Whelan Darragh F, O'Reilly Martin A, Ward Tomás E, Delahunt Eamonn, Caulfield Brian
Darragh Whelan, Insight UCD, Science Centre EAST, Belfield, Dublin 4, Ireland, E-mail:
Methods Inf Med. 2017 Oct 26;56(5):361-369. doi: 10.3414/ME16-01-0141. Epub 2017 Jun 14.
The barbell squat is a popularly used lower limb rehabilitation exercise. It is also an integral exercise in injury risk screening protocols. To date athlete/patient technique has been assessed using expensive laboratory equipment or subjective clinical judgement; both of which are not without shortcomings. Inertial measurement units (IMUs) may offer a low cost solution for the objective evaluation of athlete/patient technique. However, it is not yet known if global classification techniques are effective in identifying naturally occurring, minor deviations in barbell squat technique.
The aims of this study were to: (a) determine if in combination or in isolation, IMUs positioned on the lumbar spine, thigh and shank are capable of distinguishing between acceptable and aberrant barbell squat technique; (b) determine the capabilities of an IMU system at identifying specific natural deviations from acceptable barbell squat technique; and (c) compare a personalised (N=1) classifier to a global classifier in identifying the above.
Fifty-five healthy volunteers (37 males, 18 females, age = 24.21 +/- 5.25 years, height = 1.75 +/- 0.1 m, body mass = 75.09 +/- 13.56 kg) participated in the study. All participants performed a barbell squat 3-repetition maximum max strength test. IMUs were positioned on participants' lumbar spine, both shanks and both thighs; these were utilized to record tri-axial accelerometer, gyroscope and magnetometer data during all repetitions of the barbell squat exercise. Technique was assessed and labelled by a Chartered Physiotherapist using an evaluation framework. Features were extracted from the labelled IMU data. These features were used to train and evaluate both global and personalised random forests classifiers.
Global classification techniques produced poor accuracy (AC), sensitivity (SE) and specificity (SP) scores in binary classification even with a 5 IMU set-up in both binary (AC: 64%, SE: 70%, SP: 28%) and multi-class classification (AC: 59%, SE: 24%, SP: 84%). However, utilising personalised classification techniques even with a single IMU positioned on the left thigh produced good binary classification scores (AC: 81%, SE: 81%, SP: 84%) and moderate-to-good multi-class scores (AC: 69%, SE: 70%, SP: 89%).
There are a number of challenges in developing global classification exercise technique evaluation systems for rehabilitation exercises such as the barbell squat. Building large, balanced data sets to train such systems is difficult and time intensive. Minor, naturally occurring deviations may not be detected utilising global classification approaches. Personalised classification approaches allow for higher accuracy and greater system efficiency for end-users in detecting naturally occurring barbell squat technique deviations. Applying this approach also allows for a single-IMU set up to achieve similar accuracy to a multi-IMU setup, which reduces total system cost and maximises system usability.
杠铃深蹲是一种常用的下肢康复训练动作。它也是损伤风险筛查方案中的一项重要训练动作。迄今为止,评估运动员/患者的技术时,使用的是昂贵的实验室设备或主观临床判断;这两种方法都有缺点。惯性测量单元(IMU)可能为客观评估运动员/患者的技术提供一种低成本的解决方案。然而,尚不清楚全局分类技术是否能有效识别杠铃深蹲技术中自然出现的微小偏差。
本研究的目的是:(a)确定位于腰椎、大腿和小腿上的IMU单独或组合使用时,是否能够区分可接受的和异常的杠铃深蹲技术;(b)确定IMU系统识别与可接受的杠铃深蹲技术存在的特定自然偏差的能力;(c)比较个性化(N=1)分类器和全局分类器在识别上述情况方面的表现。
55名健康志愿者(37名男性,18名女性,年龄=24.21±5.25岁,身高=1.75±0.1米,体重=75.09±13.56千克)参与了本研究。所有参与者进行了杠铃深蹲3次最大重复量的最大力量测试。IMU分别放置在参与者的腰椎、双侧小腿和双侧大腿上;在杠铃深蹲练习的所有重复过程中,利用这些IMU记录三轴加速度计、陀螺仪和磁力计数据。由一名特许物理治疗师使用评估框架对技术进行评估和标记。从标记的IMU数据中提取特征。这些特征用于训练和评估全局和个性化随机森林分类器。
即使在二元分类中使用5个IMU设置,全局分类技术在二元分类中的准确率(AC)、灵敏度(SE)和特异性(SP)得分也很低(二元分类中:AC:64%,SE:70%,SP:28%;多分类中:AC:59%,SE:24%,SP:84%)。然而,使用个性化分类技术,即使只在左大腿上放置一个IMU,也能获得良好的二元分类得分(AC:81%,SE:81%,SP:84%)和中等至良好的多分类得分(AC:69%,SE:70%,SP:89%)。
为杠铃深蹲等康复训练动作开发全局分类运动技术评估系统存在诸多挑战。构建大型、平衡的数据集来训练此类系统既困难又耗时。使用全局分类方法可能无法检测到自然出现的微小偏差。个性化分类方法能为终端用户在检测自然出现的杠铃深蹲技术偏差时提供更高的准确性和更高的系统效率。应用这种方法还可以使单IMU设置达到与多IMU设置相似的准确性,从而降低系统总成本并最大限度提高系统可用性。
