Three-dimensional analyses of gait initiation in a healthy, young population Drew Smith 1 and Del P. Wong 2 1 Motion Analysis Research Center (MARC), Samuel.

Slides:

Advertisements

Similar presentations

After the leg is in swing (at t =0.28), the hip flexors acted to flex the hip (H2) and then immediately before contact the hip extensor moment dominated.

Advertisements

KINETIC ANALYSIS OF GAIT INITIATION D. Gordon E. Robertson, PhD, FCSB 1 Richard Smith, PhD 2 Nick ODwyer, PhD 2 1 Biomechanics Laboratory, School of Human.

Mechanics of Pushing a Loaded Cart up an Incline D. Gordon E. Robertson, Ph.D. Dianne Ellwood, B.Sc. Paul Johnson, B.Sc. Dany Lafontaine, B.Sc. School.

Kinetics of Hula Hooping: An Exploratory Analysis

3-Dimensional Gait Measurement Really expensive and fancy measurement system with lots of cameras and computers Produces graphs of kinematics (joint.

INTRODUCTION Positive Ankle Work is Decreased in Peripheral Arterial Disease Before the Onset of Claudication Pain Before the Onset of Claudication Pain.

Biophysics of somersault and arm sets in trampolining John Mitchell Thanks to Lisa Withey + Jack Mitchell for performance.

Kinetic Analysis of the Lower Limb during the Pirouette in Ballet D. Gordon E. Robertson, PhD, FCSB Cristina Fulop Tama Davis Courtney Timm Biomechanics,

Lower Extremity Support during Toddler Gait S.Potoczny 1, D.G.E. Robertson 1 & H. Sveistrup 1,2 1 School of Human Kinetics and 2 School of Rehabilitation.

Stair Gait Lecture Notes.

Biomechanics- Gait.

By Jeff C. Conforti, DPT.  To understand the basic elements of posture and gait  To learn the phases of gait  To learn the key muscles and their function.

MINIMAL FOOT CLEARANCE IN STAIR DESCENT Tyler Cluff & D. Gordon E. Robertson, PhD, FCSB School of Human Kinetics, University of Ottawa, Ontario, Canada.

TWU Biomechanics Laboratory Lower-limb dynamics in two approaches of stair descent initiation: walk and stand Ketki Rana, Kunal Singhal, Sangwoo Lee, and.

Segmental Power Analysis of Walking

KINETIC ANALYSIS OF GAIT INITIATION D. Gordon E. Robertson, PhD, FCSB 1 Richard Smith, PhD 2 Nick O’Dwyer, PhD 2 1 Biomechanics Laboratory, School of Human.

Gait Analysis Study of human locomotion Walking and running

Analysis of a continuous skill – walking and running (gait)

Biomechanics of Gait Walking

Lecture 5 Dimitar Stefanov. Definitions: Purpose of the muscles is to produce tension Metabolic efficiency – the measure of a muscle’s ability to convert.

Determinants of Gait Determinants of Gait.

Results Table 1: Muscle force and relative difference to control Fig. 2: Muscle force during stance phase for a) m.tibialis posterior; b) m. tibialis anterior;

(W= weight!) W = m  g The main force acting on the body is the gravitational force! Gravitational force W applies at the center of gravity CG of the.

Kinetics versus Kinematics for Analyzing Locomotor Coordination D. Gordon E. Robertson, Ph.D. School of Human Kinetics, University of Ottawa, Ottawa, CANADA.

1 Gait Analysis – Objectives To learn and understand: –The general descriptive and temporal elements of the normal walking movement –The important features.

Gait Analysis – Objectives

Gait Analysis – Objectives

KINS 151 Website

Control of POSTURE and BALANCE

Outline Kinetics – Linear & External Forces in human motion Mechanical work, power, & energy Impulse-momentum – Angular, External and Internal Torques.

Biomechanics of Human Movement

The preferred balance leg absorbs more energy than the preferred striking leg in single leg landings Steve McCaw, Mitch Waller, Kevin Laudner & Pete Smith.

V v Anterior cruciate ligament ruptures are frequently noncontact in nature and most commonly occur during deceleration motions. 1 It is estimated that.

POSTECH H uman S ystem D esign Lab oratory Stair ascent and descent at different inclinations Robert Riener et al. (2002, Italy and Germany) Gait and Posture.

The influence of movement speed and handedness on the expenditure of potential and kinetic energy in full body reaching movements Nicole J. Vander Wiele,

The Science of Biomechanics

Stair Stepper Mechanism Innovated design Jarrett Johnson Advisor: Cris Koutsougeras Instructor: Cris Koutsougeras Et Senior Design Fall 2013.

