The effect of anodal transcranial direct current stimulation on spatial motor skill learning in healthy and spinal cord injured humans

Ashworth-Beaumont, Jim

January 2012

Anodal transcranial direct current stimulation (tDCS) is an intervention which is thought to enhance motor learning in healthy and stroke-injured states, when applied adjunctively during skill learning. We set out to investigate whether anodal tDCS might enhance functional rehabilitation from incomplete tetraplegic SCI. To address current limitations in the measurement of task-dependent skill, a novel integrated skill training and measurement task, the Motor Skill Rehabilitation Task (MSRT) was designed and developed. Measures of performance from this task delivered the functional measure of spatial motor skill learning, Task Productivity Rate (TPR). TPR was analysed and validated as a univariate dependent outcome, which is of potential importance to the future development of clinical measures measuring goal-directed motor skills. The MSRT was included alongside conventional behavioural measures in a repeated-measures RCT pilot study, the first to investigate the effect of anodal tDCS on rehabilitation of motor skill from chronic spinal cord injury. Adjunctive application of anodal tDCS had a statistically significant benefit upon retention of skill in the incomplete spinal cord injured population, but only when the independent factor of sensory acuity was included in the analysis. Differences between the development of task-dependent skill and generic dexterity over time suggested that spatial skill development was subject to an interaction of short-term and lasting effects. A larger study in healthy persons further investigated these phenomena, also applying Transcranial Magnetic Stimulation (TMS)–evoked measurements to investigate intervention-dependent effects upon the excitability of projections between the primary motor cortex and muscles involved in the prehension task. The findings revealed that active tDCS did not enhance skill learning at 7 days beyond the training period, but did significantly alter the development of motor skill following a period of learning and subsequent skill consolidation which was associated with underlying perturbation of motor control strategy. Significant and divergent patterns of cortical plasticity were evoked in projections to muscles necessary for reaching and grasping. The main findings of this thesis do not support anodal tDCS as an effective adjunctive means of enhancing spatial motor skill in rehabilitation from incomplete tetraplegic SCI. If applied in patient populations, the clinical benefits of anodal tDCS may be contingent both on the nature of the sensorimotor deficit affecting upper limb function and the spatial demands of the behavioural task. The findings of this project serve to inform further research in relation to the effect of anodal tDCS on the brain and behavioural outcomes, the potential for efficacy in target patient groups and the sensitivity of outcome measures to spatial and temporal dimensions of practical motor skills.

610

Development of an Improved Bedside Methodology for Measurement of Cerebrovascular Reactivity

Da Costa, Leodante

18 March 2014

Changes in cerebrovascular reactivity (CVR) to carbon dioxide (CO2) are reported in many neurological conditions. My aim was to validate a method for computerized prospective targeting of CO2 levels (RespiractTM) as a bedside tool for impaired CVR. I hypothesized that 1) The RespiractTM and TCD method can be used to detect impairment of CVR after SAH and that 2) CVR is impaired in SAH patients. In 18 SAH patients and 26 controls CVR index was calculated dividing the percentage change in middle cerebral artery blood flow velocity (MCAv) by the change in PETCO2. The absolute MCAv values were similar in both groups, but CVR was significantly different (hypercapnia: 0.044 ± 0.076 - controls; 0.014 ± 0.037 - SAH; p=0.0007). I showed that impaired CVR can be detected at the bedside using TCD and CO2 challenge with the RespiractTM, control of CO2 is precise and minimal changes are required.

cerebral blood flow

cerebrovascular reactivity

carbon dioxide challenge

Transcranial Doppler

0564

Development of an Improved Bedside Methodology for Measurement of Cerebrovascular Reactivity

Da Costa, Leodante

18 March 2014

Changes in cerebrovascular reactivity (CVR) to carbon dioxide (CO2) are reported in many neurological conditions. My aim was to validate a method for computerized prospective targeting of CO2 levels (RespiractTM) as a bedside tool for impaired CVR. I hypothesized that 1) The RespiractTM and TCD method can be used to detect impairment of CVR after SAH and that 2) CVR is impaired in SAH patients. In 18 SAH patients and 26 controls CVR index was calculated dividing the percentage change in middle cerebral artery blood flow velocity (MCAv) by the change in PETCO2. The absolute MCAv values were similar in both groups, but CVR was significantly different (hypercapnia: 0.044 ± 0.076 - controls; 0.014 ± 0.037 - SAH; p=0.0007). I showed that impaired CVR can be detected at the bedside using TCD and CO2 challenge with the RespiractTM, control of CO2 is precise and minimal changes are required.

