Evaluation de l'excitabilité corticale par électroencéphalographie pour l'optimisation de la stimulation magnétique transcrânienne répétée chez les patients souffrant de troubles de l'humeur / Optimisation of repetitive transcranial magnetic stimulation using electroencephalographic measurements in patients suffering from mood disorders

Wozniak-Kwasniewska, Agata

07 October 2013

La stimulation magnétique transcranienne (SMT) est une technique non invasive qui permet de stimuler le cerveau. Les SMT répétitives (SMTr), c'est-à-dire l'application de nombreuses impulsions magnétiques, sont capable d'induire des modifications de longue durée de l'excitabilité neuronale. La SMT s'est développée dans un but thérapeutique et scientifique. Les effets après la SMTr sur le cortex moteur sont bien documentés chez les individus sains, mais on en sait moins sur la stimulation du cortex préfrontal dorso-latéral (DLPFC).L'objectif de cette thèse était de comparer différents protocoles SMTr sur des sujets sains et de trouver des marqueurs électroencéphalograpiques (EEG) de la réponse ou pas à la thérapie SMTr dans la dépression majeure et bipolaire. La principale originalité de la méthode présentée est la comparaison intra-sujet d'effets entre-protocoles et le développement de techniques de localisation de sources.Nous avons étudié chez 20 sujets sains comment les oscillations corticales sont modulées suite à quatre protocoles SMTr actifs différents, et à un protocole sham utilisé comme contrôle, du DLPFC gauche et en comparant la puissance spectrale d'EEG avant et après SMTr de durée de 15 minutes. Le spectre EEG a été estimé grâce à la transformée de Fourier rapide (FFT) et partitionné en bandes de fréquence selon la classification commune.Nous avons trouvé pour chaque protocole actif une diminution significative de puissance delta et theta sur les électrodes préfrontales gauches, principalement localisées dans le DLPFC gauche. Dans des bandes de fréquences plus hautes, la diminution de puissance dans le DLPFC a été de plus observée dans le DLFPC controlatéral et dépend du protocole de stimulation. Parce que les activités delta et theta sont généralement associées à l'inhibition corticale, ces résultats suggérent que la SMTr du DLPFC diminue transitoirement l'inhibition corticale locale. Aussi, les oscillations d'EEG rapides sont associées à l'excitabilité corticale et on peut conclure que des diminutions observées non spécifiques dans l'activité rapide localisée dans le DLPFC suggérent également une réduction de l'excitabilité corticale.Dans la deuxième expérience, nous avons travaillé sur groupe de patients, souffrant de trouble dépressif majeur (MDD) et de trouble bipolaire (BP). Dans cette étude ouverte, nous avons cherché à déterminer s'il existe des différences d'EEG de repos dans l'activité cérébrale entre patients BP et MDD, et entre les répondeurs et non-répondeurs à la SMTr à 10 Hz en étudiant des biomarqueurs d'EEG. Le protocole SMTr à 10 Hz étaient le même entre patients MDD et BP. Les propriétés EEG dans les deux troubles dépressifs ont été étudiées, en comparant la puissance spectrale des enregistrements pré- et post-SMTr EEG au cours des sessions thérapeutiques chez les patients répondeurs et non-répondeurs.La conclusion est qu'il est possible de distinguer les répondeurs des non-répondeurs au traitement SMTr. Les répondeurs avaient une puissance en basse fréquence plus importante. Une augmentation de puissance alpha a aussi été observée au niveau du cortex cingulaire ventral dans les deux groupes. La comparaison des MDD et BP a révélé une activité significativement plus élevée dans la puissance des bandes thêta et bêta chez les patients BP, principalement localisée dans le cortex préfrontal. / Transcranial magnetic stimulation (TMS) is a non-invasive technique for stimulating the brain. A brief electric current passing through a magnetic coil produces a brief, high-intensity magnetic field which stimulates the brain. Repetitive TMS, application of many magnetic pulses, is able to induce relatively long-lasting excitability changes and nowadays is being developed for various therapeutic and scientific purposes. The after-effects of rTMS over motor cortex are well documented in healthy individuals, however less is known about the stimulation of dorso-lateral prefrontal cortex (DLPFC). The aim of this PhD thesis was to compare different rTMS protocols in healthy subjects and to find neurophysiological EEG biomarkers characteristic for response or not to rTMS therapy in major and bipolar depression. The main originality of presented method is within-subject comparison of between-protocols effects. Additionally, source localisation was performed in both analyses. Here, we studied in 20 healthy subjects how cortical oscillations are modulated by four different active rTMS protocols (1 Hz, 10 Hz, cTBS and iTBS) of the left DLPFC, and by a sham-1Hz protocol used as a control condition, by comparing the spectral power of pre- and post-rTMS electroencephalographic (EEG) recordings of 15 minutes duration. EEG spectrum was estimated with the Fast Fourier transform (FFT) and partitioned using the common physiological frequency. We found for every active protocol a significant decrease of delta and theta power on left prefrontal electrodes, mainly localised in the left DLPFC. In higher frequency bands (beta and gamma), the decrease of power in the DLPFC was also observed additionally in the contralateral DLFPC and depended on the stimulation protocol. Because large delta and theta activity is usually associated with cortical inhibition, these results suggest that rTMS of DLPFC transiently decreases local cortical inhibition. Furthermore, fast EEG oscillations are associated to cortical excitability and it can be concluded that observed decreases in fast activity, unspecific to protocol, localised in the DLPFC also suggest reduced cortical excitability, which accompanies a decrease in cortical inhibition. In the second experiment we worked on two subgroups of patients, with major depressive disorder (MDD) and bipolar disorder (BP). In this open study we aimed to examine whether there are EEG differences in resting brain activity between BP and MADD patients, and between responders and non-responders to 10 Hz repetitive transcranial magnetic stimulation (rTMS) by studying EEG biomarkers. Eight MDD (6 females) and 10 BP patients (6 females) were included. The 10 Hz rTMS protocol was the same for MDD and BP. The different patterns of EEG activity in both depressive disorders were studied, by comparing spectral power of pre- and post-rTMS EEG recordings throughout the therapeutic sessions in responders and non-responders.The most important finding is that it is possible to distinguish responders from non-responders to the rTMS treatment. Responders showed significantly higher power of low frequencies. Therefore, an increase of alpha power was observed in ventral cingulate cortex in both groups. The comparison of MDD and BP disorders revealed significantly higher activity in theta and beta bands power in BP patients, mainly localised in prefrontal cortex.

