Participação do sistema glutamatérgico do córtex pré-frontal medial ventral na modulação das consequências comportamentais do estresse de nado forçado / Participation of the glutamatergic system of the ventral medial prefrontal cortex in the modulation of behavioral consequences of forced swimming stress.

Pereira, Vitor Silva

20 July 2011

Acredita-se que quantidades elevadas de glutamato estejam relacionadas à neurobiologia da depressão e trabalhos recentes indicam que a quantidade de glutamato cortical está aumentada em pacientes depressivos quando comparada a indivíduos sadios. Dentre as estruturas corticais, o córtex pré-frontal medial ventral (CPFMv), dividido em infralímbico (IL) e pré-límbico (PL), tem sido mais frequentemente implicado no desenvolvimento de transtornos mentais, como a depressão. Considerando evidências de que o IL e o PL podem agir de forma diferente quanto ao controle emocional em resposta ao estresse, o presente trabalho visou avaliar a hipótese de participação da neurotransmissão glutamatérgica do CPFMv, IL e PL, no desenvolvimento das respostas comportamentais ao estresse de nado forçado, um modelo preditivo de efeitos antidepressivos. Para tal, investigamos os efeitos induzidos pela administração no IL ou no PL, de LY 235959, um antagonista dos receptores glutamatérgicos do tipo NMDA, em três momentos diferentes, em animais submetidos ao teste do nado forçado. A administração de LY 235959, no IL ou PL, produziu efeitos do tipo antidepressivo, sendo esse efeito sensível ao tempo de administração da droga em relação à exposição ao nado forçado. Sendo assim, foi observado efeito antidepressivo quando o bloqueio glutamatérgico no PL ocorreu imediatamente após o nado ou antes da re-exposição ao estresse; enquanto no IL, o tratamento promoveu efeito antidepressivo apenas quando administrado antes da re-exposição ao nado. Portanto, os resultados sugerem que a neurotransmissão glutamatérgica mediada por receptores NMDA no CPFMv contribui para o desenvolvimento de consequências comportamentais do estresse, de modo que o bloqueio desses receptores facilitaria a adaptação ao estresse e induziria efeitos do tipo-antidepressivo. Os resultados sugerem, ainda, que o PL e o IL participam de maneira semelhante na modulação desses processos. / It is believed that high amounts of glutamate are related to the neurobiology of depression. Recent studies indicate that the amount of cortical glutamate is increased in depressed patients compared to healthy subjects. Among the cortical structures, the ventral medial prefrontal cortex (CPFMv), divided into infralimbic (IL) and prelimbic (PL) has been most often implicated in the development of mental disorders, such as depression. Considering that IL and PL play different roles on the emotional control in response to stress, this study was aimed to evaluate the hypothesis that the activation of glutamate NMDA receptors within the CPFMv, IL and PL, would facilitate the development of forced swimming-induced behavioral responses, an animal model predictive of antidepressants effects. To this end, we investigated the effects induced by the administration in the PL or the IL of LY 235959, an antagonist of NMDA receptors, at three different times, in animals submitted to the forced swimming test. The administration of LY 235959, in the IL or PL, produced antidepressant-like effects, and this effect is sensitive to moment of drug administration in relation to exposure to forced swimming. Thus, the antidepressant-like effect was observed when blocking the NMDA blockade into the PL occurred immediately after swimming or before re-exposure to stress, whereas in the IL, such treatment promoted antidepressant-like effect only when administered before re-exposure to swimming. Therefore, the results suggest that the glutamatergic neurotransmission mediated by NMDA receptors in the CPFMv contributes to the development of behavioral consequences of stress, so that blocking these receptors would facilitate the adaptation to stress and induce antidepressant-like effects. The results also suggest that PL and IL may be similarly involved in modulating these processes.

Behavior

Comportamento

Córtex pré-frontal medial ventral

Depressão

Depression

Forced Swim.

Glutamate

Glutamato

Nado forçado.

