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4. TMS assessment of corticospinal tract integrity after stroke: broadening the concept to inform neurorehabilitation prescription.

Author

Kumar, Sapna, Ferraro, Mary, Lienhoung Nguyen, Ning Cao, Ung, Nathaniel, Jose, Joshua S., Weidenauer, Cheryl, Edwards, Dylan J., and Mayer, Nathaniel H.

Subjects
TRANSCRANIAL magnetic stimulation, EVOKED potentials (Electrophysiology), PYRAMIDAL tract, STROKE, MOTOR cortex, WRIST, FOREARM
Abstract

Upper limb actions require intersegmental coordination of the scapula, shoulders, elbows, forearms, wrists, and hand muscles. Stroke hemiparesis, presenting as an impairment of an intersegmentally coordinated voluntary movement, is associated with altered integrity of corticospinal tract (CST) transmission from the motor cortex (M1) to muscles. Motor evoked potentials (MEPs) elicited by M1 transcranial magnetic stimulation (TMS) of "at rest" muscles, or as a backup, during muscle contraction have been used to identify CST integrity and predict the outcome after hemiparesis, under the implicit assumption that MEPs present in only one or two muscles are manifest surrogates of CST integrity for other muscles of the upper limbs. This study presents a method for applying TMS during motor tasks that involve proximal and distal muscles. It focuses on evaluating multi-muscle electromyography (EMG) and MEPs across all task-relevant limb segments. Protocols are presented for assessing voluntary motor behavior in individuals with hemiparetic stroke using isometric, unimanual, bimanual, and "REST" conditions that broaden the concept of the degree of CST integrity in order to inform clinical prescription for neurorehabilitation and distinguish its potential as a prognostic tool. Data describing the recordings of multi-muscle transcranial magnetic stimulation induced motor evoked potentials (TMS-MEP) will be presented in a case of subacute hemiparetic stroke to elucidate our perspective. [ABSTRACT FROM AUTHOR]

Published
2024
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10. Rigor and reproducibility in research with transcranial electrical stimulation: An NIMH-sponsored workshop

Author

Bikson, Marom, Brunoni, Andre R., Charvet, Leigh E., Clark, Vincent P., Cohen, Leonardo G., Deng, Zhi-De, Dmochowski, Jacek, Edwards, Dylan J., Frohlich, Flavio, Kappenman, Emily S., Lim, Kelvin O., Loo, Colleen, Mantovani, Antonio, McMullen, David P., Parra, Lucas C., Pearson, Michele, Richardson, Jessica D., Rumsey, Judith M., Sehatpour, Pejman, Sommers, David, Unal, Gozde, Wassermann, Eric M., Woods, Adam J., and Lisanby, Sarah H.

Published
2018
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16. Activation of MAP2K signaling by genetic engineering or HF-rTMS promotes corticospinal axon sprouting and functional regeneration.

Author

Boato, Francesco, Guan, Xiaofei, Zhu, Yanjie, Ryu, Youngjae, Voutounou, Mariel, Rynne, Christopher, Freschlin, Chase R., Zumbo, Paul, Betel, Doron, Matho, Katie, Makarov, Sergey N., Wu, Zhuhao, Son, Young-Jin, Nummenmaa, Aapo, Huang, Josh Z., Edwards, Dylan J., and Zhong, Jian

Subjects
AXONS, GENETIC engineering, NERVOUS system regeneration, TRANSCRANIAL magnetic stimulation, CENTRAL nervous system, RETINAL ganglion cells
Abstract

Facilitating axon regeneration in the injured central nervous system remains a challenging task. RAF-MAP2K signaling plays a key role in axon elongation during nervous system development. Here, we show that conditional expression of a constitutively kinase-activated BRAF in mature corticospinal neurons elicited the expression of a set of transcription factors previously implicated in the regeneration of zebrafish retinal ganglion cell axons and promoted regeneration and sprouting of corticospinal tract (CST) axons after spinal cord injury in mice. Newly sprouting axon collaterals formed synaptic connections with spinal interneurons, resulting in improved recovery of motor function. Noninvasive suprathreshold high-frequency repetitive transcranial magnetic stimulation (HF-rTMS) activated the BRAF canonical downstream effectors MAP2K1/2 and modulated the expression of a set of regeneration-related transcription factors in a pattern consistent with that induced by BRAF activation. HF-rTMS enabled CST axon regeneration and sprouting, which was abolished in MAP2K1/2 conditional null mice. These data collectively demonstrate a central role of MAP2K signaling in augmenting the growth capacity of mature corticospinal neurons and suggest that HF-rTMS might have potential for treating spinal cord injury by modulating MAP2K signaling. Stimulating growth: Recovery from spinal cord injury is hindered by the inability of CNS neurons to regenerate severed axons, and there are no effective approaches to promote axonal growth after a CNS injury. Here, Boato et al. showed that conditional BRAF activation using genetic approaches activated MAP2K signaling and promoted axonal regeneration after spinal cord injury in mice. Similarly, non-invasive repetitive transcranial magnetic stimulation (rTMS) activated MAP2K signaling and enhanced axonal regeneration and functional recovery, suggesting that rTMS might be a valuable treatment option for spinal cord injury. —MM [ABSTRACT FROM AUTHOR]

Published
2023
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18. Eccentric utilization ratio: effect of sport and phase of training

Author

McGuigan, Michael R., Doyle, Timothy L.A., Newton, Michael, Edwards, Dylan J., Nimphius, Sophia, and Newton, Robert U.

