Ground reaction forces intersect above the center of mass even when walking down visible and camouflaged curbs

Background Normative foot kinematic and kinetic data with different walking speeds will benefit rehabilitation programs and improving gait performance. The purpose of this study was to analyze foot kinematics and kinetics differences between slow walking (SW), normal walking (NW) and fast walking (FW) of healthy subjects. Methods A total of 10 healthy male subjects participated in this study; they were asked to carry out walks at a self-selected speed. After measuring and averaging the results of NW, the subjects were asked to perform a 25% slower and 25% faster walk, respectively. Temporal-spatial parameters, kinematics of the tibia (TB), hindfoot (HF), forefoot (FF) and hallux (HX), and ground reaction forces (GRFs) were recorded while the subjects walked at averaged speeds of 1.01 m/s (SW), 1.34 m/s (NW), and 1.68 m/s (FW). Results Hindfoot relative to tibia (HF/TB) and forefoot relative to hindfoot (FF/HF) dorsiflexion (DF) increased in FW, while hallux relative to forefoot (HX/FF) DF decreased. Increased peak eversion (EV) and peak external rotation (ER) in HF/TB were observed in FW with decreased peak supination (SP) in FF/HF. GRFs were increased significantly with walking speed. The peak values of the knee and ankle moments in the sagittal and frontal planes significantly increased during FW compared with SW and NW. Discussion Limited HF/TB and FF/HF motion of SW was likely compensated for increased HX/FF DF. Although small angle variation in HF/TB EV and FF/HF SP during FW may have profound effects for foot kinetics. Higher HF/TB ER contributed to the FF push-off the ground while the center of mass (COM) progresses forward in FW, therefore accompanied by higher FF/HF abduction in FW. Increased peak vertical GRF in FW may affected by decreased stance duration time, the biomechanical mechanism maybe the change in vertical COM height and increase leg stiffness. Walking speed changes accompanied with modulated sagittal plane ankle moments to alter the braking GRF during loading response. The findings of foot kinematics, GRFs, and lower limb joint moments among healthy males may set a reference to distinguish abnormal and pathological gait patterns.

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Effect of Horizontal Ground Reaction Forces during the Golf Swing: Implications for the Development of Technical Solutions of Golf Swing Analysis

Proceedings ◽

10.3390/proceedings2020049045 ◽

2020 ◽

Vol 49 (1) ◽

pp. 45

Author(s):

Maxime Bourgain ◽

Christophe Sauret ◽

Grégoire Prum ◽

Laura Valdes-Tamayo ◽

Olivier Rouillon ◽

...

Keyword(s):

Center Of Mass ◽

Field Performance ◽

Golf Swing ◽

Ground Reaction Forces ◽

Technological Developments ◽

Reaction Forces ◽

Analysis Laboratory ◽

Technical Solutions ◽

Vertical Ground Reaction Forces ◽

Full Body

The swing is a key movement for golf. Its in-field performance could be estimated by embedded technologies, but often only vertical ground reaction forces (VGRF) are estimated. However, as the swing plane is inclined, horizontal ground reaction forces (HGRF) are expected to contribute to the increase of the club angular velocity. Thus, this study aimed at investigating the role of the HGRF during the golf swing. Twenty-eight golf players were recruited and performed 10 swings with their own driver club, in a motion analysis laboratory, equipped with a full body marker set. Ground reaction forces (GRF) were measured with force-plates. A multibody kinematic optimization was performed with a full body model to estimate the instantaneous location of the golfer’s center of mass (CoM). Moments created by the GRF at the CoM were investigated. Results showed that horizontal forces should not be neglected regarding to VGRF because of their lever arm. Analyzing golf swing with only VGRF appeared not enough and further technological developments are still needed to ecologically measure other components.

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Ground reaction forces and center of mass mechanics of bipedal capuchin monkeys: Implications for the evolution of human bipedalism

American Journal of Physical Anthropology ◽

10.1002/ajpa.22176 ◽

2012 ◽

Vol 150 (1) ◽

pp. 76-86 ◽

Cited By ~ 21

Author(s):

Brigitte Demes ◽

Matthew C. O'Neill

Keyword(s):

Center Of Mass ◽

Capuchin Monkeys ◽

Ground Reaction Forces ◽

Reaction Forces

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Estimation of the ground reaction forces from a single video camera based on the spring-like center of mass dynamics of human walking

Journal of Biomechanics ◽

10.1016/j.jbiomech.2020.110074 ◽

2020 ◽

Vol 113 ◽

pp. 110074

Author(s):

