Tesis sobre el tema "EEG-TMS"
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Santos, Maria Inês Fonseca Silva. "Quantification of the TMS-EEG response in epilepsy". Master's thesis, Faculdade de Ciências e Tecnologia, 2012. http://hdl.handle.net/10362/8502.
Texto completoPurpose: The purpose of this thesis was to provide quantitative measures of the co-registration of transcranial magnetic stimulation (TMS) and electroencephalogram (EEG). The EEG is used to study changes in the neuronal activity evoked by the non-invasive technique TMS. These effects are determined mainly based on clinical judgment. Current uses in the diagnosis of epilepsy are based only on EEG, not taking into consideration the low sensitivity in the interictal period, in particular if routine recordings are used. Methods: Patient data was gathered, analyzed and compared to healthy controls. A total of ten patients and eighteen healthy subjects underwent sessions of 75 TMS pulses. The responses to the pulses were filtered and averaged. The use of topographical scalp plots of amplitude and power, and time-series analysis of power in search for late responses provide results which enable separation of epilepsy patients and healthy controls. By investigating the significance of the results it is also possible to determine, in a quantitative way how reliable the methods are for distinguishing between the two groups. Results: The definition of what is a response is critical in this project, and as such must consider: significant power change, be above a certain amplitude, and be localized. Still, this procedure results in a non distinguishable threshold to separate both groups. Conclusions: Analysis of the receiver operating characteristic (ROC) curves also led to the understanding the method established is not entirely reliable because it cannot in fact determine differences. Since all patients were under treatment with anti-epileptic drugs(AEDs), it becomes necessary to elaborate a pilot study with recently diagnosed subjects where hyperexcitability is still present.
Mazzoni, Giovanni. "implementazione ed analisi di strumentazioni combinate: eeg e tms". Bachelor's thesis, Alma Mater Studiorum - Università di Bologna, 2021. http://amslaurea.unibo.it/23341/.
Texto completoRepper-Day, Christopher. "Mapping dynamic brain connectivity using EEG, TMS, and Transfer Entropy". Thesis, University of Manchester, 2017. https://www.research.manchester.ac.uk/portal/en/theses/mapping-dynamic-brain-connectivity-using-eeg-tms-and-transfer-entropy(27a55697-1b4f-40e0-8d07-0a53d3e67a24).html.
Texto completoRowe, P. "The temporal nature of affordance : an investigation using EEG and TMS". Thesis, City, University of London, 2018. http://openaccess.city.ac.uk/20554/.
Texto completoPawley, Adam David. "Novel TMS and EEG markers of diagnosis and treatment response in epilepsy". Thesis, King's College London (University of London), 2015. https://kclpure.kcl.ac.uk/portal/en/theses/novel-tms-and-eeg-markers-of-diagnosis-and-treatment-response-in-epilepsy(02e6922a-e038-41af-bac9-169770fb7d05).html.
Texto completoBocca, Francesca [Verfasser] y Paul [Akademischer Betreuer] Taylor. "Combined TMS-EEG : studies of visual attention / Francesca Bocca. Betreuer: Paul Taylor". München : Universitätsbibliothek der Ludwig-Maximilians-Universität, 2015. http://d-nb.info/1076471935/34.
Texto completoKönig, Franca Sophie [Verfasser]. "TMS-EEG signatures of glutamatergic neurotransmission in human cortex / Franca Sophie König". Tübingen : Universitätsbibliothek Tübingen, 2020. http://d-nb.info/1224232720/34.
Texto completoValiulis, Vladas. "Transkranijinės magnetinės stimuliacijos įtaka galvos smegenų bioelektriniam aktyvumui". Doctoral thesis, Lithuanian Academic Libraries Network (LABT), 2014. http://vddb.library.lt/obj/LT-eLABa-0001:E.02~2014~D_20140925_135031-16126.
Texto completoTranscranial 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]
Valiulis, Vladas. "The effect of transcranial magnetic stimulation on brain bioelectrical activity". Doctoral thesis, Lithuanian Academic Libraries Network (LABT), 2014. http://vddb.library.lt/obj/LT-eLABa-0001:E.02~2014~D_20140925_135043-14839.
Texto completoTranskranijinė 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]
Aschenbrenner, Berthold [Verfasser] y Berthold [Akademischer Betreuer] Langguth. "Neuroplastische Effekte bei Schizophrenie: Eine kombinierte TMS/EEG Studie / Berthold Aschenbrenner ; Betreuer: Berthold Langguth". Regensburg : Universitätsbibliothek Regensburg, 2018. http://d-nb.info/116695076X/34.
Texto completoVAROLI, ERICA. "TMS-EEG: a promising tool to study the cathodal tDCS effects on cortical excitability". Doctoral thesis, Università degli Studi di Milano-Bicocca, 2020. http://hdl.handle.net/10281/280669.
Texto completoTranscranial direct current stimulation (tDCS) is a non-invasive neuromodulatory technique able to induce plasticity-related alterations in neuronal excitability. There is a growing interest in the use of tDCS in both experimental and clinical settings; in particular, the chance to induce long-term effects fostered the used of the technique to treat cognitive impairments associated with different neuropsychological and psychiatric disorders. Although tDCS is increasingly used, presently little is still known about its neurophysiological underpinnings, particularly concerning the activity on the brain regions that underlie high cognitive brain functions. In these cases, optimal tDCS stimulation parameters also have yet to be clearly defined. A deeper understanding of the mechanisms underpinning this technique would be crucial to achieving a better refinement of stimulation protocols for clinical and research purposes. For this reason, a systematic and comprehensive study of its cortical effects acquires a critical relevance. In the last years, there has been indeed a keen interest in understanding the working mechanisms of this technique. To address this issue, in this project we explored the cortical plasticity modulation induced by cathodal stimulation on healthy subjects while resting or during task execution, using an integrated system of Transcranial Magnetic Stimulation and Electroencephalography (TMS-EEG), which allows to directly measure cortical excitability modulation all over the cortex and effective connectivity. In the first study, starting from the previous results with anodal tDCS, the effects of cathodal stimulation over the right Posterior Parietal Cortex (PPC) were explored during resting state. The contralateral homologue brain area, namely the left posterior parietal cortex (PPC), was targeted with TMS before, during, and after cathodal stimulation. In the second study, we explored the behavioural effects induced by the application of cathodal tDCS over right PPC during the execution of two tasks, one of visuospatial working memory and a second tapping visual attention reorienting, which are known to involve this brain area. The aim was to find tasks sensitive to the effect of cathodal tDCS over the right PCC, to be used in the third study. A disruption of the performance was found for the Posner Cueing Task. In the third study, we employed again TMS-EEG to track the neurophysiological effects of cathodal tDCS on right PPC at an active state, i.e. while the participants were performing the task tested on the second study. The results at resting state for cathodal tDCS, both at sensors and cortical sources levels, converge in showing no differences during and after tDCS compared to pre-stimulation sessions, both at a global and local level. The previous results with anodal tDCS, instead, reported a widespread rise of cortical excitability along with a bilateral frontoparietal network, following structural connections. On the other hand, at an active state, cathodal, as well as anodal, tDCS induced modulation of cortical excitability only in the task-relevant brain regions. Several significant findings emerged from this empirical work. First of all, these data highlight a non-linear impact of anodal and cathodal stimulation on cortical excitability at rest that is not depicted by the simplistic view of anodal-excitatory and cathodal-inhibitory effects. Another relevant point is the crucial role played by the different cortical states (resting vs active). These results seem to point out that the level of cortical state can contribute to modulate the tDCS effects, in line with “activity-selectivity” hypothesis. The level of cortical state needs to be taken into account, especially to observe neuromodulatory effects also with cathodal tDCS. All these findings hold relevant implications for tDCS setup in both cognitive neuroscience experiments and rehabilitation protocols.
ZAZIO, AGNESE. "Impact of ongoing alpha oscillations on visual perception and neurophysiological response: an integration with a psychophysical approach". Doctoral thesis, Università degli Studi di Milano-Bicocca, 2019. http://hdl.handle.net/10281/241241.
Texto completoNeural oscillations are considered to be the building blocks of cognitive functioning, and in the last decades neuroscientists have developed fundamental theories on their role in brain dynamics. Recently, a growing body of evidences has shown that ongoing oscillatory activity can account for a considerable amount of variability in behavioral performance and in neurophysiological response. In the domain of visual perception, a crucial role is played by neural oscillations within alpha frequency range. Alpha activity is believed to exert an inhibitory function on stimulus processing and to reflect cortical excitability, both when it fluctuates spontaneously as well as when it is modulated, by top-down or bottom-up mechanisms. It has been recently suggested that alpha rhythm may not be considered as a unitary phenomenon; however, still little is known about the neural mechanisms associated with alpha activity as measured by non-invasive recordings. Furthermore, up to now most of the studies on the effects of ongoing alpha activity on visual perception focused on a special class of stimuli, i.e., with a near-threshold intensity, and much less is known about what happens in the response beyond sensory threshold. In the present work, we aimed at addressing these issues by studying the effects of ongoing alpha oscillations on perceptual and neurophysiological outcome in the visual domain. The first goal was to replicate recent findings on the effects of spontaneous fluctuations of pre-stimulus alpha power and phase on a visual detection task, by using near-threshold stimuli. In addition to the original study, the use of magnetoencephalography allowed us to reconstruct brain sources of pre-stimulus and evoked activity. In a second study, we aimed at modulating ongoing alpha activity by using a sensory deprivation paradigm, and tested the effects of such modulation by means of a wide range of stimulation intensities. The use of transcranial magnetic stimulation (TMS) with concurrent electroencephalography allowed to directly assess the neurophysiological and perceptual response to TMS, by means of TMS-evoked potentials and phosphene perception. Finally, in a third study we developed a formal model of the effects of ongoing alpha activity on visual perception, with the aim of disentangling possible neural mechanisms which cannot be discerned non-invasively. The model is based on cross-frequency interactions between alpha functional inhibition and gamma activity of sensory neurons and highlights the advantages of presenting a wide range of stimulus intensities in the study of the effects of pre-stimulus oscillatory activity, using a psychophysical approach. Taken together, our results are consistent with current literature about the inhibitory function played by ongoing alpha activity on visual perception. Indeed, both perceptual and neurophysiological response to an external stimulus were affected by pre-stimulus alpha activity, when it fluctuated spontaneously as well as when it was modulated by a sensory deprivation paradigm. Moreover, the present findings support the hypothesis that alpha oscillations subtend distinct mechanisms, and highlighted that new insights may arise from applying a psychophysical approach to the study of ongoing activity on perception. By using different methodological approaches, the present work provides novel advances in the field of non-invasive investigation of ongoing oscillations on behavior, specifically on alpha inhibition of visual perception.
