Caractérisation du substrat neurologique impliqué dans le traitement de stimuli visuels dynamiques émotionnels : étude d'imagerie par résonance magnétique fonctionnelle

Malgré l’engouement pour les neurosciences cognitives des émotions et les nombreuses publications des dernières décennies tentant d’élucider les bases neurobiologiques des émotions, nos connaissances sur le domaine restent embryonnaires. Plusieurs questions importantes restent toujours sans réponses incluant s’il existe ou non un système unique pour le traitement de stimuli émotionnels et s’il y a ou non des différences entre les hommes et les femmes pour le traitement de stimuli émotionnels. L’objectif de cette thèse est d’apporter certains éléments de réponses à ces questions à travers une caractérisation du substrat neurobiologique impliqué dans le traitement de stimuli émotionnels visuels et dynamiques. Ce travail a été mené via l’imagerie par résonance magnétique fonctionnelle (IRMf) cérébrale. Le premier chapitre, subdivisé en quatre sections, permet de présenter la perspective dans laquelle s’inscrit la thèse. La première section de ce chapitre sert à établir certaines balises définitionnelles liées aux émotions. La seconde section, basée sur une lecture des textes originaux, retrace les faits historiques saillants de la neurobiologie des émotions allant de Charles Darwin à Joseph Ledoux. La troisième section débute où la seconde s’arrête et continue l’histoire de la neurobiologie des émotions à travers un résumé de toutes les principales méta-analyses d’imagerie fonctionnelle cérébrale des émotions. La dernière section du chapitre permet de présenter la problématique de recherche. La recherche, à proprement parler, qui constitue le corps de la thèse est ensuite présentée sous forme de trois articles. Enfin, les résultats de cette recherche et la manière dont ils s’inscrivent dans la continuité de nos connaissances actuelles font l’objet d’une discussion générale. Le premier article (chapitre II) rapporte, chez les hommes et les femmes, les régions du cerveau qui sont plus activées lors du traitement de films érotiques que lors du traitement de films dits ‘neutres’. Un chevauchement manifeste est observé entre les hommes et les femmes. Par contre, une activation significativement plus grande est observée chez les hommes pour l’hypothalamus, une région importante pour le comportement sexuel à travers la phylogénie. De plus, chez les hommes seulement, l’activation hypothalamique est corrélée à l’excitation sexuelle subjective. Comme la recherche présentée dans le premier article se sert de conditions expérimentales relativement longues pour l’IRMf (i.e. extraits de films de 3 minutes) et que ceci peut induire une nette diminution de signal en lien avec certaines contraintes de l’IRMf, le second article (chapitre III) examine les corrélats du traitement de stimuli sexuels en utilisant, cette fois, un paradigme d’IRMf classique où plusieurs extraits de films de 33 secondes sont présentés à la place. Cette étude démontre que, pour le traitement de stimuli sexuels, ce paradigme classique d’IRMf est beaucoup plus sensible que celui du premier article. De plus, comme ce paradigme mène à une reproduction des résultats du premier papier, ce travail soutient la perspective selon laquelle les paradigmes à époques courtes sont une alternative valide aux longues époques comme méthode d’étude du traitement de stimuli émotionnels. Le troisième article (chapitre IV) capitalise sur le protocole du second article et démontre que les patrons d’activation associés au visionnement de courts extraits de films induisant du dégoût, de l’amusement, ou de l’excitation sexuelle, sont très étendus. Une analyse de conjonction formelle démontre un large chevauchent de ces patrons à travers les différents affects étudiés. Enfin, le cinquième chapitre sert de discussion générale. Les questions des différences entre les hommes et les femmes dans le traitement des émotions, de l’existence ou non d’un système général pour le traitement des émotions, ainsi que de la manière dont un tel système pourrait être conçu, sont des points saillants de la discussion. Ces points sont abordés à la lumières des connaissances actuelles et des résultats des trois articles.Despite the intense interest garnered by cognitive neurosciences of emotions and the numerous publications in recent decades attempting to partial the neurobiological basis of emotions, our knowledge of the area remains embryonic. Important questions that need to be answered include whether or not there exists a general system for processing emotional stimuli and whether or not there are differences between men and women in processing emotional stimuli. The main objective of this dissertation is to provide some answers to these questions by characterizing the neurobiological substrate involved in processing dynamic visual emotional stimuli. This work was conducted through cerebral functional magnetic resonance imaging (fMRI). The first chapter, which is divided into four sections, lays the groundwork for the thesis. The first section of this chapter serves to clarify some definitional background related to emotions. The second section, based on a reading of the original texts, traces the salient historical facts of the neurobiology of emotions from Charles Darwin to Joseph Ledoux. The third section begins where the second ends and continues the history of the neurobiology of emotions through a summary of all the main functional brain imaging meta-analyzes of emotions. The final section of the chapter introduces the research problematic. The research itself, which constitutes the body of the dissertation, is then presented in the form of three articles. Finally, results of this research and how they fit into the continuity of our current knowledge form the basis of a general discussion. The first paper (Chapter II) reports, in men and women, the brain regions that are more activated during the processing of erotic film excerpts than during the processing of so-called 'neutral' film excerpts. A clear overlap is observed between men and women. This being said, a significantly greater activation is observed in men for the hypothalamus, a region important for sexual behavior across the phylogeny. In addition, in men only, hypothalamic activation is correlated with reported sexual arousal. As the research presented in the first paper uses relatively long experimental conditions for fMRI (i.e. 3-minute film excerpts) and as this can lead to a net signal decrease due to certain fMRI constraints, the second paper (Chapter III) examines correlates of processing sexual stimuli using, this time, a classic fMRI paradigm where several short film clips of 33 seconds are used instead. This study shows that, for the processing of sexual stimuli, this conventional fMRI paradigm is much more sensitive than the one used in the first paper. Importantly, given that this paradigm leads to a reproduction of results of the first paper, this work supports the view that short epochs are a valid alternative to long epochs as a method of studying the processing of emotional stimuli. The third section (Chapter IV) capitalizes on the protocol of the second paper and demonstrates that the activation patterns associated with the viewing of short film excerpts inducing disgust, amusement, or sexual arousal, are extensive. A formal conjunction analysis shows a broad overlap of these patterns across the various affects studied. Finally, the fifth chapter provides a general discussion of the results. The question of gender differences in processing emotional stimuli, of whether or not a general system for processing emotions exists, and of how it may be understood, represent important elements of the discussion. These points are discussed in light of current knowledge and of the results of the three papers

