It's how you get there: walking down a virtual alley activates premotor and parietal areas

Wagner, Johanna; Solis‐Escalante, Teodoro; Scherer, Reinhold; Neuper, Christa; Müller-Putz, Gernot

doi:10.3389/fnhum.2014.00093

Cited by 144 publications

(197 citation statements)

References 93 publications

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“…In accordance with different studies ( [14,[62][63][64][65] the analysis of the event related spectral perturbation (ERSP) during walking shows specific power increases (interpreted as an event related synchronization, ERS) or decreases (even related desynchronization, ERD). Figure 1 illustrates such type of results recorded from C3 and C4 electrodes which are anatomically placed over the left and right sensorimotor areas corresponding to the left and right hand region, respectively, during 50 walking cycles.…”

Section: Eeg During Walking Executionsupporting

confidence: 72%

“…This has resulted in much convergence in results but also some divergent evidence within this literature. Neurophysiological, neuroimaging and behavioral data have demonstrated a high sensitivity to kinematics of human movement [120,121] including walking [122,123] as in a selfimage mirror walking or virtual environment [63], reference frame [122,[124][125][126]. It is well known that shape and motion information are treated separately by ventral and dorsal visual streams, and converge to the posterior portion of superior temporal sulcus [111,127,128].…”

Section: Walking Observation and The Mirror Neuron Systemmentioning

confidence: 99%

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

et al. 2015

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Section: Eeg During Walking Executionsupporting

confidence: 72%

Section: Walking Observation and The Mirror Neuron Systemmentioning

confidence: 99%

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

et al. 2015

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“…Furthermore, a recent study using resting state functional magnetic resonance imaging found significant changes in activity in sensorimotor areas in a group of young individuals after 20 min of aerobic exercise (Rajab et al, 2014), while a couple of studies demonstrated that functional brain activity in motor areas increased proportional to the movement rate on a pedaling task executed during scanning (Mehta et al, 2012). Finally, increased SMA activation was observed during motor imagery of locomotor-related tasks (Malouin et al, 2003) as well as during real locomotion as measured by electrophysiological studies showing SMA modulation during walking (Petersen et al, 2012; Wagner et al, 2012, 2014; Seeber et al, 2015). Thus despite the scarcity of studies assessing cerebral structural and functional changes in relation to gait parameters and aerobic training in humans, the above mentioned studies provide basic evidence that AET can have a direct impact on the brain.…”

Section: Discussionmentioning

confidence: 95%

A 12-Week Cycling Training Regimen Improves Gait and Executive Functions Concomitantly in People with Parkinson’s Disease

Nadeau

Lungu

Duchesne

et al. 2017

Front. Hum. Neurosci.

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Background: There is increasing evidence that executive functions and attention are associated with gait and balance, and that this link is especially prominent in older individuals or those who are aﬄicted by neurodegenerative diseases that affect cognition and/or motor functions. People with Parkinson’s disease (PD) often present gait disturbances, which can be reduced when PD patients engage in different types of physical exercise (PE), such as walking on a treadmill. Similarly, PE has also been found to improve executive functions in this population. Yet, no exercise intervention investigated simultaneously gait and non-motor symptoms (executive functions, motor learning) in PD patients.Objective: To assess the impact of aerobic exercise training (AET) using a stationary bicycle on a set of gait parameters (walking speed, cadence, step length, step width, single and double support time, as well as variability of step length, step width and double support time) and executive functions (cognitive inhibition and flexibility) in sedentary PD patients and healthy controls.Methods: Two groups, 19 PD patients (Hoehn and Yahr ≤2) and 20 healthy adults, matched on age and sedentary level, followed a 3-month stationary bicycle AET regimen.Results: Aerobic capacity, as well as performance of motor learning and on cognitive inhibition, increased significantly in both groups after the training regimen, but only PD patients improved their walking speed and cadence (all p < 0.05; with no change in the step length). Moreover, in PD patients, training-related improvements in aerobic capacity correlated positively with improvements in walking speed (r = 0.461, p < 0.05).Conclusion: AET using stationary bicycle can independently improve gait and cognitive inhibition in sedentary PD patients. Given that increases in walking speed were obtained through increases in cadence, with no change in step length, our findings suggest that gait improvements are specific to the type of motor activity practiced during exercise (i.e., pedaling). In contrast, the improvements seen in cognitive inhibition were, most likely, not specific to the type of training and they could be due to indirect action mechanisms (i.e., improvement of cardiovascular capacity). These results are also relevant for the development of targeted AET interventions to improve functional autonomy in PD patients.

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“…However, recent functional neuroimaging studies in humans have shown that the midline (i.e., the most medial) primary sensorimotor cortex is significantly active during steady-state walking (Fukuyama et al, 1997; Hanakawa et al, 1999; Miyai et al, 2001; Wagner et al, 2012, 2014; Seeber et al, 2014, 2015; Storzer et al, 2016). Specifically, within the gait cycle, the midline primary sensorimotor cortex cyclically increases its activity approximately between mid-beta and low-gamma frequencies (Wagner et al, 2012, 2014; Seeber et al, 2014, 2015; Storzer et al, 2016). Furthermore, Petersen et al (2012) have reported that, during treadmill walking, the activities of the midline primary motor cortex and the foot dorsiflexor become cyclically coherent, with similar timing and frequency range as the aforementioned increase in the midline sensorimotor activity.…”

Section: Introductionmentioning

confidence: 99%

Dynamic Increase in Corticomuscular Coherence during Bilateral, Cyclical Ankle Movements

Yoshida

Masani

Zabjek

et al. 2017

Front. Hum. Neurosci.

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In humans, the midline primary motor cortex is active during walking. However, the exact role of such cortical participation is unknown. To delineate the role of the primary motor cortex in walking, we examined whether the primary motor cortex would activate leg muscles during movements that retained specific requirements of walking (i.e., locomotive actions). We recorded electroencephalographic and electromyographic signals from 15 healthy, young men while they sat and performed bilateral, cyclical ankle movements. During dorsiflexion, near-20-Hz coherence increased cyclically between the midline primary motor cortex and the co-contracting antagonistic pair (i.e., tibialis anterior and medial gastrocnemius muscles) in both legs. Thus, we have shown that dynamic increase in corticomuscular coherence, which has been observed during walking, also occurs during simple bilateral cyclical movements of the feet. A possible mechanism for such coherence is corticomuscular communication, in which the primary motor cortex participates in the control of movement. Furthermore, because our experimental task isolated certain locomotive actions, the observed coherence suggests that the human primary motor cortex may participate in these actions (i.e., maintaining a specified movement frequency, bilaterally coordinating the feet, and stabilizing the posture of the feet). Additional studies are needed to identify the exact cortical and subcortical interactions that cause corticomuscular coherence and to further delineate the functional role of the primary motor cortex during bilateral cyclical movements such as walking.

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It's how you get there: walking down a virtual alley activates premotor and parietal areas

Cited by 144 publications

References 93 publications

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

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

A 12-Week Cycling Training Regimen Improves Gait and Executive Functions Concomitantly in People with Parkinson’s Disease

Dynamic Increase in Corticomuscular Coherence during Bilateral, Cyclical Ankle Movements

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