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Abstract

The surge of wearable device technology has enabled out-of-the-lab collection of running gait data for commercial, clinical, and coaching applications. However, low sampling frequencies interfere with measuring peak acceleration magnitudes accurately, and the ability to track relative changes during a prolonged run with lower sampling devices is unknown. The purposes of this study were to compare peak resultant acceleration measured simultaneously at different sampling frequencies and evaluate if different sampling frequencies could track similar relative changes in peak acceleration over a 20-min treadmill run. Seventeen participants ran on a treadmill at a self-selected, “easy” pace for 20-min (mean ± SD = 2.6 ± 0.4 m s⁻¹). Three research-grade, triaxial accelerometers (“HiRes” = 1200 Hz, “MedRes” = 462 Hz, and “LoRes” = 100 Hz) were secured to each of three anatomical locations (tibia, low-back, forehead). Mean peak resultant accelerations from each device during minutes 3 to 18 were compared within each location (linear mixed model, α = 0.050). No significant device by timepoint interaction was observed (p > 0.999). A significant main effect of sampling frequency at all three locations (HiRes > MedRes > LoRes; p < 0.001) confirmed the underestimation of low sampling frequencies on peak resultant acceleration. However, the significant main effect of time indicated that peak resultant acceleration changed similarly over time between sampling frequencies at the tibia (p = 0.010) and head (p = 0.002), but not the low-back (p = 0.318). Downsampling HiRes to 400 and 100 Hz reduced the underestimation of the resultant peaks within the MedRes and LoRes signals by <7.7% across anatomical locations. This study confirms sampling frequency of wearable devices significantly affects peak resultant acceleration and demonstrates these effects are greater for signals captured at lower sampling frequencies and caudal locations. Despite these effects, this study cautiously supports the use of ≥100 Hz sampling frequencies for within-individual peak resultant acceleration tracking during “easy” prolonged runs for research, clinical, and coaching applications.

Keywords

Accelerometers wearable devices sampling frequency running gait tibial shock

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References

Hamill

Caldwell

Derrick

TR.

Reconstructing digital signals using Shannon's sampling theorem. J Appl Biomech 1997; 13: 226–238.

Mitschke

Zaumseil

Milani

TL.

The influence of inertial sensor sampling frequency on the accuracy of measurement parameters in rearfoot running. Comput Methods Biomech Biomed Eng 2017; 20: 1502–1511.

Tenforde

Hayano

Jamison

, et al. Tibial acceleration measured from wearable sensors is associated with loading rates in injured runners. PM R 2020; 12: 679–684.

Kiernan

Hawkins

Manoukian

MAC

, et al. Accelerometer-based prediction of running injury in National Collegiate Athletic Association track athletes. J Biomech 2018; 73: 201–209.

Gruber

McDonnell

Davis

4th , et al. Monitoring Gait complexity as an indicator for running-related injury risk in collegiate cross-country runners: a proof-of-concept study. Front Sports Act Living 2021; 3: 630975.

Winter

DA.

Biomechanics and motor control of human movement. 4th ed. New York: Wiley, 2009.

Nyquist

Certain topics in telegraph transmission theory. Trans Am Inst Electr Eng 1928; 47: 617–644.

Shorten

Winslow

DS.

Spectral analysis of impact shock during running. Int J Sport Biomech 1992; 8: 288–304.

Edwards

Derrick

Hamill

Musculoskeletal attenuation of impact shock in response to knee angle manipulation. J Appl Biomech 2012; 28: 502–510.

10.

Milner

Hawkins

Aubol

KG.

Tibial acceleration during running is higher in field testing than indoor testing. Med Sci Sports Exerc 2020; 52: 1361–1366.

11.

Reenalda

Maartens

Buurke

, et al. Kinematics and shock attenuation during a prolonged run on the athletic track as measured with inertial magnetic measurement units. Gait Posture 2019; 68: 155–160.

12.

Mizrahi

Verbitsky

Isakov

, et al. Effect of fatigue on leg kinematics and impact acceleration in long distance running. Hum Mov Sci 2000; 19: 139–151.

13.

Riebe

Franklin

Thompson

, et al. Updating ACSM's recommendations for exercise preparticipation health screening. Med Sci Sports Exerc 2015; 47: 2473–2479.

14.

Clermont

Benson

Osis

, et al. Running patterns for male and female competitive and recreational runners based on accelerometer data. J Sports Sci 2019; 37: 204–211.

15.

Gruber

Boyer

Derrick

, et al. Impact shock frequency components and attenuation in rearfoot and forefoot running. J Sport Health Sci 2014; 3: 113–121.

