Global ETD Search

11	Modulation of neuronal excitability in the cognitive control network by electrical stimulation Lehr, Albert 14 May 2020 (has links) No description available. 570 dorsal anterior cingulate cortex dorsolateral prefrontal cortex Stroop task instrumental learning Biologie (PPN619462639)
12	EEG study on the differences between lean and obese individuals during regulation of food desire Kumar, Saurabh 21 November 2017 (has links) No description available. info:eu-repo/classification/ddc/610 ddc:610
13	The Influence of non-invasive Prefrontal/Frontal Brain Stimulation on Food Reappraisal Abilities and Calorie Consumption in Obese Females Grundeis, Felicitas 25 November 2019 (has links) Previous studies suggest that non-invasive transcranial direct current stimulation (tDCS) applied to the prefrontal cortex modulates food choices and calorie intake in obese humans. In a fully randomized, placebo-controlled, within-subject and double-blinded study, we applied single sessions of anodal, cathodal, and sham tDCS to the left dorsolateral prefrontal cortex (DLPFC) and contralateral frontal operculum in 25 hungry obese women and investigated possible influences on food reappraisal abilities as well as calorie intake. We hypothesized that tDCS, (i) improves the ability to regulate the desire for visually presented foods and, (ii) reduces their consumption. We could not confirm an effect of anodal or cathodal tDCS, neither on the ability to modulate the desire for visually presented foods, nor on calorie consumption. The present findings do not support the notion of prefrontal/frontal tDCS as a promising treatment option for obesity.:1. Introduction 1.1 Obejective of investigation 1.1.1 Obesity 1.1.2 Homeostasis versus hedonism? 1.1.3 Regulating the desire to eat 1.1.4 Obesity and the brain 1.2 Previous studies 1.2.1 EEG study 1.2.2 Buffet study 1.3 Transcranial direct current stimulation (TDCS) 1.4 TDCS study 2 Publication 3 Summary of work 3.1 Data Acquisition ans analysis 3.2 Results and discussion 3.2.1 Absence of evidence is not evidence of absence 3.2.2 Multifactorial influence on behavior 3.2.3 Limitations of study design 3.2.4 Limitations of method 3.3 Outlook 4 References 5 Attachments 5.1 Academic contribution 5.2 Erklärung über die eigenständige Abfassung der Arbeit 5.3 Einreichungserklärung 5.4 Curriculum vitae 5.5 Publications 5.6 Acknowledgements info:eu-repo/classification/ddc/610 ddc:610
14	Emotional processing of natural visual images in brief exposures and compound stimuli : fMRI and behavioural studies Shaw, Lynda Joan January 2009 (has links) Can the brain register the emotional valence of brief exposures of complex natural stimuli under conditions of forward and backward masking, and under conditions of attentional competition between foveal and peripheral stimuli? To address this question, three experiments were conducted. The first, a behavioural experiment, measured subjective valence of response (pleasant vs unpleasant) to test the perception of the valence of natural images in brief, masked exposures in a forward and backward masking paradigm. Images were chosen from the International Affective Picture System (IAPS) series. After correction for response bias, responses to the majority of target stimuli were concordant with the IAPS ratings at better than chance, even when the presence of the target was undetected. Using functional magnetic resonance imaging (fMRI), the effects of IAPS valence and stimulus category were objectively measured on nine regions of interest (ROIs) using the same strict temporal restrictions in a similar masking design. Evidence of affective processing close to or below conscious threshold was apparent in some of the ROIs. To further this line of enquiry, a second fMRI experiment mapping the same ROIs and using the same stimuli were presented in a foveal (‘attended’) peripheral (‘to-be-ignored’) paradigm (small image superimposed in the centre of a large image of the same category, but opposite valence) to investigate spatial parameters and limitations of attention. Results are interpreted as showing both valence and category specific effects of ‘to-be-ignored’ images in the periphery. These results are discussed in light of theories of the limitations of attentional capacity and the speed in which we process natural images, providing new evidence of the breadth of variety in the types of affective visual stimuli we are able to process close to the threshold of conscious perception. 612.8
