Gait variability in healthy old adults is more affected by a visual perturbation than by a cognitive or narrow step placement demand

Francis, Carrie A.; Franz, Jason R.; O’Connor, Shawn M.; Thelen, Darryl G.

doi:10.1016/j.gaitpost.2015.07.006

Cited by 48 publications

(70 citation statements)

References 33 publications

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“…They found that ML visual perturbations significantly increased gait variability (+152% step width variability and + 131% step length variability) in older adults but not younger adults compared to the normal condition, suggesting that older adults depend more on visual feedback for whole‐body positioning. Older adults also walked with 5% shorter step length in the ML visual perturbation condition, a significant change compared to the no visual perturbations condition . Figure illustrates an example of a motion capture system using anatomically placed markers.…”

Section: Effects Of Visual Manipulations On Gait and Balance In Healtmentioning

confidence: 99%

“…Older adults also walked with 5% shorter step length in the ML visual perturbation condition, a significant change compared to the no visual perturbations condition. 45 Figure 3 illustrates an example of a motion capture system using anatomically placed markers. Similarly, Franz et al 46 studied old and young subjects who were instructed to walk on a treadmill at their preferred speed while viewing a speed-matched virtual reality hallway in the presence and absence of continuous ML visual perturbations.…”

Section: Visual Perturbationsmentioning

confidence: 99%

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Balance and gait in the elderly: A contemporary review

Osoba

Rao

Agrawal

et al. 2019

Laryngoscope Investig Oto

279

185

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Background The prevalence of balance and gait deficits increases with age and is associated with the increased incidence of falls seen in the elderly population; these falls are associated with significant morbidity and mortality. Objectives To review changes in gait and balance associated with aging and the effect of visual perturbations on gait and balance in the elderly to provide a basis for future research. Methods PubMed and Cochrane Library were searched for articles from 1980 to present pertaining to gait and balance in older adults (>60) and younger adults (<60). Search terms included balance, posture, gait, locomotion, gait variability, gait disorders, gait disturbance, elderly, aging, falls, vision, visual, vestibular, and virtual reality. The references section of queried articles was also used to find relevant studies. Studies were excluded if subjects had a diagnosed gait or balance disorder. Results Elderly adults show age‐related decline in sensory systems and reduced ability to adapt to changes in their environment to maintain balance. Elderly adults are particularly dependent on vision to maintain postural stability. Distinct changes in spatiotemporal gait parameters are associated with aging, such as slower gait and increased gait variability, which are amplified with exposure to visual perturbations. Increased gait variability, specifically with mediolateral perturbations, poses a particular challenge for elderly adults and is linked to increased falls risk. Virtual reality training has shown promising effects on balance and gait. Conclusion Elderly adults show age‐related decline in balance and gait with increased gait variability and an associated increased risk of falls. Level of Evidence 5

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Section: Effects Of Visual Manipulations On Gait and Balance In Healtmentioning

confidence: 99%

Section: Visual Perturbationsmentioning

confidence: 99%

Balance and gait in the elderly: A contemporary review

Osoba

Rao

Agrawal

et al. 2019

Laryngoscope Investig Oto

279

185

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“…Walking balance control is especially dynamic, involving coordinated adjustments in posture (i.e., head and trunk stabilization) and foot placement from step to step (Bauby and Kuo, 2000; Kay and Warren, 2001; Donelan et al, 2004; Rankin et al, 2014). Particularly in unpredictable and challenging environmental conditions, these adjustments depend on the integration of reliable sensory feedback and the planning and execution of appropriate motor responses (O'Connor and Kuo, 2009; O'Connor et al, 2012; Francis et al, 2015; Franz et al, 2015, 2016; Goodworth et al, 2015). Accordingly, sensory and mechanical perturbations are increasingly used to study corrective motor responses in standing and walking and the onset and progression of balance deficits.…”

Section: Introductionmentioning

confidence: 99%

“…Accordingly, sensory and mechanical perturbations are increasingly used to study corrective motor responses in standing and walking and the onset and progression of balance deficits. Sensory perturbations may include those of visual (e.g., optical flow) (O'Connor and Kuo, 2009; O'Connor et al, 2012; Francis et al, 2015; Franz et al, 2015, 2016), somatosensory (e.g., tendon vibration) (Gurfinkel et al, 1976; Hay et al, 1996; Bove et al, 2003; Mullie and Duclos, 2014), or vestibular feedback (e.g., galvanic stimulation) (Day et al, 1993; Fitzpatrick et al, 1994; Bent et al, 2002; Dakin et al, 2007; Dalton et al, 2014), whereas mechanical perturbations most frequently incorporate support surface translations (Sinitksi et al, 2012; Aprigliano et al, 2016). Cortical activity and high-order cognitive processes are highly involved in the planning and execution of these motor responses.…”

Section: Introductionmentioning

confidence: 99%

“…Human balance control investigations have primarily focused on quantifying motor responses based on kinematic measurements such as movement variability and dynamic stability and/or kinetic measurements such as center of pressure and angular momentum (O'Connor and Kuo, 2009; McAndrew et al, 2011; Francis et al, 2015; Sheehan et al, 2015). These studies are rapidly accelerating our scientific understanding of human balance control, with exciting translational implications for the diagnosis and rehabilitation of people at risk of falls.…”

Section: Introductionmentioning

confidence: 99%

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Neuroimaging of Human Balance Control: A Systematic Review

Wittenberg

Thompson

Nam

et al. 2017

Front. Hum. Neurosci.

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116

106

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This review examined 83 articles using neuroimaging modalities to investigate the neural correlates underlying static and dynamic human balance control, with aims to support future mobile neuroimaging research in the balance control domain. Furthermore, this review analyzed the mobility of the neuroimaging hardware and research paradigms as well as the analytical methodology to identify and remove movement artifact in the acquired brain signal. We found that the majority of static balance control tasks utilized mechanical perturbations to invoke feet-in-place responses (27 out of 38 studies), while cognitive dual-task conditions were commonly used to challenge balance in dynamic balance control tasks (20 out of 32 studies). While frequency analysis and event related potential characteristics supported enhanced brain activation during static balance control, that in dynamic balance control studies was supported by spatial and frequency analysis. Twenty-three of the 50 studies utilizing EEG utilized independent component analysis to remove movement artifacts from the acquired brain signals. Lastly, only eight studies used truly mobile neuroimaging hardware systems. This review provides evidence to support an increase in brain activation in balance control tasks, regardless of mechanical, cognitive, or sensory challenges. Furthermore, the current body of literature demonstrates the use of advanced signal processing methodologies to analyze brain activity during movement. However, the static nature of neuroimaging hardware and conventional balance control paradigms prevent full mobility and limit our knowledge of neural mechanisms underlying balance control.

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