Low‐Frequency Brain Oscillations Track Motor Recovery in Human Stroke

Bönstrup, Marlene; Krawinkel, Lutz; Schulz, Robert; Cheng, Bastian; Feldheim, Jan; Thomalla, Götz; Cohen, Leonardo G.; Gerloff, Christian

doi:10.1002/ana.25615

Cited by 45 publications

(28 citation statements)

References 54 publications

(124 reference statements)

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“…Recently, studies using electroencephalography (EEG) have experienced a renaissance due to improvements in recording and analyzing techniques [ 7 , 56 ]. For example, Bonstrup et al [ 7 ] recorded high-density EEG while hemiparetic patients within 5 days post-stroke performed an isometric visually guided whole-hand grip task with their paretic hand. The authors found that the re-emergence of low-frequency oscillations during movement preparation coincided with hand motor recovery with more robust increases in patients making a better recovery.…”

Section: Introductionmentioning

confidence: 99%

Recovery from stroke: current concepts and future perspectives

Grefkes

Fink

2020

Neurol. Res. Pract.

181

116

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Stroke is a leading cause of acquired, permanent disability worldwide. Although the treatment of acute stroke has been improved considerably, the majority of patients to date are left disabled with a considerable impact on functional independence and quality of life. As the absolute number of stroke survivors is likely to further increase due to the demographic changes in our aging societies, new strategies are needed in order to improve neurorehabilitation. The most critical driver of functional recovery post-stroke is neural reorganization. For developing novel, neurobiologically informed strategies to promote recovery of function, an improved understanding of the mechanisms enabling plasticity and recovery is mandatory. This review provides a comprehensive survey of recent developments in the field of stroke recovery using neuroimaging and non-invasive brain stimulation. We discuss current concepts of how the brain reorganizes its functional architecture to overcome stroke-induced deficits, and also present evidence for maladaptive effects interfering with recovery. We demonstrate that the combination of neuroimaging and neurostimulation techniques allows a better understanding of how brain plasticity can be modulated to promote the reorganization of neural networks. Finally, neurotechnology-based treatment strategies allowing patient-tailored interventions to achieve enhanced treatment responses are discussed. The review also highlights important limitations of current models, and finally closes with possible solutions and future directions.

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Section: Introductionmentioning

confidence: 99%

Recovery from stroke: current concepts and future perspectives

Grefkes

Fink

2020

Neurol. Res. Pract.

181

116

View full text Add to dashboard Cite

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“…These results demonstrate that the reduced power of low-frequency oscillations observed following a stroke to the motor cortex is a key contributing factor to impaired movement. In other human patients with motor deficits, a reduction in movementdependent low frequency oscillations has been reported in the acute phase; however, motor recovery was observed and oscillatory power returned to normal levels 3 months after stroke (Bönstrup et al, 2019). These results highlight the impact of oscillatory changes after stroke on motor behaviour and show that modulating low frequency oscillations could be the key to improving motor function.…”

Section: Oscillatory Changes After Strokementioning

confidence: 50%

Driving Oscillatory Dynamics: Neuromodulation for Recovery After Stroke

Storch

Samantzis

Balbi

2021

Front. Syst. Neurosci.

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Stroke is a leading cause of death and disability worldwide, with limited treatments being available. However, advances in optic methods in neuroscience are providing new insights into the damaged brain and potential avenues for recovery. Direct brain stimulation has revealed close associations between mental states and neuroprotective processes in health and disease, and activity-dependent calcium indicators are being used to decode brain dynamics to understand the mechanisms underlying these associations. Evoked neural oscillations have recently shown the ability to restore and maintain intrinsic homeostatic processes in the brain and could be rapidly deployed during emergency care or shortly after admission into the clinic, making them a promising, non-invasive therapeutic option. We present an overview of the most relevant descriptions of brain injury after stroke, with a focus on disruptions to neural oscillations. We discuss the optical technologies that are currently used and lay out a roadmap for future studies needed to inform the next generation of strategies to promote functional recovery after stroke.

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“…RAR has been proven effective in post-SCI gait rehabilitation, as it can bypass the constraints in providing an individualized training strategy and the main limitations of iSCI individuals in overground walking ability, i.e., sensorimotor coordination, spasticity, impaired balance, and muscle weakness [ 8 , 32 , 33 , 34 , 35 , 36 ]. Consistently, the RAR − NIBS group showed a significant improvement in ambulation (including walking speed and independence and lower limb muscle strength) with a reduced requirement of assistance after the treatment.…”

Section: Discussionmentioning

confidence: 99%

Finding the Way to Improve Motor Recovery of Patients with Spinal Cord Lesions: A Case-Control Pilot Study on a Novel Neuromodulation Approach

et al. 2022

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Robot-assisted rehabilitation (RAR) and non-invasive brain stimulation (NIBS) are interventions that, both individually and combined, can significantly enhance motor performance after spinal cord injury (SCI). We sought to determine whether repetitive transcranial magnetic stimulation (rTMS) combined with active transvertebral direct current stimulation (tvDCS) (namely, NIBS) in association with RAR (RAR + NIBS) improves lower extremity motor function more than RAR alone in subjects with motor incomplete SCI (iSCI). Fifteen adults with iSCI received one daily session of RAR+NIBS in the early afternoon, six sessions weekly, for eight consecutive weeks. Outcome measures included the 6 min walk test (6MWT), the 10 m walk test (10MWT), the timed up and go (TUG) to test mobility and balance, the Walking Index for Spinal Cord Injury (WISCI II), the Functional Independence Measure-Locomotion (FIM-L), the manual muscle testing for lower extremity motor score (LEMS), the modified Ashworth scale for lower limbs (MAS), and the visual analog scale (VAS) for pain. The data of these subjects were compared with those of 20 individuals matched for clinical and demographic features who previously received the same amount or RAR without NIBS (RAR − NIBS). All patients completed the trial, and none reported any side effects either during or following the training. The 10MWT improved in both groups, but the increase was significantly greater following RAR + NIBS than RAR − NIBS. The same occurred for the FIM-L, LEMS, and WISCI II. No significant differences were appreciable concerning the 6MWT and TUG. Conversely, RAR − NIBS outperformed RAR + NIBS regarding the MAS and VAS. Pairing tvDCS with rTMS during RAR can improve lower extremity motor function more than RAR alone can do. Future research with a larger sample size is recommended to determine longer-term effects on motor function and activities of daily living.

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Low‐Frequency Brain Oscillations Track Motor Recovery in Human Stroke

Cited by 45 publications

References 54 publications

Recovery from stroke: current concepts and future perspectives

Recovery from stroke: current concepts and future perspectives

Driving Oscillatory Dynamics: Neuromodulation for Recovery After Stroke

Finding the Way to Improve Motor Recovery of Patients with Spinal Cord Lesions: A Case-Control Pilot Study on a Novel Neuromodulation Approach

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