EEG

RTMS

La dépression

EEG

RTMS

Dorso-lateral prefrontal cortex

Depression

Postnatal development of excitatory and inhibitory prefrontal cortical circuits and their disruption in autism

Trutzer, Iris Margalit

07 October 2019

The prefrontal cortices, in particular lateral prefrontal cortex (LPFC) and anterior cingulate cortex (ACC), have been implicated in top-down control of attention switching and behavioral flexibility. These cortices and their networks are disrupted in autism, a condition in which diverse behaviors such as social communication and attention control are dysregulated. However, little is known about the typical development of these cortical areas or the ways in which this process is altered in neurodevelopmental disorders. In order to identify changes that could affect the local processing of signals transmitted by the short-range pathways connecting the ACC and LPFC I assessed developmental changes in the distinct cortical layers, which send and receive different pathways and have unique inhibitory microenvironments that dictate excitatory-inhibitory balance. Normative developmental trends were compared with those seen in individuals with autism to identify changes that may contribute to symptoms of attention dysfunction. Unbiased quantitative methods were used to study overall neuron density, the density of inhibitory neurons labeled by the calcium-binding proteins calbindin (CB), calretinin (CR), and parvalbumin (PV), and the density, size, and trajectory of myelinated axons in the individual cortical layers in children and adults with and without a diagnosis of autism. There was a reduction in neuron density and an increase in the density of myelinated axons in both areas during neurotypical development. Axons in layers 1-3 of LPFC were disorganized in autism, with increased variability in the trajectory of axons in children and a decrease in the proportion of thin axons in adults. These findings were most significant in layer 1, the ultimate feedback-receiving layer in the cortex. While there were no differences in neuron populations between cohorts in children, in adults with autism there was a significant reduction in the density of CR-expressing neurons in LPFC layers 2-6 and a significant increase in the density of PV-expressing neurons in ACC layers 5-6. In autism, these findings suggest that dysregulation of the normal development of axonal networks, seen in children, may induce compensatory developmental changes in cell and axon populations in adults that could be connected to attention dysregulation. / 2021-10-07T00:00:00Z

