Ideomotor Coding: A Transcranial Magnetic Stimulation Study

Reid, Connor

10 December 2013

Ideomotor theory holds that motor plans producing action and the sensory effects of the actions are cognitively represented in a functionally similar way. The response-effect (R-E) association is considered bidirectional and automatic in nature. The current research project was designed to test the hypothesized bidirectional nature of R-E associations by determining if motor codes were activated following perception of an effect. The automaticity of motor code activation was investigated via TMS–induced motor evoked potentials (MEPs) following the presentation an after-effect. To this end, participants completed a training phase in which they learned a specific R-E association. During the testing phase, the effects were presented prior to the imperative and TMS stimuli. Behavioural results replicated previous research; participants preferred to execute the response associated with the presented effect. MEP data, however, did not support the initial hypothesis. These results are discussed with relation to ideomotor theory and experimental design.

Ideomotor

Transcranial Magnetic Stimulation

0384

Ideomotor Coding: A Transcranial Magnetic Stimulation Study

Reid, Connor

10 December 2013

Ideomotor theory holds that motor plans producing action and the sensory effects of the actions are cognitively represented in a functionally similar way. The response-effect (R-E) association is considered bidirectional and automatic in nature. The current research project was designed to test the hypothesized bidirectional nature of R-E associations by determining if motor codes were activated following perception of an effect. The automaticity of motor code activation was investigated via TMS–induced motor evoked potentials (MEPs) following the presentation an after-effect. To this end, participants completed a training phase in which they learned a specific R-E association. During the testing phase, the effects were presented prior to the imperative and TMS stimuli. Behavioural results replicated previous research; participants preferred to execute the response associated with the presented effect. MEP data, however, did not support the initial hypothesis. These results are discussed with relation to ideomotor theory and experimental design.

Ideomotor

Transcranial Magnetic Stimulation

0384

Disruption of the right temporoparietal junction using transcranial magnetic stimulation impairs the control of shared representation of action

Köhlert, Katharina

08 June 2016

Previous research and current models have proposed that the right temporoparietal junction (rTPJ) is crucially involved in the control and distinction of shared representations of action. Hitherto, this assumption has mainly been based on neuroimaging work ( (Spengler, von Cramon, & Brass, 2009); (Spengler, von Cramon, & Brass, 2010)) We tested this hypothesis, that the rTPJ is causally involved in managing shared representations by using repetitive transcranial magnetic stimulation in an offline paradigm to disrupt neural activity in this region. Using a simple imitation-inhibition task we showed that stimulation of the rTPJ led to increased reaction times when participants had to control automatic imitation of a perceived hand movement, as they had to concurrently plan and execute an opposite movement. Our study provides the first empirical evidence that the rTPJ is necessary for managing and navigating within a shared representational system. These results may also have important implications for future theorizing about the role of the TPJ region in controlling shared representations also in other domains, such as somatosensation or emotional experiences.

Transkranielle Magnetstimulation

transcranial magnetic stimulation

ddc:610

Electrically Small Dipole Antenna Probe for Quasi-static Electric Field Measurements

Zolj, Adnan

11 April 2018

The thesis designs, constructs, and tests an electrically small dipole antenna probe for the measurement of electric field distributions induced by a transcranial magnetic stimulation (TMS) coil. Its unique features include high spatial resolution, large frequency band from 100 Hz to 300 kHz, efficient feedline isolation via a printed Dyson balun, and accurate mitigation of noise. Prior work in this area is thoroughly reviewed. The proposed probe design is realized in hardware; implementation details and design tradeoffs are described. Test data is presented for the measurement of a CW capacitor electric field, demonstrating the probe’s ability to properly measure conservative electric fields caused by a charge distribution. Test data is also presented for the measurement of a CW solenoidal electric field, demonstrating the probe’s ability to measure non-conservative solenoidal electric fields caused by Faraday’s law of induction. Those are the primary fields for the transcranial magnetic stimulation. Advantages and disadvantages of this probing system versus those of prior works are discussed. Further refinement steps necessary for the development of this probe as a valuable TMS instrument are discussed.

biomagnetics

transcranial magnetic stimulation

electric field probe

Does Mental Practice Promote Cortical Reorganization and Improved Hand Function in Stroke?

