The contribution of vision, proprioception, and efference copy in storing a neural representation for guiding trail leg trajectory over an obstacle

Lajoie, Kim; Bloomfield, Leigh W.; Nelson, Fraser J.; Suh, Jaewon J.; Marigold, Daniel S.

doi:10.1152/jn.00756.2011

Cited by 44 publications

(40 citation statements)

References 39 publications

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“…Visual feedback guides motor planning via posterior parietal cortex [50,51]. These processes generate muscular pattern separately from that of locomotion.…”

Section: The Supraspinal Control Of the Cpgmentioning

confidence: 99%

Oscillations in the human brain during walking execution, imagination and observation

et al. 2015

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“…Visual feedback guides motor planning via posterior parietal cortex [50,51]. These processes generate muscular pattern separately from that of locomotion.…”

Section: The Supraspinal Control Of the Cpgmentioning

confidence: 99%

Oscillations in the human brain during walking execution, imagination and observation

et al. 2015

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“…Skilled locomotor control, such as that exemplified by the precise control of foot trajectory over an obstacle, requires effective sensorimotor integration of visual and proprioceptive input along with information about motor commands (efference copy) (Marigold 2008;Andujar et al 2010;Marigold et al 2011;Lajoie et al 2012). Previous studies have shown that even if online visual cues are obstructed during obstacle crossing (e.g.…”

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confidence: 99%

The relationship between lower limb proprioceptive sense and locomotor skill acquisition

2016

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Sensorimotor integration is essential for controlling movement and acquiring new motor tasks in humans. The aim of this project was to understand how lower limb proprioceptive sense contributes to the acquisition of a skilled walking task. We assessed lower limb joint position and movement detection sense in healthy human subjects using the Lokomat robotic exoskeleton. Subjects walked on a treadmill to practice a skilled motor task (200 trials) requiring them to match their foot height during the swing phase to the height of a virtual obstacle displayed on a monitor in front of them. Subjects were given visual feedback on their error relative to the obstacle height after it was crossed. Lower limb joint position sense was related to the final performance error, but not the learning rate of the skilled walking task. The findings from this study support the role of lower limb proprioceptive sense on locomotor skill performance in healthy adult subjects.

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“…On the other hand, voluntary control of stepping patterns can become more automatic with practice (e.g., line dancing). Locomotor skills can be learned via visual cues from the environment or proprioceptive cues from the limbs during obstacle avoidance tasks (Erni and Dietz 2001;Lajoie et al 2012). Moreover, there is some evidence that visual cue training could improve gait patterns that transfer to walking without cues in people with Parkinson's disease (Spaulding et al 2013).…”

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confidence: 99%

Locomotor sequence learning in visually guided walking

Choi

Jensen

Nielsen

2016

Journal of Neurophysiology

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Choi JT, Jensen P, Nielsen JB. Locomotor sequence learning in visually guided walking. J Neurophysiol 115: 2014 -2020, 2016. First published February 10, 2016 doi:10.1152/jn.00938.2015.-Voluntary limb modifications must be integrated with basic walking patterns during visually guided walking. In this study we tested whether voluntary gait modifications can become more automatic with practice. We challenged walking control by presenting visual stepping targets that instructed subjects to modify step length from one trial to the next. Our sequence learning paradigm is derived from the serial reaction-time (SRT) task that has been used in upper limb studies. Both random and ordered sequences of step lengths were used to measure sequence-specific and sequence-nonspecific learning during walking. In addition, we determined how age (i.e., healthy young adults vs. children) and biomechanical factors (i.e., walking speed) affected the rate and magnitude of locomotor sequence learning. The results showed that healthy young adults (age 24 Ϯ 5 yr, n ϭ 20) could learn a specific sequence of step lengths over 300 training steps. Younger children (age 6 -10 yr, n ϭ 8) had lower baseline performance, but their magnitude and rate of sequence learning were the same compared with those of older children (11-16 yr, n ϭ 10) and healthy adults. In addition, learning capacity may be more limited at faster walking speeds. To our knowledge, this is the first study to demonstrate that spatial sequence learning can be integrated with a highly automatic task such as walking. These findings suggest that adults and children use implicit knowledge about the sequence to plan and execute leg movement during visually guided walking.human; learning; locomotion; vision; walking THE AUTOMATIC CONTROL OF WALKING is critical to our daily activities. We normally do not consciously think about walking unless we encounter novel situations where we have to make voluntary gait modifications (e.g., hiking across stepping stones). On the other hand, voluntary control of stepping patterns can become more automatic with practice (e.g., line dancing). Locomotor skills can be learned via visual cues from the environment or proprioceptive cues from the limbs during obstacle avoidance tasks (Erni and Dietz 2001;Lajoie et al. 2012). Moreover, there is some evidence that visual cue training could improve gait patterns that transfer to walking without cues in people with Parkinson's disease (Spaulding et al. 2013).The classic serial reaction-time (SRT) task, first introduced by Nissen and Bullemer (1987), may be used to assess to what an extent a motor task has become automatic. The SRT task requires subjects to rapidly respond to different spatial cues by pressing corresponding buttons as fast and accurately as possible. With practice, subjects demonstrate learning by performing faster on the repeating sequence than on random sequences. This difference can only be accounted for by sequence-specific learning, which can occur with or without explicit knowledge (Coh...

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The contribution of vision, proprioception, and efference copy in storing a neural representation for guiding trail leg trajectory over an obstacle

Cited by 44 publications

References 39 publications

Oscillations in the human brain during walking execution, imagination and observation

Oscillations in the human brain during walking execution, imagination and observation

The relationship between lower limb proprioceptive sense and locomotor skill acquisition

Locomotor sequence learning in visually guided walking

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