Your search keyword '"mediodorsal thalamus"' showing total 206 results

201. Subpallidal-pedunculopontine projections but not subpallidal-mediodorsal thalamus projections contribute to spontaneous exploratory locomotor activity

Author

Michael Wu, C.T. Tsai, and Gordon J. Mogenson

Subjects

Male, General Neuroscience, Rats, Inbred Strains, Biology, Globus Pallidus, Locomotor activity, Rats, Projection (mathematics), Pons, Thalamic Nuclei, Mediodorsal thalamus, Exploratory Behavior, Animals, Neurology (clinical), Molecular Biology, Neuroscience, Developmental Biology, Pedunculopontine nucleus

Abstract

The contribution of the pedunculopontine nucleus to exploratory locomotion was investigated in rats. Locomotor activity recorded in a standard open-field apparatus was increased more than two-fold when wooden panels were inserted. This novelty-elicited locomotion was reduced significantly when procaine was injected bilaterally into the pedunculopontine nucleus but not when procaine was injected bilaterally into the mediodorsal thalamus, a second major projection site of the subpallidal area. These results support observations from earlier studies implicating hippocampal-accumbens-subpallidal-pedunculopontine projections in exploratory locomotion.

Published

1989

202. How brain lesions affect normal and neurotic behavior; an experimental approach

Author

Jules H. Masserman and Curtis Pechtel

Subjects

CATS, Social characteristics, Neurotic Disorders, Physiology, Brain, Affect (psychology), Neuroticism, Psychiatry and Mental health, Mediodorsal thalamus, Brain lesions, Humans, Wounds and Injuries, Psychology, Neuroscience

Abstract

Over a period of 6 years 50 cats and 40 monkeys were closely observed for (1) their individual and social characteristics; (2) their capacity to learn various skills; and (3) the form and persistence of the experimental neuroses induced in 23 cats and 18 monkeys by exposure to adaptational conflicts. The animals were then subjected severally to lesions of the anterior or mediodorsal thalamus, the amygdalae, or cerebral areas 13, 23, or 24. The results to date indicate that the general and specific effects of cerebral lesions vary not only with their site and extent but also with (1) the preoperative experiences of each animal and (2) its postoperative care and re-training.

Published

1956

203. [Untitled]

Subjects

0301 basic medicine, Cognitive Neuroscience, Experimental and Cognitive Psychology, Cognition, Cognitive neuroscience, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Neuropsychology and Physiological Psychology, Frontal lobe, Neuroimaging, Mediodorsal thalamus, Mediodorsal thalamic nucleus, Psychology, Set (psychology), Prefrontal cortex, Neuroscience, 030217 neurology & neurosurgery

Abstract

The function of the human mediodorsal thalamic nucleus (MD) has so far eluded a clear definition in terms of specific cognitive processes and tasks. Although it was at first proposed to play a role in long-term memory, a set of recent studies in animals and humans has revealed a more complex, and broader, role in several cognitive functions. The MD seems to play a multifaceted role in higher cognitive functions together with the prefrontal cortex and other cortical and subcortical brain areas. Specifically, we propose that the MD is involved in the regulation of cortical networks especially when the maintenance and temporal extension of persistent activity patterns in the frontal lobe areas are required.

204. Thalamocortical networks of decision making

Author

Alcaraz, Fabien, Coutureau, Etienne, Wolff, Mathieu, Kremer, Éric Joseph, Le Moine, Catherine, Cassel, Jean-Christophe, Poucet, Bruno, and STAR, ABES

Subjects

[SDV.SA] Life Sciences [q-bio]/Agricultural sciences, [SDV.MHEP] Life Sciences [q-bio]/Human health and pathology, Prise de décision, Contrôle de l’action, Anatomie, Cortex préfrontal, Action control, Prédiction, Thalamus submédian, Prefrontal cortex, Chemogenetic, Apprentissage associatif, Thalamus médiododorsal, Associative learning, Submedius thalamus, Thalamocortical loop, Pharmacogénétique, Rat, Anatomy, Mediodorsal thalamus, Boucle thalamocorticale, Decision-making

