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Sensitiveness of Variables Extracted from a Fitness Smartwatch to Detect Changes in Vertical Impact Loading during Outdoors Running.

Cristina-Ioana PîrșcoveanuAnderson Souza Oliveira
Published in: Sensors (Basel, Switzerland) (2023)
Accelerometry is becoming a popular method to access human movement in outdoor conditions. Running smartwatches may acquire chest accelerometry through a chest strap, but little is known about whether the data from these chest straps can provide indirect access to changes in vertical impact properties that define rearfoot or forefoot strike. This study assessed whether the data from a fitness smartwatch and chest strap containing a tri-axial accelerometer (FS) is sensible to detect changes in running style. Twenty-eight participants performed 95 m running bouts at ~3 m/s in two conditions: normal running and running while actively reducing impact sounds (silent running). The FS acquired running cadence, ground contact time (GCT), stride length, trunk vertical oscillation (TVO), and heart rate. Moreover, a tri-axial accelerometer attached to the right shank provided peak vertical tibia acceleration (PK ACC ). The running parameters extracted from the FS and PK ACC variables were compared between normal and silent running. Moreover, the association between PK ACC and smartwatch running parameters was accessed using Pearson correlations. There was a 13 ± 19% reduction in PK ACC ( p < 0.005), and a 5 ± 10% increase in TVO from normal to silent running ( p < 0.01). Moreover, there were slight reductions (~2 ± 2%) in cadence and GCT when silently running ( p < 0.05). However, there were no significant associations between PK ACC and the variables extracted from the FS (r < 0.1, p > 0.05). Therefore, our results suggest that biomechanical variables extracted from FS have limited sensitivity to detect changes in running technique. Moreover, the biomechanical variables from the FS cannot be associated with lower limb vertical loading.
Keyphrases
  • high intensity
  • heart rate
  • physical activity
  • lower limb
  • heart rate variability
  • machine learning