Subjects
Athletes -- Health aspects, Eccentrics and eccentricities -- Research, Health, Sports and fitness
Abstract

The eccentric utilization ratio (EUR), which is the ratio of countermovement jump (CMJ) to static jump (SJ) performance, has been suggested as a useful indicator of power performance in athletes. The purpose of the study was to compare the EUR of athletes from a variety of different sports and during different phases of training. A total of 142 athletes from rugby union, Australian Rules Football, soccer, softball, and field hockey were tested. Subjects performed both CMJ and SJ on a force plate integrated with a position transducer. The EUR was measured as the ratio of CMJ to SJ for jump height and peak power. The rugby union, Australian Rules Football, and hockey athletes were tested during off-season and preseason to provide EUR data during different phases of training. For men, EUR for soccer, Australian Rules Football, and rugby was greater than softball (effect size range, 0.83-0.92). For women, EUR for soccer was greater than field hockey and softball (0.86-1.0). There was a significant difference between the jump height and peak power method for the Australian Rules Football, rugby, and field hockey tests conducted preseason (p < 0.05). For field hockey, there was a significant increase in EUR from off-season to preseason. Athletes in sports such as soccer, rugby union, and Australian Rules Football appear to have higher EUR values, which reflects the greater reliance on stretch shortening activities in these sports. It does appear that EUR can be used to track changes in training with the values significantly increasing from off-season to preseason. The EUR provides the practitioner with information about the performance of athletes and appears to be sensitive to changes in the type of training being undertaken. KEY WORDS. countermovement jump, squat jump, stretch-shortening cycle, power

Published
2006

19. High Definition tDCS Effect on Postural Control in Healthy Individuals: Entropy Analysis of a Crossover Clinical Trial.

Author

Favoretto, Diandra B., Bergonzoni, Eduardo, Nascimento, Diego Carvalho, Louzada, Francisco, Lemos, Tenysson W., Batistela, Rosangela A., Moraes, Renato, Leite, João P., Rimoli, Brunna P., Edwards, Dylan J., and Edwards, Taiza G. S.

Subjects
POSTURAL balance, TRANSCRANIAL direct current stimulation, CROSSOVER trials, GROUND reaction forces (Biomechanics), CLINICAL trials, ENTROPY
Abstract

Objective: Converging evidence supporting an effect of transcranial direct current stimulation (tDCS) on postural control and human verticality perception highlights this strategy as promising for post-stroke rehabilitation. We have previously demonstrated polarity-dependent effects of high-definition tDCS (HD-tDCS) on weight-bearing asymmetry. However, there is no investigation regarding the time-course of effects on postural control induced by HD-tDCS protocols. Thus, we performed a nonlinear time series analysis focusing on the entropy of the ground reaction force as a secondary investigation of our randomized, double-blind, placebo-controlled, crossover clinical trial. Materials and Methods: Twenty healthy right-handed young adults received the following conditions (random order, separate days); anode center HD-tDCS, cathode center HD-tDCS or sham HD-tDCS at 1, 2, and 3 mA over the right temporo-parietal junction (TPJ). Using summarized time series of transfer entropy, we evaluated the exchanging information (causal direction) between both force plates and compared the dose-response across the healthy subjects with a Generalized Linear Hierarchical/Mixed Model (GLMM). Results: We found significant variation during the dynamic information flow (p < 0.001) among the dominant bodyside (and across time). A greater force transfer entropy was observed from the right to the left side during the cathode-center HD-tDCS up to 2 mA, with a causal relationship in the information flow (equilibrium force transfer) from right to left that decreased over time. Conclusions: HD-tDCS intervention induced a dynamic influence over time on postural control entropy. Right hemisphere TPJ stimulation using cathode-center HD-tDCS can induce an asymmetry of body weight distribution towards the ipsilateral side of stimulation. These results support the clinical potential of HD-tDCS for post-stroke rehabilitation. [ABSTRACT FROM AUTHOR]

Published
2022
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24. `An observational report of intensive robotic and manual gait training in sub-acute stroke

Author

Conesa Lucas, Costa Úrsula, Morales Eva, Edwards Dylan J, Cortes Mar, León Daniel, Bernabeu Montserrat, and Medina Josep

Subjects
Gait training, stroke, body weight support, rehabilitation, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571
Abstract

Abstract Background The use of automated electromechanical devices for gait training in neurological patients is increasing, yet the functional outcomes of well-defined training programs using these devices and the characteristics of patients that would most benefit are seldom reported in the literature. In an observational study of functional outcomes, we aimed to provide a benchmark for expected change in gait function in early stroke patients, from an intensive inpatient rehabilitation program including both robotic and manual gait training. Methods We followed 103 sub-acute stroke patients who met the clinical inclusion criteria for Body Weight Supported Robotic Gait Training (BWSRGT). Patients completed an intensive 8-week gait-training program comprising robotic gait training (weeks 0-4) followed by manual gait training (weeks 4-8). A change in clinical function was determined by the following assessments taken at 0, 4 and 8 weeks (baseline, mid-point and end-point respectively): Functional Ambulatory Categories (FAC), 10 m Walking Test (10 MWT), and Tinetti Gait and Balance Scales. Results Over half of the patients made a clinically meaningful improvement on the Tinetti Gait Scale (> 3 points) and Tinetti Balance Scale (> 5 points), while over 80% of the patients increased at least 1 point on the FAC scale (0-5) and improved walking speed by more than 0.2 m/s. Patients responded positively in gait function regardless of variables gender, age, aetiology (hemorrhagic/ischemic), and affected hemisphere. The most robust and significant change was observed for patients in the FAC categories two and three. The therapy was well tolerated and no patients withdrew for factors related to the type or intensity of training. Conclusions Eight-weeks of intensive rehabilitation including robotic and manual gait training was well tolerated by early stroke patients, and was associated with significant gains in function. Patients with mid-level gait dysfunction showed the most robust improvement following robotic training.

Published
2012
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25. Reversal of TMS-induced motor twitch by training is associated with a reduction in excitability of the antagonist muscle

Author

Fregni Felipe, Thickbroom Gary W, Volpe Bruce T, Giacobbe Viola, Pascual-Leone Alvaro, Krebs Hermano I, and Edwards Dylan J

Subjects
Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571
Abstract

Abstract Background A single session of isolated repetitive movements of the thumb can alter the response to transcranial magnetic stimulation (TMS), such that the related muscle twitch measured post-training occurs in the trained direction. This response is attributed to transient excitability changes in primary motor cortex (M1) that form the early part of learning. We investigated; (1) whether this phenomenon might occur for movements at the wrist, and (2) how specific TMS activation patterns of opposing muscles underlie the practice-induced change in direction. Methods We used single-pulse suprathreshold TMS over the M1 forearm area, to evoke wrist movements in 20 healthy subjects. We measured the preferential direction of the TMS-induced twitch in both the sagittal and coronal plane using an optical goniometer fixed to the dorsum of the wrist, and recorded electromyographic (EMG) activity from the flexor carpi radialis (FCR) and extensor carpi radialis (ECR) muscles. Subjects performed gentle voluntary movements, in the direction opposite to the initial twitch for 5 minutes at 0.2 Hz. We collected motor evoked potentials (MEPs) elicited by TMS at baseline and for 10 minutes after training. Results Repetitive motor training was sufficient for TMS to evoke movements in the practiced direction opposite to the original twitch. For most subjects the effect of the newly-acquired direction was retained for at least 10 minutes before reverting to the original. Importantly, the direction change of the movement was associated with a significant decrease in MEP amplitude of the antagonist to the trained muscle, rather than an increase in MEP amplitude of the trained muscle. Conclusions These results demonstrate for the first time that a TMS-twitch direction change following a simple practice paradigm may result from reduced corticospinal drive to muscles antagonizing the trained direction. Such findings may have implications for training paradigms in neurorehabilitation.

