Optic flow improves adaptability of spatiotemporal characteristics during split-belt locomotor adaptation with tactile stimulation

Eikema, Diderik Jan Anthony; Chien, Jung Hung; Stergiou, Nicholas; Myers, Sara A.; Scott-Pandorf, Melissa; Bloomberg, Jacob J.; Mukherjee, Mukul

doi:10.1007/s00221-015-4484-5

Cited by 15 publications

(7 citation statements)

References 41 publications

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“…This effect was attributed to enhanced proprioceptive gain in response to the reduced tactile feedback. In a subsequent study (Eikema et al 2016), we demonstrated that such effects may be reversed by the presence of simulated optic flow during split-belt learning. It is unlikely that such specific effects which require feedback of alternate treadmill belt velocities could be affected by tactile stimulation at any random part of the body.…”

Section: Discussionmentioning

confidence: 72%

“…Therefore, in the current study, we attribute the reduced LRC during preferred walking gait at the supra-threshold tactile stimulation of 250 Hz and 17.5 db to increased proprioceptive gain resulting in greater degrees of freedom and increased flexibility. However, availability of external visual cues limits any changes in proprioceptive gain and the same stimulation (250 Hz and 17.5 db) does not demonstrate enhanced transfer effects in a split-belt adaptation task (Eikema et al 2016). It is possible that 17.5 db is a threshold level at or above which vibro-tactile stimulation is perceived as noise requiring alternate sensory gain changes (e.g., proprioception) in the absence of external visual cues.…”

Section: Discussionmentioning

confidence: 99%

“…While a case can be made for sensory stimulation on other parts of the body affecting gait dynamics, our intention was to specifically target the tactile stimulus that is felt under the foot during gait. Stimulation at other locations may lead to similar effects but these locations will probably be those that have a role to play in gait control, for example, proprioceptive stimulation on the neck, thighs, or Achilles tendon (Ivanenko et al 2000a, b), vestibular stimulation on the mastoid process (Chien et al 2016), or tactile stimulation below the feet (Mukherjee et al 2015; Eikema et al 2016). We showed that continuous foot perturbation through vibratory tactors enhanced split-belt locomotor adaptation (Mukherjee et al 2015).…”

Section: Discussionmentioning

confidence: 99%

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Tactile stimuli affect long-range correlations of stride interval and stride length differently during walking

et al. 2017

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Sensory feedback below the sole of the foot using sub-threshold mechanical noise significantly reduced postural sway in patients with diabetes and stroke. However, the effects of tactile parameters on walking are still elusive. Specifically, the effects of such parameters on human gait variability need to be studied because of possible rehabilitation outcomes in terms of bringing improvement in temporal and spatial gait parameters. The purpose of this study was to investigate whether different frequency and amplitude combinations of vibro-tactile stimulation of feet would affect stride-to-stride variability in healthy young adults. Ten healthy subjects walked on a treadmill at self-selected pace while wearing customized insoles fitted with tactors that vibrated at selected frequencies and amplitudes. The results show that the frequency manipulations of tactile stimulation altered the long-range correlations (LRCs) in stride length while amplitude manipulations affected the LRCs in stride interval without having any effect on the amount of gait variability. Our findings suggest that independent neural mechanisms may be responsible for coordinating LRCs of gait parameters in the spatial and temporal domains.

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Section: Discussionmentioning

confidence: 72%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Tactile stimuli affect long-range correlations of stride interval and stride length differently during walking

et al. 2017

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“…Adaptation and transfer were more robust when visual feedback was occluded during split-belt treadmill walking (Torres-Oviedo & Bastian, 2010). Possibly, visual feedback occlusion might induce a sensory reweighting, resulting in higher proprioceptive gain, due to an increased reliance on body-based cues (Eikema et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Incremental Visual Occlusion During Split-Belt Treadmill Walking Has No Gradient Effect on Adaptation or Retention

et al. 2021

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Split-belt treadmills have become an increasingly popular means of quantifying ambulation adaptability. Multiple sensory feedback mechanisms, including vision, contribute to task execution and adaptation success. No studies have yet explored visual feedback effects on locomotor adaptability across a spectrum of available visual information. In this study, we sought to better understand the effects of visual information on locomotor adaptation and retention by directly comparing incremental levels of visual occlusion. Sixty healthy young adults completed a split-belt adaptation protocol, including a baseline, asymmetric walking condition (adapt), a symmetric walking condition (de-adapt), and another asymmetric walking condition (re-adapt). We randomly assigned participants into conditions with varied visual occlusion (i.e., complete and lower visual field occlusion, or normal vision). We captured kinematic data, and outcome measures included magnitude of asymmetry, spatial and temporal contributions to step length asymmetry, variability of the final adapted pattern, and magnitude of adaptation. We used repeated measures and four-way MANOVAs to examine the influence of visual occlusion and walking condition. Participants with complete, compared to lower visual field visual occlusion displayed less consistency in their walking pattern, evident via increased step length standard deviation ( p = .007, d = 0.89), and compared to normal vision groups ( p = .003 d = 0.81). We found no other group differences, indicating that varying levels of visual occlusion did not significantly affect locomotor adaptation or retention. This study offers insight into the role vision plays in locomotor adaptation and retention with clinical utility for improving variability in step control.

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“…However, this is not an exhaustive list. There are numerous possible protocol modifications, some of which have already been shown to affect adaptation and/or after-effects, including the addition or deprivation of sensory stimuli 26,38,39,40 , the rate of acceleration of treadmill belts at the beginning of split-belt trials 27 , the practice structure 29 , and providing feedback during adaptation 34,41 . After-effects following split-belt walking are very robust and have been replicated in numerous studies (e.g.…”

mentioning

confidence: 99%

Using a Split-belt Treadmill to Evaluate Generalization of Human Locomotor Adaptation

Vasudevan

Hamzey

Kirk

2017

JoVE

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Understanding the mechanisms underlying locomotor learning helps researchers and clinicians optimize gait retraining as part of motor rehabilitation. However, studying human locomotor learning can be challenging. During infancy and childhood, the neuromuscular system is quite immature, and it is unlikely that locomotor learning during early stages of development is governed by the same mechanisms as in adulthood. By the time humans reach maturity, they are so proficient at walking that it is difficult to come up with a sufficiently novel task to study de novo locomotor learning. The split-belt treadmill, which has two belts that can drive each leg at a different speed, enables the study of both short- (i.e., immediate) and long-term (i.e., over minutes-days; a form of motor learning) gait modifications in response to a novel change in the walking environment. Individuals can easily be screened for previous exposure to the split-belt treadmill, thus ensuring that all experimental participants have no (or equivalent) prior experience. This paper describes a typical split-belt treadmill adaptation protocol that incorporates testing methods to quantify locomotor learning and generalization of this learning to other walking contexts. A discussion of important considerations for designing split-belt treadmill experiments follows, including factors like treadmill belt speeds, rest breaks, and distractors. Additionally, potential but understudied confounding variables (e.g., arm movements, prior experience) are considered in the discussion.

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Optic flow improves adaptability of spatiotemporal characteristics during split-belt locomotor adaptation with tactile stimulation

Cited by 15 publications

References 41 publications

Tactile stimuli affect long-range correlations of stride interval and stride length differently during walking

Tactile stimuli affect long-range correlations of stride interval and stride length differently during walking

Incremental Visual Occlusion During Split-Belt Treadmill Walking Has No Gradient Effect on Adaptation or Retention

Using a Split-belt Treadmill to Evaluate Generalization of Human Locomotor Adaptation

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