Ventral Medial Prefrontal Cortex

A Unified Model of Rule-Set Learning and Selection

Pierson J. Fleischer (5929673)

16 January 2019

A new, biologically plausible model of task-set learning that reproduces effects from both rule-learning experiments and task-switching experiments.<br>

learning model

rule sets

basal ganglia

prefrontal cortex

presynaptic inhibition

task set switching

Rôle(s) des motivations naturelles dans la prise décision : bases neurobiologiques et comportementales / Roles of natural motivations in decision-making : neurobiological and behavioral bases

Chabout, Jonathan

30 October 2012

La prise de décision est un processus indispensable et vital pour les mammifères. Elle permet à l’individu de s’adapter aux changements qui s’opèrent dans son environnement et résulte de l’intégration d’informations sensorielles, émotionnelles, motivationnelles et exécutives (qui peuvent être internes ou externes à l’individu). Des études, à la fois chez le sujet humain (sujet sain, patients cérébrolésés ou atteints de pathologies psychiatriques), et sur les modèles animaux singe, rats ou souris, ont permis d’identifier le cortex préfrontal comme acteur crucial dans ces processus exécutifs complexes. La mise en place au sein de notre laboratoire d’un test d’interaction sociale permettant de générer des prises de décision rapides et adaptées en présence d’un congénère nouveau, nous a permis d’étudier les bases neurobiologiques et comportementales sous-jacentes à la prise de décision et à la flexibilité comportementale. Il est connu que les rongeurs émettent des USVs dont le rôle et les mécanismes motivationnels et/ou émotionnels restent largement inconnus à ce jour. Mon travail de thèse repose principalement sur l’identification des acteurs cérébraux de cette interaction sociale, et sur le rôle putatif des USVs. D’autre part, je me suis employé à comprendre comment les motivations naturelles (telles que la nourriture, l’exploration d’objet ou de l’environnement, et l’interaction avec un congénère) sont intégrées au canevas de prise de décision et comment elles l’influencent.Dans un premier temps, en utilisant des procédures d’imagerie cellulaire basée sur l’expression de gènes précoces (c-fos), et ce, à la fois chez des animaux contrôles et chez des animaux présentant des troubles des comportements sociaux (β2KO), nous avons pu mettre en évidence l’implication différentielle de sous-parties du cortex préfrontal chez la souris. Par la suite, la mise en place d’un logiciel spécifique d’analyse, ainsi que la modulation de l’état de motivation de l’animal lors de la tâche d’interaction sociale, nous a permis de mieux comprendre l’établissement de comportements adaptés lors de l’interaction sociale. Pour finir, en variant les contextes comportementaux, nous avons montré qu’il existe une relation étroite entre état émotionnel et motivationnel de l’animal et émission d’USVs. Notamment, les USVs semblent porter une information spécifique lors de l’interaction sociale qui reste encore largement à déterminer. / Decision-making is one of the most essential process for mammals. It allows the individual to adapt to environmental changes by the integration of sensory, emotional, motivational and executive information. Numerous studies, in human subject (healthy or not), and on animal models like monkey, rats or mice, have allowed the identification of a major actor in these complex processes: the prefrontal cortex. In our laboratory, we set up a new test, called the social interaction task -SIT-, to generate quick and adapted decision-making in presence of a new congener. This task was used to dissect neural and behavioral bases underlying decision-making and behavioral flexibility during social interaction. It is well known now that rodents emit ultrasonic vocalizations -USVs-, of which roles and mechanisms (motivational or emotional) remain largely unknown. My work was devoted to the identification of brain structures that allow flexible social interactions, and to the unraveling of the putative role(s) of USVs during SIT. I also tried to understand how natural motivations (like social interaction, exploration, and food consumption) take part in the decision-making process.First, by using cellular imaging procedure based on the expression of immediate early genes (c-fos): we were able to highlight the differential involvement of sub-areas of the prefrontal cortex in mice. Subsequently, the development of a new specific software, and the ability to modulate the motivational state of the animal, enabled us to understand better the establishment of adapted behaviors during the SIT. Finally, by varying behavioral contexts, we found a tight relationship between emotional/motivational states and USVs emissions. Notably, USVs appear to carry specific information in social interaction, and this point largely remains to be determined.

