%; AUC = 0.780–0.790) [12]. OSTA was subsequently validated in the Chinese Han population [21] and Korean men [22], and both studies obtained a sensitivity > 80%. In contrast, OSTA (cutoff < −1) demonstrated a low sensitivity (27.6–28.5%) and a high specificity (89.2–92.7%) in a large study involving Chinese men of a wide age range (40–96 years) [23]. Sub-analysis revealed that similar to women, OSTA only performed well among older subjects [23].
3.3. Performance of OST with Modified Cutoff Values
Since the original cutoff values for OSTA were established in postmenopausal elderly women, predominantly Eastern Asians, its performance, in terms of sensitivity and specificity, may vary according to sex, age, and ethnic groups. Hence, modification to the cutoff values may be necessary to ensure the optimal performance of OSTA. This hypothesis was tested by Bhat et al. (2016) among Indian subjects (aged > 50 years) using a cutoff of 2 and OSTA achieved high sensitivity (sensitivity = 95.7%, specificity = 33.6%, AUC = 0.702) in predicting osteoporosis among the subjects [24]. However, OSTA failed to show similar performance in other populations (Chinese men with the cutoff −3.5, sensitivity = 47.3% [4]; Taiwanese men with the cutoff −1.86, sensitivity 69.2% [25]). In the subsequent discussion, the readers should notice the changes in cutoff values in many studies.
3.4. Performance of OST in Comparison with Other Screening Tools
QUS is another popular osteoporosis screening tool [7]. It was reported to have a strong association with BMD and bone mineral content (BMC) measured by DXA [26]. In three studies, OSTA was found to perform equally with QUS [8,27,28]. Thus, OSTA can be used in medical settings without QUS. However, it should be noted that OSTA and QUS cannot be used interchangeably because the two tools are not equivalent [29].
OSTA was also compared against other screening algorithms. With a modified cutoff of −2, OSTA showed a sensitivity of 90.0–91.9% among postmenopausal women, which was better than SCORE (cutoff ≥ 8), ORAI (cutoff ≥ 20), ABONE (cutoff = 3), and WEIGHT (cutoff < 54 kg) [30]. In another study among the Taiwanese elderly, OSTA achieved a sensitivity of 100% in men and women, outperforming ABONE (cutoff ≥ 2), BWC (<70 kg), FRAX and GARVAN (cutoff > 3% for hip fracture, > 20% for major osteoporotic fracture), ORAI (cutoff ≥ 9), OSIRIS (cutoff ≤ 1), OSTA (cutoff < −1), and SCORE (cutoff ≥ 6) [27].
The universality of OSTA was challenged by some researchers with osteoporosis screening algorithms designed for the local populations. The performance of OSTA was proven to be equivalent in some cases. For example, the Khon Kaen Osteoporosis Study (KKOS) (cutoff < −1) scoring system shared a similar performance with OSTA (cutoff < −1) in Thai women (AUC: 0.64 vs. 0.65) [31]. The Beijing Friendship Hospital Osteoporosis Self-Assessment Tool (BFH-OST) also performed similarly to OSTA (cutoff = −1) in predicting osteoporosis in Chinese Han women and men (AUC: 0.795–0.797 vs. 0.732–0.782), despite having a higher sensitivity (73.58–89.92% vs. 50.42–65.28%) [32,33]. Among the South Indian elderly, the performance of the Male Osteoporosis Risk Estimation Score (MORES) (cutoff = 6) was also equivalent to OSTA (cutoff ≤ 2) (AUC: 0.760 vs. 0.778) [34].
In some cases, the local algorithms were better than OSTA in osteoporosis screening. Among Taiwanese women, the Osteoporosis Preclinical Assessment Tool (OPAT) containing four predictors (age, menopausal status, weight, and alkaline phosphatase activity) performed better than OSTA (sensitivity: 87% vs. 78%; AUC: 0.77 vs. 0.69) [35]. Similarly, the Korean Osteoporosis Risk-Assessment Model (KORAM) (cutoff < −9) also performed better than OSTA in predicting osteoporosis among Korean menopausal women (cutoff < 0) (AUC: 0.682–0.709 vs. 0.617–0.626) [36]. The Malaysian Osteoporosis Screening Tool (MOST) (cutoff ≥ 4) was also superior to OSTA (cutoff < 2) (AUC: 67.6% vs. 52%) in predicting osteoporosis among healthy women [37]. Despite that, these local screening tools might not be useful outside the local settings.
A summary of the literature on the performance of OST among Asians is listed in Table 1.
4. Performance of OST among Non-Asians
4.1. Performance of OST among Non-Asian Women
Although developed for Asians, the performance of OST has also been validated in non-Asians. The algorithm is the same as reported by Koh et al. (2001), but the cutoff values have been optimized to suit the designated populations. The performance of OST (cutoff < 2) was good in determining Caucasian women at risk of osteoporosis (sensitivity = 86–95.3%; specificity = 39.6–40%; AUC = 0.726–0.82) [10,38]. A study indicated that the performance of OST was similar between younger (cutoff ≤ 1 for 45–64 years) and older women (and cutoff ≤ −1 for >65 years) when different cutoff values were used [39].
4.2. Performance of OST among Non-Asian Men
The use of OST in predicting bone health among non-Asian men was also validated. In Caucasian men, OST was able to predict individuals with osteoporosis (sensitivity = 93%, specificity = 66%, AUC = 0.836) [40]. The performance was better when BMD at total hip (sensitivity = 87.5%; specificity = 58.2%; AUC = 0.787) was used as the reference compared to the lumbar spine (sensitivity = 63.6%; specificity = 59.5%; AUC = 0.66) [41]. When operated in younger men (≥35 years), OST performed optimally when the cutoff was modified to <4 (sensitivity = 83%, specificity = 57%, AUC = 0.83) [42].
