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Structure function relationships in medial entorhinal cortexTang, Qiusong 18 March 2015 (has links)
In dieser Arbeit werden Struktur-Funktionsbeziehungen in der medialen entorhinalen Hirnrinde untersucht. Schicht 2 Neurone im medialen entorhinalen Cortex unterteilen sich in calbindin-positive Pyramidenzellen und calbindin-negative Sternzellen. Calbindin-positive Pyramidenzellen bündeln ihre apikalen Dendriten zusammen und formen Zellhaufen, die in einem hexagolen arrangiert sind. Das Gitter von calbindin-positiven Pyramidenzellhaufen ist an Schicht 1 Axonen und dem Parasubiculum ausgerichtet und wird durch cholinerge Eingänge innerviert. Calbindin-positive Pyramidenzellen zeigen stark theta-modulierte Aktivität. Sternzellen sind vertreut in der Schicht 2 angeordnet und zeigen nur schwach theta-modulierte Aktivität, ein Befund, der gegen eine Rolle von zell-intrinsischen Oszillationen in der Entstehung von Theta-Modulation spricht. In der Arbeit wurden Methoden entwickelt, um durch die juxtazelluläre Färbung und Identifikation von Zellen, die räumlichen Feuermuster von Schicht 2 Sternzellen und Pyramidenzellen zu bestimmen. Insbesondere wird gezeigt, dass die zeitlichen Feuermuster von Sternzellen und Pyramidenzellen so unterschiedlich sind, dass auch Daten von nichtidentifizierten extrazellulär abgeleiteten Zellen Sternzellen und Pyramidenzellen zugeordnet werden können. Die Ergebnisse zeigen, dass Gitterzell (engl. grid cell) Feuermuster relativ selten sind und in der Regel in Pyramidenzellen beobachtet werden. Grenzzell (engl. border cell) Feuermuster sind dagegen meistens in Sternzellen zu beobachten. Weiterhin wurde die Anatomie und Physiologie des Parasubiculums untersucht. Die Ergebnisse deuten auf die Existenz eines hexagonalen ‘Gitterzell-gitters’ in der entorhinalen Hirnrinde hin und sprechen für starke Struktur-Funktionsbeziehungen in diesem Teil der Hirnrinde. / Little is known about how medial entorhinal cortical microcircuits contribute to spatial navigation. Layer 2 principal neurons of medial entorhinal cortex divide into calbindin-positive pyramidal cells and dentate-gyrus-projecting calbindin-negative stellate cells. Calbindin-positive pyramidal cells bundled dendrites together and formed patches arranged in a hexagonal grid aligned to layer 1 axons, parasubiculum and cholinergic inputs. Calbindin-positive pyramidal cells were strongly theta modulated. Calbindin-negative stellate cells were distributed across layer 2 but avoided centers of calbindin-positive pyramidal patches, and were weakly theta modulated. We developed techniques for anatomical identification of single neurons recorded in trained rats engaged in exploratory behavior. Furthermore, we assigned unidentified juxtacellular and extracellular recordings based on spike phase locking to field potential theta. In layer 2 of medial entorhinal cortex, weakly hexagonal spatial discharges and head direction selectivity were observed in both cell types. Clear grid discharges were predominantly pyramidal cells. Border cells were mainly stellate neurons. Thus, weakly theta locked border responses occurred in stellate cells, whose dendrites sample large input territories, whereas strongly theta-locked grid discharges occurred in pyramidal cells, which sample small input territories in patches organized in a hexagonal ‘grid-cell-grid’. In addition, we investigated anatomical structures and neuronal discharge patterns of the parasubiculum. The parasubiculum is a primary target of medial septal inputs and parasubicular output preferentially targeted patches of calbindin-positive pyramidal cells in layer 2 of medial entorhinal cortex. Parasubicular cells were strongly theta modulated and carried mostly head-direction and border information, and might contribute to shape theta-rhythmicity and the (dorsoventral) integration of information across entorhinal grid scales.