15	Oscillatory Network Dynamics in Perceptual Decision-Making Chand, Ganesh 17 December 2015 (has links) Synchronized oscillations of ensembles of neurons in the brain underlie human cognition and behaviors. Neuronal network oscillations can be described by the physics of coupled dynamical systems. This dissertation examines the dynamic network activities in two distinct neurocognitive networks, the salience network (SN) and the ventral temporal cortex-dorsolateral prefrontal cortex (VTC-DLPFC) network, during perceptual decision-making (PDM). The key nodes of the SN include the right anterior insula (rAI), left anterior insula (lAI), and dorsal anterior cingulate cortex (dACC) in the brain. When and how a sensory signal enters and organizes within the SN before reaching the central executive network including the prefrontal cortex has been a mystery. Second, prior studies also report that perception of visual objects (face and house) involves a network of the VTC—the fusiform face area (FFA) and para-hippocampal place area (PPA)—and the DLPFC. How sensory information enters and organizes within the VTC-DLPFC network is not well understood, in milliseconds time-scale of human’s perception and decision-making. We used clear and noisy face/house image categorization tasks and scalp electroencephalography (EEG) recordings to study the dynamics of these networks. We demonstrated that beta (13–30 Hz) oscillation bound the SN, became most active around 100 ms after the stimulus onset, the rAI acted as a main outflow hub within the SN, and the SN activities were negatively correlated with the difficult tasks. We also uncovered that the VTC-DLPFC network activities were mediated by beta (13-30 Hz) and gamma (30-100 Hz) oscillations. Beta activities were enhanced in the time frame 125-250 ms after stimulus onset, the VTC acted as main outflow hub, and network activities were negatively correlated with the difficult tasks. In contrast, gamma activities were elevated in the time frame 0-125 ms, the DLPFC acted as a main outflow hub, and network activities—specifically the FFA-PPA pair—were positively correlated with the difficult tasks. These findings significantly enhance our understanding of how sensory information enters and organizes within the SN and the VTC-DLPFC network, respectively in PDM. Electroencephalography (EEG) Neuronal oscillations Perceptual decision-making Salience network (SN) Fusiform face area (FFA) Parahippocampal place area (PPA) Dorsolateral prefrontal cortex (DLPFC)
16	Modulação da orientação temporal e espacial da atenção por meio de estimulação transcraniana por corrente contínua Araujo, Ricardo Rafael de 25 February 2011 (has links) Made available in DSpace on 2016-03-15T19:39:42Z (GMT). No. of bitstreams: 1 Ricardo Rafael de Araujo.pdf: 639007 bytes, checksum: 913741be473f0be64fda69ad9172445d (MD5) Previous issue date: 2011-02-25 / Fundo Mackenzie de Pesquisa / Attention can be understood as a set of neural mechanisms that enhance the processing of relevant information, thoughts or actions while ignoring irrelevant or scattered stimuli. Thus, attention allows the organism to interact in a proper way with the environment. Among the brain structures associated with the control of attention, the Dorsolateral Prefrontal Cortex (DLPFC) has a remarkable role in current literature as a region associated with behavioral control. Transcranial Direct Current Stimulation (TDCS) is based on the application of a low intensity electric current through electrodes placed in the scalp, aimed at modulating the activity of different brain areas. This technique has been used to study brain functions. This study has the objective of verifying how attention can be modulated through the application of bilateral tDCS on DLPFC using measures of reaction time (RT) in tasks of temporal and spatial orientation. To accomplish that, two experiments were planned and executed. In the first one, which focused on the voluntary orienting of spatial attention, each participant had to orient attention to the position indicated by an arrow; in the second, on voluntary orienting of temporal attention, each participant had to orient attention to the most frequent time interval of visual targets. In both cases, participants had to respond as fast as possible when the target was displayed by pressing