What Disconnection Tells about Motor Imagery: Evidence from Paraplegic Patients

Alkadhi, Hatem; Brugger, Peter; Hotz‐Boendermaker, Sabina; Crelier, Gérard; Curt, Armin; Hepp-Reymond, Marie-Claude; Kollias, Spyros

doi:10.1093/cercor/bhh116

Cited by 160 publications

(138 citation statements)

References 75 publications

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“…This view is supported by functional MRI (fMRI) studies in which cortical activation was detected when subjects imagined themselves walking (Bakker et al 2007(Bakker et al , 2008Iseki et al 2008) and when paraplegic patients imagined foot and leg movements (Alkadhi et al 2005;Cramer et al 2005;Hotz-Boendermaker et al 2008). A cortically EEG-driven BMI for the restoration or rehabilitation of walking could be also used as a strategy to harness or potentiate the remaining functionality and plasticity of spinal cord circuits isolated from the brain (Behrman et al 2006;Grasso et al 2004;Lunenburger et al 2006) and as a new tool for assessing the cortical contributions to walking in health and disease, or to study the changes in these contributions during learning and adaptation.…”

Section: Discussionmentioning

confidence: 94%

Neural decoding of treadmill walking from noninvasive electroencephalographic signals

Presacco

Goodman²,

Forrester

et al. 2011

Journal of Neurophysiology

189

199

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Here we show that the linear and angular kinematics of the ankle, knee, and hip joints during both normal and precision (attentive) human treadmill walking can be inferred from noninvasive scalp electroencephalography (EEG) with decoding accuracies comparable to those from neural decoders based on multiple single-unit activities (SUAs) recorded in nonhuman primates. Six healthy adults were recorded. Participants were asked to walk on a treadmill at their self-selected comfortable speed while receiving visual feedback of their lower limbs (i.e., precision walking), to repeatedly avoid stepping on a strip drawn on the treadmill belt. Angular and linear kinematics of the left and right hip, knee, and ankle joints and EEG were recorded, and neural decoders were designed and optimized with cross-validation procedures. Of note, the optimal set of electrodes of these decoders were also used to accurately infer gait trajectories in a normal walking task that did not require subjects to control and monitor their foot placement. Our results indicate a high involvement of a fronto-posterior cortical network in the control of both precision and normal walking and suggest that EEG signals can be used to study in real time the cortical dynamics of walking and to develop brain-machine interfaces aimed at restoring human gait function. brain computer interface; brain-machine interface; electroencephalography LITTLE IS KNOWN about the organization, neural network mechanisms, and computations underlying the control of walking in humans (Choi and Bastian 2007). Although central pattern generators for locomotion are important in the control of walking, supraspinal networks, including the brain stem, cerebellum, and cortex, must be critical, as demonstrated by the changing motor and cognitive (i.e., spatial attention) demands imposed by bipedal walking in unknown or cluttered dynamic environments (Choi and Bastian 2007;Grillner et al. 2008;Nielsen 2003;Rossignol et al. 2007). Neuroimaging studies show that rhythmic foot or leg movements recruit primary motor cortex (Christensen et al. 2001;Dobkin et al. 2004;Heuninckx et al. 2005Heuninckx et al. , 2008Luft et al. 2002;Sahyoun et al. 2004), whereas electrophysiological investigations demonstrate electrocortical potentials related to lower limb movements (Wieser et al. 2010), as well as a greater involvement of human cortex during steady-speed locomotion than previously thought (Gwin et al. , 2011. In this regard, studies using functional near-infrared spectroscopy (fNIRS) show involvement of frontal, premotor, and supplementary motor areas during walking (Harada et al. 2009;Miyai et al. 2001;Suzuki et al. 2004Suzuki et al. , 2008. That primary sensorimotor cortices carry information about bipedal locomotion has been directly proven by the work of Nicolelis and colleagues (Fitzsimmons et al. 2009), who demonstrated that chronic recordings from ensembles of cortical neurons in primary motor (M1) and primary somatosensory (S1) cortices can be used to predict the kinematics of bipedal wa...