Hyunho Jeong ◽

Sukyung Park

Keyword(s):

Center Of Mass ◽

Video Camera ◽

Human Walking ◽

Ground Reaction Forces ◽

Reaction Forces

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Characterization of human gait by means of body center of mass oscillations derived from ground reaction forces

IEEE Transactions on Biomedical Engineering ◽

10.1109/10.364516 ◽

1995 ◽

Vol 42 (3) ◽

pp. 293-303 ◽

Cited By ~ 33

Author(s):

A. Crowe ◽

P. Schiereck ◽

R.W. de Boer ◽

W. Keessen

Keyword(s):

Center Of Mass ◽

Human Gait ◽

Ground Reaction Forces ◽

Reaction Forces ◽

Body Center

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Common muscle synergies for control of center of mass and force in nonstepping and stepping postural behaviors

Journal of Neurophysiology ◽

10.1152/jn.00549.2010 ◽

2011 ◽

Vol 106 (2) ◽

pp. 999-1015 ◽

Cited By ~ 88

Author(s):

Stacie A. Chvatal ◽

Gelsy Torres-Oviedo ◽

Seyed A. Safavynia ◽

Lena H. Ting

Keyword(s):

Muscle Activity ◽

Center Of Mass ◽

Initial Position ◽

Neural Mechanisms ◽

Muscle Synergies ◽

Support Surface ◽

Ground Reaction Forces ◽

Postural Responses ◽

Reaction Forces ◽

Base Of Support

We investigated muscle activity, ground reaction forces, and center of mass (CoM) acceleration in two different postural behaviors for standing balance control in humans to determine whether common neural mechanisms are used in different postural tasks. We compared nonstepping responses, where the base of support is stationary and balance is recovered by returning CoM back to its initial position, with stepping responses, where the base of support is enlarged and balance is recovered by pushing the CoM away from the initial position. In response to perturbations of the same direction, these two postural behaviors resulted in different muscle activity and ground reaction forces. We hypothesized that a common pool of muscle synergies producing consistent task-level biomechanical functions is used to generate different postural behaviors. Two sets of support-surface translations in 12 horizontal-plane directions were presented, first to evoke stepping responses and then to evoke nonstepping responses. Electromyographs in 16 lower back and leg muscles of the stance leg were measured. Initially (∼100-ms latency), electromyographs, CoM acceleration, and forces were similar in nonstepping and stepping responses, but these diverged in later time periods (∼200 ms), when stepping occurred. We identified muscle synergies using non-negative matrix factorization and functional muscle synergies that quantified correlations between muscle synergy recruitment levels and biomechanical outputs. Functional muscle synergies that produce forces to restore CoM position in nonstepping responses were also used to displace the CoM during stepping responses. These results suggest that muscle synergies represent common neural mechanisms for CoM movement control under different dynamic conditions: stepping and nonstepping postural responses.

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Portable Gait Lab: Estimating Over-Ground 3D Ground Reaction Forces Using Only a Pelvis IMU

Sensors ◽

10.3390/s20216363 ◽

2020 ◽

Vol 20 (21) ◽

pp. 6363

Author(s):

Mohamed Irfan Mohamed Refai ◽

Bert-Jan F. van Beijnum ◽

Jaap H. Buurke ◽

Peter H. Veltink

Keyword(s):

Inertial Measurement Unit ◽

Center Of Mass ◽

Calibration Procedure ◽

Measurement Unit ◽

Average Error ◽

Ground Reaction Forces ◽

Inertial Measurement ◽

Reaction Forces ◽

Error State ◽

Over Ground Walking

As an alternative to force plates, an inertial measurement unit (IMU) at the pelvis can offer an ambulatory method for measuring total center of mass (CoM) accelerations and, thereby, the ground reaction forces (GRF) during gait. The challenge here is to estimate the 3D components of the GRF. We employ a calibration procedure and an error state extended Kalman filter based on an earlier work to estimate the instantaneous 3D GRF for different over-ground walking patterns. The GRF were then expressed in a body-centric reference frame, to enable an ambulatory setup not related to a fixed global frame. The results were validated with ForceShoesTM, and the average error in estimating instantaneous shear GRF was 5.2 ± 0.5% of body weight across different variable over-ground walking tasks. The study shows that a single pelvis IMU can measure 3D GRF in a minimal and ambulatory manner during over-ground gait.

