Abstract
Assessing movement biomechanics is important for understanding healthy locomotion, injury or disease progression, and recovery. However, laboratory- or clinic-based studies fail to capture the ecological factors of real-world activity. Advancements in wearable sensors provide an opportunity to capture movement biomechanics in these settings. This study demonstrates the capacity of a wearable system to measure patellar and Achilles tendon kinetics via tensiometry as well as knee and ankle kinematics via inertial measurement units (IMUs) while walking across varied terrains, including level ground, sloped pavement, and stairs. The wearable system successfully captured time-varying tendon loading over the walking gait cycle. Both patellar and Achilles tendon loading showed distinct sensitivities to changes in slope and stairs. Importantly, these tendon loading patterns correspond well with prior measurements of knee extension and ankle plantarflexion moment profiles obtained via traditional motion analysis. This represents a significant advancement over studies that relied on traditional complex, immobile equipment to obtain comparable results. The portability of the wearable system may allow for objective assessments of human performance, injury risk, functional adaptation due to injury, and treatment response in real-world environments.
References
1.
Adamczyk
, P. G.
, Harper
, S. E.
, Reiter
, A. J.
, Roembke
, R. A.
, Wang
, Y.
, Nichols
, K. M.
, and Thelen
, D. G.
, 2023
, “Wearable Sensing for Understanding and Influencing Human Movement in Ecological Contexts
,” Curr. Opin. Biomed. Eng.
, 28
, p. 100492
.10.1016/j.cobme.2023.1004922.
Menant
, J. C.
, Steele
, J. R.
, Menz
, H. B.
, Munro
, B. J.
, and Lord
, S. R.
, 2009
, “Effects of Walking Surfaces and Footwear on Temporo-Spatial Gait Parameters in Young and Older People
,” Gait Posture
, 29
(3
), pp. 392
–397
.10.1016/j.gaitpost.2008.10.0573.
Gates
, D. H.
, Wilken
, J. M.
, Scott
, S. J.
, Sinitski
, E. H.
, and Dingwell
, J. B.
, 2012
, “Kinematic Strategies for Walking Across a Destabilizing Rock Surface
,” Gait Posture
, 35
(1
), pp. 36
–42
.10.1016/j.gaitpost.2011.08.0014.
Voloshina
, A. S.
, Kuo
, A. D.
, Daley
, M. A.
, and Ferris
, D. P.
, 2013
, “Biomechanics and Energetics of Walking on Uneven Terrain
,” J. Exp. Biol.
, 216
(21
), pp. 3963
–3970
.10.1242/jeb.0817115.
Voloshina
, A. S.
, and Ferris
, D. P.
, 2018
, “Design and Validation of an Instrumented Uneven Terrain Treadmill
,” J. Appl. Biomech.
, 34
(3
), pp. 236
–239
.10.1123/jab.2016-03226.
Santuz
, A.
, Ekizos
, A.
, Eckardt
, N.
, Kibele
, A.
, and Arampatzis
, A.
, 2018
, “Challenging Human Locomotion: Stability and Modular Organisation in Unsteady Conditions
,” Sci. Rep.
, 8
(1
), p. 2740
.10.1038/s41598-018-21018-47.
Kent
, J. A.
, Sommerfeld
, J. H.
, Mukherjee
, M.
, Takahashi
, K. Z.
, and Stergiou
, N.
, 2019
, “Locomotor Patterns Change Over Time During Walking on an Uneven Surface
,” J. Exp. Biol.
, 222
(14
), p. jeb202093
.10.1242/jeb.2020938.
Downey
, R. J.
, Richer
, N.
, Gupta
, R.
, Liu
, C.
, Pliner
, E. M.
, Roy
, A.
, and Hwang
, J.
, et al., 2022
, “Uneven Terrain Treadmill Walking in Younger and Older Adults
,” PLoS One
, 17
(12
), p. e0278646
.10.1371/journal.pone.02786469.
McIntosh
, A. S.
, Beatty
, K. T.
, Dwan
, L. N.
, and Vickers
, D. R.
, 2006
, “Gait Dynamics on an Inclined Walkway
,” J. Biomech.
, 39
(13
), pp. 2491
–2502
.10.1016/j.jbiomech.2005.07.02510.
Lay
, A. N.
, Hass
, C. J.
, and Gregor
, R. J.
, 2006
, “The Effects of Sloped Surfaces on Locomotion: A Kinematic and Kinetic Analysis
,” J. Biomech.
, 39
(9
), pp. 1621
–1628
.10.1016/j.jbiomech.2005.05.00511.
Lichtwark
, G. A.
, and Wilson
, A. M.
, 2006
, “Interactions Between the Human Gastrocnemius Muscle and the Achilles Tendon During Incline, Level and Decline Locomotion
,” J. Exp. Biol.
, 209
(21
), pp. 4379
–4388
.10.1242/jeb.0243412.
Alexander
, N.
, and Schwameder
, H.
, 2016
, “Effect of Sloped Walking on Lower Limb Muscle Forces
,” Gait Posture
, 47
, pp. 62
–67
.10.1016/j.gaitpost.2016.03.02213.