Published
2011
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27. On the understanding and development of modern physical neurorehabilitation methods: robotics and non-invasive brain stimulation

Author

Edwards Dylan J

Subjects
Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571
Abstract

Abstract The incidence of physical disability in the community resulting from neurological dysfunction is predicted to increase in the coming years. The impetus for immediate and critical evaluation of physical neurorehabilitation strategies stems from the largely incomplete recovery following neurological damage, questionable efficacy of individual rehabilitation techniques, and the progressive acceptance of evidence-based medicine. The emergent technologies of non-invasive brain stimulation (NBS) and rehabilitation robotics enable a better understanding of the recovery process, as well as the mechanisms and effectiveness of intervention. With a more precise grasp of the relationship between dysfunctional and treatment-related plasticity, we can anticipate a move toward highly controlled and individualised prescription of rehabilitation. Both robotics and NBS can also be used to enhance motor control and learning in patients with neurological dysfunction. The merit of these contemporary methods as investigative and rehabilitation tools requires clarification and discussion. In this thematic series, five cohesive and eloquent papers address this issue from leading clinicians and scientists in the fields of robotics, NBS, plasticity and motor learning.

Published
2009
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29. BrainWave Nets: Are Sparse Dynamic Models Susceptible to Brain Manipulation Experimentation?

Author

Nascimento, Diego C., Pinto-Orellana, Marco A., Leite, Joao P., Edwards, Dylan J., Louzada, Francisco, and Santos, Taiza E. G.

Subjects
DYNAMIC models, TRANSCRANIAL direct current stimulation, IMPULSE response, TIME series analysis
Abstract

Sparse time series models have shown promise in estimating contemporaneous and ongoing brain connectivity. This paper was motivated by a neuroscience experiment using EEG signals as the outcome of our established interventional protocol, a new method in neurorehabilitation toward developing a treatment for visual verticality disorder in post-stroke patients. To analyze the [complex outcome measure (EEG)] that reflects neural-network functioning and processing in more specific ways regarding traditional analyses, we make a comparison among sparse time series models (classic VAR, GLASSO, TSCGM, and TSCGM-modified with non-linear and iterative optimizations) combined with a graphical approach, such as a Dynamic Chain Graph Model (DCGM). These dynamic graphical models were useful in assessing the role of estimating the brain network structure and describing its causal relationship. In addition, the class of DCGM was able to visualize and compare experimental conditions and brain frequency domains [using finite impulse response (FIR) filter]. Moreover, using multilayer networks, the results corroborate with the susceptibility of sparse dynamic models, bypassing the false positives problem in estimation algorithms. We conclude that applying sparse dynamic models to EEG data may be useful for describing intervention-relocated changes in brain connectivity. [ABSTRACT FROM AUTHOR]

Published
2020
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30. Dose and staffing comparison study of upper limb device-assisted therapy.

Author

Wuennemann, Marissa J., Mackenzie, Stuart W., Lane, Heather Pepper, Peltz, Avrielle R., Xiaoyue Ma, Gerber, Linda M., Edwards, Dylan J., and Tomoko Kitago

Subjects
ARM, DOSE-effect relationship in pharmacology, GROUP psychotherapy, HEMIPLEGIA, WORKING hours, MOTOR ability, NEUROLOGICAL disorders, TREATMENT effectiveness, MUSCLE weakness
Abstract

BACKGROUND: Neurological injuries cause persistent upper extremity motor deficits. Device-assisted therapy is an emerging trend in neuro-rehabilitation as it offers high intensity, repetitive practice in a standardized setting. OBJECTIVE: To investigate the effects of therapy duration and staff-participant configuration on device-assisted upper limb therapy outcomes in individuals with chronic paresis. METHODS: Forty-seven participants with chronic upper extremity weakness due to neurological injury were assigned to a therapy duration (30 or 60 min) and a staff-participant configuration (1-to-l or l-to-2). Therapy consisted of 3 sessions a week for 6 weeks using the Armeo®Spring device. Clinical assessments were performed at three timepoints (Pre, Post, and 3 month Follow up). RESULTS: Improvements in upper limb impairment, measured by change in Fugl-Meyer score (FM), were observed following therapy in all groups. FM improvement was comparable between 30 and 60 min sessions, but participants in the I -to-2 group had significantly greater improvement in FM from Pre-to-Post and from Pre-to-Follow up than the 1 -to-1 group. CONCLUSIONS: Device-assisted therapy can reduce upper limb impairment to a similar degree whether participants received 30 or 60 min per session. Our results suggest that delivering therapy in a 1 -to-2 configuration is a feasible and more effective approach than traditional 1-to-l staffing. [ABSTRACT FROM AUTHOR]

Published
2020
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31. Paired Associative Stimulation as a Tool to Assess Plasticity Enhancers in Chronic Stroke.

Author

Silverstein, Joshua, Cortes, Mar, Tsagaris, Katherine Zoe, Climent, Alejandra, Gerber, Linda M., Oromendia, Clara, Fonzetti, Pasquale, Ratan, Rajiv R., Kitago, Tomoko, Iacoboni, Marco, Wu, Allan, Dobkin, Bruce, and Edwards, Dylan J.

