Department of Radiology, Image Sciences Institute, UMC Utrecht, Utrecht, Netherlands.
Department of Orthopaedic Surgery, UMC Utrecht, Utrecht, Netherlands.
Eur J Radiol. 2024 Aug;177:111542. doi: 10.1016/j.ejrad.2024.111542. Epub 2024 Jun 1.
Visualization of scoliosis typically requires ionizing radiation (radiography and CT) to visualize bony anatomy. MRI is often additionally performed to screen for neural axis abnormalities. We propose a 14-minutes radiation-free scoliosis-specific MRI protocol, which combines MRI and MRI-based synthetic CT images to visualize soft and osseous structures in one examination. We assess the ability of the protocol to visualize landmarks needed to detect 3D patho-anatomical changes, screen for neural axis abnormalities, and perform surgical planning and navigation.
18 adult volunteers were scanned on 1.5 T MR-scanner using 3D T2-weighted and synthetic CT sequences. A predefined checklist of relevant landmarks was used for the parameter assessment by three readers. Parameters included Cobb angles, rotation, torsion, segmental height, area and centroids of Nucleus Pulposus and Intervertebral Disc. Precision, reliability and agreement between the readers measurements were evaluated.
91 % of Likert-based questions scored ≥ 4, indicating moderate to high confidence. Precision of 3D dot positioning was 1.0 mm. Precision of angle measurement was 0.6° (ICC 0.98). Precision of vertebral and IVD height measurements was 0.4 mm (ICC 0.99). Precision of area measurement for NP was 8 mm (ICC 0.55) and for IVD 18 mm (ICC 0.62) for IVD. Precision of centroid measurement for NP was 1.3 mm (ICC 0.88-0.92) and for IVD 1.1 mm (ICC 0.88-91).
The proposed MRI protocol with synthetic CT reconstructions, has high precision, reliability and agreement between the readers for multiple scoliosis-specific measurements. It can be used to study scoliosis etiopathogenesis and to assess 3D spinal morphology.
脊柱侧凸的可视化通常需要电离辐射(射线照相和 CT)来可视化骨解剖结构。通常还会进行 MRI 以筛查中枢神经系统异常。我们提出了一种 14 分钟的无辐射性脊柱特异性 MRI 方案,该方案将 MRI 和基于 MRI 的合成 CT 图像结合在一起,可在一次检查中可视化软组织和骨结构。我们评估了该方案检测三维病理解剖变化所需的标志的能力,筛查中枢神经系统异常,以及进行手术计划和导航的能力。
18 名成年志愿者在 1.5 T 磁共振扫描仪上使用 3D T2 加权和合成 CT 序列进行扫描。三位读者使用预定义的相关标志清单对参数进行评估。参数包括 Cobb 角、旋转、扭转、节段高度、椎间盘和髓核的面积和质心。评估了读者测量值的精度、可靠性和一致性。
91%的基于 Likert 量表的问题评分≥4,表明具有中等至高的置信度。3D 点定位的精度为 1.0 毫米。角度测量的精度为 0.6°(ICC 0.98)。椎体和 IVD 高度测量的精度为 0.4 毫米(ICC 0.99)。NP 的面积测量精度为 8 毫米(ICC 0.55),IVD 的面积测量精度为 18 毫米(ICC 0.62)。NP 的质心测量精度为 1.3 毫米(ICC 0.88-0.92),IVD 的质心测量精度为 1.1 毫米(ICC 0.88-91)。
该方案使用合成 CT 重建,具有较高的精度、可靠性和读者之间的一致性,可用于研究脊柱侧凸的病因发病机制和评估脊柱的三维形态。
