Testing the Performance of an Innovative Markerless Technique for Quantitative and Qualitative Gait Analysis

Simoni, Laura; Scarton, Alessandra; Gerli, Filippo; Macchi, Claudio; Gori, Federico; Pasquini, Guido; Pogliaghi, Silvia

doi:10.3390/s20226654

Cited by 5 publications

(20 citation statements)

References 50 publications

(98 reference statements)

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“…In the present study an additional index (i.e., Synchron Index) was developed and proposed to describe the global gait quality. Both the Harmony and Synchrony Indexes are in arbitrary units [35]. The analysis starts with the subdivision of the video file into frames, allowing us to obtain a number (n) of individual JPEG images For each pixel of each image, the software computes the brightness via a brightness edi algorithm [35,43], followed by the application of a specific correction method called th Hanning window and a high-pass Butterworth filter with order 2 at 0.5 Hz to attenuat the component due to direct current [44].…”

Section: Methodsmentioning

confidence: 99%

“…The analysis starts with the subdivision of the video file into frames, allowing us to obtain a number (n) of individual JPEG images For each pixel of each image, the software computes the brightness via a brightness edi algorithm [35,43], followed by the application of a specific correction method called th Hanning window and a high-pass Butterworth filter with order 2 at 0.5 Hz to attenuat the component due to direct current [44]. After this preprocessing, the fast Fourier trans form (FFT) algorithm used in [35] is applied to the vector of brightnes values over time for each pixel to obtain its magnitude in the frequency domain. The resul is a power spectrum for each pixel that displays the magnitude as a function of frequency and permits us to identify the peaks of the dominant frequencies [35].…”

Section: Methodsmentioning

confidence: 99%

“…To ameliorate th process of peak frequency detection presented in Simoni et al (2020), power spectra fo each pixel are then averaged in order to obtain the Averaged Power Spectrum of the video and the signal is then further processed using the detrend MATLAB function in order to attenuate the effect of flickering or pink noise [44] (Figure 1). A simple peak detection is thus performed to extract the peaks with the highes power between 0 and 15 Hz, as indicated in [35]. The frequencies o the first two largest peaks are named F1 and F2 and have been demonstrated to corre spond, respectively, to stride frequency and cadence, expressed in Hz units, for walking gait [35].…”

Section: Methodsmentioning

confidence: 99%

“…Assuming that F2 corresponds to step frequency or cadence, the Graal system indi rectly estimates the spatial parameter step length as follows [35,45,46]: A simple peak detection is thus performed to extract the peaks with the highest power between 0 and 15 Hz, as indicated in [35]. The frequencies of the first two largest peaks are named F1 and F2 and have been demonstrated to correspond, respectively, to stride frequency and cadence, expressed in Hz units, for walking gait [35].…”

Section: Methodsmentioning

confidence: 99%

“…Assuming that F2 corresponds to step frequency or cadence, the Graal system indirectly estimates the spatial parameter step length as follows [35,45,46]:…”

Section: Methodsmentioning

confidence: 99%

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Quantitative and Qualitative Running Gait Analysis through an Innovative Video-Based Approach