cerebral blood flow

cerebrovascular reactivity

carbon dioxide challenge

Transcranial Doppler

0564

Transkranijinės doplerografijos diagnostinė reikšmė esant galvos smegenų arterioveninėms malformacijoms / Transcranial doppler sonography in diagnostics of cerebral arteriovenous malformations

Jacikevičius, Kęstutis

28 March 2006

CONTENT 1. INTRODUCTION 7 2. PATIENTS AND METHODS 8 2.1. Patients 8 2.2. Control Group 8 2.3. Study Methods 9 2.4. Treatment of Patients 9 2.5. Outcome State 10 2.6. Statistical Data Analysis 10 3. RESULTS 10 3.1. Clinical Manifestations of Cerebral Arteriovenous Malformations 10 3.2. Consciousness according to Glasgow Coma Scale 10 3.3. Distribution of Patients According to Spetzler-Martin Classification 11 3.4. Localization of Cerebral Arteriovenous Malformations 11 3.5. The Localization of Intracranial Haemorrhages after the Rupture of Cerebral Arteriovenous Malformations 11 3.6. Distribution of Patients with Intracerebral Haemorrhages after the Ruptures of Cerebral Arteriovenous Malformations and without Haemorrhages according to Spetzler-Martin classification 12 3.7. The Relationships between Haemorrhagic Manifestation and Size of Cerebral Arteriovenous Malformations 13 3.8. Transcranial Doppler Sonography Sensitivity and Specificity in Patients with Cerebral Arteriovenous Malformations 13 3.9. Cerebral Haemodynamics in Patients with Cerebral Arteriovenous Malformations and Healthy Controls 15 3.10. Cerebral Haemodynamics Changes in Patients with Cerebral Arteriovenous Malformations before and after the Surgery 16 3.11. Transcranial Doppler evaluation of Different Localizations Cerebral Arteriovenous Malformations 18 3.12. Cerebral Haemodynamics in Patients with Intracerebral Haematomas after Ruptures of Cerebral Arteriovenous Malformations 19 3.13. Cerebral... [to full text]

Medicine

Cerebrovascular diseases

Arteriovenous malformations

Smegenų kraujagyslių ligos

Transcranial doppler sonography

Transkranijinė doplerografija

Arterioveninės malformacijos

Changes in corticospinal excitability induced by neuromuscular electrical stimulation

Mang, Cameron Scott

Unknown Date

No description available.

corticospinal excitability

neuromuscular electrical stimulation

motor cortex

transcranial magnetic stimulation

stimulation frequency

Investigating the neural organisation of response selection and response conflict during language production using functional magnetic resonance imaging and repetitive transcranial magnetic stimulation

Tremblay, Pascale.

January 2008

Motor response selection is the process by which an intention to act is transformed into an action; this multifaceted process occurs at the interface between cognitive and motor systems. Despite the importance of response selection, the nature and neural implementation of this process is still a subject of debate (Thompson-Schill et al, 1997; Botvinick et al., 2001; Rushworth et al., 2004; Nachev et al., 2007). While previous research has demonstrated that the selection of finger movements relies on a distributed network involving premotor and prefrontal areas, the specific contribution of these regions, however, remains unclear. It is also unclear if the selection of words engages similar processes as the selection of finger movements, that is, if response selection is a domain-general or a domain-specific process. In order to address these issues, a set of four complementary studies using functional magnetic resonance imaging (fMRI) and repetitive transcranial magnetic stimulation (rTMS) was developed in which different factors affecting response selection were examined: selection mode, response type (words vs. oral movements), attention and response competition (conflict). / The results of these studies provide new insights into the neural architecture of response selection by uncovering the respective contribution of premotor areas (pre-SMA and PMA) and prefrontal areas (DLPFC and IFG). A preliminary two-stage model of response selection is proposed, in which the PMA is generating a set of response alternatives from which the pre-SMA performs selection using one of two different mechanisms (response facilitation and response inhibition). In general, these findings do not support the hypothesis of a medio-lateral gradient of control (Goldberg, 1985) but confirm the fundamental role of the lateral (PMA) and medial (pre-SMA) premotor areas in the process of selecting motor responses. / Importantly, the results also demonstrate that selection is a domain-general (response-independent) process. Uncovering the general, multifaceted nature of brain mechanisms is essential to reveal the basic units of control in the central nervous system; this knowledge is fundamental to broaden current understanding of the basic brain operations that are used to produce language. Theoretical and clinical implications of these findings are discussed.

Speech -- physiology.

Mouth -- physiology.

Gestures.

Frontal Lobe -- physiology.

