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Effect of running speed and leg prostheses on mediolateral foot placement and its variabilityRunning-specific prostheses limit ground-force during sprinting.Characterizing the Mechanical Properties of Running-Specific Prostheses.Older Runners Retain Youthful Running Economy despite Biomechanical Differences.The correlation between metabolic and individual leg mechanical power during walking at different slopes and velocitiesThe functional roles of muscles during sloped walking.Does use of a powered ankle-foot prosthesis restore whole-body angular momentum during walking at different speeds?The fastest runner on artificial legs: different limbs, similar function?Elite long jumpers with below the knee prostheses approach the board slower, but take-off more effectively than non-amputee athletes.How do prosthetic stiffness, height and running speed affect the biomechanics of athletes with bilateral transtibial amputations?Prosthetic model, but not stiffness or height, affects the metabolic cost of running for athletes with unilateral transtibial amputations.Independent metabolic costs of supporting body weight and accelerating body mass during walking.Metabolic and biomechanical effects of velocity and weight support using a lower-body positive pressure device during walking.The Functional Roles of Muscles, Passive Prostheses, and Powered Prostheses During Sloped Walking in People With a Transtibial Amputation.Reduced prosthetic stiffness lowers the metabolic cost of running for athletes with bilateral transtibial amputations.Axial and torsional stiffness of pediatric prosthetic feet.Maximum-speed curve-running biomechanics of sprinters with and without unilateral leg amputations.Case studies in physiology: The biomechanics of the fastest sprinter with a unilateral transtibial amputation.Dynamic stability of running: the effects of speed and leg amputations on the maximal Lyapunov exponent.Leg exoskeleton reduces the metabolic cost of human hopping.Running with horizontal pulling forces: the benefits of towing.Counterpoint: Artificial legs do not make artificially fast running speeds possible.Athletes with Versus Without Leg Amputations: Different Biomechanics, Similar Running EconomyThe contributions of ankle, knee and hip joint work to individual leg work change during uphill and downhill walking over a range of speedsLong jumpers with and without a transtibial amputation have different three-dimensional centre of mass and joint take-off step kinematics.Bionic ankle-foot prosthesis normalizes walking gait for persons with leg amputationOptimal starting block configuration in sprint running; a comparison of biological and prosthetic legsPatients with sacroiliac joint dysfunction exhibit altered movement strategies when performing a sit-to-stand taskProsthetic model, but not stiffness or height, affects maximum running velocity in athletes with unilateral transtibial amputationsStep time asymmetry increases metabolic energy expenditure during runningDoes Metabolic Rate Increase Linearly with Running Speed in all Distance Runners?Neither total muscle activation nor co-activation explains the youthful walking economy of older runnersWhat determines the metabolic cost of human running across a wide range of velocities?Use of a powered ankle-foot prosthesis reduces the metabolic cost of uphill walking and improves leg work symmetry in people with transtibial amputationsIndividuals with sacroiliac joint dysfunction display asymmetrical gait and a depressed synergy between muscles providing sacroiliac joint force closure when walkingThree-Dimensional Takeoff Step Kinetics of Long Jumpers with and without a Transtibial Amputation
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description
onderzoeker
@nl
researcher ORCID ID = 0000-0002-4432-618X
@en
name
Alena M Grabowski
@ast
Alena M Grabowski
@en
Alena M Grabowski
@es
Alena M Grabowski
@nl
type
label
Alena M Grabowski
@ast
Alena M Grabowski
@en
Alena M Grabowski
@es
Alena M Grabowski
@nl
prefLabel
Alena M Grabowski
@ast
Alena M Grabowski
@en
Alena M Grabowski
@es
Alena M Grabowski
@nl
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P1153
16636366200
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0000-0002-4432-618X