BIPEDAL LOCOMOTION Prima Parte Antonio D'Angelo.

Cause-Effect ~ Total Body Level  Total Body Center of Mass (TBCM)  Free Body Diagram (FBD)  Mass-Acceleration Diagram (MAD)  General global coordinate.

Kinetics of Hula Hooping: An Exploratory Analysis Tyler Cluff D. Gordon E. Robertson Ramesh Balasubramaniam School of Human Kinetics Faculty of Health.

1 Feedback gain scaling quantifies postural abnormality of Patients with Parkinson’s disease Seyoung Kim, Fay B. Horak, Patricia Carlson-Kuhta and Sukyung.

COMPARISON OF KINETICS OF RAMP AND STAIR DESCENT Andrew Post, B.Sc. and D.G.E. Robertson, Ph.D., FCSB School of Human Kinetics, University of Ottawa, Ottawa,

Whitman and Atkeson.  Present a decoupled controller for a simulated three-dimensional biped.  Dynamics broke down into multiple subsystems that are.

Biomechanics Examines the internal and external forces acting on the human body and the effects produced by these forces Aids in technique analysis and.

The Gait Cycle:.

Comparison of Loaded and Unloaded Ramp Descent Jordan Thornley, B.Sc. and D. Gordon E. Robertson, Ph.D., FCSB School of Human Kinetics, University of Ottawa,

Marian Abowd, Dr. Cindy Trowbridge, Dr. Mark Ricard EFFECTS OF PATTERNED ELECTRICAL NEUROMUSCULAR STIMULATION ON KNEE JOINT STABILIZATION AbstractResultsConclusion.

How to improve running using Math! Camille Olson MAT 170 MWF 10:45.

Body Mechanics.

Introduction of PCA and energy flow pattern in lower limb Reporter: Yu-shin Chang Date: 99/02/05.

Plyometric (Reactive) Training Concepts

Discussion Figure 3 shows data from the same subject’s lead leg during planned gait termination. The lead leg arrived first at the quiet stance position.

Stability Balance and. Definition: the resistance to a change in the body’s acceleration, or the resistance to a disturbance of the body’s equilibrium.

KINETIC ANALYSIS OF THE LOWER LIMBS DURING FORWARD AND BACKWARD STAIR DESCENT WITH AND WITHOUT A FRONT LOAD Olinda Habib Perez & D. Gordon E. Robertson.

Discussion With FD and SBST, the peak knee moment decreased after step 2 and then stayed constant for the remaining steps. Conversely, for BD the peak.

Gender Differences in Frontal Plane Gait Biomechanics During Declined Walking With a Heavy Load Becky Krupenevich, Jake Ridings, Rachel Tatarski, Patrick.

COMPARISON OF ANKLE, KNEE AND HIP MOMENT POWERS DURING STAIR DESCENT VERSUS LEVEL WALKING François G. D.Beaulieu, M.A.; Lucie Pelland, Ph.D. and Gordon.

Muscle function during running and walking Forward dynamical simulations Split-belt treadmill with embedded force plates.

COMPARISON OF LOADED AND UNLOADED STAIR DESCENT Joe Lynch, B.Sc. and D.G.E. Robertson, Ph.D., FCSB School of Human Kinetics,University of Ottawa, Ottawa,

Contribution of Trunk Kinematics to Post-Strike Ball Velocity During a Maximal Instep Soccer Kick Brian M. Campbell1, Adam M. Fullenkamp1, James Bacher.

Balance and Stability.

Contribution of Trunk Kinematics to Post-Strike Ball Velocity During a Maximal Instep Soccer Kick Brian M. Campbell1, Adam M. Fullenkamp1, James Bacher.

Chapter 11 Plyometric (Reactive) Training Concepts

The Science of Biomechanics

Anticipatory muscular activity during stable and unstable standing

Plyometric (Reactive) Training Concepts

Transtibial Amputee Human Motion Analysis

Static Foot Structure May Predict Midfoot Mechanics

Presentation transcript:

Three-dimensional analyses of gait initiation in a healthy, young population Drew Smith 1 and Del P. Wong 2 1 Motion Analysis Research Center (MARC), Samuel Merritt University, Oakland CA, USA 2 Technological & Higher Education Institute (THEi), Hong Kong SAR, PRC

Outline  Dynamic stability  Brief review of gait initiation  Three-dimensional analyses of gait initiation in a healthy, young population:  Introduction, Methods, Results, Discussion  Directions for future study