Neurosciences

Anterior cingulate

Attention networks

Feedback pathways

Inhibitory cortical interneurons

Lateral prefrontal cortex

Postnatal brain development

Cell-type specific cholinergic modulation in anterior cingulate and lateral prefrontal cortices of the rhesus macaque

Tsolias, Alexandra

03 November 2023

The lateral prefrontal cortex (LPFC) and the anterior cingulate cortex (ACC) are two key regions of the frontal executive control network. Ascending cholinergic pathways differentially innervate these two functionally distinct cortices to modulate arousal and motivational signaling for higher-order functions. The action of acetylcholine (ACh) in sensory cortices is constrained by layer, anatomical cell type, and subcellular localization of distinct receptors, but little is known about the nature and organization of frontal-cholinergic circuitry in primates. In this dissertation, we characterized the anatomical localization of muscarinic acetylcholine receptors (mAChRs), m1 and m2–the predominant subtypes in the cortex–and their expression profiles on distinct cell types and pathways in ACC and LPFC of the rhesus monkey, using immunohistochemistry, anatomical tract-tracing, whole cell patch-clamp recordings, and single nucleus RNA sequencing. In the first series of studies (Chapter 2), we used immunohistochemistry and high-resolution confocal microscopy to reveal regional differences in m1 and m2 receptor localization on excitatory pyramidal and inhibitory neuron subpopulations and subcellular compartments in ACC (A24) versus LPFC (A46) of adult rhesus monkeys (Macaca mulatta; aged 7-11 yrs; 4 males and 2 females). The ACC exhibited a greater proportion of m2+ inhibitory neurons and a greater density of presynaptic m2+ receptors localized on inhibitory (VGAT+) terminations on pyramidal neurons compared to the LPFC. This result suggests a greater cholinergic suppression of GABAergic neurotransmission in ACC. In a second set of experiments (Chapter 3), we examined the heterogeneity of m1 and m2 laminar expression in functionally distinct ACC areas A24, A25, and A32. These differ in their connections with higher order cortical areas and limbic structures, such as the amygdala (AMY). The density of m1+ and/or m2 expressing (m1+/m2+) pyramidal neurons was significantly greater in A24 compared to A25 and to A32, while A25 exhibited a significantly greater density of m2+VGAT+ terminals. In addition, we examined the substrates for cholinergic modulation of long-range cortico-limbic processing using bidirectional neural tracers to label one specific subtype, the AMY-targeting projection neurons in these ACC areas. Compared to A24 and A32, the limbic ventral A25 had a greater density of m1+/m2+ AMY-targeting pyramidal neurons across upper layers 2-3 and deep layers 5-6, suggesting stronger cholinergic modulation of amygdalar outputs. Lastly (Chapter 4), we assessed the functional effects of cholinergic modulation on excitatory and inhibitory synaptic activity as well as the molecular signatures related to m1 and m2 receptor expression. In experiments using in vitro whole-cell patch-clamp recordings of layer 3 pyramidal neurons in ACC and LPFC, we found that application of the cholinergic agonist carbachol (CCh) significantly decreased the frequency of excitatory postsynaptic currents (EPSCs) to a greater extent in ACC A24 than in LPFC A46. Using single nucleus RNA sequencing, we found that enriched m1 and m2 transcriptional profiles in distinct cell-types and frontal areas (ACC A24 and LPFC A46) had differentially expressed genes associated with down-stream signaling cascades related to synaptic signaling and plasticity. Together, these data reveal the anatomical, functional, and transcriptomic neural substrates of diverse cholinergic modulation of local excitatory and inhibitory circuits and long-range cortico-limbic pathways in functionally-distinct ACC and LPFC frontal areas that are important for cognitive-emotional integration.

