Remote assessment of pelvic kinematics during single leg squat using smartphone sensors: Between-day reliability and identification of acute changes in motor performance

Devecchi, Valter; Saunders, Michelle; Galaiya, Sajni; Shaw, Millie; Gallina, Alessio

doi:10.1371/journal.pone.0288760

Cited by 2 publications

(1 citation statement)

References 30 publications

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“…For instance, three-dimensional pelvic kinematics during single leg squats has been shown to be reliable between days when assessed remotely using smartphone sensors [70]. Orientation data was recorded using Matlab Mobile (sampling frequency set at 10 Hz, Multimedia appendix 6) with a smartphone placed on the skin over a participant's sacrum, held in place using the elastic band of the participant's clothing.…”

Section: Pelvic Orientation During Single-leg Squatmentioning

confidence: 99%

Assessment of human motion using smartphone sensors: a tutorial for education, research and practice (Preprint)

Gallina,

Vieira

2024

Preprint

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UNSTRUCTURED Sport science and rehabilitation are naturally evolving towards the implementation of data-driven technology for the analysis of human motion. Analysis of movement has traditionally been taught, researched, and implemented in practice either visually, or using equipment often unavailable outside specialized research centers. The motion sensors in contemporary smartphones can be used to collect acceleration and orientation data, making smartphones widely-available, low-cost devices that may provide useful in the characterization of human motion. The aim of this tutorial is to review basic concepts of how acceleration and orientation data collected with smartphone sensors can be used to assess human motion. We include six examples of data collection and analysis: jump height, balance, jogging cadence, joint range of motion, pelvic orientation during single-leg squat, timed up-and-go test. Acceleration and orientation data related to each example were analyzed using spreadsheet editors; video tutorials provide step-by-step guidance on how to analyze the data. Results are interpreted with respect to biomechanics, performance analysis and potential clinical relevance. We discuss this approach in the context of education, research and practice, hoping that it will help promote data-driven education and practice in fields that may benefit from objective analysis of human motion, such as sport science and rehabilitation.

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Section: Pelvic Orientation During Single-leg Squatmentioning

confidence: 99%

Assessment of human motion using smartphone sensors: a tutorial for education, research and practice (Preprint)

Gallina,

Vieira

2024

Preprint

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Assessment of pelvic motion during single leg weightbearing tasks using smartphone sensors: a validity study (Preprint)

Xi,

Li,

Vatatheeswaran

et al. 2024

Preprint

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BACKGROUND Clinicians and athletic training specialists often assess performance of single leg, weightbearing tasks to monitor rehabilitation progress and guide exercise progression. Some of the key metrics assessed are excessive pelvic motion, balance, and duration of each repetition of the exercise. Motion can be objectively characterized using motion capture; however, motion capture is often not available in clinics due to high costs and complexity of the analyses. Smartphones have built-in sensors that can be used to measure changes in body segment orientation and acceleration, which may make them a more feasible and affordable technology to use in practice. OBJECTIVE This study aimed to determine if, compared to gold-standard motion capture, smartphone sensors can provide valid measures of pelvic orientation, acceleration and repetition duration during single leg tasks in healthy individuals. METHODS Fifty-two healthy participants performed single leg squats, and step down tasks from heights of 15 and 20 cm. Pelvic motion was assessed using motion capture and a smartphone placed over the sacrum. The Matlab Mobile application was used to collect smartphone acceleration and orientation data. Individual repetitions of each exercise were manually identified, and the following outcomes were extracted: duration of the repetition, medio-lateral acceleration, and three-dimensional pelvic orientation at peak squat. Validity was assessed by comparing metrics assessed with smartphone and motion capture using intraclass correlation coefficients (ICCs) and paired Wilcoxon tests. Differences between tasks were compared using one-way ANOVA or Friedman's test. RESULTS Across the three single leg tasks, smartphone estimates demonstrated consistently high agreement with the motion capture for all metrics (ICC point estimates: >.8 for medio-lateral acceleration and frontal plane orientation, >.9 for squat duration and orientation on the sagittal and transverse plane). Bias was identified for most outcomes (multiple p<.001). Both smartphone and motion capture recordings identified clear differences between tasks, with step down tasks usually requiring larger changes in pelvic orientation and larger medio-lateral sways. Duration did not differ between tasks. CONCLUSIONS Despite a consistent bias, the smartphone demonstrated good to excellent validity relative to gold-standard motion capture for all outcomes. This demonstrates that smartphones offer an accessible and affordable tool to objectively characterize pelvic motion during different single leg weightbearing tasks. Together with earlier reports of good between-day reliability of similar measures during single leg squats, our results suggest that smartphone sensors can be used to assess and monitor single leg task performance, both in the clinic and remotely. Future studies should investigate whether personalized interventions based on motion assessment performed with smartphone sensors, and monitored using smartphone sensors, are more effective than conventional care. CLINICALTRIAL N/A

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Remote assessment of pelvic kinematics during single leg squat using smartphone sensors: Between-day reliability and identification of acute changes in motor performance

Cited by 2 publications

References 30 publications

Assessment of human motion using smartphone sensors: a tutorial for education, research and practice (Preprint)

Assessment of human motion using smartphone sensors: a tutorial for education, research and practice (Preprint)

Assessment of pelvic motion during single leg weightbearing tasks using smartphone sensors: a validity study (Preprint)

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