Cavinato, Marianna. "Verso la comprensione dello stato vegetativo e di minima coscienza". Doctoral thesis, Università degli studi di Padova, 2013. http://hdl.handle.net/11577/3423022.
Texto completoLe limitate evidenze e la fluttuazione dei comportamenti intenzionali neiin pazienti in stato di minima coscienza (SMC) richiedono la ricerca di un indice marcatore elettrofisiologico obiettivo del livello di coscienza. Nel presente studio, è stato mostrato un confronto tra potenziali evento-correlati (ERP) utilizzando diversi livelli di complessità di stimolo. Gli ERP sono stati registrati in diciassette pazienti, di cui sei in stato vegetativo (SV), 11 in SMC, e 10 controlli sani. I partecipanti sono stati sottoposti a tre paradigmi di diverso grado di complessità: toni puri, il nome proprio del soggetto verso toni puri, e verso altri nomi. Sono state riscontrate risposte corticali in tutti i pazienti in SMC, ed in 6 degli 11 pazienti in SV. I controlli sani ed i pazienti in SMC hanno mostrato un progressivo aumento della latenza dell’onda P300 in relazione al livello di complessità dello stimolo. Nessuna modulazione di latenza è stata osservata nei pazienti in SV. Questi risultati suggeriscono che la modulazione di latenza della P300 relativa a complessità dello stimolo può rappresentare un indice obiettivo dell’integrazione tra aree di elaborazione di ordine superiore, presupposto necessario per il recupero della coscienza. Un secondo passo è stato incoraggiato dal lavoro di Schiff e coll. (2007) che riportarono il miglioramento clinico di un paziente in SMC dopo stimolazione cerebrale profonda (DBS). Abbiamo studiato sei pazienti sottoponendoli ad uno studio di tipo ABA con alternanza tra stimolazione magnetica transcranica ripetitiva (rTMS) e stimolazione dei nervi periferici. Dopo stimolazione periferica, i pazienti non ha evidenziato variazioni dei quadric clinico, comportamentale o elettroencefalografico (EEG). Tuttavia, dopo la rTMS, un paziente manifestò un aumento della frequenza di specifici comportamenti coscienti, associato ad un incremento della potenza assoluta e relativa delle bande EEG alfa, beta e delta. Successivamente, è stato arruolato un campione più consistente di pazienti per riprodurre i primi incoraggianti risultati. Trenta pazienti in SV/SMC hanno partecipato ad uno studio controllato randomizzato che comportava l’utilizzo di stimoli transcranici con stimolazione transcranica a corrente continua (tDCS) e rTMS. I pazienti in SMC hanno mostrato un aumento di connettività fronto-parietale, che indica una complessa elaborazione delle informazioni sensoriali, ed una diminuzione della fluttuazione dell’arousal. Il quadro dei pazienti in SV rimase invariato. Questi risultati suggeriscono che la rTMS può migliorare le connessioni a lungo raggio tra remote aree corticali e promuovere, in qualche modo, il recupero di coscienza nei pazienti in SMC.
Bayram, Mehmed Satuk Bugrahan. "Scalp EEG and TMS based Electrophysiological Study of Brain Function of Motor Control in Aging". Cleveland State University / OhioLINK, 2013. http://rave.ohiolink.edu/etdc/view?acc_num=csu1371688566.
Texto completoBucur, Madalina. "NEUROPHYSIOLOGICAL CORRELATES OF LANGUAGE RECOVERY AFTER TDCS IN APHASIC PATIENTS". Doctoral thesis, Università degli studi di Trento, 2022. http://hdl.handle.net/11572/341338.
Texto completoGlim, Sarah [Verfasser] y Afra [Akademischer Betreuer] Wohlschläger. "Decoding the functional relevance of intrinsic brain activity with (TMS-)EEG / Sarah Glim ; Betreuer: Afra Wohlschläger". München : Universitätsbibliothek der Ludwig-Maximilians-Universität, 2019. http://d-nb.info/118357214X/34.
Texto completoSchouten, Lucy. "No difference in motor cortical inhibition between young and Middle-Aged adults: A TMS-EEG Study". Thesis, Schouten, Lucy (2018) No difference in motor cortical inhibition between young and Middle-Aged adults: A TMS-EEG Study. Honours thesis, Murdoch University, 2018. https://researchrepository.murdoch.edu.au/id/eprint/43012/.
Texto completoGollmitzer, Judith [Verfasser] y Berthold [Akademischer Betreuer] Langguth. "Neuroplastische Korrelate des chronischen Tinnitus am auditorischen Kortex: Eine kombinierte TMS-EEG-Untersuchung / Judith Gollmitzer ; Betreuer: Berthold Langguth". Regensburg : Universitätsbibliothek Regensburg, 2017. http://d-nb.info/114251935X/34.
Texto completoDarmani, Ghazaleh [Verfasser] y Ulf [Akademischer Betreuer] Ziemann. "Pharmaco-TMS-EEG as a new tool to characterize human cortical excitability and connectivity / Ghazaleh Darmani ; Betreuer: Ulf Ziemann". Tübingen : Universitätsbibliothek Tübingen, 2018. http://d-nb.info/1172716331/34.
Texto completoEntakli, Jonathan. "Implication des projections spinales de l'aire motrice supplémentaire lors d'un contrôle précis de force : étude par TMS et EEG". Thesis, Aix-Marseille, 2013. http://www.theses.fr/2013AIXM4121/document.
Texto completoHuman dexterity is a highly developed function based on the ability to independently and precisely control forces and movements of the fingers related to the constraints of the task. Hand muscles for finger movements are steered by the lateral corticospinal (CS) system. The main source of this CS system is the primary motor area (M1), which has direct CS projections on motoneurons innervating hand muscles. Recently, CS projections from non-primary motor area have also been found, especially from the supplementary motor area (SMA). However, the functionality of this CS tract in human manual force control is little studied. The aim of this thesis was to study the implication of the CS projections from SMA in precision manual force control, using electroencephalography (EEG) and transcranial magnetic stimulation (TMS).Altogether, the results obtained in our different studies show the important implication of SMA in dexterity. It appears that this area can act in parallel with M1, directly influencing excitability of spinal motoneurons. We conclude that M1 and SMA both have direct and efficient influence on force production during fine manual motor tasks
Buldrini, Elena. "Sinestesia, ovvero la contaminazione reciproca tra i sensi. Basi neurofisiologiche e tecniche di analisi". Bachelor's thesis, Alma Mater Studiorum - Università di Bologna, 2017. http://amslaurea.unibo.it/13280/.
Texto completoSpieser, Laure. "Ré-agir vite et bien à une perturbation de mouvement : étude des mécanismes corticaux par couplage EEG-TMS chez l'homme". Thesis, Aix-Marseille 2, 2010. http://www.theses.fr/2010AIX20685/document.
Texto completoIn everyday life, our actions can be perturbed by rapid variations of environmentalexternal forces. In order to achieve our goals, we have to react “well and fast” to thesemovement perturbations. This reaction implies both cognitive and sensorimotor processes. Wewere interested in the cortical mechanisms (mainly involving the primary motor cortex, M1)underlying the interaction between cognitive and sensorimotor functions that allows theadaptation of the reaction to the perturbation according to the intention. We tried to relate themechanisms implicated during the preparation with those implicated during the realization ofthe reaction. With combined EEG-TMS (with EMG recording), we used a stimulation-recordingapproach, allowing simultaneous observation of cortical and corticospinal mechanisms, bothbefore and after the stimulation. This approach helps to obtain to a better understanding of therelationship between cerebral activity and behavior.In the first experiment, we used a central motor perturbation, i.e. subjects were asked toresist or to assist a movement evoked directly at the cortical level using TMS. We showed thatcognitive processes can directly influence cortical and corticospinal excitability before anyinvolvement of the sensorimotor processes related to the movement execution. When subjectsprepared to resist the TMS-evoked movement, the anticipatory increased activity of theintracortical inhibitory networks of M1 decreased the cortical excitability, leading to adecreased corticospinal excitability and thus to a reduced TMS-evoked movement.In the following experiments (2, 3 and 4), we were interested in cortical andcorticospinal mechanisms engaged during the preparation and the reaction to a peripheralmovement perturbation. We asked subjects either to resist or to not-react (to “let-go”) to apassive wrist extension, and we studied the mechanisms underlying the modulation of the longlatency stretch reflex (LLSR, starting about 50 ms after the perturbation) according to theintention. Concerning the corticospinal excitability, the results showed that, during thepreparation of a reaction to a peripheral perturbation, the anticipatory tuning of thecorticospinal excitability takes into account sensorimotor integrative phenomenons induced bythe afferent input due to the perturbation in such a way that the reaction, triggered by theafferent inputs, is adapted to the subject’s intention (experiment 2). At the cortical level, achange of M1 intracortical network activity (before the perturbation) precedes the modulationof the primary sensorimotor cortex activity that is linked to the LLSR generation (after theperturbation). This strongly suggests that anticipatory processes preset the primarysensorimotor cortex in order to adapt its early response to the perturbation according to thesubject’s intention (experiment 3). Finally, temporary inactivation of SMA proper (induced byTMS) showed that this non-primary motor area is also implicated in the modulation of thestretch reflex according to the intention (experiment 4).In conclusion, when we expect a motor perturbation, intention-specific preparatoryprocesses are engaged in SMA proper and the primary sensorimotor cortex that are differentfrom those involved in the realization of a movement without external force variations. Thesepreparatory processes allow the early motor reaction, generated by the primary sensorimotorcortex (triggered by the afferent input induced by the perturbation) to be adapted to thesubject’s intention
CASALI, A. GIRARDI. "PROBING THE BRAIN¿S CAPACITY FOR CONSCIOUSNESS THROUGH THE SPATIOTEMPORAL COMPLEXITY OF THE CORTICAL ACTIVITY EVOKED BY TRANSCRANIAL MAGNETIC STIMULATION". Doctoral thesis, Università degli Studi di Milano, 2012. http://hdl.handle.net/2434/169146.