Neurosciences

Acetylcholine

Anterior cingulate cortex

Frontal cortex

Lateral prefrontal cortex

Muscarinic receptors

Rhesus monkey

Organization of prefrontal and premotor layer-specific pathways in rhesus monkeys

Bhatt, Hrishti

16 February 2024

The Lateral Prefrontal Cortex (LPFC) and the Dorsal Premotor cortex (PMd) are two cortical structures that are involved in cognitive processes such as motor planning and decision-making. The LPFC is extensively connected to sensory, somatosensory, and motor cortices that help it control several cognitive functions [for review, see: (Tanji & Hoshi, 2008)]. Similarly, the PMd can integrate information from the prefrontal and motor cortex, acting as a link, in action planning and decision making [for review, see: (Hoshi & Tanji, 2007)]. Therefore, it is important to study the cortical pathways between these areas because of their common role in processing and selecting relevant information in tasks requiring decision-making. Using neural tract-tracing, immunolabeling and microscopy in rhesus monkeys (M. mulatta), we assessed the distribution and layer-specific organization of projection neurons from LPFC area 46 and PMd area 6 directed to the LPFC area 9. Our study revealed that projection neurons to area 9 were found originating from upper (L2-3) and deep (L5-6) layers of both areas, but with a slight upper layer bias. We found that the LPFC area 46 had a higher density of projection neurons directed to LPFC area 9 compared to the PMd area 6. Additionally, our data also revealed laminar differences in the perisomatic parvalbumin (PV) inhibitory inputs onto area 9 projection neurons, which were dependent on area of origin. Within ventral LPFC area 46, perisomatic PV+ inhibitory inputs onto upper layer projection neurons to area 9 was greater than those onto deep layer projection neurons. The opposite pattern was found for PMd area 6DR, where perisomatic PV+ inhibition onto deep layer projection neurons to area 9 was greater than those onto upper layer neurons. These findings provide additional insights into the layer-specific organization of prefrontal and premotor pathways that play an important role in action planning and decision-making.

Neurosciences

Cortical pathways

Inhibitory neurons

Lateral prefrontal cortex

Non-human primate

Premotor cortex

Tract-tracing

Interference processing in dual tasks / the functional role of the lateral prefrontal cortex

Stelzel, Christine

23 May 2008

Zahlreiche Untersuchungen belegen fundamentale Grenzen in der menschlichen Fähigkeit, mehrere Dinge gleichzeitig zu tun. Aktuelle Theorien zur Verarbeitung von Doppelaufgaben gehen davon aus, dass kognitive Kontrollprozesse den Verarbeitungsstrom mehrerer Aufgaben koordinieren. Funktionell-neuroanatomisch wird insbesondere der laterale Präfrontalcortex (lPFC) mit der Kontrolle zielgerichteten Verhaltens in Verbindung gebracht. Mittels funktioneller Magnetresonanztomographie (fMRT) wurde bereits eine Beteiligung des lPFC an der Verarbeitung von Doppelaufgaben nachgewiesen. Die neuronalen Mechanismen der Doppelaufgabenkoordination sind jedoch weitgehend ungeklärt. Die drei fMRT Studien der vorliegenden Dissertation spezifizieren die funktionelle Rolle des lPFC bei der Interferenzverarbeitung in Doppelaufgaben. Die Ergebnisse zeigen (1) die Allgemeinheit der lPFC-Beteiligung über verschiedenen Doppelaufgabensituationen hinweg, (2) die funktionell-neuroanatomische Dissoziierbarkeit verschiedener doppelaufgabenrelevanter Kontrollfunktionen im lPFC , (3) die Bedeutung der Interaktion des lPFC mit posterioren aufgabenrelevanten Regionen für die Kontrolle von Doppelaufgabenverarbeitung. / Numerous studies indicate fundamental limitations in the human ability to do multiple things at the same time. Recent theories on dual-task processing postulate the involvement of cognitive control processes in the coordination of the processing stream of multiple tasks. The most prominent neuroanatomical structure associated with the control of goal-directed human behavior is the lateral prefrontal cortex (lPFC). It has been show with functional Magnetic Resonance Imaging (fMRI) that the lPFC is also involved in the processing of dual tasks. However, the precise role of the lPFC for the control of dual-task processing and the neural mechanisms of dual-task coordination are still widely unknown. The three fMRI studies presented in this dissertation specify the functional role of the lPFC in interference processing in dual tasks.The results show (1) the generality of lPFC involvement across different types of dual-task situations, (2) the functional neuroanatomical dissociability of different dual-task relevant control process in the lPFC, (3) the role of the interaction of the lPFC with posterior task-relevant brain regions for the control of dual-task processing