Lischynski, RHONDA

28 April 2008

The upper extremity is often left with permanent disability following stroke and therapeutic techniques used at present have had limited success. This prospective clinical trial evaluated the effectiveness of mental practice (MP) through motor imagery (MI) a therapy technique to enhance upper extremity motor recovery after stroke. MI ability, upper extremity hand function, finger strength, and motor cortical output were examined in 18 stroke subjects (mean 67.5 years). Subjects were randomly allocated to the MP treatment group or the control group which received cognitive therapy. Both groups received their respective treatment daily for 30 minutes for a 3 week period. Assessments were performed prior to treatment, post treatment and at 3 months post treatment. Imagery ability was measured using the Kinesthetic and Visual Imagery Questionnaire (KVIQ) and mental chronometric testing. Hand function was assessed with the box and block test (BBT) and finger strength with maximum voluntary contraction (MVC). To determine the effect of MI on neural excitability, focal transcranial magnetic stimulation was applied over the primary motor cortex while participants were at rest and while they imagined themselves performing abduction of the index finger. Motor evoked potentials were recorded from the contralateral first dorsal interosseous (FDI), abductor digiti minimi (ADM) and abductor pollicis brevis (APB) muscles. Data were analyzed using multifactor and repeated measures ANOVAs with the significance level set to p < 0.05. Results showed no significant difference between groups on any of the outcome measures (p > 0.05) although all subjects improved their hand function over the study period (p < 0.05). In addition, motor threshold was found to decrease over time (p < 0.001) in all subjects demonstrating improvement in cortical motor excitability and output. Motor evoked potentials (MEPs) elicited during MI were significantly larger compared to those evoked at rest (p < 0.022). MEP amplitudes from FDI, the muscle targeted with MP, showed a significant interaction effect between time and group (p = 0.021) which reflected an increase in MEPs in the MP group over time whereas a decline occurred in the cognitive group. These findings indicate that MI enhances motor cortical output in stroke and that MP using MI appears to increase corticospinal output to the target FDI muscle. No differential effects of MP and cognitive therapy interventions were evident in terms of hand function and finger muscle strength. / Thesis (Master, Rehabilitation Science) -- Queen's University, 2008-04-25 16:23:51.775 / Heart and Stroke Foundation

Mental Practice

Stroke

Transcranial Magnetic Stimulation

Slow Right Prefrontal Transcranial Magnetic Stimulation as a Treatment for Medication-Resistant Depression: A Double-Blind, Placebo-Controlled Study

Kauffmann, Curtis D., Cheema, Muhammad A., Miller, Barney E.

16 March 2004

Over the past decade, efforts have been made to assess the positive therapeutic effects of transcranial magnetic stimulation (TMS) by altering the excitability of the brain. We conducted a double-blind, placebo-controlled study to assess the efficacy of right prefrontal slow repetitive TMS in patients with treatment refractory major depression. This pilot study supports the therapeutic potential of rTMS in the low-frequency range of 1 Hz on right prefrontal cortex for the treatment of refractory major depression. Additional studies will be necessary to assess the efficacy of rTMS with different indices (frequency, intensity, and stimulation site) for major depression and other psychiatric diseases.

depression

rTMS

TMS

transcranial magnetic stimulation

The Effects of Passive Heat Stress on Muscle Fatigue and Intracortical Excitability of the Wrist Flexors

Bender, Robert William

16 June 2011

No description available.

Physiology

central activation

heating

transcranial magnetic stimulation

CORTICAL EXCITABILITY AND INHIBITION IN POST-CONCUSSION SYNDROME

Locke, Mitchell

January 2019

Post-concussion syndrome (PCS) is a poorly understood sequela of mild traumatic brain injury (mTBI), more commonly referred to as concussion. While PCS is known to affect a subset of individuals following injury, it remains unclear how and why specific individuals incur chronic symptoms. Concussions disrupt normal neurophysiologic function within the brain, however the neurophysiologic underpinnings of PCS are unclear. Using transcranial magnetic stimulation (TMS), it is possible to non-invasively investigate neurotransmission in clinical populations such as those with PCS by stimulating the primary motor cortex (M1) and recording motor outputs in a contralateral hand muscle. A study was conducted using TMS to measure corticospinal excitability, intracortical facilitation and inhibition, and transcallosal inhibition in M1 of a group with PCS and a non-injured, healthy control group. Greater corticospinal excitability, and specific reductions in intracortical and transcallosal inhibition were observed in the PCS group, providing evidence of impaired neurotransmitter receptor activity. Importantly, these findings differed from previous observations in recovered concussion groups using similar stimulation techniques. Furthermore, it was observed that these neurophysiological differences may relate specifically to the presence of depression symptoms rather than general concussion symptoms. The physiologic and clinical implications of the findings of this thesis are discussed, and novel research avenues warranting investigation are identified. / Thesis / Master of Science in Kinesiology

Concussion

Transcranial magnetic stimulation

mTBI

motor cortex

Desenvolvimento de funcionalidades no InVesalius Navigator e comparação de neuroimagem estrutural com o cérebro padrão MNI para EMTn / Development of functionalities for InVesalius Navigator and comparison of structural neuroimaging with standard MNI brain for EMTn