4.3. Performance of OST with Modified Cutoff Values
The cutoff values of OST need to be optimized in different non-Asian populations. In comparison to the original −1 for Asians, a cutoff ≤ 2 was tested for Caucasian to obtain a similar sensitivity value [43]. Other cutoff values, such as < 3 for Portuguese men (sensitivity = 75.5%, specificity = 50.0%, AUC = 0.632) [44], < 6 for veteran US men (sensitivity = 82.6%, specificity = 33.6%, AUC = 0.67) [45], and < 4 for African men (sensitivity = 83%, specificity = 57%, AUC 0.83) [42], have been adopted previously. The non-Asians’ cutoff values are generally higher than Asians’ because they have a higher body weight.
Even within the same ethnicity, the cutoff values of OST need to be modified based on sex. A Spanish study showed that OST performed optimally at a cutoff of 2 in women (sensitivity = 94%, specificity = 59%, AUC = 0.762) and 3 in men (sensitivity = 39%, specificity = 86%, AUC = 0.623) [46].
In a group of men with rheumatoid arthritis, OST was weak (sensitivity = 64%; specificity = 54%) in determining those with low BMD even though the cutoff was modified to <4. The researchers indicated that the performance of OST could be limited by the low lean body mass of patients with rheumatoid arthritis [47].
4.4. Performance of OST in Comparison with Other Screening Tools
In comparison with other screening algorithms, OSTA (at various optimized cutoff values) performed similarly to ABONE [48], SCORE [10,48,49,50,51,52,53], SOFSURF [49,51], ORAI [10,48,49,51,52], OSIRIS [10,49], United States Preventive Services Task Force (USPSTF)–FRAX [52,53,54], RF [52], BMI [52], pBW [49], Weight Criterion [48], and QUS [49] in women. It also performed similarly to the male-specific screening tool, Mscore, developed by Zimering et al. (2007) [55]. Only the study of Hawker et al. (2012) reported that OST was weak (sensitivity = 47%, AUC = 0.69) in identifying women with low BMD when compared to a new screening tool developed by the study (sensitivity = 93%, AUC = 0.75) [56].
A summary of the literature on the performance of OST among non-Asians is listed in Table 2.
5. OST for Fracture Prediction
Fragility fracture is one of the most common complications of osteoporosis. Although OST was developed to identify individuals with low BMD, its ability to predict fracture risk was assessed in several studies [54,58,59]. Yang et al. (2013) reported that OSTA (cutoff < −1) performed well in determining new vertebral fractures among postmenopausal Chinese women (sensitivity = 81.7%; specificity = 66%; AUC = 0.812) [59].
In comparison with other fracture prediction tools, the performance of OST was weaker than DXA [58] and FRAX [58] in Chinese men and the Singh index in patients with type 2 diabetes mellitus [60]. However, a study showed that USPSTF (FRAX) (sensitivity = 25.8%; specificity = 83.3%; AUC = 0.56) was not better than OST in fracture prediction (sensitivity = 39.8%; specificity = 60.7%; AUC = 0.52) among non-Asian postmenopausal women [54].
A summary of the literature on the performance of OST to predict fracture risk is listed in Table 3.
6. Conclusions
The performance of OST in predicting osteoporosis has been tested in various Asian and non-Asian populations. It demonstrates good predictive values in terms of sensitivity, specificity, and AUC when BMD is used as the reference. Some modifications in the OST cutoff should be made and tested to optimize its performance prior to its deployment, since the performance may vary according to age, sex, ethnicities, and the site of BMD measurement. Validation studies are necessary before including OST in the national guideline for osteoporosis screening. In most studies, OST demonstrated a high sensitivity and low specificity, which is typical for a screening test. In other words, OST might direct some individuals with normal bone health for an unnecessary DXA scan. At the same time, the number of potential patients subjected to a DXA scan is maximized, allowing the early detection and treatment of osteoporosis. This will reduce the complications and burdens of the disease. Thus, we argue that the benefits of implementing OST will outweigh its cost. As a conclusion, OST is a useful osteoporosis screening tool in prioritizing high-risk individuals for a DXA scan. It enables early disease detection, optimizes the use of the diagnostic facility, and therefore reduces the disease burden of osteoporosis.
Author Contributions
S.S. performed the literature search and drafted the manuscript. K.-Y.C. and S.I.-N. critically reviewed and expanded the text. All authors have approved the final, submitted manuscript.
Funding
We thank Universiti Kebangsaan Malaysia for funding this study via grants GUP-2017-060 and AP-2017-009/1.
Conflicts of Interest
The authors declare no conflict of interest.
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Figure 1.
Flowchart of literature search.
Table 1.
Performance of OST among Asians.