fMRT

lateraler Präfrontalcortex

kognitive Kontrolle

Interferenzverarbeitung

Doppelaufgaben

fMRI

lateral prefrontal cortex

cognitive control

interference processing

dual tasks

150 Psychologie

11 Psychologie

ddc:150

Investigating Task-Order Coordination in Dual-Task Situations

Kübler, Sebastian

25 May 2021

Bisherige Studien liefern Hinweise für das Auftreten von aktiven Prozessen der Reihenfolgekoordination in Doppelaufgaben. Diese Prozesse sind notwendig für die Regulation der Bearbeitungsreihenfolge von zwei Aufgaben. Bisher ist jedoch wenig über die kognitiven und neuronalen Mechanismen bekannt, die diesen Prozessen zugrunde liegen. Ziel der vorliegenden Dissertation war deshalb die Überprüfung eines Modells aktiver Reihenfolgekoordination in Doppelaufgaben. Das Modell nimmt an, dass diese Prozesse auf Repräsentationen zurückgreifen, die Informationen über die Verarbeitungssequenz zweier Aufgaben enthält. Zusätzlich macht das Modell Annahmen über (1) den Ort der Verarbeitung und (2) den genauen Inhalt dieser Repräsentationen. Weiterhin enthält das Modell die Annahmen, dass (3) der präfrontale Kortex kausal in Reihenfolgekoordination involviert ist und dass (4) diese Prozesse von unterschiedlichen Kriterien beeinflusst werden. In dieser Dissertation wurde das Model in einer Reihe von vier Studien überprüft. Dazu wurde ein Doppelaufgabenparadigma mit zufällig wechselnder Aufgabenreihenfolge verwendet. Ich konnte zeigen, dass die Reihenfolgerepräsentationen im Arbeitsgedächtnis aufrechterhalten und aktiv verarbeitet werden. Ich konnte weiterhin zeigen, dass diese Repräsentationen nur Information über die Sequenz der Aufgaben enthalten. Spezifische Aufgabeninformation wird hingegen separat repräsentiert. Durch den Einsatz transkranieller Magnetstimulation konnte ich zudem nachweisen, dass der präfrontale Kortex eine kausale Rolle für Reihenfolgekoordination spielt. Darüber hinaus konnte ich zeigen, dass Anforderungen an Reihenfolgekoordinationsprozesse in Situationen, in denen Probanden ein von außen vorgegebenes Reihenfolgekriterium befolgen, erhöht sind im Vergleich zu Situationen, in denen Probanden ein auf einer freien Wahl basierendes Kriterium nutzen können. Die Implikationen dieser Ergebnisse werden unter Berücksichtigung des vorgeschlagenen Modells diskutiert. / Evidence from behavioral as well as neurophysiological studies indicates the occurrence of active task-order coordination processes in dual-task situations. These processes are required for planning and regulating the processing sequence of two tasks that overlap in time. So far, however, the cognitive and neural mechanisms underlying active task-order coordination are highly underspecified. To tackle this issue, in the present dissertation I tested a model of task-order coordination in dual-task situations. This model assumes that task-order coordination relies on representations that contain information about the processing sequence of the two component tasks. In addition, the model includes assumptions about the (1) locus of processing as well as (2) the exact content of these order representations. The model further assumes that (3) the lateral prefrontal cortex is causally involved in implementing task-order coordination processes and that (4) these processes are affected by different order criteria. I tested this model in a series of four studies by applying a dual-task paradigm with randomly changing task order. I demonstrated that task-order representations are actively maintained and processed in working memory during dual tasking. Moreover, I found that these order representations only contain information about the processing sequence of tasks, whereas specific component task information is represented separately. By applying transcranial magnetic stimulation, I also provided evidence for the causal role of the lateral prefrontal cortex for task-order coordination. Furthermore, I showed that the demands on task-order coordination are increased when participants have to adhere to an external and mandatory order criterion compared to when they can use an internally generated order criterion that is based on free choice. The implications of these results as well as an outlook for future research will be discussed in the framework of the proposed model.