Matsuda, Renan Hiroshi

07 March 2018

A Neuronavegação é uma técnica de visualização computacional da localização de instrumentos em relação às estruturas neuronais. A estimulação magnética transcraniana (EMT) é uma ferramenta para estimulação cerebral não-invasiva, que tem sido utilizada em aplicações clínicas, para o tratamento de algumas patologias, e também em pesquisas. Entretanto, a EMT é uma técnica altamente dependente de parâmetros como o posicionamento e orientação da bobina de estimulação em relação às estruturas neuronais. Para auxiliar no posicionamento da bobina, uma combinação entre neuronavegação e EMT é utilizada, chamada de EMTnavegada (EMTn). Essa técnica permite o monitoramento em tempo real da bobina de EMT em relação às neuroimagens. Porém, a utilização da EMTn ainda é pouco explorada, tanto na pesquisa quanto no ambiente clínico, devido ao alto custo, exigência da imagem de ressonância magnética, complexidade e baixa portabilidade dos sistemas de EMTn comerciais. O neuronavegador de código aberto e livre, InVesalius Navigator, vem sendo desenvolvido para ajudar a suprir essa necessidade. Assim, o objetivo desta dissertação foi desenvolver ferramentas para o sistema de neuronavegação InVesalius Navigator. As funcionalidades adicionadas foram: i) suporte para três tipos de rastreadores espaciais; ii) sincronização da EMT com o neuronavegador; iii) guia para o reposicionamento da bobina. Além disso, com intuito de contornar a necessidade de utilizar a imagem de ressonância magnética foram realizados estudos para a substituição por uma imagem padrão. Na parte de desenvolvimento, experimentos de caracterização foram realizados para validação das ferramentas. O sistema de neuronavegação apresentou-se intuitivo e de fácil portabilidade. Além disso, a precisão obtida foi semelhante à de sistemas comerciais. Os erros de localização foram inferiores a 3 mm, considerados aceitáveis para aplicações clínicas. Na segunda parte, procedimentos que não exigem extrema precisão, como a localização e digitalização do hotspot, a variabilidade foi considerada aceitável. Portanto, a utilização da imagem média mostrou-se uma possível alternativa para as imagens de ressonância magnética. / Neuronavigation is a computer image-guided technique to locate surgical instruments related to brain structures. The transcranial magnetic stimulation (TMS) is a non-invasive brain stimulation method, it has been used for clinical purposes, treating neurological disorders, and also for research purpose, studying cortical brain function. However, the use of TMS is highly dependent on coil position and orientation related to brain structures. The navigated TMS (nTMS) is a combined technique of neuronavigation system and TMS, this technique allows tracking TMS coil by image guidance. Yet, nTMS is not widely used, either in research and in the clinical environment, due to the high cost, magnetic resonance imaging requirement, complexity, and low portability of commercial TMS systems. Thus, the aim of this dissertation was to develop tools for the neuronavigator system InVesalius Navigator, such as: i) support for three types of spatial trackers; ii) synchronization of the TMS with the neuronavigator; iii) guide for coil repositioning. In addition, in order to overcome the magnetic resonance imaging requirement, studies were made to replace it with a standard brain image. In the development part, characterization experiments were done to validate the new functionalities. Therefore, the accuracy obtained was similar to commercial systems. Localization errors were less than 3 mm considered acceptable for clinical applications. In the second part, for procedures that do not require extreme accuracy, such as the location and scanning of the hotspot, the variability was considered acceptable. Therefore, the use of the standard brain image was a possible alternative for magnetic resonance imaging.

Cortical and cerebellar motor processing changes subsequent to motor training and cervical spine manipulation

Daligadu, Julian

01 July 2012

Chronic neck pain, including subclinical neck pain (SCNP), is a significant problem that places a burden on the healthcare system. Chiropractic manipulation has shown not only to be effective in treating symptoms of neck pain, but also in providing a neuromodulatory effect on the central nervous system. The motor cortex and cerebellum are thought to be important neural structures involved in motor learning and sensorimotor integration (SMI), and are therefore key structures to investigate how SMI is changed in a SCNP group following chiropractic care. Motor sequence learning (MSL) has also been shown to provide alterations in cerebellar projections to the motor cortex. Therefore, the studies in this thesis set out to determine if it was possible to induce both cortical and cerebellar learning, and if chiropractic care could alter motor output via transcranial magnetic stimulation measures to facilitate this learning. The study‟s results suggest that in a healthy group of subjects there is alteration in the intracortical inhibition of the motor cortex and no significant change in the cerebellum, following MSL. However, the results also suggest that in a SCNP group, there is a modulation of the cerebellar connections to the motor cortex but no effect specific to the motor cortex following both MSL and chiropractic manipulation. Therefore, these findings suggest that people with intermittent neck pain have concomitant changes in SMI and could manifest as clinical symptomology. / UOIT

Sensorimotor integration

Motor learning

Cerebellum

Transcranial magnetic stimulation

Chiropractic manipulation