a joystick key. RTs were registered. The sample was composed of 18 undergraduate students, age range 19-25 years old (12 for the first experiment and 6 more for the second). In each experiment, subjects were submitted to three tDCS conditions (anodal, cathodal and sham) on the DLPFC during the undertaking of tests. Analyses of variance were made, in order to compare the involved factors. For the experiment of spatial orientation, the anodal condition produced lower RTs, when compared to sham. For the temporal orienting experiment it was observed that, in the anodal modulation, RTs were increased for the less frequent interval (500 ms), indicating that the anodal tDCS can have influenced in a more effective way attentional orienting to the most frequent intervals. Therefore it is possible to postulate the existence of a facilitating effect of anodal tDCS in the modulation of DLPFC, which generated an impact in attentional orienting, lowering RTs to the valid condition (spatial) when compared to sham tDCS. / A atenção pode ser compreendida como um conjunto de mecanismos neurais que facilitam o processamento de informações, pensamentos ou ações relevantes enquanto ignoram outros irrelevantes ou dispersos. Deste modo a atenção permite que o organismo interaja de maneira adequada com o ambiente. Dentre as estruturas cerebrais associados ao controle da atenção, o Córtex Prefrontal Dorsolateral (CPFDL) tem tomado papel de destaque na literatura atual como uma região associada ao controle comportamental. A Estimulação Transcraniana por Corrente Contínua (ETCC) se baseia na aplicação de corrente elétrica de baixa intensidade por meio de eletrodos posicionados no escalpe com o objetivo de modular a atividade de diferentes regiões cerebrais e tem sido utilizada como modo de estudo da função cerebral. Esse trabalho tem como objetivo verificar como a atenção pode ser modulada a partir da aplicação ETCC bilateral sobre o CPFDL, utilizando medidas de tempo de reação (TR) em tarefas de orientação temporal e espacial. Para Tanto foram planejados e executados dois experimentos. No primeiro experimento, relativo à orientação voluntária da atenção espacial, cada participante deveria orientar a atenção para a posição do espaço indicada por uma seta. O segundo experimento, relativo à orientação voluntária da atenção temporal, cada participante deveria orientar a atenção para o intervalo temporal de maior recorrência. Em ambos os casos os participantes deveriam responder o mais rapidamente possível ao aparecimento do alvo pressionado uma tecla de joystick registrando-se assim o seu TR. Participaram desse estudo 18 alunos de graduação (12 no primeiro desenho experimental, e para o segundo desenho experimental foram adicionados mais 6 colaboradores) na faixa etária de 19 à 25 anos. A cada sessão os colaboradores deveriam responder a ambos os experimento enquanto eram submetidos a diferentes polaridades de ETCC (anódica, catódica e placebo) sobre o CPFDL. Foram feitas análises de variância para comparar os fatores estudados. No experimento de orientação espacial a condição anódica produziu TR menores em comparação à condição placebo. No caso do experimento de orientação temporal foi observado que na modulação anódica houve um aumento nos TR no intervalo menos recorrente de 500 ms, indicando que a ETCC anódica pode ter influenciado de modo mais efetivo o direcionamento atencional aos intervalos mais freqüentes. Neste sentido é possível sugerir a existência de um efeito facilitatório da ETCC anódica na moducalçao do CPFDL, o que gerou um impacto no direcionamento atencional, diminuindo os TR para a condição valida (orientação espacial) quando comparados a ETCC placebo. CPFDL (Córtex Prefrontal Dorsolateral) atenção DLPFC (Dorsolateral Prefrontal Cortex) attention CNPQ::CIENCIAS HUMANAS::PSICOLOGIA
17	Altered Kinase Networks in Major Depressive Disorder Alnafisah, Rawan 15 June 2023 (has links) No description available. Neurosciences Molecular Biology Bioinformatics