Subjects
PYRAMIDAL tract, REPEATED measures design, STROKE, CENTRAL nervous system
Abstract

Background and Purpose: The potential for adaptive plasticity in the post-stroke brain is difficult to estimate, as is the demonstration of central nervous system (CNS) target engagement of drugs that show promise in facilitating stroke recovery. We set out to determine if paired associative stimulation (PAS) can be used (a) as an assay of CNS plasticity in patients with chronic stroke, and (b) to demonstrate CNS engagement by memantine, a drug which has potential plasticity-modulating effects for use in motor recovery following stroke. Methods: We examined the effect of PAS in fourteen participants with chronic hemiparetic stroke at five time-points in a within-subjects repeated measures design study: baseline off-drug, and following a week of orally administered memantine at doses of 5, 10, 15, and 20 mg, comprising a total of seventy sessions. Each week, MEP amplitude pre and post-PAS was assessed in the contralesional hemisphere as a marker of enhanced or diminished plasticity. Strength and dexterity were recorded each week to monitor motor-specific clinical status across the study period. Results: We found that MEP amplitude was significantly larger after PAS in baseline sessions off-drug, and responsiveness to PAS in these sessions was associated with increased clinical severity. There was no observed increase in MEP amplitude after PAS with memantine at any dose. Motor threshold (MT), strength, and dexterity remained unchanged during the study. Conclusion: Paired associative stimulation successfully induced corticospinal excitability enhancement in chronic stroke subjects at the group level. However, this response did not occur in all participants, and was associated with increased clinical severity. This could be an important way to stratify patients for future PAS-drug studies. PAS was suppressed by memantine at all doses, regardless of responsiveness to PAS off-drug, indicating CNS engagement. [ABSTRACT FROM AUTHOR]

Published
2019
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32. Fractional Anisotropy of Thalamic Nuclei Is Associated With Verticality Misperception After Extra-Thalamic Stroke.

Author

Santos, Taiza E. G., Baggio, Jussara A. O., Rondinoni, Carlo, Machado, Laura, Weber, Karina T., Stefano, Luiz H., Santos, Antonio C., Pontes-Neto, Octavio M., Leite, Joao P., and Edwards, Dylan J.

Subjects
THALAMIC nuclei, ANISOTROPY, STROKE, DIFFUSION tensor imaging, THALAMUS
Abstract

Verticality misperception after stroke is a frequent neurological deficit that leads to postural imbalance and a higher risk of falls. The posterior thalamic nuclei are described to be involved with verticality perception, but it is unknown if extra-thalamic lesions can have the same effect via diaschisis and degeneration of thalamic nuclei. We investigated the relationship between thalamic fractional anisotropy (FA, a proxy of structural integrity), and verticality perception, in patients after stroke with diverse encephalic extra-thalamic lesions. We included 11 first time post-stroke patients with extra-thalamic primary lesions, and compared their region-based FA to a group of 25 age-matched healthy controls. For the patient sample, correlation and regression analyses evaluated the relationship between thalamic nuclei FA and error of postural vertical (PV) and haptic vertical (HV) in the roll (PVroll/HVroll) and pitch planes (PVpitch/HVpitch). Relative to controls, patients showed decreased FA of anterior, ventral anterior, ventral posterior lateral, dorsal, and pulvinar thalamic nuclei, despite the primary lesions being extra-thalamic. We found a significant correlation between HVroll, and FA in the anterior and dorsal nuclei, and PVroll with FA in the anterior nucleus. FA in the anterior, ventral anterior, ventral posterior lateral, dorsal and pulvinar nuclei predicted PV, and FA in the ventral anterior, ventral posterior lateral and dorsal nuclei predicted HV. While prior studies indicate that primary lesions of the thalamus can result in verticality misperception, here we present evidence supporting that secondary degeneration of thalamic nuclei via diaschisis can also be associated with verticality misperception after stroke. [ABSTRACT FROM AUTHOR]

Published
2019
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33. NeuroMeasure: A Software Package for Quantification of Cortical Motor Maps Using Frameless Stereotaxic Transcranial Magnetic Stimulation.

Author

Gerber, Michael B., McLean, Alasdair C., Stephen, Samuel J., Chalco, Alex G., Arshad, Usman M., Thickbroom, Gary W., Silverstein, Josh, Tsagaris, K. Zoe, Kuceyeski, Amy, Friel, Kathleen, Santos, Taiza E. G., and Edwards, Dylan J.

Subjects
TRANSCRANIAL magnetic stimulation, INTEGRATED software, COMPUTER software, MOTOR cortex, OPEN source software, APPLICATION software, CARTOGRAPHY software
Abstract

The recent enhanced sophistication of non-invasive mapping of the human motor cortex using MRI-guided Transcranial Magnetic Stimulation (TMS) techniques, has not been matched by refinement of methods for generating maps from motor evoked potential (MEP) data, or in quantifying map features. This is despite continued interest in understanding cortical reorganization for natural adaptive processes such as skill learning, or in the case of motor recovery, such as after lesion affecting the corticospinal system. With the observation that TMS-MEP map calculation and quantification methods vary, and that no readily available commercial or free software exists, we sought to establish and make freely available a comprehensive software package that advances existing methods, and could be helpful to scientists and clinician-researchers. Therefore, we developed NeuroMeasure , an open source interactive software application for the analysis of TMS motor cortex mapping data collected from Nexstim® and BrainSight®, two commonly used neuronavigation platforms. NeuroMeasure features four key innovations designed to improve motor mapping analysis: de-dimensionalization of the mapping data, fitting a predictive model, reporting measurements to characterize the motor map, and comparing those measurements between datasets. This software provides a powerful and easy to use workflow for characterizing and comparing motor maps generated with neuronavigated TMS. The software can be downloaded on our github page: https://github.com/EdwardsLabNeuroSci/NeuroMeasure Aim: This paper aims to describe a software platform for quantifying and comparing maps of the human primary motor cortex, using neuronavigated transcranial magnetic stimulation, for the purpose of studying brain plasticity in health and disease. [ABSTRACT FROM AUTHOR]

Published
2019
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34. Clinical improvement with intensive robot-assisted arm training in chronic stroke is unchanged by supplementary tDCS.

