| scholarly article | Q13442814 |
| P2093 | author name string | Feng Yang | |
| Yi-Chung Pai | |||
| Frank C Anderson | |||
| P2860 | cites work | Effects of age-related gait changes on the biomechanics of slips and falls | Q23922762 |
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| OpenSim: open-source software to create and analyze dynamic simulations of movement | Q33306019 | ||
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| Predicted threshold against backward balance loss in gait | Q37462128 | ||
| Determination of instantaneous stability against backward balance loss: two computational approaches | Q40090666 | ||
| The role of limb movements in maintaining upright stance: the "change-in-support" strategy | Q41469192 | ||
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| Feedforward adaptations are used to compensate for a potential loss of balance | Q48514832 | ||
| Mechanisms of limb collapse following a slip among young and older adults. | Q50958927 | ||
| Role of feedforward control of movement stability in reducing slip-related balance loss and falls among older adults. | Q52011381 | ||
| Retention of adaptive control over varying intervals: prevention of slip- induced backward balance loss during gait. | Q52028945 | ||
| Long-term retention of gait stability improvements. | Q52048292 | ||
| Thresholds for step initiation induced by support-surface translation: a dynamic center-of-mass model provides much better prediction than a static model. | Q52082011 | ||
| Simulated movement termination for balance recovery: can movement strategies be sought to maintain stability in the presence of slipping or forced sliding? | Q52207896 | ||
| On the relation between joint moments and pedalling rates at constant power in bicycling. | Q52652791 | ||
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| Adjustments to Zatsiorsky-Seluyanov's segment inertia parameters | Q71688924 | ||
| Age-related changes in compensatory stepping in response to unpredictable perturbations | Q71770864 | ||
| Age differences in using a rapid step to regain balance during a forward fall | Q73013141 | ||
| Role of the unperturbed limb and arms in the reactive recovery response to an unexpected slip during locomotion | Q73067434 | ||
| Center of mass velocity-position predictions for balance control | Q73165524 | ||
| Thresholds for inducing protective stepping responses to external perturbations of human standing | Q73309736 | ||
| Effect of slip on movement of body center of mass relative to base of support | Q73550978 | ||
| A Dynamic Optimization Solution for Vertical Jumping in Three Dimensions | Q73663411 | ||
| The sex and age of older adults influence the outcome of induced trips | Q74530915 | ||
| Fall-induced injuries and deaths among older adults | Q77816180 | ||
| Reactive balance adjustments to unexpected perturbations during human walking | Q78550777 | ||
| Influence of gait speed on stability: recovery from anterior slips and compensatory stepping | Q81244862 | ||
| Recovery responses to surrogate slipping tasks differ from responses to actual slips | Q82261668 | ||
| P4510 | describes a project that uses | OpenSim | Q2038919 |
| P433 | issue | 9 | |
| P407 | language of work or name | English | Q1860 |
| P921 | main subject | biophysics | Q7100 |
| P304 | page(s) | 1823-1831 | |
| P577 | publication date | 2008-06-05 | |
| P1433 | published in | Journal of Biomechanics | Q4862281 |
| P1476 | title | Predicted threshold against backward balance loss following a slip in gait | |
| P478 | volume | 41 |
| Q37259171 | Adaptation and generalization to opposing perturbations in walking |
| Q61446608 | Age-related strength loss affects non-stepping balance recovery |
| Q28390279 | Alteration in community-dwelling older adults' level walking following perturbation training |
| Q59813021 | An Initial Passive Phase That Limits the Time to Recover and Emphasizes the Role of Proprioceptive Information |
| Q29994811 | An ecologically-controlled exoskeleton can improve balance recovery after slippage |
| Q27310201 | Can stability really predict an impending slip-related fall among older adults? |
| Q34141870 | Control of center of mass motion state through cuing and decoupling of spontaneous gait parameters in level walking |
| Q40090666 | Determination of instantaneous stability against backward balance loss: two computational approaches |
| Q33945433 | Feasible stability region in the frontal plane during human gait |
| Q46011458 | Feet kinematics upon slipping discriminate between recoveries and three types of slip-induced falls. |
| Q37131841 | Generalization of gait adaptation for fall prevention: from moveable platform to slippery floor |
| Q36077723 | Generalization of motor adaptation to repeated-slip perturbation across tasks |
| Q28392455 | Generalization of treadmill-slip training to prevent a fall following a sudden (novel) slip in over-ground walking |
| Q28389481 | Learning from laboratory-induced falling: long-term motor retention among older adults |
| Q34624847 | Limb collapse, rather than instability, causes failure in sit-to-stand performance among patients with parkinson disease |
| Q42105119 | Limits of recovery against slip-induced falls while walking |
| Q91691142 | Lower extremity kinematics during forward heel-slip |
| Q57868777 | Motor Patterns During Walking on a Slippery Walkway |
| Q28390211 | Reduced intensity in gait-slip training can still improve stability |
| Q29248557 | Retention of the “first-trial effect” in gait-slip among community-living older adults |
| Q51930727 | Role of cognition and priming in interlimb generalization of adaptive control of gait stability. |
| Q28394478 | Role of individual lower limb joints in reactive stability control following a novel slip in gait |
| Q28391243 | Role of stability and limb support in recovery against a fall following a novel slip induced in different daily activities |
| Q24170034 | The impact of a systematic reduction in shoe-floor friction on heel contact walking kinematics-- a gait simulation approach |
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