Kroneberg Daniel, Elshehabi Morad, Meyer Anne-Christiane, Otte Karen, Doss Sarah, Paul Friedemann, Nussbaum Susanne, Berg Daniela, Kühn Andrea A, Maetzler Walter, Schmitz-Hübsch Tanja
Charité - Universitätsmedizin Berlin, Corporate Member of Freie Universität Berlin, Humboldt-Universität zu Berlin, and Berlin Institute of Health, Department of Neurology, Berlin, Germany.
Department of Neurology, Universitätsklinikum Schleswig-Holstein, Kiel, Germany.
Front Aging Neurosci. 2019 Jan 21;10:435. doi: 10.3389/fnagi.2018.00435. eCollection 2018.
Gait variability is an established marker of gait function that can be assessed using sensor-based approaches. In clinical settings, spatial constraints and patient condition impede the execution of longer distance walks for the recording of gait parameters. Turning paradigms are often used to overcome these constraints and commercial gait analysis systems algorithmically exclude turns for gait parameters calculations. We investigated the effect of turns in sensor-based assessment of gait variability. Continuous recordings from 31 patients with movement disorders (ataxia, essential tremor and Parkinson's disease) and 162 healthy elderly (HE) performing level walks including 180° turns were obtained using an inertial sensor system. Accuracy of the manufacturer's algorithm of turn-detection was verified by plotting stride time series. Strides before and after turn events were extracted and compared to respective average of all strides. Coefficient of variation (CoV) of stride length and stride time was calculated for entire set of strides, segments between turns and as cumulative values. Their variance and congruency was used to estimate the number of strides required to reliably assess the magnitude of stride variability. Non-detection of turns in 5.8% of HE lead to falsely increased CoV for these individuals. Even after exclusion of these, strides before/after turns tended to be spatially shorter and temporally longer in all groups, contributing to an increase of CoV at group level and widening of confidence margins with increasing numbers of strides. This could be attenuated by a more generous turn excision as an alternative approach. Correlation analyses revealed excellent consistency for CoVs after at most 20 strides in all groups. Respective stride counts were even lower in patients using a more generous turn excision. Including turns to increase continuous walking distance in spatially confined settings does not necessarily improve the validity and reliability of gait variability measures. Specifically with gait pathology, perturbations of stride characteristics before/after algorithmically excised turns were observed that may increase gait variability with this paradigm. We conclude that shorter distance walks of around 15 strides suffice for reliable and valid recordings of gait variability in the groups studied here.
步态变异性是一种既定的步态功能标志物,可通过基于传感器的方法进行评估。在临床环境中,空间限制和患者状况阻碍了为记录步态参数而进行的较长距离行走。转弯范式常用于克服这些限制,而商业步态分析系统会通过算法排除转弯以进行步态参数计算。我们研究了转弯在基于传感器的步态变异性评估中的影响。使用惯性传感器系统,对31名患有运动障碍(共济失调、特发性震颤和帕金森病)的患者以及162名健康老年人(HE)进行包括180°转弯的水平行走的连续记录。通过绘制步幅时间序列来验证制造商转弯检测算法的准确性。提取转弯事件前后的步幅,并与所有步幅的各自平均值进行比较。计算整个步幅集、转弯之间的段以及累积值的步幅长度和步幅时间的变异系数(CoV)。它们的方差和一致性用于估计可靠评估步幅变异性大小所需的步幅数量。5.8%的健康老年人未检测到转弯导致这些个体的CoV错误增加。即使排除这些个体,所有组中转弯前后的步幅在空间上往往更短,在时间上更长,导致组水平上CoV增加,并且随着步幅数量增加置信区间变宽。作为一种替代方法,更宽松的转弯切除可以减弱这种情况。相关性分析显示,所有组中最多20步后的CoV具有极佳的一致性。使用更宽松转弯切除的患者的相应步幅计数甚至更低。在空间受限的环境中纳入转弯以增加连续行走距离并不一定会提高步态变异性测量的有效性和可靠性。特别是对于步态病理学,观察到在算法切除转弯前后步幅特征的扰动,这可能会通过这种范式增加步态变异性。我们得出结论,在此处研究的组中,约15步的较短距离行走足以可靠且有效地记录步态变异性。