| Study | Objective | Subject Description | Number of Subjects Recruited | Methods | Cutoff | Sensitivity (%) | Specificity (%) | AUC | Remarks |
|---|---|---|---|---|---|---|---|---|---|
| Koh et al. (2001) [11] | To develop Osteoporosis Screening Tool for Asians (OSTA) | Postmenopausal women (mean age 62 years) recruited from 21 clinics in eight Asia countries. | 860 | DXA: 8 Hologic machines (3 Model 4500, 5 Model 2000), 4 Norland (2 XR-36, 1 S-26, 1 XR-26), 12 Lunar (3 DPX-IQ. 6 DPX-L, 3 Expert) machines | OSTA < −1 T-score< −2.5 | 91 | 45 | 0.79 | |
| SOFSURF < 1.4 T-score < −2.5 | 90 | 46 | 0.77 | ||||||
| ORAI < 15 T-score < −2.5 | 84 | 52 | 0.76 | ||||||
| SCORE < 10 T-score < −2.5 | 90 | 33 | 0.77 | ||||||
| Park et al. (2003) [17] | To validate the effectiveness of OSTA in identifying osteoporosis among Korean women | Postmenopausal women from a clinic in Korea and who were not on hormone replacement therapy (mean age: 59.1 ± 7.7 years) | 1101 | DXA GE Lunar model DPQ-IQ BMD at FN | OSTA < −1 T-score ≤ −2.0 | 80 | 72 | 0.85 | Single-centered |
| OSTA < −1 T-score ≤ −2.5 | 87 | 67 | 0.873 | ||||||
| Geater et al. (2004) [18] | To validate the performance of OSTA in predicting osteoporosis among Korean women | Thai post-menopausal women (mean age: 60.5 ± 9.7 years) without risk of osteoporosis | 388 | DXA Lunar, Madison BMD at FN and LS | OSTA < −1 FN T-score < −2.5 | 93.5 | 60.8 | Value not mentioned | |
| OSTA < −1 LS T-score < −2.5 | 79.5 | 69.5 | Value not mentioned | ||||||
| OSTA < 0 FN T-score < −2.5 | 93.5 | 29.8 | Value not mentioned | ||||||
| OSTA < 0 LS T-score < −2.5 | 92.4 | 35.7 | Value not mentioned | ||||||
| Huang et al. (2015) [16] | To determine the performance of OSTA among middle-aged and old women | Healthy women (age range: 40–96 years) from a hospital in Chengdu region, China | 15,752 | DXA (Lunar Prodigy- GE Healthcare, Madison, WI, USA) BMD at LS, FN, and TH | OSTA < −1 LS T-score < −1 | 56.9 | 87.7 | 0.812 | |
| OSTA < −1 LS T-score < −2.5 | 77.3 | 73.5 | 0.812 | ||||||
| OSTA < −1 FN T-score < −1 | 56.2 | 89.8 | 0.822 | ||||||
| OSTA < −1 FN T-score < −2.5 | 88.1 | 69.3 | 0.822 | ||||||
| Yang et al. (2015) [21] | To validate OSTA among elderly males to determine the risk of primary osteoporosis | Healthy males (mean age: 65.17± 9.29 years) | 245 | DXA (Hologic, Inc., Bedford, MA, USA) BMD at LS and LF | OSTA < 1 FN T-score < −2.5 | 84 | 49 | 0.712 | |
| OSTA < 1 TH T-score < −2.5 | Value not stated | Value not stated | 0.658 | ||||||
| OSTA < 1 LS T-score < −2.5 | Value not stated | Value not stated | 0.535 | ||||||
| Oh et al. (2016) [22] | To compare the effectiveness of Korean Osteoporosis Risk-Assessment Model for Men (KORAM-M) and OSTA | Men aged 50 and above from 2009 and 2010 Korean National Health and Nutrition Examination Survey | Development phase: 1340 Validation phase: 1110 | DXA Hologic Discovery BMD at FN or LS | Development: OSTA < −1 | 90.8 | 36.9 | 0.639 | |
| KORAM-M < −9 | 90.8 | 42.4 | 0.666 | ||||||
| Validation: OSTA < −1 | 92.3 | 33.2 | 0.627 | ||||||
| KORAM-M < −9 | 87.9 | 39.7 | 0.638 | ||||||
| Huang et al. (2017) [23] | To assess the effectiveness of OSTA using various cutoffs | Healthy men aged 40–96 years recruited from a hospital in Chengdu region, China | 11,039 | DXA (GE Lunar, Madison, WI, USA) BMD at LS and FN | OSTA < −1 LS T-score < −1 | 27.6 | 89.2 | value not stated | |
| OSTA < −1 LS T-score ≤ −2.5 | 57.3 | 86.7 | |||||||
| OSTA < −1 FN T-score < −1 | 28.5 | 92.7 | |||||||
| OSTA < −1 FN T-score ≤ −2.5 | 65.9 | 87.0 | |||||||
| Bhat et al. (2017) [24] | To evaluate the performance of OSTA in predicting OP among Indian men | Indian men above 50 years and without apparent risk of OP | 257 | DXA (QDR 4500 A, Hologic Inc., Bedford, MA, USA) BMD at LS, TH and FN | OSTA ≤ 2 T-score at any sites ≤ −2.5 | 95.7 | 33.6 | 0.702 | |
| Zha et al. (2014) [4] | To validate OSTA and QUS and their combination in predicting OP among the high-risk population | Chinese men (mean age: 78.0 years) | 472 | DXA (Discovery A, Hologic, USA) QUS (Sahara clinical bone sonometer- Hologic) BMD at LS and LH | OSTA < −3.5 FN T-score < −2.5 | 65.5 | 74.8 | 0.724 | Small sample size Sample recruited from a single centre |