Author

Edwards, Dylan J., Cortes, Mar, Rykman-Peltz, Avrielle, Chang, Johanna, Elder, Jessica, Thickbroom, Gary, Mariman, Juan J., Gerber, Linda M., Oromendia, Clara, Krebs, Hermano I, Fregni, Felipe, Volpe, Bruce T., and Pascual-Leone, Alvaro

Subjects
*TRANSCRANIAL direct current stimulation, *TRANSCRANIAL magnetic stimulation, *ARM, *STROKE
Abstract

Background: Intensive robot-assisted arm training in the chronic phase of stroke recovery can lead to clinical improvement. Combinatorial therapeutic approaches are sought to further optimize stroke recovery. Transcranial direct current stimulation (tDCS) is one candidate to combine with robotic training, as transient increases in excitability and improvements in motor behavior have separately been reported. Objective: To determine whether tDCS, delivered prior to robotic training, could augment clinical improvement. Methods: We conducted a dual-site, randomized controlled trial in 82 chronic ischemic stroke patients (inclusion > 6 m post-injury, dominant hemisphere, first stroke; residual hemiparesis) who were split into two groups to receive tDCS (M1-SO montage, anode ipsilesional, 5×7 cm electrodes, 2 mA, 20 mins) or sham tDCS, prior to robotic upper-limb training (12 weeks; 36 sessions; shoulder-elbow robot or wrist robot on alternating sessions). The primary end-point was taken after 12 weeks of training, and assessed with the Upper Extremity Fugl-Meyer impairment scale (FM). Corticomotor conduction was assessed with transcranial magnetic stimulation (TMS). Results: For the combined group (n = 82; post-training) robotic training increased the FM by 7.36 points compared to baseline (p < 0.0001). There was no difference in the FM increase between the tDCS and sham groups (6.97 and 7.73 respectively, p = 0.46). In both groups, clinically meaningful improvement (≥5 points) from baseline was evident in the majority of patients (56/77), was sustained six months later (54/72), and could be attained in severe, moderate and mild baseline hemiparesis. Clinical improvement was associated with increased excitability in the affected hemisphere as assessed by resting motor threshold (pre-post p = 0.029; pre-post 6 months p = 0.029), but not with threshold-adjusted assessment of MEP amplitude (pre-post p = 0.09; pre-post 6 months p = 0.15). Participants with motor evoked potentials were more likely to improve clinically than those without (17/18, 94%, versus 39/59, 66%, p = 0.018). Conclusions: Our study confirms the benefit of intensive robot-assisted training in stroke recovery, and indicates that conventional tDCS does not confer further advantage to robotic training. We also showed that corticospinal integrity, as assessed by TMS, is a predictor of clinically meaningful response to intensive arm therapy in chronic stroke. [ABSTRACT FROM AUTHOR]

Published
2019
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35. Robotic Arm Rehabilitation in Chronic Stroke Patients With Aphasia May Promote Speech and Language Recovery (but Effect Is Not Enhanced by Supplementary tDCS).

Author

Buchwald, Adam, Falconer, Carolyn, Rykman-Peltz, Avrielle, Cortes, Mar, Pascual-Leone, Alvaro, Thickbroom, Gary W., Krebs, Hermano Igo, Fregni, Felipe, Gerber, Linda M., Oromendia, Clara, Chang, Johanna, Volpe, Bruce T., and Edwards, Dylan J.

Abstract

Objective: This study aimed to determine the extent to which robotic arm rehabilitation for chronic stroke may promote recovery of speech and language function in individuals with aphasia. Methods: We prospectively enrolled 17 individuals from a hemiparesis rehabilitation study pairing intensive robot assisted therapy with sham or active tDCS and evaluated their speech (N = 17) and language (N = 9) performance before and after a 12-week (36 session) treatment regimen. Performance changes were evaluated with paired t -tests comparing pre- and post-test measures. There was no speech therapy included in the treatment protocol. Results: Overall, the individuals significantly improved on measures of motor speech production from pre-test to post-test. Of the subset who performed language testing (N = 9), overall aphasia severity on a standardized aphasia battery improved from pre-test baseline to post-test. Active tDCS was not associated with greater gains than sham tDCS. Conclusions: This work indicates the importance of considering approaches to stroke rehabilitation across different domains of impairment, and warrants additional exploration of the possibility that robotic arm motor treatment may enhance rehabilitation for speech and language outcomes. Further investigation into the role of tDCS in the relationship of limb and speech/language rehabilitation is required, as active tDCS did not increase improvements over sham tDCS. [ABSTRACT FROM AUTHOR]

Published
2018
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36. Manipulation of Human Verticality Using High-Definition Transcranial Direct Current Stimulation.

Author

Santos, Taiza E. G., Favoretto, Diandra B., Toostani, Iman Ghodratti, Nascimento, Diego C., Rimoli, Brunna P., Bergonzoni, Eduardo, Lemos, Tenysson Will, Truong, Dennis Q., Delbem, Alexandre C. B., Makkiabadi, Bahador, Moraes, Renato, Louzada, Francisco, Bikson, Marom, Leite, Joao P., and Edwards, Dylan J.

Abstract

Background: Using conventional tDCS over the temporo-parietal junction (TPJ) we previously reported that it is possible to manipulate subjective visual vertical (SVV) and postural control. We also demonstrated that high-definition tDCS (HD-tDCS) can achieve substantially greater cortical stimulation focality than conventional tDCS. However, it is critical to establish dose-response effects using well-defined protocols with relevance to clinically meaningful applications. Objective: To conduct three pilot studies investigating polarity and intensity-dependent effects of HD-tDCS over the right TPJ on behavioral and physiological outcome measures in healthy subjects. We additionally aimed to establish the feasibility, safety, and tolerability of this stimulation protocol. Methods: We designed three separate randomized, double-blind, crossover phase I clinical trials in different cohorts of healthy adults using the same stimulation protocol. The primary outcome measure for trial 1 was SVV; trial 2, weight-bearing asymmetry (WBA); and trial 3, electroencephalography power spectral density (EEG-PSD). The HD-tDCS montage comprised a single central, and 3 surround electrodes (HD-tDCS3x1) over the right TPJ. For each study, we tested 3x2 min HD-tDCS3x1 at 1, 2 and 3 mA; with anode center, cathode center, or sham stimulation, in random order across days. Results: We found significant SVV deviation relative to baseline, specific to the cathode center condition, with consistent direction and increasing with stimulation intensity. We further showed significant WBA with direction governed by stimulation polarity (cathode center, left asymmetry; anode center, right asymmetry). EEG-PSD in the gamma band was significantly increased at 3 mA under the cathode. Conclusions: The present series of studies provide converging evidence for focal neuromodulation that can modify physiology and have behavioral consequences with clinical potential. [ABSTRACT FROM AUTHOR]

Published
2018
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37. Normative data for human postural vertical: A systematic review and meta-analysis.