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Functional specialisation of GABAergic cells in the basolateral amygdalaBienvenu, Thomas Claude Michel January 2011 (has links)
The amygdala, in particular its basolateral part (BLA), plays a critical role in binding affective qualities to otherwise neutral stimuli, and in eliciting emotional behaviors. Plasticity of inputs to BLA projection neurons involved in emotional memory has been extensively studied. However, how BLA neurons collectively process sensory information to encode and stabilize emotional memories is unknown. Precise coordination of BLA network activities seems critical. Specifically, timed integration of salient stimuli, and synchrony with hippocampal theta oscillations appear to be important. Recent reports suggest that GABAergic neurons may be instrumental in shaping ensemble activity in the BLA. Studies of neocortex and hippocampus showed that diverse GABAergic interneuron types play highly specific roles in coordinating network operations. The presence of similar interneuron populations in the BLA suggests comparable mechanism may govern its activities. However, GABAergic cell types and their functions have not been characterized.
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Determinants of neuronal firing patterns in the hippocampusTukker, Jan Johan January 2009 (has links)
The activity of networks subserving memory and learning in the hippocampus is under the control of GABAergic interneurons. In order to test the contribution of distinct cell types, I have recorded extracellularly, labelled, and identified different types of interneuron in area CA3 of the hippocampus, a region implicated in the generation of gamma and theta oscillations, and the initiation of sharp-waves. I present here a detailed analysis of the spike timing of parvalbumin-positive (PV) basket and physiologically identified pyramidal cells in area CA3, relative to various network states recorded in area CA3 and CA1 simultaneously. Additionally, I have shown by detailed analysis that five classes of previously recorded and identified CA1 interneuron fired with cell type specific firing patterns relative to local gamma oscillations. In CA3, PV basket cells fired phase locked to theta and gamma oscillations recorded in CA1 as well as in CA3, and increased their firing rates during CA1 sharp-waves. Pyramidal cells in CA3 were also phase-locked, but fired at phases different from basket cells. During theta oscillations, CA3 pyramidal and PV basket cells were phase locked to both CA1 and CA3 theta equally, suggesting a wide coherence of these oscillations; in contrast, cells fired more strongly phase-locked to gamma oscillations in CA3 than in CA1, suggesting a specific role for CA3 in the generation of this rhythm. In contrast to theta and gamma oscillations, CA3 basket cells were phase-locked to ripples in area CA3 but not in CA1. Overall, my results show that the spike timing of several types of interneuron in CA1, and PV basket cells in CA3, is correlated in a cell- and area-specific manner with the generation of particular states of synchronous activity.
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Modeling of high-frequency coding for single cortical cells and precisely manipulating action-potential timing in vivoDoose, Jens Peter 30 July 2018 (has links)
Diese Arbeit beschäftigt sich sowohl mit der experimentell motivierten Fragestellung nach der Kontrolle der Einzelzellaktivität kortikaler Neurone sowie mit der theoretischen Beschreibung der neuronalen Dynamik und ihrer Transfereigenschaften anhand einfacher Neuronenmodelle. Hierfür werden in-vivo Daten, die mit Hilfe der juxtazellulären Stimulation mit weißem bandpass limitiertem Gaußschem Rauschen erhoben wurden, verwendet. Mit Parameterfits einfacher Neuronenmodelle werden die experimentell ermittelten Pulszugstatistiken sowie die präzisen Zeitpunkte der einzelnen Aktionspotentiale quantitativ reproduziert. Diese Untersuchungen zeigen, dass mit dynamischen Rauschstimuli in juxtazellulärer Stimulation verlässlich und reproduzierbar Pulszüge in einzelnen kortikalen Neuronen hervorgerufen werden können. Weiterhin offenbart die Analyse der Daten die Eigenschaft der untersuchten Neurone frequenzunabhängig, bishin zu Vielfachen der Feuerrate des Neurons, Information über Signalkomponenten zu transferieren. Diese Eigenschaft steht im Widerspruch zum Verhalten der einfachsten (und populärsten) integrate-and-fire Modelle, die die Zelle ohne Auflösung ihrer räumlichen Struktur näherungsweise beschreiben. Die Erweiterung solcher Ein-Kompartiment Modelle auf ein Zwei-Kompartiment Modell und die damit eingeführte Unterscheidung zwischen Soma und Dendrit ermöglicht es, für einzelne Neuronen sämtliche experimentell erhobenen Statistiken, einschließlich des Hochfrequenz-