Prise de décision

Motivation

Interaction sociale

Cortex préfrontal

Vocalisations

Decision-making

Motivation

Social interaction

Prefrontal cortex

Ultrasonic vocalizations

Emotional state

Contributions of COMT and DAT to regulation of phasic dopamine release and reward-guided behaviour

Korn, Clio

January 2016

Fine temporal regulation of dopamine transmission is critical to its effects on behaviour. Dopamine can be cleared from the synapse either by recycling via the dopamine transporter (DAT) or by enzymatic degradation involving catechol-O-methyltransferase (COMT). DAT recycling predominates in striatum and contributes to dopaminergic regulation of reward-guided behaviour, while COMT degradation predominates in cortex and modulates executive functions. However, human functional imaging studies demonstrate interactive effects of DAT and COMT genotype, suggesting that the traditional division between DAT and COMT is not so clear-cut. Given the interdependence of mesolimbic and mesocortical circuitry and the presence of COMT in the striatum, it is possible that DAT and COMT interact to a greater extent than previously thought. We investigated the contributions of DAT and COMT to regulation of dopamine transmission and reward-guided behaviour by combining in vivo electrochemical recording, pharmacology, and behavioural testing in mice. Using fast scan cyclic voltammetry to record evoked dopamine release in anaesthetised animals, we found that systemic DAT blockade increased the size of dopamine transients in the nucleus accumbens (NAc) but not in the medial frontal cortex (MFC), demonstrating that DAT regulates phasic striatal dopamine release and confirming that DAT makes little contribution to regulation of cortical dopamine transmission. Unexpectedly, COMT inhibition did not affect evoked dopamine transients in either the NAc or the MFC. In agreement with these findings, systemic administration of a DAT blocker, but not of a COMT inhibitor, increased motivation to work for reward in a progressive ratio paradigm. COMT inhibition also had little effect on reinforcement learning (RL) strategies during reward-guided decision making. Intriguingly, however, we found that DAT blockade both decreased the influence of model-free RL and increased the influence of model-based RL on behaviour. Our study confirms that DAT regulates dopamine transmission in striatum but not in cortex and indicates that sub-second changes in dopamine transmission in both regions are largely insensitive to COMT. However, our behavioural data reveal the importance of striatal dopamine in multiple components of reward-guided behaviour, including both motivational aspects traditionally associated with striatum as well as cognitive aspects heretofore mainly associated with cortical function. Together, these findings emphasise that reward processing occurs across corticostriatal circuits and contribute to our understanding of how striatal dopamine transmission regulates reward-guided behaviours.

616.89

Neural mechanisms of reward-guided learning and irrational decision-making

Papageorgiou, Georgios

January 2016

The ability to take effective decisions is fundamental for successful environmental adaptation and survival. In this thesis, I investigated situations in which decisions appear irrational, at least from certain standpoints. I conducted a behavioural decision-making experiment in two groups of macaques: controls and a group with ventromedial prefrontal cortex/medial orbitofrontal cortex (vmPFC/ mOFC) lesions. Some choices lead to compound outcomes composed of different constituent parts. Control macaques' decisions suggested their estimates of the value of the compound were biased away from the sum of the values of the constituents and towards their mean. Lesions of vmPFC/mOFC diminished the size of the effect so that macaques in some ways appeared to make more rational decisions. Based on the results of this experiment I devised a similar Functional Magnetic Resonance Imaging (fMRI) paradigm with the control animals. This demonstrated strong vmPFC/mOFC activity when similar decisions were made and suggested a value comparison process. In addition, I investigated the role of dopamine in learning using Fast-Scan Cyclic Voltammetry (FSCV), while rats performed a simple decision-making task. Theories about the role of dopamine in learning have focused on the possibility that it codes scalar reward value prediction errors. Less consideration has been given to the possibility that dopamine might reflect prediction errors about reward identities regardless of value. I measured dopamine in the nucleus accumbens when unexpected changes in reward value or identity occurred while rats executed a two-choice two-reward instrumental task. Dopamine levels in the nucleus accumbens reflected reward value prediction errors. In addition, however, they also reflected some information about reward identity under some circumstances. Further investigation suggested that this might be due to differences in the nutritional value of different reward types that did not have clear measurable impacts of behaviour in the tasks that I used.

150

Top-down attention: neural pathways in the human and non-human primate examined by electrophysiology, optogenetics and psychophysics

Hüer, Janina

08 February 2018

No description available.

