AUTHOR=Blanco-Coloma Laura , García-González Lucía , Sinovas-Alonso Isabel , Torio-Álvarez Silvia , Martos-Hernández Paula , González-Expósito Sara , Gil-Agudo Ángel , Herrera-Valenzuela Diana 

TITLE=Validation of inertial measurement units based on waveform similarity assessment against a photogrammetry system for gait kinematic analysis

JOURNAL=Frontiers in Bioengineering and Biotechnology

VOLUME=12

YEAR=2024

URL=https://www.frontiersin.org/journals/bioengineering-and-biotechnology/articles/10.3389/fbioe.2024.1449698

DOI=10.3389/fbioe.2024.1449698

ISSN=2296-4185

ABSTRACT=<p>When assessing gait analysis outcomes for clinical use, it is indispensable to use an accurate system ensuring a minimal measurement error. Inertial Measurement Units (IMUs) are a versatile motion capture system to evaluate gait kinematics during out-of-lab activities and technology-assisted rehabilitation therapies. However, IMUs are susceptible to distortions, offset and drifting. Therefore, it is important to have a validated instrumentation and recording protocol to ensure the reliability of the measurements, to differentiate therapy effects from system-induced errors. A protocol was carried out to validate the accuracy of gait kinematic assessment with IMUs based on the similarity of the waveform of concurrent signals captured by this system and by a photogrammetry reference system. A gait database of 32 healthy subjects was registered synchronously with both devices. The validation process involved two steps: 1) a preliminary similarity assessment using the Pearson correlation coefficient, and 2) a similarity assessment in terms of correlation, displacement and gain by estimating the offset between signals, the difference between the registered range of motion (∆ROM), the root mean square error (RMSE) and the interprotocol coefficient of multiple correlation (CMC<sub>P</sub>). Besides, the CMC<sub>P</sub> was recomputed after removing the offset between signals (CMC<sub>Poff</sub>). The correlation was strong (r &gt; 0.75) for both limbs for hip flexion/extension, hip adduction/abduction, knee flexion/extension and ankle dorsal/plantar flexion. These joint movements were studied in the second part of the analysis. The ∆ROM values obtained were smaller than 6°, being negligible relative to the minimally clinically important difference (MCID) estimated for unaffected limbs, and the RMSE values were under 10°. The offset for hips and ankles in the sagittal plane reached -9° and -8°, respectively, whereas hips adduction/abduction and knees flexion/extension were around 1°. According to the CMC<sub>P</sub>, the kinematic pattern of hip flexion/extension (CMC<sub>P</sub> &gt; 0.90) and adduction/abduction (CMC<sub>P</sub> &gt; 0.75), knee flexion/extension (CMC<sub>P</sub> &gt; 0.95) and ankle dorsi/plantar flexion (CMC<sub>P</sub> &gt; 0.90) were equivalent when captured by each system synchronously. However, after offset correction, only hip flexion/extension (CMC<sub>Poff</sub> = 1), hip adduction/abduction (CMC<sub>Poff</sub> &gt; 0.85) and knee flexion/extension (CMC<sub>Poff</sub> &gt; 0.95) satisfied the conditions to be considered similar.</p>