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Abstract

Background:

Reduced gravity treadmills have become increasingly prevalent in clinical settings. The purpose of this study was to assess the influence of manipulated levels of bodyweight during reduced gravity treadmill running on sensor-derived spatiotemporal, kinematic, and kinetic measures.

Hypotheses:

Reduced gravity conditions would result in significantly altered biomechanical measures compared with 100% gravity conditions, with the most pronounced effects anticipated in the 20% condition.

Study Design:

Cross-sectional clinic-based study.

Methods:

A total of 16 runners (8 male [M; age, 28.88 ± 5.69 years; body mass index [BMI], 25.08 ± 3.74 kg/m²], 8 female [F; age, 28.75 ± 5.23 years, BMI, 21.05 ± 3.46 kg/m2]) participated in this study. Participants wore commercially available sensors on their shoelaces and ran in a reduced gravity treadmill at a self-selected pace for 5 minutes each at 100%, 80%, 60%, 40%, and 20% bodyweight in a randomized order. The pace remained constant across all conditions, and rating of perceived exertion (RPE) was obtained following each condition. Step-by-step spatiotemporal, kinematic, and kinetic metrics were extracted to calculate mean outcome measures for each bodyweight condition. Repeated measures analyses of variance were conducted to assess the influence of the different bodyweight reduction levels on RPE and runners’ biomechanics.

Results:

Higher pressure creating lower bodyweight conditions resulted in significantly increased stride length and decreased cadence, contact time, impact g, and RPE, along with a shift toward forefoot strike types compared with higher body weight conditions (P < 0.01). All other outcomes were comparable across conditions.

Conclusion:

Reduced bodyweight running significantly altered spatiotemporal measures and reduced the vertical component of loading.

Clinical Relevance:

Our findings offer objective information on expected biomechanical changes across pressure levels that clinicians should consider when incorporating reduced gravity treadmill running into rehabilitation plans.

Keywords

antigravity treadmill biomechanics gait analysis wearable sensors

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References

Baggaley

Willy

Meardon

. Primary and secondary effects of real-time feedback to reduce vertical loading rate during running. Scand J Med Sci Sports. 2017;27:501-507.

Borg

. Borg’s Perceived Exertion and Pain Scales. Human Kinetics; 1998.

Bowser

Fellin

Milner

Pohl

Davis

. Reducing impact loading in runners: a one-year follow-up. Med Sci Sports Exerc. 2018;50:2500-2506.

Brayne

Barnes

Heller

Wheat

. Using a wireless consumer accelerometer to measure tibial acceleration during running: agreement with a skin-mounted sensor. Sports Eng. 2018;21:487-491.

Davis

Milner

Hamill

. Does increased loading during running lead to tibial stress fractures? A prospective study. Med Sci Sports Exerc. 2004;36:S58.

Davis

Futrell

. Gait retraining: altering the fingerprint of gait. Phys Med Rehabil Clin N Am. 2016;27:339-355. PMID: 26616188

DeJong

Hertel

. Validation of foot strike assessment during running using wearable sensors. J Athl Train. 2020;55:1307-1310.

DeJong

Hertel

. Outdoor running activities captured using wearable sensors in adult competitive runners. Int J Athl Ther Train. 2020;25:76-85.

DeJong Lempke

Hart

Hryvniak

Rodu

Hertel

. Use of wearable sensors to identify biomechanical alterations in runners with exercise-related lower leg pain. J Biomech. 2021;126:110646. PMID: 34329881

10.

Farina

Wright

Ford

Wirfel

Smoliga

. Physiological and biomechanical responses to running on lower body positive pressure treadmills in healthy populations. Sports Med Auckl NZ. 2017;47:261-275. PMID: 27380101

11.

Grabowski

Kram

. Effects of velocity and weight support on ground reaction forces and metabolic power during running. J Appl Biomech. 2008;24:288-297.

12.

Gregory

Koldenhoven

Higgins

Hertel

. External ankle supports alter running biomechanics: a field-based study using wearable sensors. Physiol Meas. 2019;40:044003.

13.

Hadizadeh

Amri

Roohi

Mohafez

. Assessment of gait symmetry improvements in national athletes after anterior cruciate ligament reconstruction during rehabilitation. Int J Sports Med. 2016;37:997-1002.

14.

Hodges-Long

Cross

Magrum

Feger

Hertel

. The effect of body weight reduction using a lower body positive pressure treadmill on plantar pressure measures while running. Phys Ther Sport. 2020;43:100-107.

15.

Hollis

Koldenhoven

Resch

Hertel

. Running biomechanics as measured by wearable sensors: effects of speed and surface. Sports Biomech. 2021;20(5):521-531.

16.

Kemler

Blokland

Backx

Huisstede

. Differences in injury risk and characteristics of injuries between novice and experienced runners over a 4-year period. Phys Sportsmed. 2018;46:485-491.

17.

Koldenhoven

Hertel

. Validation of a wearable sensor for measuring running biomechanics. Digit Biomark. 2018;2:74-78.

18.

Koldenhoven

Virostek

DeJong

Higgins

Hertel

. Increased contact time and strength deficits in runners with exercise-related lower leg pain. J Athl Train. 2020;55:1247-1254.

19.

Milner

Ferber

Pollard

Hamill

Davis

. Biomechanical factors associated with tibial stress fracture in female runners. Med Sci Sports Exerc. 2006;38:323-328. PMID: 16531902

20.

de Oliveira Silva

Briani

Pazzinatto

Ferrari

Aragao

de Azevedo

. Vertical ground reaction forces are associated with pain and self-reported functional status in recreational athletes with patellofemoral pain. J Appl Biomech. 2015;31:409-414.

21.

Running USA Releases Latest U.S. Running Trends Report. https://www.wpr.org/sites/default/files/running_usa_trends_report_2019-r4.pdf. Accessed April 9, 2021.

22.

Schubert

Kempf

Heiderscheit

. Influence of stride frequency and length on running mechanics. Sports Health. 2014;6:210-217.

23.

Smoliga

Wirfel

Paul

Doarnberger

Ford

. Effects of unweighting and speed on in-shoe regional loading during running on a lower body positive pressure treadmill. J Biomech. 2015;48:1950-1956.

24.

Stockland

Giveans

Ames

. The effect of an anti-gravity treadmill on running cadence. Int J Sports Phys Ther. 2019;14:860-865.

25.

Sylos-Labini

Lacquaniti

Ivanenko

. Human locomotion under reduced gravity conditions: biomechanical and neurophysiological considerations. BioMed Res Int. 2014;2014:547242.

26.

Thomson

Einarsson

Witvrouw

Whiteley

. Running speed increases plantar load more than per cent body weight on an AlterG® treadmill. J Sports Sci. 2017;35:277-282.

27.

Thomson

Whiteley

Hansen

Welzel

Racinais

Wilson

. Effect of speed and gradient on plantar force when running on an AlterG® treadmill. BMC Sports Sci Med Rehabil. 2021;13:34.

Supplementary Material

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Influence of Reduced-Gravity Treadmill Running on Sensor-Derived Biomechanics

Abstract

Background:

Hypotheses:

Study Design:

Methods:

Results:

Conclusion:

Clinical Relevance:

Keywords

Get full access to this article

References

Supplementary Material