Investigating the relation between striatal volume and IQ.

The volume of the input region of the basal ganglia, the striatum, is reduced with aging and in a number of conditions associated with cognitive impairment. The aim of the current study was to investigate the relation between the volume of striatum and general cognitive ability in a sample of 303 healthy children that were sampled to be representative of the population of the United States. Correlations between the WASI-IQ and the left striatum, composed of the caudate nucleus and putamen, were significant. When these data were analyzed separately for male and female children, positive correlations were significant for the left striatum in male children only. This brain structure-behavior relation further promotes the increasingly accepted view that the striatum is intimately involved in higher order cognitive functions. Our results also suggest that the importance of these brain regions in cognitive ability might differ for male and female children

Negative Associations between Corpus Callosum Midsagittal Area and IQ in a Representative Sample of Healthy Children and Adolescents

Documented associations between corpus callosum size and cognitive ability have heretofore been inconsistent potentially owing to differences in sample characteristics, differing methodologies in measuring CC size, or the use of absolute versus relative measures. We investigated the relationship between CC size and intelligence quotient (IQ) in the NIH MRI Study of Normal Brain Development sample, a large cohort of healthy children and adolescents (aged six to 18, n = 198) recruited to be representative of the US population. CC midsagittal area was measured using an automated system that partitioned the CC into 25 subregions. IQ was measured using the Wechsler Abbreviated Scale of Intelligence (WASI). After correcting for total brain volume and age, a significant negative correlation was found between total CC midsagittal area and IQ (r = −0.147; p = 0.040). Post hoc analyses revealed a significant negative correlation in children (age<12) (r = −0.279; p = 0.004) but not in adolescents (age $\geq$ 12) (r = −0.005; p = 0.962). Partitioning the subjects by gender revealed a negative correlation in males (r = −0.231; p = 0.034) but not in females (r = 0.083; p = 0.389). Results suggest that the association between CC and intelligence is mostly driven by male children. In children, a significant gender difference was observed for FSIQ and PIQ, and in males, a significant age-group difference was observed for FSIQ and PIQ. These findings suggest that the correlation between CC midsagittal area and IQ may be related to age and gender

Negative associations between corpus callosum midsagittal area and IQ in a representative sample of healthy children and adolescents.