Magnetic Resonance Imaging.

Transcranial Magnetic Stimulation.

The Effects of Neuromuscular Electrical Stimulation of the Submental Muscle Group on the Excitability of Corticobulbar Projections

Doeltgen, Sebastian Heinrich

January 2009

Neuromuscular electrical stimulation (NMES) has become an increasingly popular rehabilitative treatment approach for swallowing disorders (dysphagia). However, its precise effects on swallowing biomechanics and measures of swallowing neurophysiology are unclear. Clearly defined NMES treatment protocols that have been corroborated by thorough empirical research are lacking. The primary objective of this research programme was therefore to establish optimal NMES treatment parameters for the anterior hyo-mandibular (submental) musculature, a muscle group that is critically involved in the oral and pharyngeal phases of swallowing. Based on previous research, the primary hypothesis was that various NMES treatment protocols would have differential effects of either enhancing or inhibiting the excitability of corticobulbar projections to this muscle group. The research paradigm used to test this hypothesis was an evaluation of MEP amplitude and onset latency, recorded in the functional context of volitional contraction of the submental musculature (VC) and contraction of this muscle group during the pharyngeal phase of volitional swallowing (VPS, volitional pharyngeal swallow). Outcome measures were recorded before and at several time points after each NMES treatment trial. This methodology is similar to, but improved upon, research paradigms previously reported. Changes in corticobulbar excitability in response to various NMES treatment protocols were recorded in a series of experiments. Ten healthy research participants were recruited into a study that evaluated the effects of event-related NMES, whereas 15 healthy research participants were enrolled in a study that investigated the effects of non-event-related NMES. In a third cohort of 35 healthy research participants, task-dependent differences in corticobulbar excitability were evaluated during three conditions of submental muscle contraction: VC, VPS and submental muscle contraction during the pharyngeal phase of reflexive swallowing (RPS, reflexive pharyngeal swallowing). Event-related NMES induced frequency-depended changes in corticobulbar excitability. NMES administered at 80 Hz facilitated MEP amplitude, whereas NMES at 5 Hz and 20 Hz inhibited MEP amplitude. No changes were observed after NMES at 40 Hz. Maximal excitatory or inhibitory changes occurred 60 min post-treatment. Changes in MEP amplitude in response to event-related NMES were only observed when MEPs were recorded during the VC condition, whereas MEPs recorded during the VPS condition remained unaffected. Non-event-related NMES did not affect MEP amplitude in either of the muscle contraction conditions. Similarly, MEP onset latencies remained unchanged across all comparisons. MEPs were detected most consistently during the VC contraction condition. They were less frequently detected and were smaller in amplitude for the VPS condition and they were infrequently detected during pre-activation by RPS. The documented results indicate that event-related NMES has a more substantial impact on MEP amplitude than non-event-related NMES, producing excitatory and inhibitory effects. Comparison of MEPs recorded during VC, VPS and RPS suggests that different neural networks may govern the motor control of submental muscle activation during these tasks. This research programme is the first to investigate the effects of various NMES treatment protocols on the excitability of submental corticobulbar projections. It provides important new information for the use of NMES in clinical rehabilitation practices and our understanding of the neural networks governing swallowing motor control.

transcranial magnetic stimulation (TMS)

motor evoked potential (MEP)