Texto completoKirály, Julia Elisabeth [Verfasser] y Ulf [Akademischer Betreuer] Ziemann. "The role of GABAAergic neurotransmission in the human brain probed by paired-pulse TMS-EEG / Julia Elisabeth Király ; Betreuer: Ulf Ziemann". Tübingen : Universitätsbibliothek Tübingen, 2019. http://d-nb.info/1204879923/34.
Texto completoSarasso, Simone. "High density EEG studies of local sleep changes following synaptic plasticity in humans". Doctoral thesis, Università degli studi di Padova, 2008. http://hdl.handle.net/11577/3425572.
Texto completoFilipova, Nina [Verfasser] y Alkomiet [Akademischer Betreuer] Hasan. "Humanphysiologische Korrelate für plastische Modulation verschiedener kortikaler Areale : eine experimentelle klinisch-neurophysiologische Studie mittels TMS, EEG und tDCS / Nina Filipova ; Betreuer: Alkomiet Hasan". München : Universitätsbibliothek der Ludwig-Maximilians-Universität, 2018. http://d-nb.info/115987963X/34.
Texto completoCasula, Elias Paolo. "THE COMBINED USE OF TRANSCRANIAL MAGNETIC STIMULATION AND ELECTROENCEPHALOGRAPHY IN THE INVESTIGATION OF REACTIVITY, CONNECTIVITY AND PLASTICITY OF THE PRIMARY MOTOR CORTEX". Doctoral thesis, Università degli studi di Padova, 2015. http://hdl.handle.net/11577/3424271.
Texto completoLa presente tesi si compone di due parti principali: una teorica e una sperimentale. La prima parte, suddivisa in due capitoli, è un approfondimento teorico sullo strumento stimolazione magnetica transcranica (TMS) e sul suo utilizzo simultaneo (ossia, in coregistrazione) con le tecniche di neuroimaging. La seconda parte comprende alcuni degli studi condotti durante il mio dottorato. Nello specifico, si tratta di tre studi che coprono i diversi aspetti applicativi delle ricerche che ho condotto in questi tre anni, ossia lo studio e l’utilizzo della coregistrazione TMS-EEG in ricerca (studio 1), in ambito clinico (studio 2) e per aspetti tecnico-metodologici (studio 3). Il primo studio (studio 1), condotto nel Dipartimento di Psicologia Generale di Padova, era volto all’analisi degli effetti neuromodulatori di un protocollo rTMS su volontari sani. Il secondo studio (study 2) è stato condotto all’Istituto di Neurologia dello University College London (Londra, Regno Unito) all’interno del progetto internazionale “TrackOnHD”, uno studio longitudinale avente come obiettivo l'indagine approfondita della Malattia di Huntington (HD) attraverso un approccio multimodale. L’obiettivo di questo studio era la ricerca di potenziali marker TMS-EEG che riflettessero il deficit di inibizione cerebrale che caratterizza questa patologia. Il terzo studio (study 3), svolto in collaborazione col Dipartimento di Ingegneria dell’Informazione di Padova, aveva l’obiettivo di sviluppare un algoritmo di correzione in grado di rimuovere un artefatto indotto dalla TMS durante la registrazione EEG. CAPITOLO I - LA STIMOLAZIONE MAGNETICA TRANSCRANICA (TMS) Negli ultimi anni lo sviluppo di nuove tecniche in grado di analizzare l’attivazione cerebrale durante processi cognitivi e motori, ha portato ad un avanzamento progressivo delle conoscenze sul cervello umano. La stimolazione magnetica transcranica (TMS) è stata uno degli strumenti la cui popolarità è cresciuta in questi ultimi anni, grazie alla possibilità di stimolare, in modo focale e non invasivo, il cervello in vivo (Barker et al., 1985). Tale capacità ha consentito, per la prima volta, la straordinaria possibilità di inferire delle relazioni causali tra cervello, processi cognitivi e motori, e comportamento (Pascual-Leone et al., 2000). Nel primo capitolo della presente tesi vengono passate in rassegna tutte le possibili applicazioni della TMS in campo cognitivo, fisiologico e riabilitativo. Nello specifico, la prima parte è dedicata ai meccanismi di funzionamento della TMS e ai parametri di stimolazione che ne definiscono i diversi effetti sul cervello. Nella seconda parte vengono invece passati in rassegna i tre principali protocolli di stimolazione: la TMS a singolo impulso, utilizzata per la caratterizzazione spaziale e temporale dei processi cognitivi, per analizzare la reattività della corteccia motoria primaria, e per verificare l’integrità del tratto cortico-spinale; la TMS a doppio impulso, per studiare la connettività e l’interazione di network cerebrali a riposo e durante lo svolgimento di un task; e la TMS ripetitiva (rTMS), utilizzata per analizzare i fenomeni di plasticità cerebrale sia durante processi cognitivi, sia in relazione a trattamenti riabilitativi. CAPITOLO II - L’UTILIZZO SIMULTANEO DELLA TMS CON L’EEG ED ALTRE TECNICHE DI NEUROIMAGING Nonostante la grande popolarità che la TMS ha conosciuto negli ultimi anni, molti aspetti del suo meccanismo d’azione sono ancora poco chiari (Miniussi et al., 2010). Tale ambiguità è dovuta al fatto che, fatta eccezione per la corteccia motoria e visiva primaria, la stimolazione TMS non fornisce dei marker “visibili” di eccitabilità corticale. Negli ultimi anni, grazie al miglioramento tecnologico degli strumenti di indagine neuroscientifica, si è iniziato a utilizzare simultaneamente (in coregistrazione) la TMS con diverse tecniche di neuroimaging. Ciò ha consentito di trarre delle inferenze di tipo “causale” e non più solo “correlazionale” (come nei tradizionali studi di neuroimaging) grazie alle informazioni spaziali e temporali sull’effetto della TMS che le tecniche di neuroimaging offrono. Nel secondo capitolo della presente tesi, vengono trattati dettagliatamente le potenzialità e i limiti delle diverse coregistrazioni TMS-neuroimaging. In particolare, nella parte centrale del capitolo è dato ampio spazio all’argomento centrale di questa tesi, ossia la coregistrazione TMS-EEG. L’approccio TMS-EEG, tra i vari metodi di coregistrazione, è stato quelli che negli ultimi anni ha riscontrato maggiore successo e diffusione, dovuto all’enorme potenzialità che questo metodo garantisce nello studio delle dinamiche cerebrali. L’EEG, infatti, è in grado di registrare, ad altissima risoluzione temporale, i potenziali post-sinaptici indotti dalla depolarizzazione neuronale evocata dalla TMS (Ilmoniemi et al., 1997). L’analisi dell’attività EEG indotta dalla TMS - in termini di tempo, spazio, frequenza e potenza - è in grado di fornire delle preziose informazioni sia sull’attivazione locale indotta dalla stimolazione (reattività cerebrale), sia su quella distale (connettività cerebrale), sia sulle modificazioni a seguito di protocolli di stimolazione ripetitiva (plasticità cerebrale). D’altra parte, la coregistrazione TMS-EEG presenta numerose difficoltà di tipo tecnico, dovuto ai numerosi artefatti che la stimolazione elettromagnetica induce sul segnale EEG (così come sui segnali delle altre tecniche di neuroimaging), questi aspetti sono trattati in maniera dettagliata all’interno del capitolo. Infine, l’ultima parte del capitolo è dedicata agli altri metodi di coregistrazione TMS con risonanza magnetica (MRI), risonanza magnetica funzionale (fMRI), tomografia a emissione di positroni (PET), tomografia a emissione di fotone singolo (SPECT) e spettroscopia del vicino infrarosso (NIRS). CAPITOLO III – STUDIO 1: EFFETTI NEUROMODULATORI DELLA RTMS A BASSA FREQUENZA: EVIDENZE DALL’APPROCCIO TMS-EEG Tradizionalmente gli effetti neuromodulatori della rTMS sono stati studiati attraverso l’analisi dei potenziali motori evocati (MEP). Tuttavia, come noto, i MEP sono una misura indiretta dell’eccitabilità corticale avendo una forte componente anche spinale. Con lo sviluppo di nuovi sistemi EEG compatibili con la TMS, è stato possibile analizzare gli effetti della stimolazione in modo più diretto, tramite l’analisi dei potenziali corticali evocati dalla TMS (TEPs). In questo studio abbiamo analizzato l’effetto di un protocollo di TMS ripetitiva (rTMS) a bassa frequenza (1 Hz) molto noto, soprattutto in ambito riabilitativo, per sortire un effetto di inibizione dell’eccitabilità corticale. Il protocollo è stato applicato sulla corteccia motoria primaria di quindici volontari sani e sulla corteccia visiva primaria di altri quindici volontari sani, assunti come gruppo di controllo per analizzare la specificità spaziale della stimolazione. Gli effetti della stimolazione ripetitiva sono stati testati su diverse misure elettrofisiologiche evocate da una stimolazione a singolo impulso della corteccia motoria, prima e subito dopo il protocollo rTMS, ossia: MEP, TEPs, local mean field power (LMFP) e distribuzione dell’attività sullo scalpo. I risultati sui MEP hanno mostrato una diminuzione significativa dell’ampiezza a seguito del protocollo rTMS sulla corteccia motoria. I risultati sui TEP hanno mostrato un pattern noto composto di quattro principali picchi: P30, N45, P60 e N100. A seguito del protocollo rTMS sulla corteccia motoria si è osservato un