Tayfur Beyza, Ritsche Paul, Sunderlik Olivia, Wheeler Madison, Ramirez Eric, Leuteneker Jacob, Faude Oliver, Franchi Martino V, Johnson Alexa K, Palmieri-Smith Riann
School of Kinesiology, University of Michigan, Ann Arbor, MI, USA; Orthopedic Rehabilitation & Biomechanics (ORB) Laboratory, University of Michigan, Ann Arbor, MI, USA.
Department of Sport, Exercise and Health, University of Basel, Basel, Switzerland.
Ultrasound Med Biol. 2025 Feb;51(2):364-372. doi: 10.1016/j.ultrasmedbio.2024.11.004. Epub 2024 Nov 23.
Deep learning approaches such as DeepACSA enable automated segmentation of muscle ultrasound cross-sectional area (CSA). Although they provide fast and accurate results, most are developed using data from healthy populations. The changes in muscle size and quality following anterior cruciate ligament (ACL) injury challenges the validity of these automated approaches in the ACL population. Quadriceps muscle CSA is an important outcome following ACL injury; therefore, our aim was to validate DeepACSA, a convolutional neural network (CNN) approach for ACL injury.
Quadriceps panoramic CSA ultrasound images (vastus lateralis [VL] n = 430, rectus femoris [RF] n = 349, and vastus medialis [VM] n = 723) from 124 participants with an ACL injury (age 22.8 ± 7.9 y, 61 females) were used to train CNN models. For VL and RF, combined models included extra images from healthy participants (n = 153, age 38.2, range 13-78) that the DeepACSA was developed from. All models were tested on unseen external validation images (n = 100) from ACL-injured participants. Model predicted CSA results were compared to manual segmentation results.
All models showed good comparability (ICC > 0.81, < 14.1% standard error of measurement, mean differences of <1.56 cm) to manual segmentation. Removal of the erroneous predictions resulted in excellent comparability (ICC > 0.94, < 7.40% standard error of measurement, mean differences of <0.57 cm). Erroneous predictions were 17% for combined VL, 11% for combined RF, and 20% for ACL-only VM models.
The new CNN models provided can be used in ACL-injured populations to measure CSA of VL, RF, and VM muscles automatically. The models yield high comparability to manual segmentation results and reduce the burden of manual segmentation.
诸如DeepACSA之类的深度学习方法能够实现肌肉超声横截面积(CSA)的自动分割。尽管它们能提供快速且准确的结果,但大多数是使用来自健康人群的数据开发的。前交叉韧带(ACL)损伤后肌肉大小和质量的变化对这些自动方法在ACL人群中的有效性提出了挑战。股四头肌CSA是ACL损伤后的一项重要结果;因此,我们的目的是验证DeepACSA,一种用于ACL损伤的卷积神经网络(CNN)方法。
来自124名ACL损伤参与者(年龄22.8±7.9岁,61名女性)的股四头肌全景CSA超声图像(股外侧肌[VL]n = 430,股直肌[RF]n = 349,股内侧肌[VM]n = 723)用于训练CNN模型。对于VL和RF,组合模型包括DeepACSA所基于的来自健康参与者(n = 153,年龄38.2岁,范围13 - 78岁)的额外图像。所有模型均在来自ACL损伤参与者的未见外部验证图像(n = 100)上进行测试。将模型预测的CSA结果与手动分割结果进行比较。
所有模型与手动分割显示出良好的可比性(组内相关系数>0.81,测量标准误差<14.1%,平均差异<1.56平方厘米)。去除错误预测后具有出色的可比性(组内相关系数>0.94,测量标准误差<7.40%,平均差异<0.57平方厘米)。VL组合模型的错误预测率为17%,RF组合模型为11%,仅ACL的VM模型为20%。
所提供的新CNN模型可用于ACL损伤人群,以自动测量VL、RF和VM肌肉的CSA。这些模型与手动分割结果具有高度可比性,并减轻了手动分割的负担。
