Muscle contributions to propulsion and support during running
about
Validation of Hill-type muscle models in relation to neuromuscular recruitment and force-velocity properties: predicting patterns of in vivo muscle forceHumans, geometric similarity and the Froude number: is ''reasonably close'' really close enough?Musculoskeletal simulation can help explain selective muscle degeneration in Duchenne muscular dystrophy.Effects of a leaf spring structured midsole on joint mechanics and lower limb muscle forces in runningMuscle contributions to fore-aft and vertical body mass center accelerations over a range of running speedsOptimizing Locomotion Controllers Using Biologically-Based Actuators and ObjectivesModeling and simulating the neuromuscular mechanisms regulating ankle and knee joint stiffness during human locomotion.Muscle Synergies Facilitate Computational Prediction of Subject-Specific Walking Motions.MOtoNMS: A MATLAB toolbox to process motion data for neuromusculoskeletal modeling and simulation.Muscle contributions to medial tibiofemoral compartment contact loading following ACL reconstruction using semitendinosus and gracilis tendon grafts.An Informational Algorithm as the Basis for Perception-Action Control of the Instantaneous Axes of the Knee.Establishing the Basis for Mechanobiology-Based Physical Therapy Protocols to Potentiate Cellular Healing and Tissue Regeneration.Tensiomyographic Markers Are Not Sensitive for Monitoring Muscle Fatigue in Elite Youth Athletes: A Pilot Study.Task-level strategies for human sagittal-plane running maneuvers are consistent with robotic control policies.EMG-driven forward-dynamic estimation of muscle force and joint moment about multiple degrees of freedom in the human lower extremity.Limited ankle dorsiflexion increases the risk for mid-portion Achilles tendinopathy in infantry recruits: a prospective cohort study.Hip muscle loads during running at various step ratesIs my model good enough? Best practices for verification and validation of musculoskeletal models and simulations of movement.Contributions of lower extremity kinematics to trunk accelerations during moderate treadmill running.Distinct motor strategies underlying split-belt adaptation in human walking and running.Simbody: multibody dynamics for biomedical researchOpenSim: a musculoskeletal modeling and simulation framework for in silico investigations and exchange.Stretching Your Energetic Budget: How Tendon Compliance Affects the Metabolic Cost of RunningSimulating Ideal Assistive Devices to Reduce the Metabolic Cost of Running.Inferring Muscle-Tendon Unit Power from Ankle Joint Power during the Push-Off Phase of Human Walking: Insights from a Multiarticular EMG-Driven Model.Effects of two neuromuscular training programs on running biomechanics with load carriage: a study protocol for a randomised controlled trial.Contributions of muscles to mediolateral ground reaction force over a range of walking speeds.Cervical Spine Injuries: A Whole-Body Musculoskeletal Model for the Analysis of Spinal Loading.Muscle activities during walking and running at energetically optimal transition speed under normobaric hypoxia on gradient slopesReal-Time Gait Event Detection Based on Kinematic Data Coupled to a Biomechanical ModelClassifying running-related injuries based upon etiology, with emphasis on volume and pace.How muscle fiber lengths and velocities affect muscle force generation as humans walk and run at different speeds.An investigation of jogging biomechanics using the full-body lumbar spine model: Model development and validation.A musculoskeletal model of human locomotion driven by a low dimensional set of impulsive excitation primitives.Flexing computational muscle: modeling and simulation of musculotendon dynamics.The validity of plantarflexor strength measures obtained through hand-held dynamometry measurements of force.Subject-specific knee joint geometry improves predictions of medial tibiofemoral contact forcesNormative values of eccentric hip abduction strength in novice runners: an equation adjusting for age and gender.The Differential Effect of Arm Movements during Gait on the Forward Acceleration of the Centre of Mass in Children with Cerebral Palsy and Typically Developing Children.Subtalar arthrodesis alignment: the effect on ankle biomechanics.