deglutition

motor control

Modulation of swallowing behaviour by olfactory and gustatory stimulation

Abdul Wahab, Norsila

January 2012

Swallowing impairment or dysphagia can be a consequence of several neurological and anatomical disorders such as stroke, Parkinson’s diseases, and head and neck cancer. Management of patients with dysphagia often involves diet modification, sensory stimulation, and exercise programme with the primary goal being safe swallowing to maintain nutrition. The aim of this project was to evaluate the effects of lemon odour and tastant on swallowing behaviour in healthy young adults. Specifically, the neural excitability and biomechanical characteristics of swallowing were measured in two studies. Neural excitability was evaluated by measuring motor-evoked potentials (MEPs) from the submental muscles which were evoked by transcranial magnetic stimulation (TMS) of the motor cortex. Biomechanical characteristics were evaluated through measures of submental muscle contraction, pressure changes in the oral cavity and pharynx, and the dynamics of the upper oesophageal sphincter (UES). Two groups of volunteers (16 in each group) participated in two separate studies. In the MEP study, 25% and 100% concentrations of lemon concentrate were presented separately as olfactory and gustatory stimuli. The four stimuli were randomly presented in four separate sessions. The olfactory stimulus was nebulized and presented via nasal cannula. Filter paper strips impregnated with the lemon concentrate placed on the tongue served as the gustatory stimulus. Tap water was used as control. TMS-evoked MEPs were measured at baseline, during control condition, during stimulation, immediately poststimulation, and at 30-, 60-, and 90-min poststimulation. Experiments were repeated using the combination of odour and tastant concentration that most significantly influenced the MEP. The biomechanical study used (a) surface electromyography (sEMG) to record contraction of the submental muscles, (b) lingual array with pressure transducers to record glossopalatal pressures, and (c) pharyngeal manometry to record pressures in the pharynx and the UES. Similar methods of presenting the stimuli were used to randomly present the 25% and 100% concentrations of lemon odour and tastant. All data were recorded concurrently during stimulation. The concentration of odour and tastant that produced the largest submental sEMG amplitude was selected for presentation of combined stimulation. Data were then recorded during combined stimulation and at 30-, 60-, and 90-min poststimulation. Results from the MEP study showed increased MEP amplitude at 30-, 60-, and 90-min poststimulation during swallowing compared to baseline, but only for the combined stimulation. Poststimulation results from the biomechanical study showed decreased middle glossopalatal pressure at 30 min and decreased anterior and middle glossopalatal contact duration at 60 min. No poststimulation changes were found in sEMG and pharyngeal manometry measures. During combined odour and tastant stimulation, there were increased pressure and contact duration at the anterior glossopalatal contact and decreased hypopharyngeal pressure. Generally, these changes correspond to increased efficiency of swallowing. In conclusion, these are the first studies to have measured the effects of flavour on neural excitability and biomechanics of swallowing and the first to have shown changes in MEP and several biomechanical characteristics of swallowing following flavour stimulation. These changes were present poststimulation, suggesting mechanisms of neural plasticity that may underlie potential value in the rehabilitation of patients with dysphagia.

sour

olfaction

gustation

deglutition

transcranial magnetic stimulation

electromyography

lingual pressure

manometry

Transkranijinės magnetinės stimuliacijos įtaka galvos smegenų bioelektriniam aktyvumui / The effect of transcranial magnetic stimulation on brain bioelectrical activity

Valiulis, Vladas

25 September 2014

Transkranijinė magnetinė stimuliacija (TMS) – tai modernus neinvazinis vaistams rezistentiškų psichiatrinių sutrikimų gydymo būdas. Fiziologiniai TMS tyrimai pasižymi įvairiais, dažnai prieštaringais rezultatais, daugeliu atvejų didžiausias dėmesys skiriamas betarpiškiems poveikiams po vienos TMS procedūros, bet ne po pilno terapinio kurso. Manoma, kad rezultatų įvairovę TMS praktikoje įtakoja skirtingi stimuliacijos parametrai ir netikslumai parenkant stimuliuojamą zoną smegenyse. Nors TMS terapija dažnai traktuojama kaip švelnesnė alternatyva elektros impulsų terapijai (EIT), palyginamųjų fiziologinių šių metodikų tyrimų labai trūksta. Darbo tikslas buvo įvertinti TMS terapijos kurso poveikį bioelektriniam galvos smegenų aktyvumui ir palyginti jį su EIT terapijos poveikiu. Buvo tirta aukšto ir žemo dažnių (10 Hz ir 1 Hz) TMS terapijos įtaka EEG dažnių galios spektrui bei sukeltiniam klausos potencialui P300, naudojant standartinį ir neuronavigacinį taikinio pozicionavimą. TMS sukelti EEG pokyčiai palyginti su EIT terapijos sukeltais EEG pokyčiais, išmatuota TMS terapijos sąlygotų pokyčių dinamika kelių mėnesių bėgyje. Rezultatai parodė, kad TMS terapijos pasekoje smegenyse ryškiausiai padidėja delta dažnio galia. Naudojant standartinį pozicionavimą 10 Hz TMS sukėlė įvairesnius ir intensyvesnius EEG galios spektro pokyčius nei 1 Hz TMS. Pritaikius neuronavigacinę sistemą 10 Hz TMS atveju sumažėjo teta ir alfa dažnių galios pokyčiai. Praėjus keliems mėnesiams nuo TMS... [toliau žr. visą tekstą] / Transcranial magnetic stimulation (TMS) is a modern non invasive method of drug resistant psychiatric disorder treatment. TMS physiology research is hindered by variable, often controversial results. In most studies main attention is being focused on immediate effects after single TMS procedure rather than the influence of a complete therapy course. It is considered that variability of results in TMS practice is caused by different stimulation parameters and imprecision of stimulated area placement in the brain. Although TMS therapy is often viewed as a milder alternative to electroconvulsive therapy (ECT), comparative physiological studies of these two methods are very rare. The aim of this study was to evaluate the effect of rTMS therapy course on bioelectrical brain activity and compare it to an ECT effect. Research included the effect of high and low frequency (10 Hz and 1 Hz) TMS on EEG band power spectrum and auditory evoked potential P300, using both standard and neuronavigated target positioning. TMS evoked EEG changes were also compared to the changes of ECT. Change dynamics after several months of TMS therapy were also measured. Results showed that after TMS therapy the most notable change in the brain occurs in the form of delta power increase. When using standard positioning 10 Hz TMS evokes more diverse and intense EEG band power spectrum changes than the 1 Hz TMS. Application of neuronavigation system decreases theta and alpha band power changes in 10 Hz TMS... [to full text]