Doppelaufgaben

PRP-Paradigma

Reihenfolgenkoordination

exekutive Kontrolle

transkranielle Magnetstimulation

präfrontaler Kortex

zentrale Aufmerksamkeit

dual-task situations

PRP paradigm

task-order coordination

executive control

transcranial magnetic stimulation

lateral prefrontal cortex

central bottleneck

153 Kognitive Prozesse und Intelligenz

CP 6000

CP 4000

ddc:153

Inferência do tempo de atividade neural a partir do efeito BOLD em ressonância magnética funcional / Inference of neural activity time from BOLD effect in functional magnetic resonance imaging

Biazoli Junior, Claudinei Eduardo

01 April 2011

A inferência do curso temporal da atividade neural a partir do efeito BOLD é um importante problema, ainda em aberto. A forma da curva BOLD não reflete diretamente as características temporais da atividade eletrofisiológica dos neurônios. Nessa tese, é introduzido o conceito de tempo de processamento neural (TPN) como um dos parâmetros do modelo biofísico da função de resposta hemodinâmica (HRF). O objetivo da introdução desse conceito é obter estimativas mais acuradas da duração da atividade neural a partir do efeito BOLD, que possui auto grau de nãolinearidade. Duas formas de estimar os parâmetros do modelo do efeito BOLD foram desenvolvidas. A validade e aplicabilidade do conceito de TPN e das rotinas de estimação foram avaliadas por simulações computacionais e análise de séries temporais experimentais. Os resultados das simulações e da aplicação foram comparados com medidas da forma da HRF. O experimento analisado consistiu em um paradigma de tomada de decisão na presença de distratores emocionais. Esperase que o TPN em áreas sensoriais primárias seja equivalente ao tempo de apresentação de estímulos. Por outro lado, o TPN em áreas relacionadas com a tomada de decisão deve ser menor que a duração dos estímulos. Além disso, o TPN deve depender da condição experimental em áreas relacionadas ao controle de distratores emocionais. Como predito, o valores estimados do TPN no giro fusiforme foram equivalentes à duração dos estímulos e o TPN no giro do cíngulo dorsal variou com a presença de distrator emocional. Observou-se ainda lateralidade do TPN no córtex pré-frontal dorsolateral. As medidas da forma da HRF obtidas por um método convencional não dectectaram as variações observadas no TPN / The extraction of information about neural activity dynamics related to the BOLD signal is a challenging task. The temporal evolution of the BOLD signal does not directly reflect the temporal characteristics of electrical activity of neurons. In this work, we introduce the concept of neural processing time (NPT) as a parameter of the biophysical model of the hemodynamic response function (HRF). Through this new concept we aim to infer more accurately the duration of neuronal response from the highly nonlinear BOLD effect. We describe two routines to estimate the parameters of the HRF model. The face validity and applicability of the concept of NPT and the estimation procedures are evaluated through simulations and analysis of experimental time series. The results of both simulation and application were compared with summary measures of HRF shape. We analysed an experiment based on a decision-making paradigm with simultaneous emotional distracters. We hypothesize that the NPT in primary sensory areas is approximately the stimulus presentation duration. On the other hand, the NPT in brain areas related to decisionmaking processes should be less than the stimulus duration. Moreover, in areas related to processing of an emotional distracter, the NPT should depend on the experimental condition. As predicted, the NPT in fusiform gyrus is close to the stimulus duration and the NPT in dorsal anterior cingulate gyrus depends on the presence of an emotional distracter. Interestingly, the estimated NPTs in the dorsolateral prefrontal cortex indicate functional laterality of this region. The analysis using standard measures of HRF did not detect the variations observed in our method (NPT)