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Section: Discussionmentioning

confidence: 94%

Neural decoding of treadmill walking from noninvasive electroencephalographic signals

Presacco

Goodman²,

Forrester

et al. 2011

Journal of Neurophysiology

189

199

View full text Add to dashboard Cite

show abstract

“…[25][26][27] The importance of cortical sensorimotor mechanisms underlying the effects of VF seem to be supported by the cumulative rather than independent pain-reducing effects of the combination of VF and transcranial direct current stimulation as observed in patients with neuropathic pain after SCI, 5 as well as by its simultaneous impact on motor functions and pain. 6 In addition, motor imagery abilities 20,[31][32][33][34] and cortical sensorimotor activity during movement observation, 20 motor imagery, 31,[34][35][36] or attempted movements 31,[34][35][36][37] have been shown to be intact after SCI, at least for simple movements. Still, these may not be preserved for complex movements.…”

Section: Vf Interventions Modulate Cortical Sensorimotor Integrationmentioning

confidence: 99%

“…Still, these may not be preserved for complex movements. 38 Moreover, reports of decreased activation levels and delayed timing, 35 as well as of additional brain regions being activated, 31,34 suggest that sensorimotor tasks may require more attention after SCI. A better understanding of the cortical sensorimotor mechanisms underlying the effects of VF in patients with SCI is therefore warranted.…”

Section: Vf Interventions Modulate Cortical Sensorimotor Integrationmentioning

confidence: 99%

Virtual feedback for motor and pain rehabilitation after spinal cord injury

Roosink

Mercier

2014

Spinal Cord

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Study design: Interventions using virtual feedback (VF) impact on motor functions and pain and may be relevant for neurorehabilitation after spinal cord injury (SCI) in which motor dysfunctions and (concomitant) pain are frequently observed. Potential mechanisms underlying VF include a modulation of cortical sensorimotor integration, increased therapy engagement and distraction from effort and pain. Still, the optimal parameters for VF and their technical implementation are currently unknown. Objectives: To provide an overview of interventions that have used VF to improve motor functions or to reduce pain after SCI. Methods: Literature review. Results: A total number of 17 studies were identified. VF interventions commonly focused on improving motor functions (n = 12) or reducing pain (n = 4). Only one study assessed both motor functions and pain. Studies generally report beneficial effects. However, the evidence is of low-level quality and many practical as well as theoretical issues remain unclear. Remaining knowledge gaps include: (1) optimal VF system characteristics, (2) the impact of different VF modalities and tasks, (3) dose-response relationships and (4) the identification of patients that are likely to benefit from VF. Future work should start by closing these knowledge gaps using systematic and controlled multi-session interventions and by assessing the underlying mechanisms involved. Conclusion: These results provide an important incentive to further assess the potential of VF interventions to simultaneously improve motor functions and reduce pain after SCI, which could contribute to better neurorehabilitation outcomes after SCI.

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“…44 The patients often feel they have full motor control over the limb (opening and closing, positioning, movement), which to some extent can be objectively measured by neuropsychological testing and be shown to induce a specific activation pattern of the brain (for example, functional MRI studies). [45][46][47] Although the involved circuits have not been delineated with sufficient preciseness, supernumerary phantom limb sensations are similarly associated with changes in the brain.…”

Section: Supernumerary Phantom Limbs In Scimentioning

confidence: 99%

Supernumerary phantom limbs in spinal cord injury

et al. 2010

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Study design and objectives: Case report and review of supernumerary phantom limbs in patients suffering from spinal cord injury (SCI). Setting: SCI rehabilitation centre. Case report: After a ski accident, a 71-year-old man suffered an incomplete SCI (level C3; AIS C, central cord syndrome), with a C3/C4 dislocation fracture. From the first week after injury, he experienced a phantom duplication of both upper limbs that lasted for 7 months. The supernumerary limbs were only occasionally related to painful sensation, specifically when they were perceived as crossed on his trunk. Although the painful sensations were responsive to pain medication, the presence of the illusory limb sensations were persistent. During neurological recovery, the supernumerary limbs gradually disappeared. A rubber hand illusion paradigm was used twice during recovery to monitor the patient's ability to integrate visual, tactile and proprioceptive stimuli. Conclusion: Overall, the clinical relevance of supernumerary phantom limbs is not clear, specific treatment protocols have not yet been developed, and the underlying neural mechanisms are not fully understood. Supernumerary phantom limbs have been previously reported in patients with (sub)cortical lesions, but might be rather undocumented in patients suffering from traumatic SCI. For the appropriate diagnosis and treatment after SCI, supernumerary phantoms should be distinguished from other phantom sensations and pain syndromes after SCI.

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What Disconnection Tells about Motor Imagery: Evidence from Paraplegic Patients

Cited by 160 publications

References 75 publications

Neural decoding of treadmill walking from noninvasive electroencephalographic signals

Neural decoding of treadmill walking from noninvasive electroencephalographic signals

Virtual feedback for motor and pain rehabilitation after spinal cord injury

Supernumerary phantom limbs in spinal cord injury

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