| OSTA < −3.5 TH T-score < −2.5 | 81.8 | 72.7 | 0.787 | ||||||
| OSTA < −3.5 LS T-score < −2.5 | 45.4 | 74.7 | 0.652 | ||||||
| OSTA < −3.5 T-score at any site < −2.5 | 47.3 | 76.8 | 0.676 | ||||||
| QUS < −1.15 FN T-score < −2.5 | 88.9 | 47.4 | 0.762 | ||||||
| QUS < −2.15 TH T-score < −2.5 | 82.4 | 86.6 | 0.883 | ||||||
| QUS < −1.25 LS T-score < −2.5 | 82.7 | 57.9 | 0.750 | ||||||
| QUS < −1.25 T-score at any site < −2.5 | 80.4 | 59.7 | 0.762 | ||||||
| Chang & Yang (2016) [25] | To conduct a cutoff study among males by using OST, BMI, age and body weight | Retrospective data of Northern Taiwan males with mean age of 71.9 ± 13.3 years | 834 | DXA BMD at FN | OST < −1.86 T-score ≤ −2.5 | 69.2 | 63 | 0.70 | Subjects were patients referred to BMD test by orthopaedic surgeons |
| BMI < 23 kg/m2 T-score ≤ −2.5 | 60.4 | 61.6 | 0.63 | ||||||
| Weight < 58.8 kg T-score ≤ −2.5 | 43.9 | 78.2 | 0.66 | ||||||
| Kung et al. (2003) [28] | To develop OSTA for Asian men | Community-dwelling Chinese men (age: 50–93 years) | 420 | Development followed by validation in 356 men DXA: QDR 2000 Plus Hologic, Waltham, MA, USA BMD at LS and LF QUS: Sahara Hologic, Waltham, MA, USA | Development: OSTA < −1 T-score ≤ −2.5 | 73 | 68 | 0.790 | Subjects were not selected randomly |
| Validation: OSTA < −1 T-score ≤ −2.5 | 71 | 68 | 0.780 | ||||||
| Validation: QUI < −1.2 T-score ≤ −2.5 | 76 | 72 | 0.80 | ||||||
| Either OSTA <−1 or QUI < −2.5 T-score ≤ −2.5 | 88 | 64 | 0.82 | ||||||
| Chan et al. (2006) [30] | To compare the validity of various OP risk indices in elderly Chinese females | Community-dwelling postmenopausal women (age ≥55) | 135 | DXA (Hologic QDR 4500 W) BMD at FN and LS | OSTA (cutoff ≤ −2 FN T-score ≤ −2.5 LS T-score ≤ −2.5 | 90.9 | 58.8 | 0.82 | Small sample size |
| 91.9 | 42.9 | 0.73 | |||||||
| SCORE (cutoff ≥ 8) FN T-score ≤ −2.5 LS T-score ≤ −2.5 | 93.9 | 60.8 | 0.80 | ||||||
| 86.5 | 60.2 | 0.72 | |||||||
| ORAI (cutoff ≥ 20) FN T-score ≤ −2.5 LS T-score ≤ −2.5 | 75.8 | 66.7 | 0.76 | ||||||
| 62 | 62 | 0.68 | |||||||
| ABONE (cutoff = 3) FN T-score ≤ −2.5 LS T-score ≤ −2.5 | 81.8 | 55.9 | 0.70 | ||||||
| 73 | 54.1 | 0.66 | |||||||
| SCORE (cutoff ≥ 8) FN T-score ≤ | 67.9 | 77.5 | 0.78 | ||||||
| 62.2 | 76.5 | 0.73 | |||||||
| Chaovisitsaree et al. (2007) [19] | To compare OSTA with DXA in determining osteopenia and osteoporosis menopausal women | Thai menopausal women (age range: 45–87 years) from Menopause Clinic in Chiang Mai University | 315 | DXA BMD at FN, LS and radius | OSTA < −1 LS T-score ≤−1 FN T-score ≤−1 Radius T-score ≤−1 | 36.2 | 71.4 | Value not mentioned | |
| 40.6 | 72.0 | ||||||||
| 48.3 | 75.1 | ||||||||
| OSTA < −1 LS T-score ≤−2.5 FN T-score ≤−2.5 Radius T-score ≤−2.5 | 45.8 | 68.9 | |||||||
| 75.0 | 67.8 | ||||||||
| 60 | 68.5 | ||||||||
| Chen et al. (2016) [27] | To compare the performance of different screening tools to predict fracture or OP risk among older people | Community-dwelling older people aged 60 and above (mean age: 67.4 ± 6,4 years) recruited from Tanzi District, Taiwan | 553 | DXA Hologic Discovery Wi Bone Densitometer BMD at FN QUS GE Lunar, Madison, WI | QUS FN T-score ≤ −2.5 | 20 (M) 59 (F) | 86 (M) 75 (F) | 0.72(M) 0.77(F) | |
| ABONE ≥ 2 | 100 (M) 100 (F) | 28 (M) 10 (F) | 0.78(M) 0.70(F) | ||||||
| BWC < 70 kg | 100 (M) 100 (F) | 36 (M) 7 (F) | 0.92(M) 0.80(F) | ||||||
| FRAX Hip fracture (>3%) | 80 (M) 83 (F) | 71 (M) 54 (F) | 0.86(M) 0.75(F) | ||||||
| MOF (>20%) | 0 (M) 17 (F) | 99 (M) 96 (F) | 0.77(M) 0.71(F) | ||||||
| GARVAN Hip fracture (>3%) | 60 (M) 28 (F) | 79 (M) 95 (F) | 0.72(M) 0.80(F) | ||||||
| Any osteoporotic fracture (>20%) | 20 (M) 55 (F) | 96 (M) 73 (F) | 0.72(M) 0.75(F) | ||||||
| ORAI ≥ 9 | 100 (M) 100 (F) | 19 (M) 5 (F) | 0.87(M) 0.77(F) | ||||||
| OSIRIS ≤ 1 | 100 (M) 100 (F) | 29 (M) 6 (F) | 0.94(M) 0.83(F) | ||||||
| OSTA ≤ −1 | 100 (M) 100 (F) | 58 (M) 27 (F) | 0.94(M) 0.83(F) | ||||||
| SCORE ≥ 6 | 100 (M) 100 (F) | 45 (M) 15 (F) | 0.91(M) 0.80(F) | ||||||
| Chen et al. (2017) [35] | To establish a prediction model to identify osteopenia risk in women aged 40–55 years | Taiwanese women recruited from a health checkup centre | 1350 | DXA (DPX-L; GE Lunar Health Care, Madison, WI, USA) BMD at LS | OSTA ≤ 1 | 78 | 47 | 0.69 | Novel algorithm to predict osteopenia |