incremento significato dell’ampiezza dei TEP P60 e N100, la cui origine è legata all’attività dei potenziali post-sinaptici inibitori GABAb (Ferreri et al., 2011; Premoli et al., 2014). I risultati sul LMFP hanno mostrato un incremento di attività generale indotta dalla TMS sulla corteccia motoria a partire da circa 90 ms dalla stimolazione, ossia la latenza del picco massimo di inibizione GABAb. A seguito del protocollo di stimolazione di controllo, applicato sulla corteccia visiva, non si è riscontrato nessun cambiamento significativo. I risultati di questo studio hanno una rilevanza su tre aspetti: (1) si è confermato l’effetto inibitorio del protocollo rTMS a 1-Hz, offrendo anche un correlato centrale di inibizione (TEPs) oltre che periferico (MEPs); (2) sono state definite la spazialità e l’origine dell’inibizione indotta dalla rTMS a bassa frequenza; (3) la N100 evocata dalla TMS si conferma essere un marker affidabile del grado di inibizione corticale. I risultati di questo studio potrebbero avere una rilevanza sia in campo terapeutico e riabilitativo, specie per i disturbi alla cui base si suppone vi sia un deficit di inibizione corticale (ad es. malattia di Parkinson, malattia di Huntington); sia in campo di ricerca, specie in studi in cui si vogliano correlare performance a task cognitivi o motori con il grado di eccitazione/inibizione corticale. CAPITOLO IV – STUDIO 2: DEFICIT DI INIBIZIONE NELLA MALATTIA DI HUNTIGTON: EVIDENZE DALLA COREGISTRAZIONE TMS-EEG Evidenze recenti hanno mostrato le potenzialità dell’utilizzo della coregistrazione TMS-EEG in ambito clinico e diagnostico. Diverse misure TMS-EEG in termini di potenziali evocati (TEPs), analisi di sorgenti, attività oscillatoria e potenza dell’attività globale, sono state utilizzate per lo studio di dinamiche cerebrali deficitarie in diverse patologie, come: schizofrenia (Ferrarelli et al., 2008); disordini psicotici (Hoppenbrouwers et al., 2008); depressione (Kähkönen et al., 2005); disturbi di coscienza (Massimini et al., 2005); epilessia (Rotenborg et al., 2008) e autismo (Sokhadze et al., 2012). Ad esempio, diverse evidenze hanno mostrato il potenziale contributo dei TEPs nello studio degli equilibri eccitatori/inibitori corticali, data la loro origine GABAergica (Ferreri et al., 2011; Premoli et al., 2014). In particolare, la N100 TMS-evocata sembra essere strettamente correlata al grado di inibizione GABAergica, come mostrato da evidenze a carattere farmacologico (ad es. Kähkönen et al., 2003; Premoli et al., 2014); studi comportamentali (ad es. Bender et al., 2005; Bonnard et al., 2009) e studi in pazienti (ad es. Helfrich et al., 2013). Nel presente studio, facente parte di un ampio progetto internazionale multicentrico (“TrackOnHD”), abbiamo utilizzato la coregistrazione TMS-EEG per analizzare dei possibili marker elettrofisiologici della malattia di Huntington, tramite stimolazione della corteccia motoria primaria. La malattia di Huntington (HD) è caratterizzata da una progressiva degenerazione dei neuroni striatali di natura GABAergica. Tale degenerazione porta a un eccessivo incremento del tono eccitatorio mediato dal glutammato, un fenomeno noto come eccitossicità. Nel presente studio sono stati analizzati dodici pazienti HD e dodici volontari sani su varie misure TMS-EEG, EMG, fMRI e cliniche (nel capitolo sono riportati solo i risultati relativi alle misure TMS-EEG). I risultati hanno mostrato una riduzione significativa e specifica della N100, come rilevato dall’analisi dei TEP per permutazioni punto-per-punto e dall’analisi dell’attività media globale da 94 a 104 ms dopo l’impulso TMS. Le mappe dello scalpo della distribuzione dell’attività hanno mostrato una riduzione della negatività su entrambi gli emisferi, con un effetto maggiore sul sito di stimolazione. Le analisi di perturbazione dello spettro evento-relata e della coerenza inter-trial hanno mostrato una differenza significativa nell’attività oscillatoria dei due gruppi all’interno della finestra di interesse GABAb-ergico (60-110 ms dopo l’impulso TMS). I risultati osservati potrebbero essere prodotti dal deficit di inibizione GABAergica nei pazienti HD conseguente alla degenerazione neuronale nello striato. Anche se preliminari, i risultati dello studio hanno rilevato dei marker TMS-EEG potenzialmente d’interesse per la valutazione dei deficit inibitori in pazienti HD. Ulteriori analisi sono necessarie per correlare i risultati ottenuti con le altre misure raccolte all’interno del progetto. CAPITOLO V – STUDIO 3: ARTEFATTI TMS-EEG: UN NUOVO ALGORITMO ADATTATIVO PER IL DETREND DEL SEGNALE Durante un EEG, la stimolazione TMS può generare un artefatto a lunga latenza, noto come artefatto “decay”. Tale artefatto rappresenta un problema per l’analisi dei potenziali evocati dalla TMS (TEP). In letteratura, per risolvere il problema, sono comunemente utilizzate due principali strategie: l’utilizzo di un detrend lineare e l’utilizzo dell’independent component analysis (ICA). Tuttavia, nessuna di queste soluzioni può essere considerata ottimale. Per quanto riguarda l’utilizzo di un detrend lineare, dal momento che nella maggior parte dei casi l’artefatto decay non segue un andamento lineare, questo tipo di correzione risulta inefficiente. Per quanto invece riguarda l’ICA, anche questa procedura presenta dei limiti intrinseci: (1) può essere eccessivamente influenzato dalle scelte dello sperimentatore e (2) può causare la rimozione di componenti fisiologiche, oltre che artefattuali. Il nostro obiettivo è di verificare l’efficienza di un nuovo detrend adattivo, sviluppato su MATLAB, in collaborazione col dipartimento di Ingegneria Informatica di Padova, capace di discriminare i diversi trend dell’artefatto decay (ossia lineare e non-lineare). Quaranta volontari sani sono stati stimolati con 55 impulsi TMS singoli sulla corteccia motoria primaria di sinistra. Le risposte EEG indotte dalla TMS sono state analizzate in cinque condizioni: RAW (in cui non veniva applicata nessuna correzione dell’artefatto decay); INFOMAX29 (in cui l’artefatto decay veniva corretto con un algoritmo ICA-INFOMAX, considerando tutti i 29 canali); FASTICA (in cui l’artefatto decay veniva corretto con un algoritmo fastICA, considerando tutti i 29 canali); INFOMAX15 (in cui l’artefatto decay veniva corretto con un algoritmo ICA-INFOMAX, considerando solo 15 canali) e ALG (in cui l’artefatto decay veniva corretto tramite il nostro algoritmo adattivo). Per verificare se la correzione dell’artefatto avesse influenzato anche i TEP, sono state analizzare le differenze in una finestra temporale da -100 a +400 ms dall’impulso TMS attraverso l’utilizzo di un test per permutazioni, non-parametrico e corretto per cluster. Successivamente, sono state comparate le ampiezze e le latenze picco-picco dei TEP all’interno delle finestre temporali negli elettrodi risultati significativi. La risposta grand-average ha rilevato cinque picchi principali: P30, N45, P60, N100 e P180. Sono state rilevate delle differenze significative (i.e. Monte Carlo p < 0.05) in un cluster di elettrodi vicino alla stimolazione, comprendente i canali FC1, CP1, C3 e FC2. Le analisi sull’ampiezza picco-picco hanno rilevato una significativa modulazione dell’ampiezza dopo la correzione INFOMAX29 (in 3 TEP su 8), FASTICA (in 4 TEP su 12), INFOMAX15 (in 5 TEP su 15) e ALG (in 2 TEP su 15), rispetto al segnale RAW originale. I risultati LMFP e delle mappe di distribuzione sullo scalpo hanno rilevato diverse anomalie a seguito della correzione INFOMAX29 e FASTICA. I risultati hanno mostrato che la correzione ICA modifica in modo significativo l’ampiezza, la morfologia e la distribuzione di una parte dei TEP analizzati e nello stesso tempo non garantisce una completa rimozione dell’artefatto decay. Al contrario, a seguito della correzione col nostro algoritmo (condizione ALG), l’ampiezza, la morfologia e la distribuzione dei TEP rimanevano fedeli a quella originale, con una rimozione pressoché completa dell’artefatto decay. Il principale contributo di questo studio è stato la proposta di un nuovo algoritmo di correzione per un artefatto a lunga latenza che la TMS induce sul segnale EEG (artefatto decay) rendendo difficoltosa l’analisi. I risultati hanno dimostrato che questo metodo è più efficiente delle strategie attualmente in utilizzo in letteratura, non avendo i limiti intrinseci presentati dall’algoritmo ICA.
Zipser, Carl Moritz [Verfasser], Ulf [Akademischer Betreuer] Ziemann y Thomas [Akademischer Betreuer] Deller. "Spatiotemporal dynamics of brain activation in multiple sclerosis patients and healthy control subjects: a TMS-EEG study / Carl Moritz Zipser. Gutachter: Ulf Ziemann ; Thomas Deller". Frankfurt am Main : Univ.-Bibliothek Frankfurt am Main, 2014. http://d-nb.info/105499143X/34.