Dynamic stability  Inverted pendulum model  Most of our mass is located high above a small base of support  Gravity acts to de-stabilize system  Only 1 position is not unstable  Requires a dynamic stability control system  Sensory + motor + reflexes + mechanical  Failure of control system = falls  (Gait = ‘controlled falling’)

Dynamic stability  Definition:  Refers to the ability of the human to recover from perturbations while maintaining an upright posture over a stationary or moving base of support  Perturbations can be internal (muscle forces) or external (gravity, pushes, pulls, changes in friction)  Posture is the alignment of the body segments with respect to gravity  Balance is the maintenance of posture

Dynamic stability  Spectrum of inverted pendulum activities:  Sit-to-stand => quiet standing => walking => running => walking => quiet standing, and so forth  Special aspects: turns, ramps, stairs, obstacles  Each phase meets criteria of pendulum model  What about the transitions?  E.g., in what ways does quiet standing resemble walking? At what point does quiet standing become walking? Walking become running? And so forth.  What can successful transitions tell us about unsuccessful ones?  E.g., ‘freezing’ in Parkinson's disease, or falls in the elderly while negotiating turns while walking

Gait initiation research  Gait initiation  Complete after 1, 2, or 3 steps  Quiet standing => gait initiation  Step 1:  Soleus (-) and tibialis anterior (+) activity  COP moves backward  Paradoxically, swing limb is initially loaded then unloaded  Swing limb lifted by hip flexors

Gait initiation research  Differing views on when completed  Depend on which variable being considered: COM velocity, acceleration, joint angle patterns, GRF  To date, no 3D studies have been conducted  Steady-state gait and quiet standing are well-studied  Pronounced change in energy states make energy a good variable to study

Three-dimensional analyses of gait initiation  Purpose  Examine patterns of joint powers and patterns of energy absorption and generation during the first 3 steps, defined as gait initiation  Compare sagittal and frontal planes powers and energies  Hypotheses  Sagittal powers and energies will have little contribution before and during the initial transfer of weight in the first step (STEP1)  Most of the energy in STEP1 will come from hip joint  In successive steps (STEP2, STEP3), sagittal plane energies will dominate

Three-dimensional analyses of gait initiation  Methods  Subjects:  15 undergraduate students provided informed consent to participate  Mean (± SD) mass: 74.0 (±16.7) kg, height: (±102.3)mm, BMI: 24.1 (±4.2)kg-m²  Protocol:  Standing, feet shoulder-width apart on two force platforms for min of 5s  Initiate walking with left foot landing on 3 rd force platform.  Continue walking for a minimum of 4m  5 trials per subject

Three-dimensional analyses of gait initiation  Model:  21-markers defining 11 segments  8-camera VICON MX system (100Hz)  3 Bertec force platforms (1,000Hz)  Data analysis:  Joint and segment kinematics and kinetics  Inverse dynamics  Time-normalised (0-100%) of 3 successive steps using 6 gait events  Identified from averaged subject data

Three-dimensional analyses of gait initiation

 Joint powers:  Product of joint moment of force and joint angular velocity  Joint absorption and generation energies:  Calculated by integrating joint powers using a trapezoidal technique  Statistics  3x2x2 ANOVA to examine main and interaction effects of step, plane, and joint on absorption and generation energy  Post hoc test with Bonferroni correction where appropriate  Paired-sample t-tests used where there were 2 groups

Three-dimensional analyses of gait initiation SagittalFrontal

Three-dimensional analyses of gait initiation SagittalFrontal

Three-dimensional analyses of gait initiation SagittalFrontal

Three-dimensional analyses of gait initiation  Results

Three-dimensional analyses of gait initiation  Results #s: compare across STEPs K,H: compare between joints

Three-dimensional analyses of gait initiation  Hip has smallest correlations, ankle has largest for both legs  Right knee (STEP2) is negatively correlated

Three-dimensional analyses of gait initiation  Discussion:  Analysis supported hypotheses  Correlations between planes:  STEP1 and STEP3 (left leg) – increasing + correlations from proximal to distal joints  STEP2 (right leg) – similar in magnitude but knee is – correlation  Raises possibility of energy flow not just between joints in the same plane but between planes within the same joint  Increases potential of system to be even more efficient than previously believed

Directions for future research  Gait termination:  Reverse pattern of gait initiation?  More energy absorption is likely  ‘Freezing’ in Parkinson’s disease:  Most interventions have focused on sagittal plane  Frontal plane has significant energies in frontal plane in STEP1  Joint stiffness:  Calculating joint stiffness as a time-series  How does this pattern change in each plane?  Can this have clinical implications?

Dr Shirley Rietdyk Purdue University ACKNOWLEDGEMENT