16.

Kiernan

Hawkins

May the force be with you: acceleration-based estimates of vertical ground reaction forces during running. Med Sci Sports Exerc 2020; 52: 216–216.

17.

Reenalda

Maartens

Homan

, et al. Continuous three dimensional analysis of running mechanics during a marathon by means of inertial magnetic measurement units to objectify changes in running mechanics. J Biomech 2016; 49: 3362–3367.

18.

Neugebauer

Collins

Hawkins

DA.

Ground reaction force estimates from ActiGraph GT3X+ hip accelerations. PLoS One 2014; 9: e99023.

19.

Borg

Hassmén

Lagerström

Perceived exertion related to heart rate and blood lactate during arm and leg exercise. Eur J Appl Physiol Occup Physiol 1987; 56: 679–685.

20.

PCB Piezotronics, Inc. Model 356A32 platinum stock products; triaxial, mini (5 gm) high sensitivity, ICP^® accel., Installation and operating manual, https://www.pcb.com/contentStore/docs/pcb_corporate/vibration/products/manuals/356a32.pdf Accessed May 1, 2021.

21.

Xsens Dynamics Technologies. 2006. MTi and MTx user manual and technical documentation. Enschede, The Netherlands.

22.

ActiGraph, LLC. ActiGraph GT3x-BT user's manual, https://actigraphcorp.com/actigraph-wgt3x-bt/ Accessed May 1, 2021.

23.

John

Sasaki

Staudenmayer

, et al. Comparison of raw acceleration from the Genea and ActiGraph^™ GT3X+ activity monitors. Sensors 2013; 13: 14754–14763.

24.

Hamill

Derrick

Holt

KG.

Shock attenuation and stride frequency during running. Hum Mov Sci 1995; 14: 45–60.

25.

Wosk

Voloshin

Wave attenuation in skeletons of young healthy persons. J Biomech 1981; 14: 261–267.

26.

Glass

Peckham

Sanders

JR.

Consequences of failure to meet assumptions underlying the fixed effects analyses of variance and covariance. Rev Educ Res 1972; 42: 237–288.

27.

Abt

Sell

Chu

, et al. Running kinematics and shock absorption do not change after brief exhaustive running. J Strength Cond Res 2011; 25: 1479–1485.

28.

Mercer

Bates

Dufek

, et al. Characteristics of shock attenuation during fatigued running. J Sports Sci 2003; 21: 911–919.

29.

Provot

Chiementin

Oudin

, et al. Validation of a high sampling rate inertial measurement unit for acceleration during running. Sensors 2017; 17: 1958.

30.

García-Pérez

Pérez-Soriano

Llana Belloch

, et al. Effects of treadmill running and fatigue on impact acceleration in distance running. Sports Biomech 2014; 13: 259–266.

31.

Mitschke

Kiesewetter

Milani

The effect of the accelerometer operating range on biomechanical parameters: stride length, velocity, and peak tibial acceleration during running. Sensors 2018; 18: 130.

32.

Potter

Ojeda

Perkins

, et al. Effect of IMU design on IMU-derived stride metrics for running. Sensors 2019; 19: 2601.

33.

Saha

Lakes

RS.

The effect of soft tissue on wave-propagation and vibration tests for determining the in vivo properties of bone. J Biomech 1977; 10: 393–401.

34.

Sheerin

Reid

Besier

TF.

The measurement of tibial acceleration in runners-a review of the factors that can affect tibial acceleration during running and evidence-based guidelines for its use. Gait Posture 2019; 67: 12–24.

35.

Valiant

McMahon

Frederick

. A new test to evaluate the cushioning properties of athletic shoes. In: Jonsson

(ed.) Biomechanics X-B. Champaign, IL: Human Kinetics, 1987, pp.937–941.

36.

Ziegert

Lewis

JL.

The effect of soft tissue on measurements of vibrational bone motion by skin-mounted accelerometers. J Biomech Eng 1979; 101: 218–220.

37.

Voloshin

Mizrahi

Verbitsky

, et al. Dynamic loading on the human musculoskeletal system – effect of fatigue. Clin Biomech 1998; 13: 515–520.

38.

Edwards

Derrick

Hamill

Time series analysis in biomechanics. In B. Müller and S. Wolf (eds.), Handbook of human motion. Springer Cham, 2017. pp.1–24. https://doi.org/10.1007/978-3-319-30808-1

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All devices are not created equal: Simultaneous data collection of three triaxial accelerometers sampling at different frequencies

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