Texto completoSchildt, Christopher J. "CLOSED-LOOP AFFERENT NERVE ELECTRICAL STIMULATION FOR REHABILITATION OF HAND FUNCTION IN SUBJECTS WITH INCOMPLETE SPINAL CORD INJURY". UKnowledge, 2016. http://uknowledge.uky.edu/cbme_etds/43.
Texto completoRonconi, Luca. "The deployment of visual attention in autism spectrum disorders". Doctoral thesis, Università degli studi di Padova, 2014. http://hdl.handle.net/11577/3423653.
Texto completoIl disturbo dello spettro autistico (DSA) è un disturbo neuroevolutivo pervasivo che colpisce quasi l'1% della popolazione. Una delle principali sfide nell'attuale ricerca sul DSA è definire i deficit neurocognitivi precoci che costituiscono le fondamenta dei disturbi "chiave" nelle abilità sociali e comunicative. In particolare, precoci disfuzioni attentive potrebbero giocare un ruolo decisivo nell'emergere del DSA. Nella presente tesi di dottorato presento sei studi che contribuiscono significativamente alla comprensione delle alterazioni dell'attenzione visiva nei DSA e le loro possibili basi neurali. Nel primo studio, mostriamo che gli individui affetti da DSA sono compromessi nell'abilità di allargare ("zoom-out") la dimensione del fuoco attentivo e che questo problema può avere un impatto negativo nell'orientamento rapido verso una posizione segnalata nel campo visivo. Il secondo e terzo studio mostrano come genitori senza alcuna storia clinica di DSA ma con elevati tratti autistici possano trasmettere ai loro infanti sottili alterazioni nell'attenzione visiva (a carico sia del meccanismo di orientamento che di quello di zoom) che possono avere conseguenze negative sul futuro sviluppo delle abilità socio-comunicative dei loro figli. Nel quarto e quinto studio, abbiamo utilizzato la stimolazione magnetica transcranica e l'elettroencefalografia ad alta densità, rispettivamente, in partecipanti adulti a sviluppo tipico e mostriamo che un network di aree frontali (principalmente FEF e IFG) e parietali (principalmente IPS/SPL) sono fondamentali nella regolazione della dimensione del fuoco attentivo. Nell'ultimo studio, abbiamo valutato il profilo spaziale del fuoco attentivo in individui con DSA e mostriamo come l'anulo inibitorio circostante al fuoco attentivo – fondamentale per attenuare il processamento d'informazioni irrilevanti – è significativamente più debole nel DSA rispetto al gruppo di controllo. Complessivamente, queste evidenze mostrano l'importanza dei deficit attentivi nelle manifestazioni chiave del DSA e nel suo decorso evolutivo. Definire le anomalie dell'attenzione e i corrispondenti correlati neurali è estremamente importante (i) per migliorare la diagnosi precoce del disturbo e (ii) per implementare tempestivi programmi preventivi mirati a ridurre l'incidenza dei DSA.
Cappon, Davide. "On the effects of transcranial alternating stimulation (tACS) on neuronal dynamics and cognition". Doctoral thesis, Università degli studi di Padova, 2018. http://hdl.handle.net/11577/3427258.
Texto completoAlcuni minuti in una piazza affollata di Londra permettono di apprezzare l'ampia gamma di azioni che gli esseri umani sono capaci di esprimere— camminare, leggere un libro, toccare lo schermo dello smartphone, mangiare, stringere la mano e attraversare la strada. L'inibizione della risposta è un meccanismo essenziale del controllo motorio dell'azione e rappresenta uno dei processi più studiati. Ad esempio, attraversare la strada quando inavvertitamente si avvicina una motocicletta a grande velocità potrebbe richiedere l'inibizione di mettere i piedi giù per evitare di essere feriti. Questa capacità di sopprimere rapidamente una risposta in un ambiente dinamico è stata tradizionalmente associata al controllo cosciente. In modo cruciale, recenti prove sperimentali hanno sfidato la concezione che il controllo inibitorio è limitato alle condizioni in cui gli stimoli sono accessibili alla consapevolezza cosciente. Tale attivazione inconscia e automatica del sistema motorio non necessariamente richiede che gli stimoli siano consapevolmente percepiti e si ritiene essenziale per agire in un ambiente in costante evoluzione. Questa attivazione è stata interpretata come un processo motorio basale che permette a meccanismi preparatori di sopprimere automaticamente un movimento attivato senza la necessità di processi cognitivi coscienti. Così, sebbene ci siano delle differenze tra i processi automatici e quelli volontari, tali processi potrebbero non avere rappresentazioni neurali completamente distinte. Infatti, il controllo motorio automatico sembra avere come substrato neurale il circuito corticale-ganglio basale che è stato associato al controllo motorio volontario. La ricerca contemporanea ha inoltre dimostrato che l’incremento delle oscillazioni beta nelle dinamiche del sistema corticale-ganglio basale può essere funzionalmente rilevante per l'inibizione del movimento. Di conseguenza, le oscillazioni beta sono state proposte come un meccanismo essenziale che consente al network motorio di comunicare in modo dinamico e flessibile. Nel frattempo, la ricerca attuale ha dimostrato che è possibile interagire con l'attività neuronale mediante tecniche di stimolazione cerebrale non invasiva (NIBS) come la stimolazione transcranica a corrente diretta (tDCS), la stimolazione transcranica a corrente alternata (tACS). In particolare, tACS consente la diffusione di corrente alternata a diverse frequenze ed è stata utilizzata per manipolare le oscillazioni cerebrali in modo controllabile. Comunque, questo concetto è ancora nelle fasi iniziali della ricerca e molto deve essere fatto per comprendere appieno i meccanismi sottostanti. Basandosi su queste scoperte, la ricerca presentata in questa tesi ha lo scopo di dimostrare un ruolo causale delle oscillazioni neurali beta sull’ inibizione inconscia e automatica, adottando la tACS sulla corteccia motoria primaria e l'area motoria supplementare. Inoltre, la combinazione di tACS con TMS e EEG mi ha permesso di caratterizzare i meccanismi di base della sua azione attraverso la misurazione dell’eccitabilità corticospinale e delle dinamiche oscillatorie neuronali. Nel complesso, questo lavoro contribuisce alla nostra comprensione del sistema motorio umano, offrendo al tempo stesso nuove conoscenze sull'approccio combinato di tACS e EEG nella caratterizzazione di un ruolo causale delle dinamiche oscillatorie neuronali sul comportamento.
D'AMBROSIO, SASHA. "SLEEPING WHILE AWAKE: A NEUROPHYSIOLOGICAL INVESTIGATION ON SLEEP DURING WAKEFULNESS". Doctoral thesis, Università degli Studi di Milano, 2020. http://hdl.handle.net/2434/707369.
Texto completoSleep and wakefulness are considered two mutually exclusive states. The alternation between those two states seems to be a defining characteristic of our life, a ubiquitous phenomenon demonstrated in every animal species investigated so far. However, during the last decade, advances in neurophysiology have blurred the boundaries between those states. The mechanisms of sleep have always intrigued neurophysiologists and great advances have been made over the last century in understanding them: we now know that the defining characteristic underlying sleep activity is a specific pattern of neuronal activity, namely the slow oscillation. The slow oscillation, which is characterized by the periodic alternation between periods of activity (ON-periods) and periods of hyperpolarization and neuronal silence (OFF-periods) is the default mode of activity of the sleeping cortex. This alternation is due to the tendency of neurons to fall into a silent period after an initial activation; such tendency is known as “bistability”. There is accumulating evidence that sleep-like bistability, and the ensuing OFF-periods, may occur locally in the awake human brain in some pathological conditions, in sleep transition, as well as after sleep deprivation. Therefore, to the extent that bistability and OFF periods represents the basic neuronal features of sleep, a paradigm shift is in place: from a neurophysiological perspective sleep can intrude into wakefulness. In this thesis, I explore the fluid boundaries between sleep and wakefulness and investigate their possible implications on the problem of personal persistence over time. Moreover, I study the clinical implications of the intrusion of sleep into wakefulness in patients with focal brain injury due to stroke. Specifically, I aim to: 1) show how the sleep-like bistability can be responsible for the loss of function in stroke patients. This may have implications for understanding the pathophysiology of stroke and helping to foster recovery; 2) establish the basis for a model of local sleep that might be present in the everyday life, id est the sensation of sleepiness. Indeed, sleepiness could reflect islands of sleep during wakefulness; 3) advocate the biological criterion of identity, in which the continuity necessary for maintaining ourselves over time could be represented by never resting activity in the brain.
Dugué, Laura. "Attentional and perceptual cycles : investigations using psychophysics, electroencephalography and transcranial magnetic stimulations : (cycles attentionnels et perceptuels)". Toulouse 3, 2013. http://thesesups.ups-tlse.fr/2184/.
Texto completoDo we experience the world continuously or as a discrete sequence of events, like samples of a video camera? This is the first question motivating my PhD work. Previous experiments have shown that visual information may be sampled periodically by attention, this processing being supported by oscillations in the EEG brain activity. In paper 1, using TMS, we were able to establish for the first time a causal relation between the phase of ongoing oscillations, brain excitation and visual perception. In another series of experiments, we explored the spatio-temporal behaviour of attention during visual search tasks. Using various experiments (papers 2 to 4) and various techniques (TMS, EEG, psychophysics), we brought convincing and converging evidence in favour of a periodic sampling of visual information by attention. Moreover, in paper 5, we were able to clarify an age-old debate concerning visual search tasks by ruling out the possibility that attention is distributed in parallel over all stimuli in the search array, suggesting a sequential processing of the different stimuli during the search. Overall, this PhD work gives strong arguments in favour of a periodic, and perhaps sequential, processing of visual information by attention
BOTTA, ALESSANDRO. "(e)motion: The interplay between emotional processing and the sensorimotor system". Doctoral thesis, Università degli studi di Genova, 2022. https://hdl.handle.net/11567/1096771.
