Lower Extremity Corrective Reactions to Slip Events

Overview

Journal J Biomech

Specialty Physiology

Date 2001 Oct 24

PMID 11672718

Citations 55

Authors

R Cham

M S Redfern

Affiliations

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Abstract

A significant number of injuries in the workplace is attributed to slips and falls. Biomechanical responses to actual slip events determine whether the outcome of a slip will be recovery or a fall. The goal of this study was to examine lower extremity joint moments and postural adjustments for experimental evidence of corrective strategies evoked during slipping in an attempt to prevent falling. Sixteen subjects walked onto a possibly oily vinyl tile floor, while ground reaction forces and body motion were recorded at 350 Hz. The onset of corrective reactions by the body in an attempt to recover from slips became evident at about 25% of stance and continued until about 45% into stance, i.e. on average between 190 and 350 ms after heel contact. These reactions included increased flexion moment at the knee and extensor activity at the hip. The ankle, on the other hand, acted as a passive joint (no net moment) during fall trials. Joint kinematics showed increased knee flexion and forward rotation of the shank in an attempt to bring the foot back towards the body. Once again, the ankle kinematics appeared to play a less dominant role (compared to the knee) in recovery attempts. This study indicates that humans generate corrective reactions to slips that are different than previously reported responses to standing perturbations translating the supporting surface.

Citing Articles

Inertial measurement units worn on the dorsum of the foot and proximal to the ankle can provide valid slip recovery measures.

Morris M, Franck C, Madigan M Gait Posture. 2024; 115:59-63.

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PMID: 38523707 PMC: 10957654. DOI: 10.3389/fspor.2024.1371730.

Susceptibility to walking balance perturbations in young adults is largely unaffected by anticipation.

Eichenlaub E, Urrego D, Sapovadia S, Allen J, Mercer V, Crenshaw J Hum Mov Sci. 2023; 89:103070.

PMID: 36878025 PMC: 10238661. DOI: 10.1016/j.humov.2023.103070.

Severity of Unconstrained Simultaneous Bilateral Slips: The Impact of Frontal Plane Feet Velocities Relative to the Center of Mass to Classify Slip-Related Falls and Recoveries.

Ouattas A, Rasmussen C, Hunt N Front Public Health. 2022; 10:898161.

PMID: 35899166 PMC: 9309647. DOI: 10.3389/fpubh.2022.898161.

Role of Knee and Ankle Extensors' Muscle-Tendon Properties in Dynamic Balance Recovery from a Simulated Slip.

Debelle H, Maganaris C, OBrien T Sensors (Basel). 2022; 22(9).

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