| OPAT ≥ 1 −1 ≥ T-score > −2.5 at LS | 87 | 42 | 0.77 | ||||||
| Panichyawat & Tanmahasamut (2012) [31] | To compare the performance of OSTA and Khon Kaen Osteoporosis Study (KKOS) scoring system to predict OP among postmenopausal women in Thailand | Postmenopausal women (mean age: 55.8 ± 5.9 years) from menopause clinic | 441 | DXA BMD at FN and TH | OSTA = −1 T-score at any site ≤ −2.5 | 51.7 | 77.4 | 0.65 | Subjects from a single centre |
| OSTA = 0 T-score at any site ≤ −2.5 | 66.7 | 57.1 | 0.62 | ||||||
| KKOS = −1 T-score at any site ≤ −2.5 | 56.3 | 71.8 | 0.64 | ||||||
| KKOS = 0 T-score at any site ≤ −2.5 | 57.5 | 67.2 | 0.62 | ||||||
| Oh et al. (2013) [36] | To develop Korean Osteoporosis Risk-Assessment Model (KORAM) and compare its performance with OSTA | Postmenopausal women who participated in the 2009 and 2010 Korean National Health and Nutrition Examination Survey | Development: 1209 Validation: 1046 | DXA QDR Discovery, Hologic BMD at TF, FN and LS | Development: OSTA < 0 FN or LS T-score < −2.5 | 96.8 | 28.3 | 0.626 | |
| OSTA < 0 FN or LS T-score < −2.0 | 93.7 | 34.6 | 0.641 | ||||||
| KORAM < −9 FN or LS T-score < −2.5 | 91.2 | 50.6 | 0.709 | ||||||
| KORAM < −9 FN or LS T-score < −2.0 | 85.2 | 60.1 | 0.726 | ||||||
| Validation: OSTA <0 FN or LS T-score < −2.5 | 94.2 | 29.2 | 0.617 | ||||||
| OSTA < 0 FN or LS T-score < −2.0 | 90.9 | 35.0 | 0.629 | ||||||
| KORAM < −9 FN or LS T-score < −2.5 | 84.8 | 51.6 | 0.682 | ||||||
| KORAM < −9 FN or LS T-score < −2.0 | 79.2 | 60.2 | 0.697 | ||||||
| Lim et al. (2011) [37] | To develop and validate Malaysian Osteoporosis Screening Tool (MOST) to detect low BMD in Malaysia | Healthy women (mean age: 51.3 ± 5.4 years) from a residential area | Development: 514 Validation: 72 | DXA Norland XR-36 BMD at FN and LS | OST < 2 FN T-score ≤−2.5 | 88 | 52 | Value not mentioned | |
| ORAI > 8 FN T-score ≤−2.5 | 90 | 52 | |||||||
| SCORE > 7 FN T-score ≤−2.5 | 89 | 58 | |||||||
| SOFSURF > −1 FN T-score ≤−2.5 | 92 | 37 | |||||||
| MOST ≥ 4 FN/LS T-score ≤−2.5 | Development: 80.2 Validation: 100 | Development: 55.5 Validation: 67.6 | |||||||
| Ma et al. (2016) [33] | To compare the performance of OSTA and BFH in determining osteoporosis among postmenopausal Han Chinese women | Community-dwelling Han Chinese postmenopausal women with age range of 40–89 years (mean age: 60.71 ± 8.47 years) | 1721 | DXA Hologic Discovery QDR Wi BMD at LS, FN and TH | OSTA < −1 T-score at any sites <−2.5 | 65.28 | 77.15 | 0.782 | Subjects from a single centre |
| BFH-OST < −9.1 T-score at any sites <−2.5 | 73.58 | 72.66 | 0.797 | ||||||
| Lin et al. (2017) [32] | To assess the performance new screening tool to determine osteoporosis | Development phase: Community-dwelling Han Chinese males aged 50 and above (mean age: 65.42 ± 8.8) Validation phase: Hospital-dwelling Han Chinese men | Development: 1870 Validation: 574 | DXA Discovery Wi, QDR series, Hologic, Waltham, MA, USA BMD at hip and LS | Development: BFH-OSTM ≤ 70 T-score < −2.5 | 84.96 | 53.49 | 0.763 | |
| Validation: OSTA ≤ −1 T-score < −2.5 | 50.42 | 82.20 | 0.732 | ||||||
| BFH-OSTM ≤ 70 T-score < −2.5 | 89.92 | 48.57 | 0.795 | ||||||
| Satyaraddi et al. (2017) [34] | To evaluate the performance of OSTA and Male Osteoporosis Risk Estimation Score (MORES) in predicting OP among South Indian rural elderly men | Indian men aged 65 and above (mean age: 71.9 ± 5.2 years) recruited by cluster random sampling | 512 | DXA Hologic QDR4500 Discovery A BMD at LS and FN | OSTA ≤ 2 LS T-score ≤ −2.5 | 94 | 17 | 0.716 | Further validation study is needed for a larger cohort of subjects |
| FN T-score ≤ −2.5 | 99 | 18 | 0.778 | ||||||
| MORES ≥ 6 LS T-score ≤ −2.5 | 98 | 15 | 0.855 | ||||||
| FN T-score ≤ −2.5 | 98 | 13 | 0.760 |
Abbreviation: AP, anteroposterior; AUC, area under curve; BMD, bone mineral density; BWC, body weight criteria; LS, lumbar spine; FN, femoral neck; TH, total hip; MOF, Major osteoporotic fracture; OP, osteoporosis; PF, proximal femur.
Table 2.
Performance of OST for non-Asians.