570

top-down attention

optogenetics

visual pathways

neuronal networks

attentional blink

pupil size

prefrontal cortex

Biologie (PPN619462639)

Os receptores TRPV1 do córtex pré-frontal medial ventral modulam a atividade do barorreflexo cardíaco em ratos / The TRPV1 receptors of the ventral medial prefrontal cortex modulate the activity of cardiac baroreflex in rats

Davi Campos La Gatta

21 June 2013

O córtex pré-frontal medial (CPFM) é uma estrutura pertencente ao sistema límbico, sendo topograficamente divido em córtex cíngulo 1, cíngulo 2, pré- límbico (PL), infra-límbico (IL) e dorsopenducular (DP). Sua porção ventral (CPFMv) corresponde ao PL, IL e DP. O PL e o IL são capazes de modular o arco reflexo baroceptor, permitindo ajustes cardiovasculares que ocorrem durante reações de defesa. Trabalhos mostram que a transmissão glutamatérgica do CPFMv é capaz de controlar a atividade barorreflexa através de receptores NMDA. Além disso a liberação de glutamato pode ser modulada por outros neurotransmissores, como os endocanabinóides, que além de ativarem receptores CB1, também são agonistas de receptores TRPV1, nos quais facilitam a liberação de glutamato em várias áreas do sistema nervoso central. Portanto, a hipótese deste trabalho é a de que os receptores TRPV1 presentes no CPFM estariam participando da modulação do barorreflexo. Para testar esta hipóstese foram utilizados ratos Wistar, pesando de 240 a 260 gramas. Esses animais foram submetidos a estereotaxia para implante de cânulas guia no CPFMv. Setenta e duas horas depois foi implantado um cateter de polietileno na artéria femoral dos animais, o qual foi conectado ao aparelho de aquisição para monitoração da frequência cardíaca e pressão arterial no dia do teste. Um segundo cateter foi implantado na veia femoral para infusão de drogas vasoativas. Foram usados dois antagonistas de receptores TRPV1, a capsazepina e o a 6-iodonordiidrocapsaicina (6-IODO), além do agonista desses receptores, a capsaicina. A microinjeção da capsazepina no CPFMv reduziu o ganho das curvas de regressão linear dos componentes bradicárdico e taquicárdico do barorreflexo. Os parâmetros da curva sigmoide também foram reduzidos. Posteriormente, a administração de 6-IODO também reduziu o ganho das curvas de regressão linear das respostas bradicárdica e taquicárdica, bem como os parâmetros das curvas de regressão não-linear. Esta droga também foi utilizada para verificar se os receptores TRPV1 do PL e IL modulam diferentemente a resposta barorreflexa. Foi verificado que ambas as subáreas modulam a atividade barorreflexa da mesma maneira. A capsaicina, quando microinjetada bilateralmente no CPFMv aumentou o ganho das curvas de regressão linear relativas à bradicardia e taquicardia reflexas bem como aumentou os valores dos parâmetros da curva sigmoide. Além disso, o pré-bloqueio dos receptores TRPV1 do CPFMv com uma dose inefetiva de 6-IODO aboliu o aumento da atividade barorreflexa induzida pela capsaicina. Em um outro grupo de animais foi feito o pré-tratamento do CPFMv com uma dose inefetiva de 6-IODO e cinco minutos depois administrou-se doses maiores de capsaicina. Observou-se um deslocamento da curva dose resposta da capsaicina para a direita, sem alteração do efeito máximo. A conclusão do presente trabalho é a de que os receptores TRPV1 presentes no CPFMv modulam a resposta do arco reflexo baroceptor. / Medial prefrontal cortex (MPFC) is a limbic structure, being topographically divided in cingulate cortex 1, cingulate cortex 2, prelimbic (PL), infralimbic (IL) and dorsopenducular (DP) cortices. The ventral portion of the MPFC (vMPFC) comprises the IL, PL and DP. The IL and PL regions are able to modulate cardiovascular responses associated with defensive reactions, such as the baroreceptor reflex arc. Some studies have shown that the vMPFC glutamatergic transmission modulates the baroreflex activity, through NMDA receptors. Moreover, the glutamatergic release is controlled by other neurotransmitters, such as the endocannabinoids which are agonists of the TRPV1 receptors, besides its action on the CB1 receptors. Furthermore, the TRPV1 channels facilitate the glutamatergic transmission in several brain areas. Thus, the hypothesis of the present work is that the vMPFC TRPV1 receptors are involved in the baroreflex modulation. In order to test this assumption, male Wistar rats weighing 240-260 g were used. These animals were submitted to the stereotaxic surgery to implant stainless steel guide cannulas into the vMPFC. Seventy-two hours later, the animals had a polyethylene catheter implanted into the femoral artery which was connected to the acquisition system to blood pressure and heart rate recording in the day-test. A second catheter was implanted into the femoral vein in order to infuse vasoactive drugs. Two TRPV1 receptors antagonists, 6-iodonordihydrocapsaicina (6-IODO) and caspazepine, besides the TRPV1 agonist, capsaicin, were used. Capsazepine microinjection into the vMPFC reduced the slope of the linear regression of the bardycardic and tachycardic components of the baroreflex. The sigmoid curve parameters were also reduced. Afterwards, the administration of 6-IODO also decreased the slope of the tachycardic and bradycardic responses, as well as the non-linear regression curve parameters. On the other hand, capsaicin bilaterally microinjected into the vMPFC increased the slope in both bradycardic and tachycardic reflex responses as well as the sigmoid curve parameters. Pretreatment of the vMPFC TRPV1 receptors with an ineffective dose of 6-IODO abolished the baroreflex activity increasing induced by capsaicin. In another group of animals, higher doses of capsaicin were administred into the vMPFC 5 minutes after the microinjection of an ineffective dose of 6-IODO. Thus, a doseresponse curve right displacement was observed, with no alteration in the maximum effect level of capsaicin. Beyond that, PL and IL TRPV1 receptors equally modulate baroreceptor reflex arc. In conclusion, the present work shows tha vMPFC TRPV1 receptors are involved in the baroreceptor reflex response

