Time-dependent tuning of balance control and aftereffects following optical flow perturbation training in older adults

Richards, Jackson T.; Selgrade, Brian P.; Qiao, Mu; Plummer, Prudence; Wikstrom, Erik A.; Franz, Jason R.

doi:10.1186/s12984-019-0555-3

Cited by 13 publications

(4 citation statements)

References 41 publications

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“…A similar reliance on vision has been demonstrated in older adults, presumed to arise as a sensory response to deficits in proprioceptive and/or somatosensory acuity. Perhaps accordingly, compared to young adults with high proprioceptive acuity, older adults exhibit disproportionate increases in SWV when exposed to ML optical flow perturbations [17,5]. Our PwMS presented with similar plantar tactile sensitivity to that of age-matched controls (Semmes-Weinstein, Table 1).…”

Section: Plos Onementioning

confidence: 62%

“…Symptoms of MS arise from demyelination around axons and include impaired proprioceptive acuity, which in turn leads to poor control of balance [2][3][4]. Furthermore, up to 86% of patients with relapsing-remitting MS have vestibulopathies [5], which likely impair their balance [6]. Indeed, an estimated 56% of PwMS fall annually, and 37% of PwMS are frequent fallers [7].…”

Section: Introductionmentioning

confidence: 99%

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Can optical flow perturbations detect walking balance impairment in people with multiple sclerosis?

et al. 2020

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People with multiple sclerosis (PwMS) who exhibit minimal to no disability are still over twice as likely to fall as the general population and many of these falls occur during walking. There is a need for more effective ways to detect preclinical walking balance deficits in PwMS. Therefore, the purpose of this study was to investigate the effects of optical flow perturbations applied using virtual reality on walking balance in PwMS compared to age-matched controls. We hypothesized that susceptibility to perturbations-especially those in the mediolateral direction-would be larger in PwMS compared to controls. Fourteen PwMS and fourteen age-matched controls walked on a treadmill while viewing a virtual hallway with and without optical flow perturbations in the mediolateral or anterior-posterior directions. We quantified foot placement kinematics, gait variability, lateral margin of stability and, in a separate session, performance on the standing sensory organization test (SOT). We found only modest differences between groups during normal, unperturbed walking. These differences were larger and more pervasive in the presence of mediolateral perturbations, evidenced by higher variability in step width, sacrum position, and margin of stability at heel-strike in PwMS than controls. PwMS also performed worse than controls on the SOT, and there was a modest correlation between step width variability during perturbed gait and SOT visual score. In conclusion, mediolateral optical flow perturbations revealed differences in walking balance in PwMS that went undetected during normal, unperturbed walking. Targeting this difference may be a promising approach to more effectively detect preclinical walking balance deficits in PwMS.

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Section: Plos Onementioning

confidence: 62%

Section: Introductionmentioning

confidence: 99%

Can optical flow perturbations detect walking balance impairment in people with multiple sclerosis?

et al. 2020

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“…A single study explored sensory perturbations to perturb gait as a training tool 97 . Mediolateral shifts of the visual scenery projected in front of a treadmill perturbed foot placement, and this resulted in a decreased variability of the margins of stability in unperturbed walking after the training.…”

Section: Perturbation-based Trainingmentioning

confidence: 99%

Mechanisms that stabilize human walking

Leeuwen

Bruijn

Dieën

2022

BJMB

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In this paper we review what mechanisms are used to stabilize human bipedal gait. Based on mechanical reasoning, potential mechanisms to control the body center of mass trajectory are modulation of foot placement, stance leg control consisting of modulation of ankle moments and push-off forces, and modulations of the body’s angular momentum. The first two mechanisms and especially the first are dominant in controlling center of mass accelerations during gait, while angular momentum control plays a lesser role, but may be important to control body alignment and orientation. The same control mechanisms stabilize both steady-state and perturbed gait in both the mediolateral and antero-posterior directions. Control is at least in part active and is affected by proprioceptive, visual and vestibular information. Results support that this reflects a feedback process in which sensory information is used to obtain an estimate of the center of mass state based on which foot placement and ankle moments are modulated. These active feedback mechanisms suggest training approaches for populations at risk of falling, such as augmenting their effective use by means of augmented feedback, or using their complementary nature to train one mechanism by constraining the other mechanisms.

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“…Muscle coupling between the ECR decreased as the prediction horizon PH increased, and this trend was more pronounced in patients than in controls even when no evident changes were observed in the signals (see Figure 2C as an example and Table 3 for differences between groups). In contrast, the co-activation index, considered as the gold standard for the evaluation of changes in load- sharing [see for example (Bekkers et al, 2018; Richards et al, 2019)], did not show any significant difference between groups (see Table 6).…”

Section: Discussionmentioning

confidence: 99%

Analysis of Muscle Load-Sharing in Patients With Lateral Epicondylitis During Endurance Isokinetic Contractions Using Non-linear Prediction

et al. 2019

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The aim of this paper is to analyze muscle load-sharing in patients with Lateral Epicondylitis during dynamic endurance contractions by means of non-linear prediction of surface EMG signals. The proposed non-linear cross-prediction scheme was used to predict the envelope of an EMG signal and is based on locally linear models built in a lag-embedded Euclidean space. The results were compared with a co-activation index, a common measure based on the activation of a muscle pair. Non-linear prediction revealed changes in muscle coupling, that is load-sharing, over time both in a control group and Lateral Epicondylitis (p < 0.05), even when subjects did not report pain at the end of the exercise. These changes were more pronounced in patients, especially in the first part of the exercise and up to 50% of the total endurance time (p < 0.05). By contrast, the co-activation index showed no differences between groups. Results reflect the changing nature of muscular activation strategy, presumably because of the mechanisms triggered by fatigue. Strategies differ between controls and patients, pointing to an altered coordination in Lateral Epicondylitis.

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Time-dependent tuning of balance control and aftereffects following optical flow perturbation training in older adults

Cited by 13 publications

References 41 publications

Can optical flow perturbations detect walking balance impairment in people with multiple sclerosis?

Can optical flow perturbations detect walking balance impairment in people with multiple sclerosis?

Mechanisms that stabilize human walking

Analysis of Muscle Load-Sharing in Patients With Lateral Epicondylitis During Endurance Isokinetic Contractions Using Non-linear Prediction

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