P2860
Q28652191-0ECEEFF5-4B20-40E9-A13D-03ACFCB1E0EDQ28708814-31E3BE33-EE0F-4724-BE8F-F813A58FCFA7Q30300638-5E9056A4-0AF5-4C73-A9AF-B4918F19DD9CQ30361455-839D81E8-DC88-425C-931D-DB10D95E2037Q30485864-7AD1BBF5-22F2-4960-9C57-5E1C532B4497Q30659766-249AD444-D0D8-43D4-BBA2-A04860E947CDQ30670562-C62158D4-DFFC-4092-8534-F1FB05415F80Q30821426-ECD17264-FFF3-4680-8FC0-39D97D2AE185Q31025320-823C02AC-AA65-408C-8C49-83C48D4022DCQ33579956-AAAF8B6B-1389-40A5-9FFE-FCB0CAFCDE71Q33753086-08098DB2-C991-469C-AA4A-4241CF229047Q33768703-11232DFD-1082-4B16-B22D-11281FF00FD0Q33806557-806AE411-62F0-4248-A591-DC274E03B1ECQ34532484-42DADEFA-C191-458F-ADE8-83032745AA2FQ34540953-60D09E50-AF2E-4767-A6C5-DB70AE79FDD3Q34568936-B469B9A9-46F8-4CAE-AB2E-D8F45324012AQ34976244-A1ACADFB-DBA8-47CE-A597-EC6325F7CCF1Q35062172-FD733747-2DEB-4AB7-9994-7123D836B9F2Q35078983-255411A3-560A-4C6E-977F-FA1920B4BF3AQ35182221-B11DF57A-A6F9-44F0-B70B-332C2CE6E931Q35324000-77F155C4-67B9-49C0-9E2A-C5D1035B0E70Q35423403-A0E1CBF0-BD3B-497E-9D70-5AF738CBB5B9Q35941106-F0182489-34A3-4570-932D-E4543200B3C5Q36140552-6DB3074F-6571-458D-9587-CCC41E791F55Q36169000-E060E5B6-1AA5-4AF5-85CA-3453465C784FQ36172061-94E0F172-CD0B-4479-8CEF-53A8E5B25462Q36223250-2C989389-F949-4C80-A556-B9162152323AQ36239547-2CAA9D1F-9A79-4049-8AB5-95B6BCB42567Q36310600-50798778-75E9-4C84-91F2-8DE249299B80Q36321785-803231CE-6311-4171-9BCF-20976D38365DQ36764086-685B5B58-BC91-4466-BE90-263232AEDCDDQ36851035-BFB0D50A-3C13-40A4-8E17-4236E16EC168Q36853253-F2258981-E9ED-4A37-BC97-BDA3021ECBE8Q36955926-58E59ADC-D8BB-4244-92F3-09E8067F2890Q36995382-FB740873-C6F0-4288-83E0-6F3CFBC0F231Q37401298-72C0475A-3391-41BD-BFC2-4D7E5BCC852FQ37466629-49FF24C9-32CD-41B1-83AC-13AE72640D09Q37584522-7508BDA8-75D1-4973-A89D-D079AFBE66D6Q37672422-E962C1F9-C5DB-4418-9932-39404E913CA3Q38081848-2DC77B15-7971-4D66-9BB1-65A6E129C0F7
P2860
Muscle contributions to propulsion and support during running
description
2010 nî lūn-bûn
@nan
2010 թուականի Օգոստոսին հրատարակուած գիտական յօդուած
@hyw
2010 թվականի օգոստոսին հրատարակված գիտական հոդված
@hy
2010年の論文
@ja
2010年論文
@yue
2010年論文
@zh-hant
2010年論文
@zh-hk
2010年論文
@zh-mo
2010年論文
@zh-tw
2010年论文
@wuu
name
Muscle contributions to propulsion and support during running
@ast
Muscle contributions to propulsion and support during running
@en
type
label
Muscle contributions to propulsion and support during running
@ast
Muscle contributions to propulsion and support during running
@en
prefLabel
Muscle contributions to propulsion and support during running
@ast
Muscle contributions to propulsion and support during running
@en
P2093
P2860
P1476
Muscle contributions to propulsion and support during running
@en
P2093
Samuel R Hamner
Scott L Delp
P2860
P304
P356
10.1016/J.JBIOMECH.2010.06.025
P577
2010-08-09T00:00:00Z