Atividade barorreflexa

Córtex pré-frontal medial ventral

Receptores TRPV1

Baroreflex activity

TRPV1 receptors

Ventral medial prefrontal cortex

"Avaliação volumétrica e neuroquímica do córtex pré-frontal dorsolateral esquerdo de pacientes pediátricos com transtorno depressivo maior: um estudo utilizando espectroscopia por ressonância magnética de próton" / Volumetric and neurochemical evaluation of the left dorsolateral prefrontal cortex in pediatric patients with major depressive disorder: a study using Proton Magnetic Resonance Spectroscopy

Sheila Cavalcante Caetano

12 January 2006

A Ressonância Magnética e a Espectroscopia por Ressonância Magnética de Hidrogênio têm sido empregadas em estudos anatômicos e neuroquímicos do Transtorno Depressivo Maior (TDM). Dezenove crianças com TDM e 24 controles saudáveis foram avaliados em um magneto de 1,5 Tesla (Philips Intera 8.1.1.). Em comparação aos controles saudáveis, crianças com TDM apresentaram: menores volumes de hipocampo esquerdo; e no voxel único em CPFDL esquerdo: menores níveis dos compostos de colina, e maiores níveis de mio-inositol em CPFDL esquerdo. Menores níveis dos compostos de colina podem refletir uma diminuição da renovação de membranas. Maiores níveis de mio-inositol podem representar uma alteração no sistema de segundos mensageiros intracelulares / Magnetic resonance imaging and proton magnetic resonance spectroscopy have been applied to anatomical and neurochemical studies of Major Depressive Disorder (MDD). Nineteen children with MDD and 24 healthy controls were evaluated on a 1.5 Tesla (Philips Intera 8.1.1.) MRI. Compared to healthy controls, children with MDD presented: smaller left hippocampal volumes; and lower levels of choline-containing-compounds and higher myo-inositol levels in the left DLPFC. Lower levels of choline-containing-compounds in pediatric patients with MDD may reflect lower cell membrane turn-over. Higher myo-inositol levels in MDD may represent a disturbed secondary messengers system