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The Role of Ankle Plantarflexors in Maintaining Dynamic Balance During Human Walking

ASME 2012 Summer Bioengineering Conference, Parts A and B ◽

10.1115/sbc2012-80734 ◽

2012 ◽

Author(s):

Richard R. Neptune ◽

Craig P. McGowan ◽

Allison L. Hall

Keyword(s):

Angular Momentum ◽

Dynamic Balance ◽

Center Of Mass ◽

The Body ◽

Whole Body ◽

Human Walking ◽

Ground Reaction Forces ◽

Reaction Forces ◽

Anterior Posterior

The regulation of whole-body angular momentum is essential for maintaining dynamic balance during human walking and appears to be tightly controlled during normal and pathological movement (e.g., [1, 2]). The primary mechanism to regulate angular momentum is muscle force generation, which accelerates the body segments and generates ground reaction forces that alter angular momentum about the body’s center-of-mass to restore and maintain dynamic balance. Previous modeling studies have shown the ankle plantarflexors are important contributors to the anterior/posterior, vertical and medial/lateral ground reaction forces during human walking [3, 4], and therefore appear critical to regulating angular momentum and maintaining dynamic balance during walking.

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Ground reaction forces intersect above the center of mass in single support, but not in double support of human walking

Journal of Biomechanics ◽

10.1016/j.jbiomech.2021.110387 ◽

2021 ◽

Vol 120 ◽

pp. 110387

Author(s):

Johanna Vielemeyer ◽

Roy Müller ◽

Nora-Sophie Staufenberg ◽

Daniel Renjewski ◽

Rainer Abel

Keyword(s):

Center Of Mass ◽

Human Walking ◽

Ground Reaction Forces ◽

Double Support ◽

Reaction Forces

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Running ground reaction forces across footwear conditions are predicted from the motion of two body mass components

Journal of Applied Physiology ◽

10.1152/japplphysiol.00925.2018 ◽

2019 ◽

Vol 126 (5) ◽

pp. 1315-1325 ◽

Cited By ~ 3

Author(s):

Andrew B. Udofa ◽

Kenneth P. Clark ◽

Laurence J. Ryan ◽

Peter G. Weyand

Keyword(s):

Ground Reaction Force ◽

Lower Limb ◽

Reaction Force ◽

Ground Reaction Forces ◽

Vertical Ground Reaction Force ◽

Time Patterns ◽

Foot Strike ◽

Reaction Forces ◽

Vertical Ground ◽

Force Time

Although running shoes alter foot-ground reaction forces, particularly during impact, how they do so is incompletely understood. Here, we hypothesized that footwear effects on running ground reaction force-time patterns can be accurately predicted from the motion of two components of the body’s mass (mb): the contacting lower-limb (m1 = 0.08mb) and the remainder (m2 = 0.92mb). Simultaneous motion and vertical ground reaction force-time data were acquired at 1,000 Hz from eight uninstructed subjects running on a force-instrumented treadmill at 4.0 and 7.0 m/s under four footwear conditions: barefoot, minimal sole, thin sole, and thick sole. Vertical ground reaction force-time patterns were generated from the two-mass model using body mass and footfall-specific measures of contact time, aerial time, and lower-limb impact deceleration. Model force-time patterns generated using the empirical inputs acquired for each footfall matched the measured patterns closely across the four footwear conditions at both protocol speeds ( r2 = 0.96 ± 0.004; root mean squared error = 0.17 ± 0.01 body-weight units; n = 275 total footfalls). Foot landing angles (θF) were inversely related to footwear thickness; more positive or plantar-flexed landing angles coincided with longer-impact durations and force-time patterns lacking distinct rising-edge force peaks. Our results support three conclusions: 1) running ground reaction force-time patterns across footwear conditions can be accurately predicted using our two-mass, two-impulse model, 2) impact forces, regardless of foot strike mechanics, can be accurately quantified from lower-limb motion and a fixed anatomical mass (0.08mb), and 3) runners maintain similar loading rates (ΔFvertical/Δtime) across footwear conditions by altering foot strike angle to regulate the duration of impact. NEW & NOTEWORTHY Here, we validate a two-mass, two-impulse model of running vertical ground reaction forces across four footwear thickness conditions (barefoot, minimal, thin, thick). Our model allows the impact portion of the impulse to be extracted from measured total ground reaction force-time patterns using motion data from the ankle. The gait adjustments observed across footwear conditions revealed that runners maintained similar loading rates across footwear conditions by altering foot strike angles to regulate the duration of impact.

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