Concurrent validity of walking speed measured by a wearable sensor and a stopwatch during the 10-meter walk test in individuals with stroke

Concurrent validity of walking speed measured by a wearable sensor and a stopwatch during the 10-meter walk test in individuals with stroke

Walking speed is often measured with a stopwatch throughout stroke recovery. Wearable sensors also have been used recently to measure walking speed and provide information about spatiotemporal characteristics of walking. Research Question: Do walking speeds measured with stopwatch and APDM wearable...

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Bibliographic Details
Published in:Gait & posture Vol. 107; pp. 61 - 66
Main Authors: Cleland, Brice T., Alex, Titus, Madhavan, Sangeetha
Format: Journal Article
Language:English
Published: England Elsevier B.V 01-01-2024
Subjects:
Gait
Gait speed
Humans
Locomotion
Reproducibility of Results
Stroke
Validation studies
Walk Test
Walking
Walking pace
Walking Speed
Wearable Electronic Devices
Locomotion
Stroke
Gait speed
Walking pace
Validation studies
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Summary:Walking speed is often measured with a stopwatch throughout stroke recovery. Wearable sensors also have been used recently to measure walking speed and provide information about spatiotemporal characteristics of walking. Research Question: Do walking speeds measured with stopwatch and APDM wearable sensors have concurrent validity? Individuals with chronic stroke (n = 62) performed the 10-meter walk test at comfortable and maximal speeds. Walking speeds were measured with a stopwatch and APDM Opal wireless wearable sensors (3-unit). Tests of concurrent validity between stopwatch and APDM (Bland-Altman plots, systematic and proportional bias, and intraclass correlations) and test-retest reliability between trials (intraclass correlations, standard error of measurement, and minimal detectable change) were performed. Walking speeds measured with APDM were ∼0.07 m/s slower than those measured with stopwatch (systematic bias; t ≥ 13.1, p < 0.001). Intraclass correlations ranged from poor to excellent. There were greater differences in walking speeds between APDM and stopwatch for individuals with faster walking speeds (proportional bias). Test-retest reliability was excellent for both APDM and stopwatch (intraclass correlation≥0.94). Standard error of measurement ranged from 0.04 to 0.07 m/s and minimal detectable change ranged from 0.10 to 0.19 m/s. Significance: It may be inappropriate to use walking speed measurements from APDM sensors and stopwatch interchangeably in individuals with chronic stroke. Differences in walking speeds may reflect stopwatch error or the derivation of walking speed from wearable sensors. Test-retest reliability was excellent for both stopwatch and APDM, but minimal detectable change values were large. Large changes in walking speed may be required to be confident that the change is a true and clinically meaningful change and not measurement error. The validity and reliability of measuring walking speed with wearable sensors in individuals with chronic stroke has important implications for determining community ambulation, assessing improvements after rehabilitation, and developing exercise prescriptions. •Walking speeds from stopwatch and wearable sensors had poor to excellent agreement.•Measures also had systematic and proportional bias.•Stopwatch and wearable sensors had excellent test-retest reliability.•Speeds from stopwatch and wearable sensors should not be used interchangeably.
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ISSN:0966-6362
1879-2219
DOI:10.1016/j.gaitpost.2023.09.012