18	Can transcranial magnetic stimulation and music conjointly influence the mood of the healthy population? A psychophysiological approach Roghani Zanjani, Samaneh 08 1900 (has links) Mémoire de maîtrise présenté en vue de l'obtention de la maîtrise en psychologie (M. Sc) / L'humeur, en tant qu’élément central dans notre perception du monde, englobe diverses émotions et affecte grandement le bien-être mental et physiologique. Une régulation efficace de l'humeur est vitale pour un fonctionnement quotidien normal et tout dérèglement peut mener à des troubles psychologiques majeurs comme la dépression. Au niveau cérébral, le système de récompense, en particulier le cortex préfrontal dorsolatéral gauche (CPFdl) et ses projections dopaminergiques, joue un rôle central dans la régulation de l'humeur et du plaisir. De nombreuses recherches montrent maintenant que l’écoute de la musique influence notre humeur, en agissant sur le système de récompense. En outre, la stimulation magnétique transcrânienne répétitive excitatrice (SMTr) ciblant le CPFdl gauche a donné des résultats prometteurs en modifiant l'humeur et l'activité du système de récompense, ainsi qu'en modulant le plaisir perçu et la motivation pendant l'écoute de la musique en augmentant l'excitabilité et la plasticité corticales. Cependant, les études existantes sur l'impact de la SMTr sur l'humeur des personnes en bonne santé aboutissent à des résultats contradictoires, et l'effet conjoint de la SMTr et de la musique sur l'humeur reste inexploré. Cette étude vise donc à déterminer si la SMTr excitatrice peut augmenter les effets de la musique sur l'humeur chez des volontaires sains. Plus précisément, nous souhaitons valider l'impact de la musique, de la SMTr et de leur application combinée sur l'humeur des participants. Vingt-quatre participants ont suivi quatre sessions expérimentales, comprenant soit la SMTr seule, l’écoute de la musique seule, la SMTr associée à l’écoute de la musique, ou les conditions placebo/sham. L'humeur des participants a été évaluée à l'aide d'un questionnaire sur l'humeur et d'enregistrements de l'activité électrodermale (EDA) avant et après les stimuli. Les résultats ont révélé une amélioration significative de l'humeur générale et de l'humeur positive, ainsi qu'une diminution significative de l'humeur négative au cours de la séance de musique seule, ce qui indique l'efficacité de la musique en tant qu'intervention pour améliorer l'humeur. À l'inverse, la séance de SMTr seule a entraîné une diminution de l'humeur positive et une augmentation de l'humeur négative, ce qui suggère un effet négatif potentiel de la SMTr sur l'humeur. . Dans la session SMTr + musique, on a observé une tendance à l'amélioration de l'humeur, ce que nous interprétons comme le fait que l'application de la SMTr sur le CPFdl gauche a entrainé une baisse de l'humeur, tandis que l'écoute de la musique contrecarrait cet effet en induisant une humeur positive et en réduisant l'humeur négative.En conclusion, les résultats de cette étude soulignent le potentiel de la musique en tant qu'intervention visant à améliorer l'humeur. En outre, les résultats suggèrent que la SMTr excitatrice ciblant le CPFdl gauche peut entraîner une baisse de l'humeur. Il est nécessaire de poursuivre les recherches dans ce domaine, notamment en explorant d'autres combinaisons de stimuli, telles que la SMTr excitatrice sur le CPFdl droit associée à la musique, afin de mieux comprendre les mécanismes sous-jacents et d'optimiser l'utilisation de ces interventions pour la régulation de l'humeur. Ces recherches supplémentaires permettront de mieux comprendre la modulation de l'humeur et d'améliorer l'efficacité des interventions dans ce domaine. / Mood, as a central element in our perception of the world, encompasses a variety of emotions and greatly affects mental and physiological well-being. Effective mood regulation is vital for normal daily functioning, and any disruption can lead to major psychological disorders such as depression. At the cerebral level, the reward system, in particular, the left dorsolateral prefrontal cortex (DLPFC) and its dopaminergic projections, plays a central role in regulating mood and pleasure. A large body of research now shows that listening to music influences our mood, by affecting the reward system. In addition, excitatory repetitive transcranial magnetic stimulation (rTMS) targeting the left DLPFC has shown promising results in altering mood and the reward system activity, as well as modulating perceived pleasure and motivation during music listening by increasing cortical excitability and plasticity. However, existing studies on the impact of rTMS on mood in healthy individuals yield conflicting results, and the joint effect of rTMS and music on mood remains unexplored. This study aims to determine whether excitatory