about
Recycling energy to restore impaired ankle function during human walkingDirection-dependent control of balance during walking and standing.Distinct fast and slow processes contribute to the selection of preferred step frequency during human walkingMechanical work as an indirect measure of subjective costs influencing human movement.Dynamic principles of gait and their clinical implicationsExtraction of individual muscle mechanical action from endpoint force.Mechanical and metabolic requirements for active lateral stabilization in human walking.Human walking isn't all hard work: evidence of soft tissue contributions to energy dissipation and return.Mechanics and energetics of swinging the human leg.Energetic costs of producing muscle work and force in a cyclical human bouncing task.Systematic variation of prosthetic foot spring affects center-of-mass mechanics and metabolic cost during walkingTwo independent contributions to step variability during over-ground human walking.The effects of a controlled energy storage and return prototype prosthetic foot on transtibial amputee ambulation.Energetic consequences of walking like an inverted pendulum: step-to-step transitions.Mechanical and energetic consequences of rolling foot shape in human walkingEndpoint force fluctuations reveal flexible rather than synergistic patterns of muscle cooperation.Elastic coupling of limb joints enables faster bipedal walking.Redirection of center-of-mass velocity during the step-to-step transition of human walking.Energetic cost of walking with increased step variabilityComment on "Contributions of the individual ankle plantar flexors to support, forward progression and swing initiation during walking" ((Neptune et al., 2001) and "Muscle mechanical work requirements during normal walking: the energetic cost of raisSimultaneous positive and negative external mechanical work in human walking.A least-squares estimation approach to improving the precision of inverse dynamics computations.Computational methods for analyzing the structure of cancellous bone in planar sections.Metabolic and mechanical energy costs of reducing vertical center of mass movement during gait.Postural feedback responses scale with biomechanical constraints in human standing.Biomechanical energy harvesting: generating electricity during walking with minimal user effort.Effect of altered sensory conditions on multivariate descriptors of human postural sway.An optimal state estimation model of sensory integration in human postural balance.Comparison of kinematic and kinetic methods for computing the vertical motion of the body center of mass during walking.The effect of lateral stabilization on walking in young and old adults.Visual and haptic feedback contribute to tuning and online control during object manipulation.The advantages of a rolling foot in human walking.Human adaptation to interaction forces in visuo-motor coordination.Biophysics. Harvesting energy by improving the economy of human walking.Energetics of actively powered locomotion using the simplest walking model.Optimization-based differential kinematic modeling exhibits a velocity-control strategy for dynamic posture determination in seated reaching movements.An optimal control model for analyzing human postural balance.A biomechanical analysis of muscle strength as a limiting factor in standing posture.Mechanical and metabolic determinants of the preferred step width in human walking.Active control of lateral balance in human walking.
P50
Q27334269-707295FA-2609-4B62-8D4A-787C745A4D2EQ30490312-2FA75B67-3008-4B9D-9008-25C0F957E476Q30588669-DF498A60-CC5A-4451-8798-F55BE43860BDQ31049361-58AB21EA-8C4F-4BB6-90F9-94D784FCD0A4Q33628937-F08E09D1-37A2-44D0-83A3-BC1D97CFD997Q33924828-87C29F2D-9020-448D-B107-45E0E3B08F5BQ34316725-982CE2A8-DFD1-4D93-9F8F-FA18BF27B4B4Q34353368-DB0737FA-9003-42FC-A38B-B7DFDC5F6729Q34388350-3DF9527F-7A20-4D4D-9DF9-D11C519FA787Q34785102-F63CFA91-3E59-41CC-A752-FACC99DB4A39Q34858135-4215520D-D37C-4B4B-852D-E6EE2A966C20Q34981741-3869BC81-B1E2-4482-B982-82DBC3D9CD30Q34997497-6CE0B602-91D7-4462-BF1D-F924CD2F9821Q36094143-0F83B0F5-B760-4EB1-8192-D96007C7681CQ36958716-75669F91-4452-4980-A781-93219144AAA1Q36978603-6D15BB02-9CC2-43A2-8E63-D3DD49EDE3ADQ37226852-7E3A51AB-648E-4A92-908C-48547E19B6B8Q37305109-0EE43D5E-4DA7-4105-91F0-9710D58F31E9Q42197867-00A89E2C-F92A-40F5-B434-3C19CDF72806Q42845631-F456480E-CDF1-4919-B2BF-9AAE02F8AC1BQ43448949-F20D9498-AA6A-473A-BE26-0EEC166A7BFAQ45283540-F3DEEBC8-F338-4602-98A0-BFF482F64EE2Q46616356-42F0FBF5-E1B5-4211-9212-656C3C365C2CQ46648149-6F3AC124-C0D6-49C0-ADE6-0CD1D53DA7BCQ47383652-BC478E8E-3BF9-458A-BB39-E82AA67C8F0CQ47926705-9D8E2C89-31BD-4BC8-BE8D-529397259FD1Q48374726-13F25AFC-B837-4221-AEC7-8B610A33F225Q48793478-6B663ECE-4FA7-4979-A28C-CBAB2501A7A4Q48968165-C32E7F23-8B77-4E2B-AEDC-55DFD1202390Q50861462-C2147431-2CF5-45C5-9B90-7E65C00E0C8BQ50986868-B56BACA0-F6DA-49B8-86C5-6F1DC0B212E9Q51123608-CE14976F-A311-44D0-A111-3295E1CB1691Q51126087-B4396E7E-C421-4ED9-860C-5A609B218ED5Q51358377-45E8B4E2-CBB5-4A60-B0C6-B8740F4977BDQ52045493-D5C05CA9-CD6D-4C6D-8EF6-BD76714A327BQ52227933-62B4EC69-D3AC-4223-8C86-031024BE8ECDQ52358551-600CB47F-9967-4F51-B2F4-B58AF424F3E3Q52403691-88998DD5-8496-4D33-A4D8-0EBDB6F20AF9Q53885554-ED69B037-65D6-4606-922E-7B8CF8559E03Q53906602-7BCC32A9-C453-4C98-83D7-6FDDF547CAC2
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Arthur Kuo
@ast
Arthur Kuo
@en
Arthur Kuo
@es
Arthur Kuo
@nl
type
label
Arthur Kuo
@ast
Arthur Kuo
@en
Arthur Kuo
@es
Arthur Kuo
@nl
prefLabel
Arthur Kuo
@ast
Arthur Kuo
@en
Arthur Kuo
@es
Arthur Kuo
@nl
P1053
L-3359-2013
P106
P21
P2456
P31
P3829
P496
0000-0001-5233-9709