Author

Conceição, Laila B., Baggio, Jussara A. O., Mazin, Suleimy C., Edwards, Dylan J., and Santos, Taiza E. G.

Subjects
STROKE patients, POSTURE, ERROR detection (Information theory), SYSTEMATIC reviews, META-analysis
Abstract

Perception of verticality is required for normal daily function, yet the typical human detection error range has not been well characterized. Vertical misperception has been correlated with poor postural control and functionality in patients after stroke and after vestibular disorders. Until now, all the published studies that assessed Subjective Postural Vertical (SPV) in the seated position used small groups to establish a reference value. However, this sample size does not represent the healthy population for comparison with conditions resulting in pathological vertical. Therefore, the primary objective was to conduct a systematic review with meta-analyses of Subjective Postural Vertical (SPV) data in seated position in healthy adults to establish the reference value with a representative sample. The secondary objective was to investigate the methodological characteristics of different assessment protocols of SPV described in the literature. A systematic literature search was conducted using Medline, EMBASE, and Cochrane libraries. Mean and standard deviation of SPV in frontal and sagittal planes were considered as effect size measures. Sixteen of 129 identified studies met eligibility criteria for our systematic review (n = 337 subjects in the frontal plane; n = 187 subjects in sagittal plane). The meta-analyses measure was estimated using the pooled mean as the estimator and its respective error. Mean reference values were 0.12°±1.49° for the frontal plane and 0.02°±1.82° for the sagittal plane. There was a small variability of the results and this systematic review resulted in representative values for SPV. The critical analysis of the studies and observed homogeneity in the sample suggests that the methodological differences used in the studies did not influence SPV assessment of directional bias in healthy subjects. These data can serve as a reference for clinical studies in disorders of verticality. [ABSTRACT FROM AUTHOR]

Published
2018
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39. Combined transcranial direct current stimulation and robotic upper limb therapy improves upper limb function in an adult with cerebral palsy.

Author

Friel, Kathleen M., Lee, Peter, Soles, Lindsey V., Smorenburg, Ana R. P., Hsing-Ching Kuo, Gupta, Disha, and Edwards, Dylan J.

Subjects
CEREBRAL palsy treatment, HEMIPLEGIA, ANALYSIS of variance, ARM, KINEMATICS, MEDICAL needs assessment, NEUROPLASTICITY, REHABILITATION, RESEARCH funding, ROBOTICS, TRANSCUTANEOUS electrical nerve stimulation, TREATMENT effectiveness, DATA analysis software, THERAPEUTICS
Abstract

BACKGROUND: Robotic therapy can improve upper limb function in hemiparesis. Excitatory transcranial direct current stimulation (tDCS) can prime brain motor circuits before therapy. OBJECTIVE: We tested safety and efficacy of tDCS plus robotic therapy in an adult with unilateral spastic cerebral palsy (USCP). METHODS: In each of 36 sessions, anodal tDCS (2 mA, 20 min) was applied over the motor map of the affected hand. Immediately after tDCS, the participant completed robotic therapy, using the shoulder, elbow, and wrist (MIT Manus). The participant sat in a padded chair with affected arm abducted, forearm supported, and hand grasping the robot handle. The participant controlled the robot arm with his affected arm to move a cursor from the center of a circle to each of eight targets (960 movements). Motor function was tested before, after, and six months after therapy with the Wolf Motor Function Test (WMFT) and Fugl-Meyer (FM). RESULTS: Reaching accuracy on the robot task improved significantly after therapy. The WMFT and FM improved clinically meaningful amounts after therapy. The motor map of the affected hand expanded after therapy. Improvements were maintained six months after therapy. CONCLUSIONS: Combined tDCS and robotics safely improved upper limb function in an adult with USCP. [ABSTRACT FROM AUTHOR]

Published
2017
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41. A Framework for Combining rTMS with Behavioral Therapy.

Author

Zoe Tsagaris, K., Labar, Douglas R., and Edwards, Dylan J.

Subjects
TRANSCRANIAL magnetic stimulation, REPETITION training, BEHAVIOR therapy
Abstract

Upon its inception, repetitive transcranial magnetic stimulation (rTMS) was delivered at rest, without regard to the potential impact of activity occurring during or around the time of stimulation. rTMS was considered an experimental intervention imposed on the brain; therefore, the myriad features that might suppress or enhance its desired effects had not yet been explored. The field of rTMS has since grown substantially and therapeutic benefits have been reported, albeit with modest and inconsistent improvements. Work in this field accelerated following approval of a psychiatric application (depression), and it is now expanding to other applications and disciplines. In the last decade, experimental enquiry has sought new ways to improve the therapeutic benefits of rTMS, intended to enhance underlying brain reorganization and functional recovery by combining it with behavioral therapy. This concept is appealing, but poorly defined and requires clarity. We provide an overview of how combined rTMS and behavioral therapy has been delineated in the literature, highlighting the diversity of approaches. We outline a framework for study design and reporting such that the effects of this emerging method can be better understood. [ABSTRACT FROM AUTHOR]

Published
2016
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42. Moving Forward by Stimulating the Brain: Transcranial Direct Current Stimulation in Post-Stroke Hemiparesis.