rTMS can enhance the effects of music on mood in healthy volunteers. More specifically, we aim to validate the impact of music, rTMS, and their combined application on participants' mood. Twenty-four participants completed four experimental sessions, comprising either rTMS alone, listening to music alone, rTMS + music, or placebo/sham conditions. Participants' mood was assessed using a mood questionnaire and electrodermal activity (EDA) recordings before and after the stimuli. Results revealed a significant improvement in overall mood and positive mood, as well as a significant decrease in negative mood during the music-only session, indicating the effectiveness of music as a mood-enhancing intervention. Conversely, the rTMS session alone resulted in a decrease in positive mood and an increase in negative mood, suggesting a potential negative effect of rTMS on mood. In rTMS + music session, there was a trend in mood improvement, which we interpret as meaning that applying rTMS to the left DLPFC resulted in a decrease in the mood while listening to music counteracted this effect by inducing positive mood and reducing negative mood. In conclusion, the results of this study underline the potential of music as a mood-enhancing intervention. In addition, the results suggest that excitatory rTMS targeting the left DLPFC may lead to a decrease in mood. Further research in this area is necessary, including exploring alternative combinations of stimuli, such as excitatory rTMS on the right DLPFC in conjunction with music to better understand the underlying mechanisms and optimize the use of these interventions for mood regulation. This additional research will contribute to a more comprehensive understanding of mood modulation and enhance the effectiveness of interventions in this field. Mood Reward System Left Dorsolateral Prefrontal Cortex Transcranial Magnetic Stimulation Electrodermal Activity. Système de Récompense Cortex Préfrontal Dorsolatéral Gauche Stimulation Magnétique Transcrânienne Activité Électrodermale Humeur Psychology / Psychologie (UMI : 0621)
19	Investigation of LTP-like Plasticity, Memory and Prefrontal Cortical Thickness: a TMS-EEG and Brain Imaging Study Drodge, Jessica 04 January 2023 (has links) Introduction: Memory is a complex cognitive process formerly linked to mechanisms of brain plasticity that can be estimated in the left dorsolateral prefrontal cortex (DLPFC) using transcranial magnetic stimulation and electroencephalography (TMS-EEG). Also, cortical thickness in the DLPFC may be a potential proxy measure of brain plasticity as previous literature reports a link between better memory and thicker cortex. However, the link between brain plasticity and memory performance as well as DLPFC thickness remains to be clarified. Methods: Intermittent theta burst stimulation (iTBS) probed plasticity-like mechanisms in the left DLPFC in 17 cognitively healthy participants. TMS-EEG recordings were performed before and after sham and active iTBS to quantify plasticity via transcranial magnetic stimulation-evoked potentials (TEPs). Composite memory scores for each domain (verbal episodic, visual episodic and working memory) were obtained using the Cambridge Neuropsychological Test Automated Battery. Anatomical T1 images were acquired by magnetic resonance imaging and processed by open-source software (CIVET) and the Automated Anatomical Labeling atlas to extract cortical thickness of the DLPFC. All statistical analyses (linear mixed model, Tukey's post hoc test and Pearson's correlations) were completed in R Studio. Results: iTBS resulted in increased TEP amplitude P30 (F= 5.239, p = 0.029), as shown by a significant interaction between condition (iTBS, sham) and time (pre- and post-condition). Specifically, Tukey's post hoc test revealed that the P30 increase was near trending significant post-iTBS compared to pre-iTBS for the active condition (p = 0.166) but not for the sham condition (p = 0.294). A trending significant relationship was observed between the magnitude of P30 change post-iTBS and thicker left DLPFC (r = 0.488; p = 0.108). Lastly, no significant relationships between P30 change and memory performance were observed. Conclusion: These preliminary findings suggest there could be a relationship between increased capacity for brain plasticity and a thicker left DLPFC. To further investigate these relationships, we plan to recruit additional cognitively healthy participants. Our preliminary findings support the foundation for future clinical studies in which DLPFC thickness could be explored as a predictive factor for response to plasticity-targeting iTBS treatment. Transcranial Magnetic Stimulation (TMS) Electroencephalography (EEG) Dorsolateral Prefrontal Cortex (DLPFC) Healthy Subjects Cortical Thickness