| Study | Objective | Subject Description | Number of Subjects Recruited | Methods | Cutoff | Sensitivity (%) | Specificity (%) | AUC | Remarks |
|---|---|---|---|---|---|---|---|---|---|
| Richy et al. 2004 [10] | To validate and compare the performance of OST with other osteoporosis risk indices | Postmenopausal White women (mean age: 61.5 ± 8.8 years) without Paget’s disease or advanced osteoarthritis | 4035 | DXA: Hologic QDR 2000 BMD at any site | OST < 2 T-score ≤ −2.5 T-score ≤ −2 | 86 82 | 40 44 | 0.726 0.713 | Subjects were either referred or came spontaneously for osteoporosis evaluation and may differ in some ways from the general population |
| SCORE > 7 T-score ≤ −2.5 T-score ≤ −2 | 86 78 | 40 46 | 0.708 0.700 | ||||||
| ORAI > 8 T-score ≤ −2.5 T-score ≤ −2 | 76 73 | 48 51 | 0.670 0.668 | ||||||
| OSIRIS < 1 T-score ≤ −2.5 T-score ≤ −2 | 64 58 | 69 73 | 0.730 0.717 | ||||||
| Cadarette et al. 2004 [38] | To validate the performance of osteoporosis risk indices to determine women at high risk of osteoporosis | Women (mean age: 62.4 years) with age range of 45–90 years | 644 | DXA BMD at FN and LS | ORAI > 8 T-score < −2.5 | 92.5 | 38.7 | 0.80 | The study included data from women who have been selected for BMD testing |
| OST chart <2 T-score < −2.5 | 91.5 | 45.7 | 0.82 | ||||||
| OST equation < 2 T-score < −2.5 | 95.3 | 39.6 | 0.82 | ||||||
| Body weight criterion < 70 kg | 93.4 | 34.6 | 0.73 | ||||||
| Adler et al. 2003 [40] | To assess the performance of OST in men | American men (mean age: 64.3 ± 12.3 years) recruited from pulmonary and rheumatology clinic | 181 | Hologic QDR 4500 (Hologic, Inc., Bedford, MA, USA) BMD at LS, FN and TH | OST = 3 T-score ≤ −2.5 | 93 | 66 | 0.836 | The study was not designed specifically to validate OST Small sample size |
| OST= 3 T-score ≤ −2.0 | 74 | 72 | 0.815 | ||||||
| Ghazi et al. (2007) [41] | To evaluate the performance of OST in predicting men with low BMD | White men (age range: 50–85 years) from a hospital in Morocco | 229 | DXA Lunar Prodigy Vision machine (GE) BMD at TH and LS | OST = 2 TH T-score ≤ −2.5 | 87.5 | 58.2 | 0.787 | |
| OST = 2 LS T-score ≤ −2.5 | 63.6 | 59.5 | 0.660 | ||||||
| OST = 2 T-score ≤ −2.5 at any site | 64 | 60.3 | 0.667 | ||||||
| Lynn et al. (2008) [43] | To evaluate the use of OST, Male Osteoporosis Screening Tool (MOST) and Quantitative Ultrasound Index (QUI) and body weight as osteoporosis screening tools | Caucasian and Hong Kong Chinese men, aged ≥ 65 years and community-dwelling from Osteoporotic Fractures in Men (MrOS) Study | 4658 Caucasian men 1914 Hong Kong Chinese men | DXA Hologic QDR 4500 W (Hologic Inc.) BMD at LS and PF | Caucasian: | ||||
| OST ≤1 T-score at any site ≤ −2.5 | 79.3 | 48.5 | 0.714 | ||||||
| OST ≤2 T-score at any site ≤ −2.5 | 87.6 | 36.1 | |||||||
| MOST ≤26 T-score at any site ≤ −2.5 | 88.5 | 50 | 0.799 | ||||||
| MOST ≤27 T-score at any site ≤ −2.5 | 94.7 | 37.8 | |||||||
| Chinese: | |||||||||
| OST ≤−2 T-score at any site ≤ −2.5 | 81.8 | 56.2 | 0.759 | ||||||
| OST ≤−1 T-score at any site ≤ −2.5 | 91.9 | 36.4 | |||||||
| MOST ≤21 T-score at any site ≤ −2.5 | 86.8 | 59.3 | 0.831 | ||||||
| MOST ≤22 T-score at any site ≤ −2.5 | 94.2 | 42.3 | |||||||
| Gourlay et al. (2005) [39] | To compare the performance of three osteoporosis risk indices in two different age groups. | Postmenopausal women aged 45–96 years | 4035 | DXA: Hologic QDR 1000, 2000 and 4500 (Hologic Inc., Waltham, MA, USA) BMD at FN | OST ≤ 1 Ages 45−64 years | 89.2 | 45 | 0.768 | Subjects from a single centre |
| OST ≤ −1 Ages ≥ 65 years | 84.6 | 47.5 | 0.762 | ||||||
| ORAI ≥ 8 Ages 45−64 years | 88.5 | 46.2 | 0.750 | ||||||
| ORAI ≥ 13 Ages ≥ 65 years | 89.2 | 44.7 | 0.747 | ||||||
| SCORE ≥ 7 Ages 45−64 years | 88.5 | 39.8 | 0.757 | ||||||
| SCORE ≥ 11 Ages ≥ 65 years | 88.8 | 42.3 | 0.745 | ||||||
| Sinnott et al. (2006) [42] | To assess the performance of QUS, OST, WBC and BMI to predict low BMD in African American | African American men (age: 35 and above) recruited from clinics | 128 | DXA: GE Lunar (General Electric, Madison, WI, USA) BMD at LS and non-dominant hip QUS Achilles Plus System (Lunar, Madison, WI, USA) | QUS ≤ −1 T-score ≤ −2.0 | 83 | 71 | 0.80 | Small sample size |
| OST < 4 T-score ≤ −2.0 | 83 | 57 | 0.83 | ||||||
| WBC < 85 kg | 74 | 50 | 0.70 | ||||||
| BMI ≥ 30 | 83 | 43 | 0.70 | ||||||
| Machado et al. (2009) [44] | To compare three different OP risk indices at different cutoffs in determining individuals who are at risk of OP | Portuguese men age 50 and above (mean age: 63.77 ± 8.22 years) | 202 | DXA: Hologic QDR4500/c BMD at LS and PF | OST < 1 OST < 2 OST < 3 OST < 4 | 47.1 61.8 75.5 85.3 | 72.6 63.7 50.0 32.7 | 0.598 0.627 0.632 0.590 | |
| OSTA < 1 OSTA < 2 OSTA < 3 OSTA < 4 | 38.2 55.9 73.5 76.5 | 82.1 67.9 58.3 42.9 | 0.602 0.619 0.659 0.597 | ||||||
| BWC < 65 kg BWC < 70 kg BWC < 75 kg BWC < 80 kg | 26.5 47.1 73.5 82.4 | 89.3 77.4 61.3 35.7 | 0.579 0.622 0.674 0.590 | ||||||
| Richards et al. (2014) [57] | To determine the performance of OST in predicting osteoporosis in males. | Male US veterans above 50 years recruited from VA Medical Centers | 518 | DXA: Hologic (Bedford, MA, USA) BMD at TH, LS or DF | OST ≤ 6 T-score ≤ −2.5 | 82.6 | 33.6 | 0.67 | DXA machines from differed manufacturers were used and the results were not standardized. |
| Crandall et al. [54] [47] | To compare the performance of USPSTF (FRAX) with OST and SCORE to predict osteoporosis | Women aged 50–64 years who participated Women’s Health Initiative Observational Study and Clinical Trials at three of the 40 clinical centres | 5165 | DXA Hologic QDR2000 or QDR4500 (Bedford, MA, USA) BMD at hip or LS | USPSTF (FRAX ≥ 9.3%) FN T-score ≤ −2.5 | 34.1 | 85.8 | 0.60 | |