Documented associations between corpus callosum size and cognitive ability have heretofore been inconsistent potentially owing to differences in sample characteristics, differing methodologies in measuring CC size, or the use of absolute versus relative measures. We investigated the relationship between CC size and intelligence quotient (IQ) in the NIH MRI Study of Normal Brain Development sample, a large cohort of healthy children and adolescents (aged six to 18, n = 198) recruited to be representative of the US population. CC midsagittal area was measured using an automated system that partitioned the CC into 25 subregions. IQ was measured using the Wechsler Abbreviated Scale of Intelligence (WASI). After correcting for total brain volume and age, a significant negative correlation was found between total CC midsagittal area and IQ (r = -0.147; p = 0.040). Post hoc analyses revealed a significant negative correlation in children (ag

Mediterranean-type diet and brain structural change from 73 to 76 years in a Scottish cohort

STUDY FUNDING The data were collected by a Research into Ageing programme grant; research continues as part of the Age UK–funded Disconnected Mind project. The work was undertaken by The University of Edinburgh Centre for Cognitive Ageing and Cognitive Epidemiology, part of the cross-council Lifelong Health and Wellbeing Initiative (MR/K026992/1), with funding from the BBSRC and Medical Research Council. Imaging and image analysis was performed at the Brain Research Imaging Centre (sbirc.ed.ac.uk/), Edinburgh, supported by the Scottish Funding Council SINAPSE Collaboration. Derivation of mean cortical thickness measures was funded by the Scottish Funding Council’s Postdoctoral and Early Career Researchers Exchange Fund awarded by SINAPSE to David Alexander Dickie. L.C.A.C. acknowledges funding from the Scottish Government's Rural and Environment Science and Analytical Services (RESAS) division.Peer reviewedPublisher PD

Las variaciones de superficie cortical en la corteza dorsolateral prefrontal predicen mejor el futuro desempeño cognitivo que la inteligencia fluida y la memoria operativa

Are cognitive and biological variables useful for predicting future behavioral outcomes? Method: In two independent groups, we measured a set of cognitive (fluid and crystallized intelligence, working memory, and attention control) and biological (cortical thickness and cortical surface area) variables on two occasions separated by six months, to predict behavioral outcomes of interest (performance on an adaptive version of the n-back task) measured twelve and eighteen months later. We followed three stages: discovery, validation, and generalization. In the discovery stage, cognitive/biological variables and the behavioral outcome of interest were assessed in a group of individuals (in-sample). In the validation stage, the cognitive and biological variables were related with a parallel version of the behavioral outcome assessed several months later. In the generalization stage, the validation findings were tested in an independent group of individuals (out-of-sample). Results: The key fi nding revealed that cortical surface area variations within the right dorsolateral prefrontal cortex predict the behavioral outcome of interest in both groups, whereas the cognitive variables failed to show reliable predictive validity. Conclusions: Individual differences in biological variables might predict future behavioral outcomes better than cognitive variables concurrently correlated with these behavioral outcomesAntecedentes: ¿Predicen las variables cognitivas y biológicas el futuro desempeño cognitivo? Método: en dos grupos independientes de participantes se miden variables cognitivas (inteligencia fluida y cristalizada, memoria operativa y control atencional) y biológicas (grosor y superficie cortical) en dos ocasiones separadas por seis meses, para predecir el desempeño en la tarea n-back valorado doce y dieciocho meses después. Se completan tres etapas: descubrimiento, validación y generalización. En la de descubrimiento se valoran en un grupo de individuos las variables cognitivas/biológicas y el desempeño a predecir. En la de validación, se relacionan las mismas variables con una versión paralela de la n-back completada meses después. En la de generalización, los resultados de la validación se replican en un grupo independiente de individuos. Resultados: las variaciones de superficie cortical en la corteza dorsolateral prefrontal derecha predicen el desempeño cognitivo en los dos grupos independientes de individuos, mientras que las variables cognitivas no contribuyen a la predicción del desempeño futuro. Conclusiones: las diferencias individuales en determinadas variables biológicas predicen el desempeño cognitivo mejor que las variables cognitivas que correlacionan concurrentemente con ese desempeñoThis project was supported by PSI2017-82218-P (Ministerio de Economía, Industria y Competitividad, Spain