Texto completoPISONI, ALBERTO. "Investigating the neural correlates of language production by means of TDCS". Doctoral thesis, Università degli Studi di Milano-Bicocca, 2014. http://hdl.handle.net/10281/52583.
Texto completoCRIVELLI, DAVIDE. "Agentività in interazione. Neuropsicologia delle affordances sociali". Doctoral thesis, Università Cattolica del Sacro Cuore, 2013. http://hdl.handle.net/10280/1736.
Texto completoSocial interactions require an agent to be able to select and process relevant environmental information, to be situated in a complex context and to interact with other agents, according to the opportunities and boundaries of that context. Sensing ourselves and detecting others as intentional agents is a crucial step for the overall social understanding process and, in particular, for our ability to perceive others’ intentions and goals. Those social skills foster our physical, cognitive and affective development by promoting adaptive interactions. Consequently, a dysfunction of such skills can seriously affect the autonomy and quality of life. A distributed system is thought to subserve the perception of agency and others’ mental states, but the internal structure of processes that constitute our ability to understand our similars and interact adequately is still largely unknown. This project aimed at investigating early stages of those processes and, in particular, the initial elaboration of social cues (social affordances) for the detection of agentivity and opportunities for interaction in social situations. It is structured in three main empirical studies: the first one aimed at looking electrophysiological correlates (ERPs and source localization data) of visual information processing for the detection of agency in interactions; the second one aimed at looking for possible markers (ERPs) of the uneven profile of basic WS social understanding; the third one tested the causal role of rTPJ in mediating pre-reflective processing of agency and intentionality from observed behaviour by means of TMS.
CRIVELLI, DAVIDE. "Agentività in interazione. Neuropsicologia delle affordances sociali". Doctoral thesis, Università Cattolica del Sacro Cuore, 2013. http://hdl.handle.net/10280/1736.
Texto completoSocial interactions require an agent to be able to select and process relevant environmental information, to be situated in a complex context and to interact with other agents, according to the opportunities and boundaries of that context. Sensing ourselves and detecting others as intentional agents is a crucial step for the overall social understanding process and, in particular, for our ability to perceive others’ intentions and goals. Those social skills foster our physical, cognitive and affective development by promoting adaptive interactions. Consequently, a dysfunction of such skills can seriously affect the autonomy and quality of life. A distributed system is thought to subserve the perception of agency and others’ mental states, but the internal structure of processes that constitute our ability to understand our similars and interact adequately is still largely unknown. This project aimed at investigating early stages of those processes and, in particular, the initial elaboration of social cues (social affordances) for the detection of agentivity and opportunities for interaction in social situations. It is structured in three main empirical studies: the first one aimed at looking electrophysiological correlates (ERPs and source localization data) of visual information processing for the detection of agency in interactions; the second one aimed at looking for possible markers (ERPs) of the uneven profile of basic WS social understanding; the third one tested the causal role of rTPJ in mediating pre-reflective processing of agency and intentionality from observed behaviour by means of TMS.
Hurdal, Monica Kimberly. "Mathematical and computer modelling of the human brain with reference to cortical magnification and dipole source localisation in the visual cortx". Thesis, Queensland University of Technology, 1998.
Buscar texto completoFarzan, Faranak. "Inhibition of Gamma Oscillations in Healthy Subjects and Patients with Schizophrenia". Thesis, 2010. http://hdl.handle.net/1807/26355.
Texto completoFernandes, Tiago José Cardoso Pires Timóteo. "TMS-EEG combined with granger causality: an innovative information flow approach over the full brain connectivity". Master's thesis, 2015. http://hdl.handle.net/10451/20724.
Texto completoAtualmente, no mundo das neurociências, a conectividade cerebral é um tema em destaque. Este conceito encontra-se dividido em conetividade estrutural (relações anatómicas entre estruturas cerebrais), conectividade funcional (dependências estatísticas entre estruturas cerebrais) e conectividade efetiva (relações de causalidade entre estruturas cerebrais). Esta tese debaterá fundamentalmente sobre o último destes conceitos, tentando oferecer uma interpretação para o fluxo de informações entre as áreas do cérebro. Muitas técnicas podem ser utilizadas na sua análise, entre os quais a Causalidade de Granger (GC) ou a estimulação magnética transcraniana em combinação com eletroencefalografia (TMS-EEG). Por um lado, a GC permite uma interpretação das ligações diretas dentro e fora das mesmas áreas cerebrais, sendo uma abordagem explicativa sobre os dados, onde não é necessária nenhuma hipótese sobre o comportamento das relações causais. No entanto, os resultados de GC são muito sensíveis, uma vez que dependem de sinais não-estacionários e não colineares, aspetos bastante presentes em sinais de eletroencefalografia (EEG). Desta forma, a qualidade dos resultados de causalidade irá sempre depender da qualidade do pré-processamento do sinal original, onde se tenta ao máximo reduzir o seu efeito tentando não alterar os padrões de conectividade artificialmente. Por outro lado, TMS é uma técnica que permite que a estimulação do cérebro através da despolarização de certas populações de neurónios, criando uma "onda" de propagação ao longo do cérebro, de acordo com o local de estimulação e as suas ligações fisiológicas. Estes sinais são medidos através de sistemas de EEG, fazendo de TMS-EEG uma poderosa ferramenta nos estudos de conectividade efetiva, uma vez que permite criar estados independentes da intenção consciente da pessoa, garantindo um acompanhamento abrangente da sua propagação. A combinação destas duas ferramentas poderosas (GC e TMS-EEG) permitirá uma abordagem inovadora no desenvolvimento do conhecimento relativo à conectividade efetiva no cérebro. É com essa intenção que esta tese foi desenvolvida, tendo criado uma ferramenta computacional que permita medir e inferir padrões de conectividade efetiva através da combinação de TMS-EEG com GC. Sendo uma abordagem pioneira, a tese foi estruturada para que inicialmente se desenvolvessem garantias relativas a que uma redução nos efeitos ambíguos da GC, como a não-estacionaridade e não-colinearidade dos sinais de EEG, não afetasse a qualidade dos resultados de causalidade, ou que minimizasse a sua dependência dos métodos de pré-processamento. Portanto, este projeto visa, em primeiro lugar encontrar respostas na abordagem da GC, tanto para as suas limitações como para os seus parâmetros, permitindo que, posteriormente, houvesse uma otimização da análise de dados de TMS-EEG. Nesta primeira fase, os testes foram realizados com dados simulados. Só numa segunda fase é que, o objetivo principal a que esta tese se propunha, foi alcançado. Para isso foi criada uma toolbox em Matlab (Effective Connectivity test Toolbox - ECt) permitindo uma combinação compatível de GC com TMS-EEG. Esta projeto tentou validar esta toolbox para que se torne uma ferramenta futura para estudos de conectividade cerebral. Sendo um pouco mais específico, na primeira fase, foi encetada uma comparação entre os métodos de estimadores de conectividade do cérebro. A tradicional implementação de GC foi comparada com um método inovador de combinar a modelação fatorial com a GC (FM-GC), e com duas aplicações de transferência de entropia (onde dois métodos de estimadores de entropia foram utilizados – Binning Estimator e k-Nearest Neighbor). Esta abordagem mostrou que, perante os dados simulados criados, a GC se adaptou melhor tanto ao ruído implementado no sistema, comprovando ser o método com maior sensibilidade e especificidade. Provou-se também que para condições reais de EEG, nomeadamente número de pontos por trecho (512) e o número de ensaios (1 ensaio) a utilizar, GC verificou valores de falsos positivos menores comparativamente com os outros métodos. De seguida foram consideradas e testadas soluções que permitissem suavizar os efeitos da não-estacionariedade e colinearidade nos resultados da GC, tentando perceber novamente o desempenho deste método em dados simulados. Relativamente aos métodos de não-estacionaridade, o demean e o detrending foram implementados sendo que foi também analisada a capacidade de redução da presença de ‘raízes unitárias’, conduzindo à atenuação da não-estacionaridade, através do Augmented Dickey-Fuller (ADF). Este protocolo foi aplicado em dois tipos dados simulados – estacionários e não-estacionários. Foi também analisada a possibilidade de tornar os modelos autorregressivos (MVAR) mais estáveis através da conjugação de vários ensaios. Relativo ao primeiro teste pouca diferença foi verificada, no entanto conclui-se que inclusão desses métodos (demeaning & detrending) deveria ser introduzida na pipeline de pré-processamento. Relativamente à segunda etapa provou-se a eficácia de um aglomerar de ensaios sendo que o valor que otimizava essa estabilidade era de 5 ensaios. Por fim, testaram-se e debateram-se métodos que reduzissem a colinearidade e o overfitting do modelo. Relativo ao problema de colinearidade foi debatido, com base nas referências bibliográficas, que a implementação de uma solução para o problema inverso (encontrar matematicamente as fontes de sinal de EEG) seria necessário para remover essa ambiguidade. Sendo que a escolha recaiu sobre a análise de componentes independentes (ICA), assumindo que cada componente independente assegura o comportamento de uma fonte de sinal elétrico no cérebro. Relativamente ao overfitting verificou-se apenas, num sinal simulado de ERP, que com o acrescer de sensores (variáveis) existe um aumentar de parâmetros que traduzem o overfitting como, os coeficientes de correlação (relação diretamente proporcional) ou as intensidades máximas de GC (que foram otimizadas para um número de sensores entre 15 e 20). Na segunda parte do projeto, e de forma a responder ao objetivo principal, foi realizada uma experiência de TMS-EEG, que por um lado permitisse garantir dados realistas e provenientes dessa modalidade, como por outro que permitisse validar as mais-valias da toolbox ECt. Nesse âmbito, foram realizadas, a seis sujeitos, duas condições, uma estimulação real de TMS e uma inovadora estimulação sham, que foram repetidas cercas de 200 vezes. Em ambos os casos, o foco esteve no período de repouso (rs) entre os pulsos de TMS. Nestas condições, foi possível tentar validar a eficácia da ECt, pois no período de repouso após um pulso de TMS o comportamento de ambas as condições era suposto de ser idêntico, não se esperando mudanças ao nível da conectividade. Isto levou a formular a hipótese de que quando comparando as duas condições, estatisticamente os resultados não seriam significativamente diferentes. Colocada a hipótese, estruturou-se a toolbox em três pontos. O primeiro recaiu sobre os métodos de pré-processamento. Este abordou aspetos relativos ao tratamento dos dados de EEG recolhidos, onde se procedia a uma correção da baseline, procedia a uma redução da frequência de amostragem, se concatenavam os dados de todos os sujeitos para que posteriormente a abordagem de ICA fosse mais coerente. No segundo ponto debateu-se a aplicação do método da GC, onde se realizaram procedimentos como: estimar a ordem do modelo, estimar o modelo MVAR e, posteriormente, calcular os índices de GC. O último ponto incidiu sobre uma abordagem estatística inovadora de três níveis de análise. O primeiro pretendia validar os resultados de GC dentro de um sujeito e de uma das condições, através de uma análise estatística dos resultados de GC contra um surrogate (teste inverso de granger - RGT). O segundo nível pretendia comparar os resultados de GC entre condições dentro de um sujeito (Maximum permutation statistics). Por último, o terceiro nível tinha como objetivo comparar os valores de GC entre condições e sujeitos (t-test paralelo). Os resultados permitiram, numa primeira fase, verificar que os métodos de pré-processamento permitiram a redução de conectividade espúria, uma vez que 10 em 12 (2 condições vezes 6 sujeitos) dos conjuntos de dados preservaram mais de 60% dos ensaios sobrevivendo às restrições impostas pelo modelo. Considerando os resultados estatísticos obtidos, e tendo em consideração a falta de sujeitos (apenas 6 indivíduos), eles parecem ser promissores já que não existe uma expressão significativa nas matrizes de causalidade quando comparadas no segundo nível de análise estatística (Comparação de um sujeito entre condições), onde apenas 9% das ligações possíveis foram estatisticamente significativas. Relativamente ao último nível de análise os resultados não mostram qualquer inferência significativa entre variáveis, muito provavelmente devido ao fraco poder estatístico (apenas 6 sujeitos) do procedimento realizado. Para concluir, todos os aspetos considerados e discutidos nesta tese, relativos tanto a esta teoria como a esta toolbox podem e deveram ser consideradas como um primeiro passo, visto que este projeto visou criar uma base para o estudo da conectividade efetiva em protocolos de TMS. No futuro pode permitir abrir a porta à compreensão da complexidade da estrutura de causalidade e dinâmica do sistema cerebral.