Author

Peters, Heather T., Edwards, Dylan J., Wortman-Jutt, Susan, Page, Stephen J., Brighina, Filippo, and Elsner, Bernhard

Subjects
BRAIN stimulation, HEMIPARESIS, TRANSCRANIAL direct current stimulation, STROKE diagnosis, NEUROPLASTICITY, DIAGNOSIS
Abstract

Stroke remains a leading cause of disability worldwide, with a majority of survivors experiencing long term decrements in motor function that severely undermine quality of life. While many treatment approaches and adjunctive strategies exist to remediate motor impairment, many are only efficacious or feasible for survivors with active hand and wrist function, a population who constitute only a minority of stroke survivors. Transcranial direct current stimulation (tDCS), a type of non-invasive brain stimulation, has been increasingly utilized to increase motor function following stroke as it is able to be used with stroke survivors of varying impairment levels, is portable, is relatively inexpensive and has few side effects and contraindications. Accordingly, in recent years the number of studies investigating its efficacy when utilized as an adjunct to motor rehabilitation regimens has drastically increased. While many of these trials have reported positive and promising efficacy, methodologies vary greatly between studies, including differences in stimulation parameters, outcome measures and the nature of physical practice. As such, an urgent need remains, centering on the need to investigate these methodological differences and synthesize the most current evidence surrounding the application of tDCS for post-stroke motor rehabilitation. Accordingly, the purpose of this paper is to provide a detailed overview of the most recent tDCS literature (published 2014-2015), while highlighting these variations in methodological approach, as well to elucidate the mechanisms associated with tDCS and post-stroke motor re-learning and neuroplasticity. [ABSTRACT FROM AUTHOR]

Published
2016
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43. Spared Primary Motor Cortex and The Presence of MEP in Cerebral Palsy Dictate the Responsiveness to tDCS during Gait Training.

Author

Collange Grecco, Luanda A., Santos Oliveira, Claudia, Galli, Manuela, Cosmo, Camila, de Almeida Carvalho Duarte, Natália, Zanon, Nelci, Edwards, Dylan J., and Fregni, Felipe

Subjects
TRANSCRANIAL direct current stimulation, NEUROREHABILITATION, CEREBRAL palsy treatment, NEUROPHYSIOLOGY, REGRESSION analysis
Abstract

The current priority of investigations involving transcranial direct current stimulation (tDCS) and neurorehabilitation is to identify biomarkers associated with the positive results of the interventions such that respondent and non-respondent patients can be identified in the early phases of treatment. The aims were to determine whether: (1) present motor evoked potential (MEP); and (2) injuries involving the primary motor cortex, are associated with tDCS-enhancement in functional outcome following gait training in children with cerebral palsy (CP). We reviewed the data from our parallel, randomized, sham-controlled, double-blind studies. Fifty-six children with spastic CP received gait training (either treadmill training or virtual reality training) and tDCS (active or sham). Univariate and multivariate logistic regression analyses were employed to identify clinical, neurophysiologic and neuroanatomic predictors associated with the responsiveness to treatment with tDCS. MEP presence during the initial evaluation and the subcortical injury were associated with positive effects in the functional results. The logistic regression revealed that present MEP was a significant predictor for the sixminute walk test (6MWT; p = 0.003) and gait speed (p = 0.028), whereas the subcortical injury was a significant predictor of gait kinematics (p = 0.013) and gross motor function (p = 0.021). In this preliminary study involving children with CP, two important prediction factors of good responses to anodal tDCS combined with gait training were identified. Apparently, MEP (integrity of the corticospinal tract) and subcortical location of the brain injury exerted different influences on aspects related to gait, such as velocity and kinematics. [ABSTRACT FROM AUTHOR]

Published
2016
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44. The sensory side of post-stroke motor rehabilitation.

Author

Bolognini, Nadia, Russo, Cristina, and Edwards, Dylan J.

Subjects
STROKE, NEUROREHABILITATION, SENSORIMOTOR integration, MOTOR ability, SENSORY stimulation
Abstract

Contemporary strategies to promote motor recovery following stroke focus on repetitive voluntary movements. Although successful movement relies on efficient sensorimotor integration, functional outcomes often bias motor therapy toward motor-related impairments such as weakness, spasticity and synergies; sensory therapy and reintegration is implied, but seldom targeted. However, the planning and execution of voluntary movement requires that the brain extracts sensory information regarding body position and predicts future positions, by integrating a variety of sensory inputs with ongoing and planned motor activity. Neurological patients who have lost one or more of their senses may show profoundly affected motor functions, even if muscle strength remains unaffected. Following stroke, motor recovery can be dictated by the degree of sensory disruption. Consequently, a thorough account of sensory function might be both prognostic and prescriptive in neurorehabilitation. This review outlines the key sensory components of human voluntary movement, describes how sensory disruption can influence prognosis and expected outcomes in stroke patients, reports on current sensory-based approaches in post-stroke motor rehabilitation, and makes recommendations for optimizing rehabilitation programs based on sensory stimulation. [ABSTRACT FROM AUTHOR]

Published
2016
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45. Polarity-Dependent Misperception of Subjective Visual Vertical during and after Transcranial Direct Current Stimulation (tDCS).

Author

Santos-Pontelli, Taiza E. G., Rimoli, Brunna P., Favoretto, Diandra B., Mazin, Suleimy C., Truong, Dennis Q., Leite, Joao P., Pontes-Neto, Octavio M., Babyar, Suzanne R., Reding, Michael, Bikson, Marom, and Edwards, Dylan J.

Subjects
STROKE patients, TRANSCRANIAL direct current stimulation, STROKE treatment, PILOT projects, RANDOMIZED controlled trials
Abstract

Pathologic tilt of subjective visual vertical (SVV) frequently has adverse functional consequences for patients with stroke and vestibular disorders. Repetitive transcranial magnetic stimulation (rTMS) of the supramarginal gyrus can produce a transitory tilt on SVV in healthy subjects. However, the effect of transcranial direct current stimulation (tDCS) on SVV has never been systematically studied. We investigated whether bilateral tDCS over the temporal-parietal region could result in both online and offline SVV misperception in healthy subjects. In a randomized, sham-controlled, single-blind crossover pilot study, thirteen healthy subjects performed tests of SVV before, during and after the tDCS applied over the temporal-parietal region in three conditions used on different days: right anode/left cathode; right cathode/left anode; and sham. Subjects were blind to the tDCS conditions. Montage-specific current flow patterns were investigated using computational models. SVV was significantly displaced towards the anode during both active stimulation conditions when compared to sham condition. Immediately after both active conditions, there were rebound effects. Longer lasting after-effects towards the anode occurred only in the right cathode/left anode condition. Current flow models predicted the stimulation of temporal-parietal regions under the electrodes and deep clusters in the posterior limb of the internal capsule. The present findings indicate that tDCS over the temporal-parietal region can significantly alter human SVV perception. This tDCS approach may be a potential clinical tool for the treatment of SVV misperception in neurological patients. [ABSTRACT FROM AUTHOR]

Published
2016
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46. Opportunities for Guided Multichannel Non-invasive Transcranial Current Stimulation in Poststroke rehabilitation.