Córtex pré-frontal

Criança

Hipocampo

Transtorno depressivo

Child

Depressive disorder

Hippocampus

Magnetic resonance spectroscopy

Prefrontal cortex

Neurocomputational model for learning, memory consolidation and schemas

Dupuy, Nathalie

January 2018

This thesis investigates how through experience the brain acquires and stores memories, and uses these to extract and modify knowledge. This question is being studied by both computational and experimental neuroscientists as it is of relevance for neuroscience, but also for artificial systems that need to develop knowledge about the world from limited, sequential data. It is widely assumed that new memories are initially stored in the hippocampus, and later are slowly reorganised into distributed cortical networks that represent knowledge. This memory reorganisation is called systems consolidation. In recent years, experimental studies have revealed complex hippocampal-neocortical interactions that have blurred the lines between the two memory systems, challenging the traditional understanding of memory processes. In particular, the prior existence of cortical knowledge frameworks (also known as schemas) was found to speed up learning and consolidation, which seemingly is at odds with previous models of systems consolidation. However, the underlying mechanisms of this effect are not known. In this work, we present a computational framework to explore potential interactions between the hippocampus, the prefrontal cortex, and associative cortical areas during learning as well as during sleep. To model the associative cortical areas, where the memories are gradually consolidated, we have implemented an artificial neural network (Restricted Boltzmann Machine) so as to get insight into potential neural mechanisms of memory acquisition, recall, and consolidation. We analyse the network's properties using two tasks inspired by neuroscience experiments. The network gradually built a semantic schema in the associative cortical areas through the consolidation of multiple related memories, a process promoted by hippocampal-driven replay during sleep. To explain the experimental data we suggest that, as the neocortical schema develops, the prefrontal cortex extracts characteristics shared across multiple memories. We call this information meta-schema. In our model, the semantic schema and meta-schema in the neocortex are used to compute consistency, conflict and novelty signals. We propose that the prefrontal cortex uses these signals to modulate memory formation in the hippocampus during learning, which in turn influences consolidation during sleep replay. Together, these results provide theoretical framework to explain experimental findings and produce predictions for hippocampal-neocortical interactions during learning and systems consolidation.

"Avaliação volumétrica e neuroquímica do córtex pré-frontal dorsolateral esquerdo de pacientes pediátricos com transtorno depressivo maior: um estudo utilizando espectroscopia por ressonância magnética de próton" / Volumetric and neurochemical evaluation of the left dorsolateral prefrontal cortex in pediatric patients with major depressive disorder: a study using Proton Magnetic Resonance Spectroscopy

Caetano, Sheila Cavalcante

12 January 2006

A Ressonância Magnética e a Espectroscopia por Ressonância Magnética de Hidrogênio têm sido empregadas em estudos anatômicos e neuroquímicos do Transtorno Depressivo Maior (TDM). Dezenove crianças com TDM e 24 controles saudáveis foram avaliados em um magneto de 1,5 Tesla (Philips Intera 8.1.1.). Em comparação aos controles saudáveis, crianças com TDM apresentaram: menores volumes de hipocampo esquerdo; e no voxel único em CPFDL esquerdo: menores níveis dos compostos de colina, e maiores níveis de mio-inositol em CPFDL esquerdo. Menores níveis dos compostos de colina podem refletir uma diminuição da renovação de membranas. Maiores níveis de mio-inositol podem representar uma alteração no sistema de segundos mensageiros intracelulares / Magnetic resonance imaging and proton magnetic resonance spectroscopy have been applied to anatomical and neurochemical studies of Major Depressive Disorder (MDD). Nineteen children with MDD and 24 healthy controls were evaluated on a 1.5 Tesla (Philips Intera 8.1.1.) MRI. Compared to healthy controls, children with MDD presented: smaller left hippocampal volumes; and lower levels of choline-containing-compounds and higher myo-inositol levels in the left DLPFC. Lower levels of choline-containing-compounds in pediatric patients with MDD may reflect lower cell membrane turn-over. Higher myo-inositol levels in MDD may represent a disturbed secondary messengers system

Child

Córtex pré-frontal

Criança

Depressive disorder

Hipocampo

Hippocampus

Magnetic resonance spectroscopy

Prefrontal cortex

Transtorno depressivo