scholarly article | Q13442814 |
P356 | DOI | 10.1152/JAPPLPHYSIOL.00587.2016 |
P698 | PubMed publication ID | 28104752 |
P50 | author | Alena M Grabowski | Q59683515 |
Paolo Taboga | Q89531931 | ||
P2093 | author name string | Owen N Beck | |
P2860 | cites work | The Foot's Arch and the Energetics of Human Locomotion. | Q27301561 |
Effect of running speed and leg prostheses on mediolateral foot placement and its variability | Q27318850 | ||
The spring in the arch of the human foot | Q28305050 | ||
Running-specific prostheses limit ground-force during sprinting. | Q30494354 | ||
MECHANICAL WORK IN RUNNING. | Q33971520 | ||
Energetically optimal stride frequency in running: the effects of incline and decline | Q34187382 | ||
Energetics of running: a new perspective | Q34762537 | ||
The energetic benefits of tendon springs in running: is the reduction of muscle work important? | Q35222442 | ||
The effects of changes in the sagittal plane alignment of running-specific transtibial prostheses on ground reaction forces | Q35789845 | ||
Leg stiffness of sprinters using running-specific prostheses | Q36065437 | ||
Characterizing the Mechanical Properties of Running-Specific Prostheses | Q36223707 | ||
Leg stiffness and stride frequency in human running | Q36824685 | ||
Carbon fibre prostheses and running in amputees: a review | Q37351016 | ||
Altered Running Economy Directly Translates to Altered Distance-Running Performance | Q39667289 | ||
Leg stiffness primarily depends on ankle stiffness during human hopping | Q41616494 | ||
Metabolic cost of generating horizontal forces during human running | Q41650572 | ||
Runners adjust leg stiffness for their first step on a new running surface | Q41683339 | ||
Partitioning the metabolic cost of human running: a task-by-task approach | Q43108078 | ||
Mechanical work and efficiency in level walking and running | Q43615094 | ||
The fastest runner on artificial legs: different limbs, similar function? | Q44668679 | ||
The spring-mass model for running and hopping | Q45163238 | ||
Mechanism of leg stiffness adjustment for hopping on surfaces of different stiffnesses. | Q45972227 | ||
The energetic cost of maintaining lateral balance during human running | Q46520344 | ||
Independent metabolic costs of supporting body weight and accelerating body mass during walking. | Q47395315 | ||
The fastest sprinter in 2068 has an artificial limb? | Q48519034 | ||
The metabolic cost of human running: is swinging the arms worth it? | Q51068044 | ||
Running-specific prostheses permit energy cost similar to nonamputees. | Q51842031 | ||
Counterpoint: Artificial legs do not make artificially fast running speeds possible. | Q55052791 | ||
Running in the real world: adjusting leg stiffness for different surfaces. | Q55067685 | ||
Energy cost of running | Q56114293 | ||
P433 | issue | 4 | |
P407 | language of work or name | English | Q1860 |
P304 | page(s) | 976-984 | |
P577 | publication date | 2017-01-19 | |
P1433 | published in | Journal of Applied Physiology | Q1091719 |
P1476 | title | Reduced prosthetic stiffness lowers the metabolic cost of running for athletes with bilateral transtibial amputations | |
P478 | volume | 122 |
Q100533825 | Adding carbon fiber to shoe soles may not improve running economy: a muscle-level explanation |
Q39159416 | How Biomechanical Improvements in Running Economy Could Break the 2-hour Marathon Barrier. |
Q47203475 | How do prosthetic stiffness, height and running speed affect the biomechanics of athletes with bilateral transtibial amputations? |
Q64991463 | Long jumpers with and without a transtibial amputation have different three-dimensional centre of mass and joint take-off step kinematics. |
Q47224723 | Prosthetic model, but not stiffness or height, affects the metabolic cost of running for athletes with unilateral transtibial amputations. |
Q89802298 | Prosthetic shape, but not stiffness or height, affects the maximum speed of sprinters with bilateral transtibial amputations |
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