Brain connectivity is a ‘hot’ topic these days in neuroscience. One of its branches is the effective connectivity, which intends to offer an interpretation for the information flow across brain areas. Many techniques can be used, between which Granger Causality (GC) and transcranial magnetic stimulation in combination with electroencephalography (TMS-EEG) have a prominent position. On one hand GC allows an interpretation of direct connections among brain areas, being an explanatory approach over the data, where no assumptions regarding the behavior of the causal relations are needed. However, several issues affect the results of GC, since they have to be contained over the restrictions of the model (i.e. non-stationarity and colinearity) and they are highly affected by spurious causality making the statistical reliability tenuous. On the other hand, TMS is a brain stimulation technique that allows the depolarization of populations of neurons, creating a ‘wave’ of propagation over the brain, according to the place of stimulation and its physiological connections. When these waves are measured with an EEG system, a combination of TMS-EEG is made. Such technique can become a powerful tool in connectivity studies. Uniting these two powerful tools (GC and TMS-EEG) should allow a new and innovative approach to measure effective connectivity in the brain. However, as yet, no study was made coupling these two methods. Therefore this project aims firstly to find answers in the GC approach for both its limitations and its parameters, allowing for the optimizations of the further TMS-EEG data analysis with GC. Secondly, and as a major goal, to create a Matlab toolbox (Effective Connectivity test - ECt), that allows the compatible combination of GC with TMS-EEG, making possible to use it as a future tool for brain connectivity studies. In the first phase, a comparison between methods of brain connectivity estimators was made (GC was compared with: Factor Modelling combined with GC, and with Transfer Entropy), showing that GC outperformed others. It was also taken into account and tested solutions for the non-stationarity and colinearity of the data over simulated data. Such procedure allowed to select specific GC parameters such as, number of ensemble trials, data length and number of variables. In a second part of the project, a TMS-EEG experiment was performed. Two conditions were recorded, a real TMS stimulation and a groundbreaking sham stimulation. The focus was on the resting state (rs) period in between the TMS pulses, because in a single pulse stimulation on the rs no changes in terms of connectivity were expected. Thus, this procedure allowed to validate the toolbox on recorded data by comparing such two conditions. An innovative pre-processing and statistical approach on the GC was implemented and validated, allowing the reduction of spurious connectivity. Considering the results, having in considerations the lack of subjects (only 6 subjects), they look promising since no big effect is seen (less than 9% of connections are significant) over the statistical analysis. All things considered, the toolbox, techniques here discussed and its premises, can be considered as a first step into measuring effective connectivity with a coupling of two techniques such as TMS-EEG and GC. In the future this might lead to a better understanding of the structure complexity and system dynamics of the brain.
Esser, Steven Kyle. "Investigating cortical connectivity and plasticity with TMS/EEG and computer modeling : implications for sleep and consciousness /". 2008. http://www.library.wisc.edu/databases/connect/dissertations.html.
Texto completoMolteni, Federica. "A TMS-EEG study on the modulation of perceptual bias in the right Posterior Parietal Cortex". Doctoral thesis, 2017. http://hdl.handle.net/11562/965152.
Texto completoThe right posterior parietal cortex (rPPC) is involved in visuo-spatial processing, as neglect patients (Vallar, 1998) and TMS studies revealed (Fierro et al., 2000; Bjoertomt et al., 2002; Ellison et al., 2004; Fierro et al., 2006; Ricci et al., 2012). Within this framework, one of the most frequently used research tasks is the Landmark Task (LT, Milner et al., 1992, 1993), a line bisection judgments task whose neural correlates are well known (Fink et al., 2000, 2001; Ҫiҫek et al., 2009). Remarkably, it affords to disentangle perceptual and response biases (Bisiach et al., 1998). Given this background, by combining EEG and TMS, we want to investigate the behavioral (i.e. modulation of perceptual bias, PB) and neurophysiological (i.e. brain activity changes) effects of single pulse TMS over rPPC. The experiment followed the subsequent steps: (i) hunting procedure (Salatino et al., 2014), delivering ten single pulses for each of the 9 points of a grid centrally located over P6, while the subject was performing the LT; (ii) administration of the LT while recording EEG with (TMS ON) and without (TMS OFF) stimulation of the parietal hotspot. In both conditions, symmetrically and asymmetrically bisected lines were used. Participants were divided in three different groups depending on the modulation of the PB on the TMS ON condition as compared with the TMS OFF condition: the Neglect-like bias group (n=16, PB TMS ON> PB TMS OFF), the Pseudoneglect-like bias group (n=14, PB TMS ON< PB TMS OFF), and the No Bias group (n=14, PB TMS ON= PB TMS OFF). We also performed a spatiotemporal analysis on the difference between asymmetrical vs symmetrical lines for the TMS ON and the TMS OFF conditions, separately on each groups (Groppe et al., 2011a & 2011b). In an early stage of processing we have found a significant effects in O2 and P8 electrodes in the TMS OFF condition in two groups (Pseudoneglect and No Bias), that was still present, in the same sites, in the TMS ON condition only for the No Bias group. Later in time there was a significant interaction effect of the TMS condition on the type of stimuli for only the No Bias group in the electrodes of the left hemisphere. Finally, between 200 and 430 ms, in all the groups, the difference waves were significant in almost all electrodes. The present data thus show that rPPC is involved in magnitude estimation of line length. Generally we could conclude that the TMS induces different type of modulation of PB. Indeed TMS could not modulate the PB in a group of participants (No bias), probably due to preexisting differences between participants, as our results in the early time window in the TMS OFF condition would suggest. One possibility is that the effects of the TMS are determined not only by the properties of the stimulus or by the TMS itself, but also by the state of the cortex during the task execution (Silvanto & Pascual-Leone, 2008). These results seem to suggest that our groups are different in the perceptual processing of the stimuli. Recently we are testing differences between groups. These would help us to clarify if, at a neural level, the no bias group is significantly different from the neglect and pseudoneglect like bias group. We are also trying to better understand the pre-existing difference found in our participants.
Kötter, Thomas [Verfasser]. "Das Phänomen der umgekehrten Bahnung : neue Erkenntnisse durch den Einsatz transkranieller Magnetstimulation ; eine EEG-basierte TMS-Studie / vorgelegt von Thomas Kötter". 2007. http://d-nb.info/984795987/34.
Texto completoDEL, FELICE Alessandra. "Innovative research techniques applied to sleep: an insight into sleep patophysiology". Doctoral thesis, 2013. http://hdl.handle.net/11562/555150.