Pickle
, N. T.
, Grabowski
, A. M.
, Auyang
, A. G.
, and Silverman
, A. K.
, 2016
, “The Functional Roles of Muscles During Sloped Walking
,” J. Biomech.
, 49
(14
), pp. 3244
–3251
.10.1016/j.jbiomech.2016.08.00414.
Kimel-Naor
, S.
, Gottlieb
, A.
, and Plotnik
, M.
, 2017
, “The Effect of Uphill and Downhill Walking on Gait Parameters: A Self-Paced Treadmill Study
,” J. Biomech.
, 60
, pp. 142
–149
.10.1016/j.jbiomech.2017.06.03015.
Yang
, Z.
, Qu
, F.
, Liu
, H.
, Jiang
, L.
, Cui
, C.
, and Rietdyk
, S.
, 2019
, “The Relative Contributions of Sagittal, Frontal, and Transverse Joint Works to Self-Paced Incline and Decline Slope Walking
,” J. Biomech.
, 92
, pp. 35
–44
.10.1016/j.jbiomech.2019.05.02716.
Camargo
, J.
, Ramanathan
, A.
, Flanagan
, W.
, and Young
, A.
, 2021
, “A Comprehensive, Open-Source Dataset of Lower Limb Biomechanics in Multiple Conditions of Stairs, Ramps, and Level-Ground Ambulation and Transitions
,” J. Biomech.
, 119
, p. 110320
.10.1016/j.jbiomech.2021.11032017.
Riener
, R.
, Rabuffetti
, M.
, and Frigo
, C.
, 2002
, “Stair Ascent and Descent at Different Inclinations
,” Gait Posture
, 15
(1
), pp. 32
–44
.10.1016/S0966-6362(01)00162-X18.
Protopapadaki
, A.
, Drechsler
, W. I.
, Cramp
, M. C.
, Coutts
, F. J.
, and Scott
, O. M.
, 2007
, “Hip, Knee, Ankle Kinematics and Kinetics During Stair Ascent and Descent in Healthy Young Individuals
,” Clin. Biomech.
, 22
(2
), pp. 203
–210
.10.1016/j.clinbiomech.2006.09.01019.
Rasnick
, R.
, Standifird
, T.
, Reinbolt
, J. A.
, Cates
, H. E.
, and Zhang
, S.
, 2016
, “Knee Joint Loads and Surrounding Muscle Forces During Stair Ascent in Patients With Total Knee Replacement
,” PLoS One
, 11
(6
), p. e0156282
.10.1371/journal.pone.015628220.
Pinnington
, H. C.
, and Dawson
, B.
, 2001
, “The Energy Cost of Running on Grass Compared to Soft Dry Beach Sand
,” J. Sci. Med. Sport
, 4
(4
), pp. 416
–430
.10.1016/S1440-2440(01)80051-721.
Davies
, S. E. H.
, and Mackinnon
, S. N.
, 2006
, “The Energetics of Walking on Sand and Grass at Various Speeds
,” Ergonomics
, 49
(7
), pp. 651
–660
.10.1080/0014013060055802322.
Baroudi
, L.
, Newman
, M. W.
, Jackson
, E. A.
, Barton
, K.
, Shorter
, K. A.
, and Cain
, S. M.
, 2020
, “Estimating Walking Speed in the Wild
,” Front. Sports Act. Living
, 2
, p. 583848
.10.3389/fspor.2020.58384823.
Slaughter
, P. R.
, and Adamczyk
, P. G.
, 2020
, “Tracking Quantitative Characteristics of Cutting Maneuvers With Wearable Movement Sensors During Competitive Women's Ultimate Frisbee Games
,” Sensors
, 20
(22
), p. 6508
.10.3390/s2022650824.
Dixon
, P.
, Shah
, V.
, and Willmott
, A.
, 2021
, “Effects of Outdoor Walking Surface and Slope on Hip and Knee Joint Angles in the Sagittal Plane
,” Gait Posture
, 90
, pp. 48
–49
.10.1016/j.gaitpost.2021.09.02525.
Kowalsky
, D. B.
, Rebula
, J. R.
, Ojeda
, L. V.
, Adamczyk
, P. G.
, and Kuo
, A. D.
, 2021
, “Human Walking in the Real World: Interactions Between Terrain Type, Gait Parameters, and Energy Expenditure
,” PLoS One
, 16
(1
), p. e0228682
.10.1371/journal.pone.022868226.
Lebleu
, J.
, Parry
, R.
, Bertouille
, C.
, de Schaetzen
, M.
, Mahaudens
, P.
, Wallard
, L.
, and Detrembleur
, C.
, 2021
, “Variations in Patterns of Muscle Activity Observed in Participants Walking in Everyday Environments: Effect of Different Surfaces
,” Physiother. Can.
, 73
(3
), pp. 268
–275
.10.3138/ptc-2019-009727.
Ippersiel
, P.
, Shah
, V.
, and Dixon
, P. C.
, 2022
, “The Impact of Outdoor Walking Surfaces on Lower-Limb Coordination and Variability During Gait in Healthy Adults
,” Gait Posture
, 91
, pp. 7
–13
.10.1016/j.gaitpost.2021.09.17628.