Author

Otal, Begonya, Ripolles, Oscar, Ruffini, Giulio, Lindberg, Pavel, Kennedy, Niamh C., Mylius, Veit, Dutta, Anirban, Foerster, Águida, Kuceyeski, Amy, Miranda, Pedro C., Edwards, Dylan J., Ilić, Tihomir V., and Nitsche, Michael A.

Subjects
TRANSCRANIAL direct current stimulation, STROKE rehabilitation, BRAIN imaging
Abstract

Stroke is a leading cause of serious long-term disability worldwide. Functional outcome depends on stroke location, severity, and early intervention. Conventional rehabilitation strategies have limited effectiveness, and new treatments still fail to keep pace, in part due to a lack of understanding of the different stages in brain recovery and the vast heterogeneity in the poststroke population. Innovative methodologies for restorative neurorehabilitation are required to reduce long-term disability and socioeconomic burden. Neuroplasticity is involved in poststroke functional disturbances and also during rehabilitation. Tackling poststroke neuroplasticity by non-invasive brain stimulation is regarded as promising, but efficacy might be limited because of rather uniform application across patients despite individual heterogeneity of lesions, symptoms, and other factors. Transcranial direct current stimulation (tDCS) induces and modulates neuroplasticity, and has been shown to be able to improve motor and cognitive functions. tDCS is suited to improve poststroke rehabilitation outcomes, but effect sizes are often moderate and suffer from variability. Indeed, the location, extent, and pattern of functional network connectivity disruption should be considered when determining the optimal location sites for tDCS therapies. Here, we present potential opportunities for neuroimaging-guided tDCSbased rehabilitation strategies after stroke that could be personalized. We introduce innovative multimodal intervention protocols based on multichannel tDCS montages, neuroimaging methods, and real-time closed-loop systems to guide therapy. This might help to overcome current treatment limitations in poststroke rehabilitation and increase our general understanding of adaptive neuroplasticity leading to neural reorganization after stroke. [ABSTRACT FROM AUTHOR]

Published
2016
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47. Cerebellar Transcranial Direct Current Stimulation (ctDCS).

Author

Grimaldi, Giuliana, Argyropoulos, Georgios P., Bastian, Amy, Cortes, Mar, Davis, Nicholas J., Edwards, Dylan J., Ferrucci, Roberta, Fregni, Felipe, Galea, Joseph M., Hamada, Masahi, Manto, Mario, Miall, R. Chris, Morales-Quezada, Leon, Pope, Paul A., Priori, Alberto, Rothwell, John, Tomlinson, S. Paul, and Celnik, Pablo

Subjects
CEREBELLUM, SHORT-term memory, NEUROLOGICAL disorders, TRANSCRANIAL direct current stimulation, MOTOR cortex
Abstract

The cerebellum is critical for both motor and cognitive control. Dysfunction of the cerebellum is a component of multiple neurological disorders. In recent years, interventions have been developed that aim to excite or inhibit the activity and function of the human cerebellum. Transcranial direct current stimulation of the cerebellum (ctDCS) promises to be a powerful tool for the modulation of cerebellar excitability. This technique has gained popularity in recent years as it can be used to investigate human cerebellar function, is easily delivered, is well tolerated, and has not shown serious adverse effects. Importantly, the ability of ctDCS to modify behavior makes it an interesting approach with a potential therapeutic role for neurological patients. Through both electrical and non-electrical effects (vascular, metabolic) ctDCS is thought to modify the activity of the cerebellum and alter the output from cerebellar nuclei. Physiological studies have shown a polarity-specific effect on the modulation of cerebellar–motor cortex connectivity, likely via cerebellar–thalamocortical pathways. Modeling studies that have assessed commonly used electrode montages have shown that the ctDCS-generated electric field reaches the human cerebellum with little diffusion to neighboring structures. The posterior and inferior parts of the cerebellum (i.e., lobules VI-VIII) seem particularly susceptible to modulation by ctDCS. Numerous studies have shown to date that ctDCS can modulate motor learning, and affect cognitive and emotional processes. Importantly, this intervention has a good safety profile; similar to when applied over cerebral areas. Thus, investigations have begun exploring ctDCS as a viable intervention for patients with neurological conditions. [ABSTRACT FROM AUTHOR]

Published
2016
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48. The reliability of repeated TMS measures in older adults and in patients with subacute and chronic stroke.

Author

Schambra, Heidi M., Todd Ogden, R., Martínez-Hernández, Isis E., Xuejing Lin, Brenda Chang, Y., Rahman, Asif, Edwards, Dylan J., and Krakauer, John W.

Subjects
TRANSCRANIAL magnetic stimulation, MEASUREMENT errors, STROKE, BRAIN stimulation, BIOMARKERS
Abstract

The reliability of transcranial magnetic stimulation (TMS) measures in healthy older adults and stroke patients has been insufficiently characterized. We determined whether common TMS measures could reliably evaluate change in individuals and in groups using the smallest detectable change (SDC), or could tell subjects apart using the intraclass correlation coefficient (ICC). We used a single-rater test-retest design in older healthy, subacute stroke, and chronic stroke subjects. At twice daily sessions on two consecutive days, we recorded resting motor threshold, test stimulus intensity, recruitment curves, short-interval intracortical inhibition, and facilitation, and long-interval intracortical inhibition. Using variances estimated from a random effects model, we calculated the SDC and ICC for each TMS measure. For all TMS measures in all groups, SDCs for single subjects were large; only with modest group sizes did the SDCs become low. Thus, while these TMS measures cannot be reliably used as a biomarker to detect individual change, they can reliably detect change exceeding measurement noise in moderate-sized groups. For several of the TMS measures, ICCs were universally high, suggesting that they can reliably discriminate between subjects. TMS measures should be used based on their reliability in particular contexts. More work establishing their validity, responsiveness, and clinical relevance is still needed. [ABSTRACT FROM AUTHOR]

Published
2015
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