Abstract

Survival of living organisms depends on the ability to make decision adapted to theircurrent needs and desires. Such an ability results from the integration of multiple basiccognitive processes such as events prediction and action control. These processes are bestinvestigated within the framework of associative learning. Past research has demonstratedthat these processes are supported by a widespread neuronal circuit, in which the prefrontalcortex and his major afferent structure, the mediodorsal thalamus (MD), play a central role.In this context, this thesis work aimed at investigating the functional role of the exchangesbetween these two structures in decision making.In a first part of this work, we assessed the role of the MD in prediction and control.We showed that MD lesioned rats are unable to adapt their behavior to a change in rewardvalue, in an experimental procedure asking the integration of instrumental and Pavloviancontingencies. This result confirmed the fundamental role of MD in goal representation. As asecond step, we performed an anatomical study in order to characterize the architecture ofthe thalamocortical pathways arising from the MD. We first showed that multiplethalamocortical pathways originate from segregated neuronal populations within the MD.We also discovered a poorly known thalamic structure innervating the orbitofrontal cortex,the submedius nuclei. In order to understand the functional role of these pathways, we useda conditional chemogenetic technique aimed at inactivating neuronal populations selectedon the basis of their projections. Using this technique, we showed that the animal’s abilitiesto represent either the value or the action-reward relationship depend on the directionalityof MD and prefrontal cortex exchanges. Finally, we identified a specific role for thesubmedius nuclei in updating Pavlovian contingencies, by using a more classical lesioningapproach.Taken together, these results support the idea that decision making involved severalthalamocortical loops, differentially supporting prediction and action control., La capacité des organismes à survivre dans un environnement changeant dépendlargement de leur aptitude à prendre des décisions adaptées. Cette fonction complexerésulte notamment de l’intégration de processus de prédiction et de contrôle de l’action,classiquement étudiés dans le corpus théorique et méthodologique des apprentissagesassociatifs. Les bases neurobiologiques de ces processus sont largement distribués au seinde circuits au sein desquels le cortex préfrontal et son afférence principale, le thalamusmédiodorsal (MD) jouent un rôle important. Dans ce contexte, le travail entrepris au coursde ce travail de thèse visait à déterminer le rôle fonctionnel des échanges entre ces deuxstructures dans le cadre de la prise de décision.Une première partie de ce travail a visé à confirmer le rôle spécifique du MD dans lesprocessus de prise de décision. Par l’utilisation d’un protocole expérimental nécessitantl’intégration des contingences instrumentales et Pavloviennes pour obtenir unerécompense, nous avons démontré que des rats porteurs d’une lésion du MD n’étaient pascapables d’adapter leur comportement en fonction des changements de valeur de larécompense, confirmant ainsi le rôle fondamental du MD dans la représentation du but.Surla base de ce résultat, nous avons ensuite entrepris une étude d’anatomie descriptive visantà caractériser finement l’architecture des projections thalamocorticales issues du MD. Cetteétude nous a permis de démontrer que de multiples voies thalamocorticales issues du MDtrouvent leur origine dans des populations neuronales thalamiques essentiellementségrégées mais également que la région orbitofrontale était innervée par une régionthalamique méconnue, le thalamus submédian. Pour éprouver les fonctions de cesdifférentes voies, nous avons d’abord mis en place une stratégie d’inactivation réversible depopulations neuronales sélectionnées sur la base de leurs projections spécifiques par uneméthode pharmacogénétique conditionnelle. L’utilisation de cette méthode nous a permisde révéler que la capacité de l’animal à se représenter la valeur ou la relation actionrécompensedépend de la direction des échanges entre le MD et le cortex préfrontalmédian. Par ailleurs, une approche lésionnelle comparée plus classique nous a permisd’identifier un rôle fonctionnel spécifique du thalamus submédian dans la mise à jour descontingences Pavloviennes.12Pris dans leur ensemble, ces résultats sont en accord avec l’idée que des bouclesthalamocorticales distinctes sont impliquées dans les processus de prédiction et de contrôlede l’action nécessaires à une prise de décision adaptée.

205. Altered thalamocortical rhythmicity and connectivity in mice lacking Ca V 3.1 T-type Ca²⁺ channels in unconsciousness

Author

Choi, Soonwook, Yu, Eunah, Lee, Seongwon, and Llinás, Rodolfo R.

Published

2015

206. Extrasynaptic GABAA receptors in mediodorsal thalamic nucleus modulate fear extinction learning

Author

Sukchan Lee, Eun Mi Hwang, Hee-Sup Shin, Bo Yong Lee, Gireesh Gangadharan, and Afshin Paydar

Subjects

Male, Agonist, Mediodorsal Thalamic Nucleus, medicine.drug_class, Extrasynaptic GABAA receptor, Transfection, Extinction, Psychological, Tonic (physiology), Mice, Cellular and Molecular Neuroscience, medicine, Animals, Receptor, Molecular Biology, Mice, Knockout, Integrases, GABAA receptor, Research, Classical conditioning, Tonic GABA inhibition, Fear, Isoxazoles, social sciences, Extinction (psychology), Receptors, GABA-A, humanities, Pyridazines, Freezing behavior, Fear extinction, nervous system, GABRA4, Synapses, Gabazine, Psychology, Mediodorsal thalamus, Extrasynaptic GABA(A) receptor, Anxiety disorders, Neuroscience, medicine.drug

Abstract

Background: The gamma-amino-butyric acid (GABA) system is a critical mediator of fear extinction process. GABA can induce "phasic" or "tonic" inhibition in neurons through synaptic or extrasynaptic GABA(A) receptors, respectively. However, role of the thalamic "tonic GABA inhibition" in cognition has not been explored. We addressed this issue in extinction of conditioned fear in mice. Results: Here, we show that GABA(A) receptors in the mediodorsal thalamic nucleus (MD) modulate fear extinction. Microinjection of gabazine, a GABA(A) receptor antagonist, into the MD decreased freezing behavior in response to the conditioned stimulus and thus facilitated fear extinction. Interestingly, microinjection of THIP (4,5,6,7-tetrahydroisoxazolo[5,4-c]pyridin-3-ol), a preferential agonist for the delta-subunit of extrasynaptic GABA(A) receptors, into the MD attenuated fear extinction. In the opposite direction, an MD-specific knock-out of the extrasynaptic GABA(A) receptors facilitated fear extinction. Conclusions: Our results suggest that "tonic GABA inhibition" mediated by extrasynaptic GABA(A) receptors in MD neurons, suppresses fear extinction learning. These results raise a possibility that pharmacological control of tonic mode of GABA(A) receptor activation may be a target for treatment of anxiety disorders like post-traumatic stress disorder.