Texto completoAs has been stated, we have gained more knowledge on sleep physiology in the last 60 years than in the previous 6000 (Hobson, 1989). This holds true thanks to the massive advances technologies have provided in the past century, ranging from the introduction of electroencephalogram (EEG) in the twenties of the last century by Berger to the latest optogenetic approaches (Adamantidis et al., 2013). The major change put forward by this more detailed understanding of sleep function and functioning has been the transition of sleep as a state of absolute inertia, paralleled to death by almost all the ancient literature, to a reactive state of the brain: during sleep, cerebral activity presents its most diverse expressions, from the bold slow waves sleep of the deep stages to the wake like activity of REM associated with muscular atonia, and is able to differently react to external perturbations with rapid frequency shifts (Terzano and Parrino, 2000). Moreover, the modulations that sleep and sleep deprivation exert have been postulated deriving both from plain clinical observations, i.e. in epilepsy, and from animal studies. Sleep deprivation is the best method for provoking EEG epileptiform abnormalities and seizures (Bennett, 1963; Pratt et al., 1968; Jovanovic, 1991; King et al., 1998) in most types of epilepsy (Dinner, 2002), and many epileptic syndromes, such as the generalized idiopathic epilepsies (IGE), are prone to circadian fluctuations related to the sleep-wake cycle - with seizures gathering mostly early in the morning or at awakening (Niedermeyer et al., 1985). The mechanisms underlying the activation of paroxysmal activity remain to be elucidated. The activation of epileptic patterns has been attributed to drowsiness and sleep (Pratt et al., 1968), while sleep deprivation has been shown to have a specific activating effect on patients who remain awake during recording (Naitoh and Dement, 1974). In animals, sleep deprivation results in a lowering of the threshold for electroshock convulsions (Cohen and Dement, 1965) and kindling (Shouse, 1988) due to a shift in the balance between excitatory and inhibitory neurotransmitters (Naitoh and Dement, 1974). But while animal studies deploy invasive techniques, as did the pioneer physiology studies by (Bremer 1935 and 1936; Moruzzi and Magoun, 1949) that allowed the definition of cerebral and truncal structures involved in sleep building-up and maintenance and their neurotransmitters, growing concerns about in vivo animal studies have pushed towards other research methods, that moreover could be applied to the human being too. Indeed, one of the major limitations in the field of sleep research up to the last decades was determined by the only available technique applicable in humans - electroencephalogram. Since the eighties of the last century, a series of technological advances introduced in clinical practice Magnetic Resonance Imaging (MRI). MRI permits not only a more detailed visualization of brain structures than those of previous neuroimaging, such as computed tomography (CT) scanning, but also, due to the implementation of new acquisition sequences and analysis procedures, the identification of blood oxygenation level dependent (BOLD) activations. The latter consists of a cerebral area in which any sort of metabolic process is going on, in a frame time of a few seconds, and is generally related to areas active due to a given task. The serendipitous observation that persistent BOLD activated areas are present also in the idling brain led to the proposal of the concept of a default mode network (DMN), that is, a series of possibly interconnected cerebral regions that switch on in the very moment any brain engagement is supposed to switch off (Raichle et al., 2001). The persistence of an analogous pattern also during sleep led to the hypothesis of this network to be the neural substrate of mentation and perhaps consciousness. Further improvements in the mathematical models that support BOLD signal analysis were subsequently able to disentangle the various components of the this “resting brain activity”, generating an array of so called resting state networks (RSNs) (Rosazza and Minati, 2011) that encompass diverse physiological functions. A step further was possible with the introduction, almost 15 years ago, of MRI compatible EEG equipment that prevents the generation of oddy currents inside the electrode: the concomitant EEG registration with an MRI scan permits to relate a particular EEG activity with the underlying BOLD signal. The same magnetic field shielded electrodes were later on exploited in the contest of electro-magnetic fields generated through wires rolled into a coil, that were presented by Baker in 1985 as transcranial magnetic stimulation (TMS). TMS final effect is that of electrically stimulating the superficial layers of the cortex, and EEG-TMS co-registration offered the chance to investigate the direct effect of a pulse on the cortex (Ilmoniemi et al., 1997) by removing possible interferences from the descending motor pathways, that were intermixed in the standard parameter by which TMS alone is evaluated - the motor evoked potential (MEP) recorded from a muscle corresponded to the cortical activated area (Groppa et al., 2012). The perturbation TMS induces on the cerebral activity can also be studied as the modulation of EEG rhythms (Thut and Miniussi, 2009), that react differently depending on the stimulating paradigm (Manganotti and Del Felice, 2012) or on the intrinsic brain rhythm or stimulus frequency (Thut et al., 2012). The last technological innovation I am going to describe has been developed over the last decade: the introduction of high-density scalp EEGs (hdEEG), with up to 256 electrodes spread out over the scalp, the occiput and the cheeks of the subject, that offers a much higher spatial resolution than standard EEG caps. This high spatial resolution sampling has revived an older analysis method aimed at identifying via a mathematical approach called the inverse solution method the number, location and orientation of deep generators of scalp activity, the so called electrical source imaging (ESI) (Fender, 1987; Brunet et al., 2011). ESI involves numerous scalp electrodes, HdEEG , and realistic head models derived from structural MRI, and has so far mainly been applied to epileptic discharges (Scherg and Von Cramon, 1985, Liu et al., 1998, Babiloni et al., 2003, Michel et al., 2004), with only few reports in sleep (Siniatchkin et al., 2010). The aim of this dissertation thesis is to discuss the application of these technologies to the clarification of open issues in sleep physiology and pathophysiology. A first approach was to study the effects of sleep deprivation on cortical excitability through EEG-TMS co-registration experiments, both in healthy controls and in the frame of pathologically abnormal cortical excitability (i.e. epilepsy). A second set of experiments focused on fMRI data of subjects sleeping in the bore of the scanner during a concomitant external perturbation – an electrical stimulation at the wrist in the specific case. Finally, the potentiality of ESI has been applied to physiological sleep figures, in order to contribute to the open issue of their generators’ nature. A similar study design was also used in a population of focal epileptic patients, given the still actual debate over the relation of sleep figures and epileptic spikes. These techniques encompass different neurophysiological aspects providing a multiprospective view of sleep phenomena. The translation of such an approach to other states of reduced consciousness (i.e. vegetative or minimally conscious states) should be one of the future directions of research.
Bagattini, Chiara. "Neural correlates of visual and spatial awareness". Doctoral thesis, 2014. http://hdl.handle.net/11562/710361.
Texto completoThis PhD thesis focuses on attempting to experimentally investigate the neural correlates of awareness related to visual and spatial perception in humans. Specifically, this project aimed at looking into the electrophysiological markers of awareness in normal conditions and when awareness is lost due to a real or a “virtual” lesion. In both the studies conducted we adopted a causal multimodal approach, namely Transcranial Magnetic Stimulation and EEG (TMS-EEG) co-registration, which can provide insights into the neural correlates of visual and spatial awareness. The first study focuses on spatial awareness and specifically on the investigation of the mechanisms underlying neglect syndrome. Neglect is defined as a disorder of consciousness in which patients fail to report, respond to, or orient to stimuli presented on the opposite side of the brain lesion. One of the most influential models to explain the dysfunction underlying this syndrome takes into account the concept of inter-hemispheric rivalry, which postulates a pathological hyperactivation of the unaffected hemisphere due to the reduced inhibitory influences from the lesioned hemisphere. The aim of the present study is to test these models analyzing the effect that low frequency repetitive TMS (rTMS) exerts on the stimulated and contralateral hemispheres in the processing of visual stimuli. Specifically we aim at assessing the contribution of left and right parietal cortices in an impaired neglect-like functioning induced by means of low frequency rTMS in healthy participants. Fourteen healthy volunteers performed a Line Bisection task and a simple detection task of unilateral checkerboards stimuli. Both tasks were performed either before and after 30 minutes of low frequency rTMS (1 Hz) over the right posterior parietal cortex. The EEG signal was continuously recorded throughout the experiment. The efficacy of rTMS in inducing neglect-like phenomena was confirmed by the results of the Line Bisection task where participants showed a rightward deviation after rTMS, a performance comparable to that of neglect patients. Detection task results showed that the effect of rTMS was a lengthening of reaction times for both left and right visual stimuli and a reduction of the amplitude of P200 component registered both on left and right parietal sites. TMS-evoked potentials recorded during 30 minutes of stimulation, showed that low frequency rTMS induced a reduction of cortical excitability both of the stimulated right parietal cortex and of the left contralateral homologous area. Therefore, our results did not show a hyperactivation of the left hemisphere due to the inhibition of the right hemisphere (as theorized by “rivalry models”). Conversely, the inhibition of the right parietal cortex induced a spreading of the inhibition to the homologous area of the left hemisphere. The second study focuses on visual awareness and specifically aimed at investigating the neural correlates of phosphene perception. Single-pulse TMS of the visual cortex is known to induce visual sensations, i.e. phosphenes, which appear as brief flashes of light without light actually entering the eyes. Recent studies have shown that TMS can produce visual sensations not only when it is applied over early visual areas but also when parietal cortex is stimulated. As the pivotal neural basis involved in the perception of parietal phosphenes still remain unknown, the main question is whether parietal phosphenes are generated directly by local mechanisms or emerge through indirect activation of other visual areas. To characterize the electrophysiological correlates of occipital and parietal phosphene perception we investigated TMS-evoked potentials in a sample of healthy participants by comparing trials in which a phosphene was perceived with trials in which no visual percept was reported. When the left occipital cortex was stimulated, phosphene perception started to affect TMS-evoked potentials at a late latency, whereas phosphenes elicited by left parietal cortex stimulation modulated TMS-evoked potentials at an earlier latency. This difference in the time-course of cortical activation between occipital and parietal phosphenes could underlie a different mechanism in their generation. The early latency of the phosphene effect observed when TMS was applied over the parietal cortex might suggest that parietal phosphenes should be considered as the direct result of the activation of the stimulated area, rather than the consequence of a feedback activation of the early visual cortex. Furthermore, we investigated electrophysiological correlates of parietal phosphene perception in a hemianopic patient (SL) who suffered from a complete destruction of the left primary visual cortex. Ipsilesional parietal phosphene perception in patient SL showed a similar pattern of results to that of parietal phosphene perception in healthy participants, starting to affect TMS-evoked potentials at an early stage of latency. This evidence might thus support the idea of parietal cortex as an independent generator of magnetically induced conscious visual experiences.
"Auditory processing and motor systems: EEG analysis of cortical field potentials". Tulane University, 2013.
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Kietzmann, Tim Christian. "Aspects of Object Recognition: Sampling, Invariance, and Plasticity". Doctoral thesis, 2015. https://repositorium.ub.uni-osnabrueck.de/handle/urn:nbn:de:gbv:700-2015051213203.
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