Simoni

Scarton

Macchi

et al. 2021

Sensors

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Quantitative and qualitative running gait analysis allows the early identification and the longitudinal monitoring of gait abnormalities linked to running-related injuries. A promising calibration- and marker-less video sensor-based technology (i.e., Graal), recently validated for walking gait, may also offer a time- and cost-efficient alternative to the gold-standard methods for running. This study aim was to ascertain the validity of an improved version of Graal for quantitative and qualitative analysis of running. In 33 healthy recreational runners (mean age 41 years), treadmill running at self-selected submaximal speed was simultaneously evaluated by a validated photosensor system (i.e., Optogait—the reference methodology) and by the video analysis of a posterior 30-fps video of the runner through the optimized version of Graal. Graal is video analysis software that provides a spectral analysis of the brightness over time for each pixel of the video, in order to identify its frequency contents. The two main frequencies of variation of the pixel’s brightness (i.e., F1 and F2) correspond to the two most important frequencies of gait (i.e., stride frequency and cadence). The Optogait system recorded step length, cadence, and its variability (vCAD, a traditional index of gait quality). Graal provided a direct measurement of F2 (reflecting cadence), an indirect measure of step length, and two indexes of global gait quality (harmony and synchrony index). The correspondence between quantitative indexes (Cadence vs. F2 and step length vs. Graal step length) was tested via paired t-test, correlations, and Bland–Altman plots. The relationship between qualitative indexes (vCAD vs. Harmony and Synchrony Index) was investigated by correlation analysis. Cadence and step length were, respectively, not significantly different from and highly correlated with F2 (1.41 Hz ± 0.09 Hz vs. 1.42 Hz ± 0.08 Hz, p = 0.25, r2 = 0.81) and Graal step length (104.70 cm ± 013.27 cm vs. 107.56 cm ± 13.67 cm, p = 0.55, r2 = 0.98). Bland–Altman tests confirmed a non-significant bias and small imprecision between methods for both parameters. The vCAD was 1.84% ± 0.66%, and it was significantly correlated with neither the Harmony nor the Synchrony Index (0.21 ± 0.03, p = 0.92, r2 = 0.00038; 0.21 ± 0.96, p = 0.87, r2 = 0.00122). These findings confirm the validity of the optimized version of Graal for the measurement of quantitative indexes of gait. Hence, Graal constitutes an extremely time- and cost-efficient tool suitable for quantitative analysis of running. However, its validity for qualitative running gait analysis remains inconclusive and will require further evaluation in a wider range of absolute and relative running intensities in different individuals.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

“…Assuming that F2 corresponds to step frequency or cadence, the Graal system indirectly estimates the spatial parameter step length as follows [35,45,46]:…”

Section: Methodsmentioning

confidence: 99%

See 3 more Smart Citations

Quantitative and Qualitative Running Gait Analysis through an Innovative Video-Based Approach

Simoni

Scarton

Macchi

et al. 2021

Sensors

Self Cite

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Image Processing for the Rehabilitation Assessment of Locomotion Injuries and Post Stroke Disabilities

Bejinariu

Luca

Onu

et al. 2021

2021 International Conference on E-Health and Bioengineering (EHB)

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Multi‐feature gait analysis approach using deep learning in constraint‐free environment

2023

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A quantitative gait assessment system is crucial for clinical analysis and decision‐making. Such rigorous evaluation involves costly clinical setups and domain experts for observation and analysis. To circumvent such constraints, the proposed work is conducted in a markerless environment and divided into three stages: First, we prepared a markerless gait database using videos from MNIT RAMAN LABORATORY in Jaipur. Second, we adapt the skeletal landmark data to generate kinematic gait characteristics comparable to gold‐standard marker‐based techniques. We provide a novel set of parameters based on video sequences and spatiotemporal and sagittal kinematic parameters to optimize accuracy and reliability. Third, we develop multi‐feature based gait analysis, an ensemble model based on Convolutional Neural Networks + LSTM (Long‐Short Term Memory), for gait classification. In addition, we deployed transfer learning models to correlate with our ensemble model. The findings indicate that gait analysis can be used successfully in a low‐cost clinical gait monitoring system in a constraint‐free environment. While considering the multiple gait variables, our proposed model attained an accuracy of 95.3%. Our model for quantifying gait analysis will improve access to quantitative gait analysis in clinics and rehabilitation centers and enable researchers to conduct large‐scale studies for gait‐related disorders.

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Testing the Performance of an Innovative Markerless Technique for Quantitative and Qualitative Gait Analysis

Cited by 5 publications

References 50 publications

Quantitative and Qualitative Running Gait Analysis through an Innovative Video-Based Approach

Quantitative and Qualitative Running Gait Analysis through an Innovative Video-Based Approach

Image Processing for the Rehabilitation Assessment of Locomotion Injuries and Post Stroke Disabilities

Multi‐feature gait analysis approach using deep learning in constraint‐free environment

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