| OST <2 FN T-score ≤ −2.5 | 79.8 | 66.3 | 0.73 | ||||||
| SCORE >7 FN T-score ≤ −2.5 | 74 | 70.8 | 0.72 | ||||||
| Geusens et al (2002) [51] | To compare the performance of 4 osteoporosis risk indices in determining postmenopausal women with low BMD | Women (45 years and above) from US clinic, Rotterdam Study (55 years and above), women screened for a clinical trial (55 to 81 years old) and women from the general clinic (50 to 80 years) | 1102 women from US clinic 3374 women from Rotterdam Study 23,833 women screened for a clinical trial 4204 women from the general clinic | DXA Hologic (Waltham, MA, USA); Norland (Fort Atkinson, WI, USA); and Lunar (Madison, WI, USA) BMD at FN or LS | OST <2 T-score ≤−2.5 | 88 | 52 | Value not mentioned | Large sample size Selection bias may occur |
| ORAI >8 T-score ≤−2.5 | 90 | 52 | |||||||
| SCORE >7 T-score ≤−2.5 | 89 | 58 | |||||||
| SOFSURF >−1 T-score ≤−2.5 | 92 | 37 | |||||||
| Wallace et al. (2004) [48] | To compare the performance of five osteoporosis risk indices in determining postmenopausal African-American women with low BMD | Women (mean age: 59.4 ± 12.5 years) from an osteoporosis study | 174 | DXA Hologic QDR 2000 BMD at FN | ABONE ≥ 2 T-score ≤ −2.5 | 73.0 | 59.6 | Value not mentioned | Small sample size |
| ORAI ≥ 9 T-score ≤ −2.5 | 65.6 | 78.9 | |||||||
| OST < 2 T-score ≤ −2.5 | 75.4 | 75.0 | |||||||
| SCORE ≥ 6 T-score ≤ −2.5 | 83.6 | 53.9 | |||||||
| Weight Criterion < 70 kg T-score ≤ −2.5 | 68.9 | 69.2 | |||||||
| Zimering et al. (2007) [55] | To compare a novel osteoporosis screening tool with OST in predicting low BMD | Development phase: Caucasian men (mean age: 68.4 ± 10.2 years) Validation phase: Caucasian men (mean age: 68.4 ± 10.2 years) African American men (mean age: 60.9 ± 13 years) | Development: 639 Caucasian men Validation: 197 Caucasian men 134 African American | DXA Hologic QDR 4500 SL machine (Waltham, MA, USA) BMD at FN, TH and LS | Caucasian Mscore (cutoff = 9) FN T-score ≤ −2.5 | 88 | 57 | 0.84 | Mscore is the first validated risk assessment tool developed in men |
| OST (cutoff= 4) FN T-score ≤ −2.5 | 85 | 51 | 0.81 | ||||||
| M score age-weight (cutoff = 9) FN T-score ≤ −2.5 | 85 | 58 | 0.81 | ||||||
| African American Mscore = 9 FN T-score ≤ −2.5 | NT | NT | NT | ||||||
| OST (cutoff = 4) FN T-score ≤ −2.5 | 100 | 72 | 0.99 | ||||||
| Mscore age-weight (cutoff = 9) FN T-score ≤ −2.5 | 100 | 73 | 0.99 | ||||||
| Jiang et al. (2016) [52] | To compare the performance of screening tools with BMI alone in identifying early postmenopausal women with OP | Postmenopausal women (mean age: 57 ± 4.2 years) | 445 | DXA | BMI < 28 | 95 | 38 | 0.73 | Small sample size Low statistical power of detecting the difference in AUCs |
| OST < 2 T-score ≤ −2.5 | 79 | 56 | 0.73 | ||||||
| ORAI ≥ 9 T-score ≤ −2.5 | 74 | 60 | 0.69 | ||||||
| SCORE ≥ 6 T-score ≤ −2.5 | 92 | 34 | 0.75 | ||||||
| USPSTF ≥ 9.3% | 24 | 83 | 0.62 | ||||||
| RF ≥ 1 risk factors | 66 | 62 | 0.64 | ||||||
| Pecina et al. (2016) [53] | To compare the effectiveness of risk tools to predict OP in women aged 50–64 | Retrospective data of women (mean age: 56.6 ± 3.4) who underwent DXA scan in a clinic | 290 | DXA BMD at hip/LS | USPSTF FRAX ≥ 9.3% | 36 | 73 | 0.55 | |
| SCORE ≥ 6 | 74 | 42 | 0.58 | ||||||
| OST < 2 | 56 | 69 | 0.63 | ||||||
| ORAI ≥ 9 | 52 | 67 | 0.60 | ||||||
| Hawker et al. (2012) [56] | To develop a screening tool to guide bone density testing in healthy mid-life women | Healthy women (age range 40–60) receiving their first BMD in an urban teaching hospital | 944 | DXA Lunar Prodigy (GE Healthcare, Madison WI, USA) BMD at FN, TH and LS | New tool T-score ≤ −2.0 | 93 | 36 | 0.75 | Only Caucasian population is involved |
| OST ≤1 T-score ≤ −2.0 | 47 | Value not mentioned | 0.69 | ||||||
| Cook et al. (2005) [49] | To assess the performance of various osteoporosis screening tools and quantitative ultrasound in relation to DXA scan | Postmenopausal women (age range: 29–87 years) recruited from DXA scanning clinics | 208 | DXA Hologic QDR 4500 C (Hologic Inc., Bedford, MA, USA) BMD at LS and PF | OST < −1 T-score ≤ −2.5 | 0.52 | 0.82 | 0.716 | |
| SCORE T-score ≤ −2.5 | 0.5 | 0.83 | 0.720 | ||||||
| ORAI T-score ≤ −2.5 | 0.43 | 0.86 | 0.664 | ||||||
| QUS BUA calcaneus T-score ≤ −2.5 | 0.56 | 0.92 | 0.766 | ||||||
| VOS calcaneus T-score ≤ −2.5 | 0.61 | 0.72 | 0.723 | ||||||
| Perez-Castrillon et al. (2007) [46] | To identify if the combination of OST and calcaneal DXA improves the diagnosis of OP | Males with a mean age of 47 ± 13 years and females with mean age of 66 ± 8 years recruited from two university hospitals | 67 males 94 females | DXA: Pixi-Lunar, DPXL Lunar (Madison, WI, USA) and Hologic QDR-4500; Hologic Inc. (Bedford, MD, USA) BMD at right calcaneal and hip | Men OST≤3 T-score < −2.5 | 39 | 86 | 0.623 | Small sample size |
| Women OST ≤ 2 T-score < −2.5 | 94 | 59 | 0.762 | ||||||
| Richards et al. (2009) [47] | To evaluate the performance of OST in predicting low BMD in male patients with rheumatoid arthritis | Males (mean age: 65.4 ± 10.5 years) recruited from a multicenter registry of rheumatoid arthritis | 795 | DXA Hologic Inc. (Bedford, MA, USA) BMD at Femur and LS | OST ≤ 4 | 64 | 54 | Not mentioned | Low lean body mass in RA could limit the utility of the OST in this population |
Abbreviation: AP, anteroposterior; AUC, area under curve; BMD, bone mineral density; LS, lumbar spine; FN, femoral neck; TH, total hip; NT, not tested; OP, osteoporosis; PF, proximal femur; QUS, quantitative ultrasound; RF, Risk Factor-Based Approach; USPSTF, the U.S. Preventive Services Task Force; WBC, Weight-based Criterion.