Lafferty
, L.
, Wawrzyniak
, J.
, Chambers
, M.
, Pagliarulo
, T.
, Berg
, A.
, Hawila
, N.
, and Silvis
, M.
, 2022
, “Clinical Indoor Running Gait Analysis May Not Approximate Outdoor Running Gait Based on Novel Drone Technology
,” Sports Health
, 14
(5
), pp. 710
–716
.10.1177/1941738121105093129.
Yaguchi
, H.
, Sekiguchi
, Y.
, Honda
, K.
, Fukushi
, K.
, Huang
, C.
, Nakahara
, K.
, Zhenzhao
, C.
, and Izumi
, S.-I.
, 2022
, “Biomechanical Characteristics of Long Stair Climbing in Healthy Young Individuals in a Real-World Study Using a Wearable Motion Analysis System
,” Biomechanics
, 2
(4
), pp. 601
–612
.10.3390/biomechanics204004730.
Hernández-Stender
, C. L.
, Molina-Rueda
, F.
, Cuesta-Gómez
, A.
, and Alguacil-Diego
, I. M.
, 2024
, “Lower Limb Muscle Activation During Outdoor Running: Differences Between Sprinters, Middle-Distance and Long-Distance Runners
,” Sports Biomech.
, 23
(7
), pp. 949
–960
.10.1080/14763141.2021.190255431.
Kim
, S.
, Ro
, K.
, and Bae
, J.
, 2017
, “Estimation of Individual Muscular Forces of the Lower Limb During Walking Using a Wearable Sensor System
,” J. Sens.
, 2017
(1
), pp. 1
–14
.10.1155/2017/674792132.
Hullfish
, T. J.
, O'Connor
, K. M.
, and Baxter
, J. R.
, 2020
, “Instrumented Immobilizing Boot Paradigm Quantifies Reduced Achilles Tendon Loading During Gait
,” J. Biomech.
, 109
, p. 109925
.10.1016/j.jbiomech.2020.10992533.
Kwon
, M. P.
, Hullfish
, T. J.
, Humbyrd
, C. J.
, Boakye
, L. A. T.
, and Baxter
, J. R.
, 2023
, “Wearable Sensor and Machine Learning Estimate Tendon Load and Walking Speed During Immobilizing Boot Ambulation
,” Sci. Rep.
, 13
(1
), p. 18086
.10.1038/s41598-023-45375-x34.
Martin
, J. A.
, Brandon
, S. C. E.
, Keuler
, E. M.
, Hermus
, J. R.
, Ehlers
, A. C.
, Segalman
, D. J.
, Allen
, M. S.
, and Thelen
, D. G.
, 2018
, “Gauging Force by Tapping Tendons
,” Nat. Commun.
, 9
(1
), pp. 1
–9
.10.1038/s41467-018-03797-635.
Harper
, S. E.
, Roembke
, R. A.
, Zunker
, J. D.
, Thelen
, D. G.
, and Adamczyk
, P. G.
, 2020
, “Wearable Tendon Kinetics
,” Sensors
, 20
(17
), p. 4805
.10.3390/s2017480536.
Harper
, S. E.
, Schmitz
, D. G.
, Adamczyk
, P. G.
, and Thelen
, D. G.
, 2022
, “Fusion of Wearable Kinetic and Kinematic Sensors to Estimate Triceps Surae Work During Outdoor Locomotion on Slopes
,” Sensors
, 22
(4
), p. 1589
.10.3390/s2204158937.
Reiter
, A. J.
, Martin
, J. A.
, Knurr
, K. A.
, Adamczyk
, P. G.
, and Thelen
, D. G.
, 2024
, “Achilles Tendon Loading During Running Estimated Via Shear Wave Tensiometry: A Step Toward Wearable Kinetic Analysis
,” Med. Sci. Sports Exercise
, 56
(6
), pp. 1077
–1084
.10.1249/MSS.000000000000339638.
Schmitz
, D. G.
, Thelen
, D. G.
, and Cone
, S. G.
, 2022
, “A Kalman Filter Approach for Estimating Tendon Wave Speed From Skin-Mounted Accelerometers
,” Sensors
, 22
(6
), p. 2283
.10.3390/s2206228339.
Whitehead
, J. M. A.
, Esposito
, E. R.
, and Wilken
, J. M.
, 2016
, “Stair Ascent and Descent Biomechanical Adaptations While Using a Custom Ankle–Foot Orthosis
,” J. Biomech.
, 49
(13
), pp. 2899
–2908
.10.1016/j.jbiomech.2016.06.03540.
Waanders
, J. B.
, Murgia
, A.
, Hortobágyi
, T.
, DeVita
, P.
, and Franz
, J. R.
, 2020
, “How Age and Surface Inclination Affect Joint Moment Strategies to Accelerate and Decelerate Individual Leg Joints During Walking
,” J. Biomech.
, 98
, p. 109440
.10.1016/j.jbiomech.2019.109440Copyright © 2025 by ASME
You do not currently have access to this content.