Biophysics

TMS

EEG

P300

EIT

Transkranijinė magnetinė stimuliacija

TMS

EEG

P300

ECT

Transcranial magnetic stimulation

The effect of transcranial magnetic stimulation on brain bioelectrical activity / Transkranijinės magnetinės stimuliacijos įtaka galvos smegenų bioelektriniam aktyvumui

Valiulis, Vladas

25 September 2014

Transcranial magnetic stimulation (TMS) is a modern non invasive method of drug resistant psychiatric disorder treatment. TMS physiology research is hindered by variable, often controversial results. In most studies main attention is being focused on immediate effects after single TMS procedure rather than the influence of a complete therapy course. It is considered that variability of results in TMS practice is caused by different stimulation parameters and imprecision of stimulated area placement in the brain. Although TMS therapy is often viewed as a milder alternative to electroconvulsive therapy (ECT), comparative physiological studies of these two methods are very rare. The aim of this study was to evaluate the effect of rTMS therapy course on bioelectrical brain activity and compare it to an ECT effect. Research included the effect of high and low frequency (10 Hz and 1 Hz) TMS on EEG band power spectrum and auditory evoked potential P300, using both standard and neuronavigated target positioning. TMS evoked EEG changes were also compared to the changes of ECT. Change dynamics after several months of TMS therapy were also measured. Results showed that after TMS therapy the most notable change in the brain occurs in the form of delta power increase. When using standard positioning 10 Hz TMS evokes more diverse and intense EEG band power spectrum changes than the 1 Hz TMS. Application of neuronavigation system decreases theta and alpha band power changes in 10 Hz TMS... [to full text] / Transkranijinė magnetinė stimuliacija (TMS) – tai modernus neinvazinis vaistams rezistentiškų psichiatrinių sutrikimų gydymo būdas. Fiziologiniai TMS tyrimai pasižymi įvairiais, dažnai prieštaringais rezultatais, daugeliu atvejų didžiausias dėmesys skiriamas betarpiškiems poveikiams po vienos TMS procedūros, bet ne po pilno terapinio kurso. Manoma, kad rezultatų įvairovę TMS praktikoje įtakoja skirtingi stimuliacijos parametrai ir netikslumai parenkant stimuliuojamą zoną smegenyse. Nors TMS terapija dažnai traktuojama kaip švelnesnė alternatyva elektros impulsų terapijai (EIT), palyginamųjų fiziologinių šių metodikų tyrimų labai trūksta. Darbo tikslas buvo įvertinti TMS terapijos kurso poveikį bioelektriniam galvos smegenų aktyvumui ir palyginti jį su EIT terapijos poveikiu. Buvo tirta aukšto ir žemo dažnių (10 Hz ir 1 Hz) TMS terapijos įtaka EEG dažnių galios spektrui bei sukeltiniam klausos potencialui P300, naudojant standartinį ir neuronavigacinį taikinio pozicionavimą. TMS sukelti EEG pokyčiai palyginti su EIT terapijos sukeltais EEG pokyčiais, išmatuota TMS terapijos sąlygotų pokyčių dinamika kelių mėnesių bėgyje. Rezultatai parodė, kad TMS terapijos pasekoje smegenyse ryškiausiai padidėja delta dažnio galia. Naudojant standartinį pozicionavimą 10 Hz TMS sukėlė įvairesnius ir intensyvesnius EEG galios spektro pokyčius nei 1 Hz TMS. Pritaikius neuronavigacinę sistemą 10 Hz TMS atveju sumažėjo teta ir alfa dažnių galios pokyčiai. Praėjus keliems mėnesiams nuo TMS... [toliau žr. visą tekstą]

Biophysics

TMS

EEG

P300

ECT

Transcranial magnetic stimulation

TMS

EEG

P300

EIT

Transkranijinė magnetinė stimuliacija