肩部的MRI肌肉横截面积可以预测肌肉体积:一项尸体的MRI研究。

Heath B. Henninger, Garrett V. Christensen, Carolyn E. Taylor, J. Kawakami, Bradley Hillyard, R. Tashjian, P. Chalmers
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引用次数: 11

摘要

背景:肌肉体积对肩部功能很重要。它可以用来估计肩部肌肉在健康、病理和修复方面的平衡,并且是基于肌肉大小的力量指标。虽然先前的研究表明,二维(2-D)图像上的肌肉面积与三维(3-D)肌肉体积相关,但他们没有提供从成像中预测肌肉体积的方程,也没有验证测量结果。问题/目的我们希望创建一种算法,该算法可以快速,准确,可靠地估计肩部肌肉的体积,使用MR图像上的横截面积,误差低。具体来说,我们希望(1)确定哪个MR成像平面在肩部肌肉横截面积和体积之间提供最高的相关性;(2)推导由横截面积预测肌肉体积的方程,并验证其预测能力;(3)量化肌肉横截面积测量的可靠性。方法对10具尸体肩部进行三维MRI扫描,选取的样本量与以往肩部肌肉体积的研究进行比较,并考虑到综合分析的成本,然后进行解剖,用水置换法测量肌肉体积。从每个MR系列中,生成旋转袖肌和三角肌的三维模型,并在定义的解剖标志处选择这些肌肉模型的二维切片。生成线性回归方程来预测体积和面积之间相关性最高的平面和先前肌肉体积和面积研究中确定的平面上的肌肉体积。通过对六具不同尸体的肩部进行核磁共振扫描,他们也做出了体积预测,然后对其进行解剖,以量化肌肉体积。该验证人群允许计算与实际肌肉体积相比的预测误差。最后,测量MR图像上肌肉面积的可靠性使用类内相关系数计算,作为在单个时间点在两个观察者之间测量的可靠性。结果肩袖体积与面积相关性最高的平面为肩胛关节面与肩胛骨中点之和,三角肌为大结节顶部的横切面。水和数字肌肉体积高度相关(r≥0.993,误差< 4%),肌肉面积与体积高度相关(r≥0.992,误差< 2%)。所有相关性p < 0.001。预测肌肉体积的平均误差较低(< 10%)。所有类内相关系数均> 0.925,表明MR图像确定肌肉面积具有较高的类间可靠性。结论MRI可可靠测量三角肌和肩袖肌横截面积,预测肌肉体积误差小。临床相关性使用简单的线性方程,来自常见临床图像分析软件的二维肌肉面积测量可用于从MR图像数据估计三维肌肉体积。未来的研究应该确定这些肌肉体积的估计值是否可以用于评估患者的功能、肩部健康的变化以及肌肉萎缩的人群。此外,这些肌肉体积估计技术可以作为输入到肌肉骨骼模型检查动力学和运动学的人类依赖于主体特定的肌肉结构。
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The Muscle Cross-sectional Area on MRI of the Shoulder Can Predict Muscle Volume: An MRI Study in Cadavers.
BACKGROUND Muscle volume is important in shoulder function. It can be used to estimate shoulder muscle balance in health, pathology, and repair and is indicative of strength based on muscle size. Although prior studies have shown that muscle area on two-dimensional (2-D) images correlates with three-dimensional (3-D) muscle volume, they have not provided equations to predict muscle volume from imaging nor validation of the measurements. QUESTIONS/PURPOSES We wished to create an algorithm that quickly, accurately, and reliably estimates the volume of the shoulder muscles using cross-sectional area on MR images with low error. Specifically, we wished to (1) determine which MR imaging planes provide the highest correlation between shoulder muscle cross-sectional area and volume; (2) derive equations to predict muscle volume from cross-sectional area and validate their predictive capability; and (3) quantify the reliability of muscle cross-sectional area measurement. METHODS Three-dimensional MRI was performed on 10 cadaver shoulders, with sample size chosen for comparison to prior studies of shoulder muscle volume and in consideration of the cost of comprehensive analysis, followed by dissection for muscle volume measurement via water displacement. From each MR series, 3-D models of the rotator cuff and deltoid muscles were generated, and 2-D slices of these muscle models were selected at defined anatomic landmarks. Linear regression equations were generated to predict muscle volume at the plane(s) with the highest correlation between volume and area and for planes identified in prior studies of muscle volume and area. Volume predictions from MR scans of six different cadaver shoulders were also made, after which they were dissected to quantify muscle volume. This validation population allowed the calculation of the predictive error compared with actual muscle volume. Finally, reliability of measuring muscle areas on MR images was calculated using intraclass correlation coefficients for inter-rater reliability, as measured between two observers at a single time point. RESULTS The rotator cuff planes with the highest correlation between volume and area were the sum of the glenoid face and the midpoint of the scapula, and for the deltoid, it was the transverse plane at the top of the greater tuberosity. Water and digital muscle volumes were highly correlated (r ≥ 0.993, error < 4%), and muscle areas correlated highly with volumes (r ≥ 0.992, error < 2%). All correlations had p < 0.001. Muscle volume was predicted with low mean error (< 10%). All intraclass correlation coefficients were > 0.925, suggesting high inter-rater reliability in determining muscle areas from MR images. CONCLUSION Deltoid and rotator cuff muscle cross-sectional areas can be reliably measured on MRI and predict muscle volumes with low error. CLINICAL RELEVANCE Using simple linear equations, 2-D muscle area measurements from common clinical image analysis software can be used to estimate 3-D muscle volumes from MR image data. Future studies should determine if these muscle volume estimations can be used in the evaluation of patient function, changes in shoulder health, and in populations with muscle atrophy. Additionally, these muscle volume estimation techniques can be used as inputs to musculoskeletal models examining kinetics and kinematics of humans that rely on subject-specific muscle architecture.
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