Balloon model

Cingulate gyrus

Córtex pré-frontal dorsolateral

Decision-making

Dorsal lateral prefrontal cortex

Emoções

Emotion

Functional laterality

Functional magnetic resonance imaging

Fusiform gyrus

Giro do cíngulo

Giro fusiforme

Lateralidade funcional

Modelo de balão

Neural network/physiology

Rede nervosa/fisiologia

Sadness

Tomada de decisões

Tristeza

Inferência do tempo de atividade neural a partir do efeito BOLD em ressonância magnética funcional / Inference of neural activity time from BOLD effect in functional magnetic resonance imaging

Claudinei Eduardo Biazoli Junior

01 April 2011

A inferência do curso temporal da atividade neural a partir do efeito BOLD é um importante problema, ainda em aberto. A forma da curva BOLD não reflete diretamente as características temporais da atividade eletrofisiológica dos neurônios. Nessa tese, é introduzido o conceito de tempo de processamento neural (TPN) como um dos parâmetros do modelo biofísico da função de resposta hemodinâmica (HRF). O objetivo da introdução desse conceito é obter estimativas mais acuradas da duração da atividade neural a partir do efeito BOLD, que possui auto grau de nãolinearidade. Duas formas de estimar os parâmetros do modelo do efeito BOLD foram desenvolvidas. A validade e aplicabilidade do conceito de TPN e das rotinas de estimação foram avaliadas por simulações computacionais e análise de séries temporais experimentais. Os resultados das simulações e da aplicação foram comparados com medidas da forma da HRF. O experimento analisado consistiu em um paradigma de tomada de decisão na presença de distratores emocionais. Esperase que o TPN em áreas sensoriais primárias seja equivalente ao tempo de apresentação de estímulos. Por outro lado, o TPN em áreas relacionadas com a tomada de decisão deve ser menor que a duração dos estímulos. Além disso, o TPN deve depender da condição experimental em áreas relacionadas ao controle de distratores emocionais. Como predito, o valores estimados do TPN no giro fusiforme foram equivalentes à duração dos estímulos e o TPN no giro do cíngulo dorsal variou com a presença de distrator emocional. Observou-se ainda lateralidade do TPN no córtex pré-frontal dorsolateral. As medidas da forma da HRF obtidas por um método convencional não dectectaram as variações observadas no TPN / The extraction of information about neural activity dynamics related to the BOLD signal is a challenging task. The temporal evolution of the BOLD signal does not directly reflect the temporal characteristics of electrical activity of neurons. In this work, we introduce the concept of neural processing time (NPT) as a parameter of the biophysical model of the hemodynamic response function (HRF). Through this new concept we aim to infer more accurately the duration of neuronal response from the highly nonlinear BOLD effect. We describe two routines to estimate the parameters of the HRF model. The face validity and applicability of the concept of NPT and the estimation procedures are evaluated through simulations and analysis of experimental time series. The results of both simulation and application were compared with summary measures of HRF shape. We analysed an experiment based on a decision-making paradigm with simultaneous emotional distracters. We hypothesize that the NPT in primary sensory areas is approximately the stimulus presentation duration. On the other hand, the NPT in brain areas related to decisionmaking processes should be less than the stimulus duration. Moreover, in areas related to processing of an emotional distracter, the NPT should depend on the experimental condition. As predicted, the NPT in fusiform gyrus is close to the stimulus duration and the NPT in dorsal anterior cingulate gyrus depends on the presence of an emotional distracter. Interestingly, the estimated NPTs in the dorsolateral prefrontal cortex indicate functional laterality of this region. The analysis using standard measures of HRF did not detect the variations observed in our method (NPT)

Córtex pré-frontal dorsolateral

Emoções

Giro do cíngulo

Giro fusiforme

Lateralidade funcional

Modelo de balão

Rede nervosa/fisiologia

Tomada de decisões

Tristeza

Balloon model

Cingulate gyrus

Decision-making

Dorsal lateral prefrontal cortex

Emotion

Functional laterality

Functional magnetic resonance imaging

Fusiform gyrus

Neural network/physiology

Sadness