Medical Physics Department, School of Medicine, Iran University of Medical Sciences, Tehran, Iran.
Quantitative Medical Imaging Systems Group, Research Center for Molecular and Cellular Imaging, Tehran University of Medical Sciences, Tehran, Iran; Medical Physics and Biomedical Engineering Department, Tehran University of Medical Sciences, Tehran, Iran.
J Clin Densitom. 2020 Jan-Mar;23(1):108-116. doi: 10.1016/j.jocd.2019.02.005. Epub 2019 Feb 22.
Cortical bone is affected by metabolic diseases. Some studies have shown that lower cortical bone mineral density (BMD) is related to increases in fracture risk which could be diagnosed by quantitative computed tomography (QCT). Nowadays, hybrid iterative reconstruction-based (HIR) computed tomography (CT) could be helpful to quantify the peripheral bone tissue. A key focus of this paper is to evaluate liquid calibration phantoms for BMD quantification in the tibia and under hybrid iterative reconstruction-based-CT with the different hydrogen dipotassium phosphate (KHPO) concentrations phantoms.
Four ranges of concentrations of KHPO were made and tested with 2 exposure settings. Accuracy of the phantoms with ash gravimetry and intermediate KHPO concentration as hypothetical patients were evaluated. The correlations and mean differences between measured equivalent QCT BMD and ash density as a gold standard were calculated. Relative percentage error (RPE) in CT numbers of each concentration over a 6-mo period was reported.
The correlation values (R was close to 1.0), suggested that the precision of QCT-BMD measurements using standard and ultra-low dose settings were similar for all phantoms. The mean differences between QCT-BMD and the ash density for low concentrations (about 93 mg/cm) were lower than high concentration phantoms with 135 and 234 mg/cm biases. In regard to accuracy test for hypothetical patient, RPE was up to 16.1% for the low concentration (LC) phantom for the case of high mineral content. However, the lowest RPE (0.4 to 1.8%) was obtained for the high concentration (HC) phantom, particularly for the high mineral content case. In addition, over 6 months, the KHPO concentrations increased 25% for 50 mg/cm solution and 0.7 % for 1300 mg/cm solution in phantoms.
The excellent linear correlations between the QCT equivalent density and the ash density gold standard indicate that QCT can be used with submilisivert radiation dose. We conclude that using liquid calibration phantoms with a range of mineral content similar to that being measured will minimize bias. Finally, we suggest performing BMD measurements with ultra-low dose scan concurrent with iterative-based reconstruction to reduce radiation exposure.
代谢性疾病会影响皮质骨。一些研究表明,较低的皮质骨骨密度(BMD)与骨折风险的增加有关,而这种增加可以通过定量计算机断层扫描(QCT)来诊断。如今,基于混合迭代重建的(HIR)计算机断层扫描(CT)可以帮助定量测量周围的骨组织。本文的一个重点是评估不同浓度二氢钾磷酸盐(KHPO)的液体校准体模,以用于基于混合迭代重建的 CT 对胫骨和周围骨组织的 BMD 定量。
制作了四个 KHPO 浓度范围并进行了测试,测试了两种曝光设置。评估了具有骨灰称重和中间 KHPO 浓度的假想患者的体模的准确性。计算了与骨灰密度作为金标准的测量等效 QCT BMD 之间的相关性和平均差异。报告了在 6 个月期间每个浓度的 CT 数的相对百分比误差(RPE)。
相关值(R 接近 1.0)表明,使用标准和超低剂量设置进行 QCT-BMD 测量的精度对于所有体模都相似。对于低浓度(约 93mg/cm),QCT-BMD 与骨灰密度之间的平均差异低于高浓度体模,偏差分别为 93 和 234mg/cm。关于假想患者的准确性测试,对于高矿物质含量的情况,低浓度(LC)体模的 RPE 高达 16.1%。然而,对于高浓度(HC)体模,特别是对于高矿物质含量的情况,获得了最低的 RPE(0.4 至 1.8%)。此外,在 6 个月期间,KHPO 浓度在 50mg/cm 溶液中增加了 25%,在 1300mg/cm 溶液中增加了 0.7%。
QCT 等效密度与骨灰密度金标准之间的优异线性相关性表明,QCT 可以在亚毫希弗辐射剂量下使用。我们得出结论,使用具有与正在测量的矿物质含量相似范围的液体校准体模将最大限度地减少偏差。最后,我们建议使用超低剂量扫描与基于迭代的重建相结合进行 BMD 测量,以减少辐射暴露。
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