20	Modulation de l'apprentissage visuel par stimulation électrique transcrânienne à courant direct du cortex préfrontal Lafontaine, Marc Philippe 08 1900 (has links) Le traitement visuel répété d’un visage inconnu entraîne une suppression de l’activité neuronale dans les régions préférentielles aux visages du cortex occipito-temporal. Cette «suppression neuronale» (SN) est un mécanisme primitif hautement impliqué dans l’apprentissage de visages, pouvant être détecté par une réduction de l’amplitude de la composante N170, un potentiel relié à l’événement (PRE), au-dessus du cortex occipito-temporal. Le cortex préfrontal dorsolatéral (CPDL) influence le traitement et l’encodage visuel, mais sa contribution à la SN de la N170 demeure inconnue. Nous avons utilisé la stimulation électrique transcrânienne à courant direct (SETCD) pour moduler l’excitabilité corticale du CPDL de 14 adultes sains lors de l’apprentissage de visages inconnus. Trois conditions de stimulation étaient utilisées: inhibition à droite, excitation à droite et placebo. Pendant l’apprentissage, l’EEG était enregistré afin d’évaluer la SN de la P100, la N170 et la P300. Trois jours suivant l’apprentissage, une tâche de reconnaissance était administrée où les performances en pourcentage de bonnes réponses et temps de réaction (TR) étaient enregistrées. Les résultats indiquent que la condition d’excitation à droite a facilité la SN de la N170 et a augmentée l’amplitude de la P300, entraînant une reconnaissance des visages plus rapide à long-terme. À l’inverse, la condition d’inhibition à droite a causé une augmentation de l’amplitude de la N170 et des TR plus lents, sans affecter la P300. Ces résultats sont les premiers à démontrer que la modulation d’excitabilité du CPDL puisse influencer l’encodage visuel de visages inconnus, soulignant l’importance du CPDL dans les mécanismes d’apprentissage de base. / Repeated visual processing of an unfamiliar face suppresses neural activity in face-specific areas of the occipito-temporal cortex. This "repetition suppression" (RS) is a primitive mechanism involved in learning of unfamiliar faces, which can be detected through amplitude reduction of the N170 event-related potential (ERP). The dorsolateral prefrontal cortex (DLPFC) exerts top-down influence on early visual processing. However, its contribution to N170 RS and learning of unfamiliar faces remains unclear. Transcranial direct current stimulation (tDCS) transiently increases or decreases cortical excitability, as a function of polarity. We hypothesized that DLPFC excitability modulation by tDCS would cause polarity-dependent modulations of N170 RS during encoding of unfamiliar faces. tDCS-induced N170 RS enhancement would improve long-term recognition reaction time (RT) and/or accuracy rates, whereas N170 RS impairment would compromise recognition ability. Participants underwent three tDCS conditions in random order at ~72 hour intervals: right anodal/left cathodal, right cathodal/left anodal and sham. Immediately following tDCS conditions, an EEG was recorded during encoding of unfamiliar faces for assessment of P100 and N170 visual ERPs. P300 was analyzed to detect prefrontal function modulation. Recognition tasks were administered ~72 hours following encoding. Results indicate the right anodal/left cathodal condition facilitated N170 RS and induced larger P300 amplitudes, leading to faster recognition RT. Conversely, the right cathodal/left anodal condition caused increases in N170 amplitudes and RT, but did not affect P300. These data are the first to demonstrate that DLPFC excitability modulation can influence early visual encoding of unfamiliar faces, highlighting the importance of DLPFC in basic learning mechanisms. Suppression neuronale Apprentissage Cortex préfrontal dorsolatéral Traitement visuel Potentiels reliés aux événements Repetition suppression Learning Dorsolateral prefrontal cortex Transcranial direct current stimulation Face processing Event-related potentials

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