Changes in resting-state functionally connected parieto-frontal networks after videogame practice

Neuroimaging studies provide evidence for organized intrinsic activity under task-free conditions. This activity serves functionally relevant brain systems supporting cognition. Here, we analyze changes in resting-state functional connectivity after videogame practice applying a test–retest design. Twenty young females were selected from a group of 100 participants tested on four standardized cognitive ability tests. The practice and control groups were carefully matched on their ability scores. The practice group played during two sessions per week across 4 weeks (16 h total) under strict supervision in the laboratory, showing systematic performance improvements in the game. A group independent component analysis (GICA) applying multisession temporal concatenation on test–retest resting-state fMRI, jointly with a dual-regression approach, was computed. Supporting the main hypothesis, the key finding reveals an increased correlated activity during rest in certain predefined resting state networks (albeit using uncorrected statistics) attributable to practice with the cognitively demanding tasks of the videogame. Observed changes were mainly concentrated on parietofrontal networks involved in heterogeneous cognitive functions

Interactive effects of dehydroepiandrosterone and testosterone on cortical thickness during early brain development

Humans and the great apes are the only species demonstrated to exhibit adrenarche, a key endocrine event associated with prepubertal increases in the adrenal production of androgens, most significantly dehydroepiandrosterone (DHEA) and to a certain degree testosterone. Adrenarche also coincides with the emergence of the prosocial and neurobehavioral skills of middle childhood and may therefore represent a human-specific stage of development. Both DHEA and testosterone have been reported in animal and in vitro studies to enhance neuronal survival and programmed cell death depending on the timing, dose, and hormonal context involved, and to potentially compete for the same signaling pathways. Yet no extant brain-hormone studies have examined the interaction between DHEA- and testosterone-related cortical maturation in humans. Here, we used linear mixed models to examine changes in cortical thickness associated with salivary DHEA and testosterone levels in a longitudinal sample of developmentally healthy children and adolescents 4–22 years old. DHEA levels were associated with increases in cortical thickness of the left dorsolateral prefrontal cortex, right temporoparietal junction, right premotor and right entorhinal cortex between the ages of 4–13 years, a period marked by the androgenic changes of adrenarche. There was also an interaction between DHEA and testosterone on cortical thickness of the right cingulate cortex and occipital pole that was most significant in prepubertal subjects. DHEA and testosterone appear to interact and modulate the complex process of cortical maturation during middle childhood, consistent with evidence at the molecular level of fast/nongenomic and slow/genomic or conversion-based mechanisms underlying androgen-related brain development

Structural changes after videogame practice related to a brain network associated with intelligence

Here gray and white matter changes after four weeks of videogame practice were analyzed using optimized voxel-based morphometry (VBM), cortical surface and cortical thickness indices, and white matter integrity computed from several projection, commissural, and association tracts relevant to cognition. Beginning with a sample of one hundred young females, twenty right handed participants were recruited for the study and assigned to a practice or a control group carefully matched by their general cognitive ability scores. After the first scan, the practice group played ‘Professor Layton and The Pandora's Box’ 4 h per week during four weeks. A second scan was obtained at the end of practice and intelligence was measured again. Image analyses revealed gray and white matter changes in the practice group. Gray matter changes theoretically relevant for intelligence were observed for the practice group mainly in frontal clusters (Brodmann areas 9 and 10) and also in smaller parietal and temporal regions. White matter findings were focused in the hippocampal cingulum and the inferior longitudinal fasciculus. These gray and white matter changes presumably induced by practice did not interact with intelligence tests' scores