Table 3.
Performance of OST to predict fracture risk.
| Study | Objective | Subject Description | Number of Subjects Recruited | Methods | Cutoff | Sensitivity (%) | Specificity (%) | AUC | Remarks |
|---|---|---|---|---|---|---|---|---|---|
| Yang et al. (2013) [53] | To validate the performance of OSTA in determining vertebral fracture among postmenopausal women in China | Postmenopausal women (average age: 62 years) recruited from OP clinic in Beijing, China | 1201 | DXA Hologic, Inc. (Bedford, MA, USA) BMD at LS, FN and TH | OSTA < −1 and fracture | 81.7 | 66 | 0.812 | All subjects are recruited from one single OP centre |
| Crandall et al. (2014) [54] | To compare the performance of USPSTFS, OST and SCORE in predicting fracture risk among postmenopausal women | Postmenopausal women aged 50–64 years who participated in Women’s Health Initiative Observational Study and Clinical Trials | 62,492 | DXA Hologic QDR2000 or QDR4500 (Bedford, MA, USA) BMD at hip or LS | USPSTF(FRAX) ≥9.3% | 25.8 | 83.3 | 0.56 | |
| SCORE > 7 | 38.6 | 65.8 | 0.53 | ||||||
| OST < 2 | 39.8 | 60.7 | 0.52 | ||||||
| Lin et al. (2016) [55] | To validate the use of three tools in predicting new osteoporotic fractures in older Chinese men | Han Chinese men aged 50 and above | 496 | DXA Discovery Wi, QDR, Hologic (Waltham, MA, USA) BMD at FN, LS and TH | TH T-score < −1.4 | 67.57 | 65.45 | 0.711 | Subjects from a single centre Two different groups of population were involved OSTA less effective in predicting risk |
| FN T-score < −2.5 | 42.34 | 89.87 | 0.706 | ||||||
| LS T-score < −1.6 | 52.25 | 77.14 | 0.706 | ||||||
| FRAX > 2.9 | 81.98 | 62.08 | 0.738 | ||||||
| OSTA < −1.2 | 53.15 | 76.88 | 0.661 | ||||||
| Liu et al. (2017) [56] | To evaluate the performance of Singh score and OSTA in predicting hip fracture in patients with type 2 diabetes mellitus | Postmenopausal women with 87 of them (age range: 56–86 years) had a hip fracture | 261 | DXA Discovery W, Hologic, Inc. (Bedford, MA, USA) BMD at hip and LS Retrospective Singh score: Standard digital anteroposterior radiographs | LS T-score < −1.85 | 60.9 | 77 | 0.747 | Small sample size |
| TH T-score < −2.45 | 52.9 | 71.8 | 0.699 | ||||||
| FN T-score <−2.05 | 74.7 | 47.1 | 0.659 | ||||||
| Femoral trochanter T-score <−2.25 | 50.6 | 69.5 | 0.631 | ||||||
| OSTA < −2.5 | 44.8 | 73.8 | 0.534 | ||||||
| Singh index < 2.5 OSTA and Singh | 42.5 Value not mentioned | 88.2 Value not mentioned | 0.636 0.795 |
AUC, area under curve; BMD, bone mineral density; LS, lumbar spine; FN, femoral neck; TH, total hip; OP, osteoporosis; USPSTF, the U.S. Preventive Services Task Force.
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Subramaniam, S.; Ima-Nirwana, S.; Chin, K.-Y. Performance of Osteoporosis Self-Assessment Tool (OST) in Predicting Osteoporosis—A Review. Int. J. Environ. Res. Public Health 2018, 15, 1445. https://doi.org/10.3390/ijerph15071445
AMA Style
Subramaniam S, Ima-Nirwana S, Chin K-Y. Performance of Osteoporosis Self-Assessment Tool (OST) in Predicting Osteoporosis—A Review. International Journal of Environmental Research and Public Health. 2018; 15(7):1445. https://doi.org/10.3390/ijerph15071445
Chicago/Turabian StyleSubramaniam, Shaanthana, Soelaiman Ima-Nirwana, and Kok-Yong Chin. 2018. "Performance of Osteoporosis Self-Assessment Tool (OST) in Predicting Osteoporosis—A Review" International Journal of Environmental Research and Public Health 15, no. 7: 1445. https://doi.org/10.3390/ijerph15071445
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