Transfers, quantitativ zu reproduzieren. Zusätzlich zu den obigen Untersuchungen wird eine Methode vorgestellt, um, anhand von Input-Output Statistiken konkreter Neurone, Gaußsche Stimuli zu berechnen, die in der jeweiligen Zelle einen vorgeschriebenen Pulszug hervorrufen. In Experimenten und Simulationen wird gezeigt, dass diese vorgeschriebenen Pulszüge mit einer Verlässlichkeit erzeugt werden können, die in etwa der intrinsischen Verlässlichkeit des untersuchten Neurons entspricht. / This work elaborates on the question to which extent experimental control about the activity of single cortical neurons can be achieved and deals with the theoretical description of the neuronal dynamics. To this end, in-vivo data that have been recorded from juxtacellular experiments in cortical neurons are used. By means of parameter optimization, simple neuron models are fitted in order to quantitatively reproduce the measured spike train statistics and specific action potential timings. The analysis reveals that dynamic noise-stimuli can be used in juxtacellular stimulation to reliably generate reproducible spike trains in single cortical neurons. The analysis also reveals that the cells show a marked broadband coding of information, up to frequencies that are multiples of the firing rate of the respective neuron. This is in contrast to what is known for the simplest (and most popular) integrate-and-fire models, for which the cellular dynamics are described by a single space-independent variable. The extension of these one-compartment models to two-compartment models introduces a spatially distinction between soma and dendrite and we could show that for particular neurons it is sufficient to quantitatively reproduce all experimentally measured spike-train and input-output statistics, including the highfrequency information-transfer. Therefore, the effect of the spatial structure can be an important (structural) mechanism that can have influence on the neuronal dynamics. Additionally to the above considerations, by means of input-output statistics of particular neurons, we propose a method to compute Gaussian stimuli that are supposed to evoke prescribed spike trains in the respective neuron. Using experiments and simulations, we show that the prescribed spike trains can be evoked with a reliability that is comparable to the intrinsic reliability of the neuron under investigation.
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Functional properties of the intact and compromised midbrain dopamine systemKaufmann, Anna-Kristin January 2017 (has links)
The midbrain dopamine system is involved in many aspects of purposeful behaviour and, when compromised, can have devastating effects on movement and cognition as seen in diseases like Parkinson's. In the healthy brain, dopamine neurons are thought to play particularly important roles in learning by signalling errors in reward prediction. The objective of this thesis was to investigate the diversity in the functional properties of the midbrain dopamine system, and how this is altered through genetic variation of relevance to Parkinson's and development of cell phenotype. This objective was addressed with a combination of behavioural experiments, in vivo single-cell recording and labelling (both in anaesthetised as well as awake rodents), immunofluorescence labelling, retrograde tracing and stereology. In a first set of experiments, it was demonstrated that chronic as well as acute genetic challenges can alter the firing patterns of midbrain dopamine neurons. Using a novel bacterial artificial chromosome-transgenic rat model, it was shown that the R1441C mutation in human leucine-rich repeat kinase 2, which is linked to Parkinson's, leads to motor deficits and an age-dependent reduction in the in vivo firing variability and burst firing of substantia nigra pars compacta (SNc) dopamine neurons. These findings help reveal processes of early, pre-degenerative dysfunction in dopamine neurons in Parkinson's. Similar effects on firing variability and burst firing of SNc dopamine neurons were found in a mouse model with conditional knock- out of the transcription factors Forkhead box A1 and A2 (FoxA1/2) in midbrain dopamine neurons. These findings indicate that FoxA1/2 are not only crucial for the early development of dopamine neurons, but also their function in the mature brain. In a second set of experiments in wildtype mice, it was demonstrated that midbrain dopamine neurons (located in SNc and ventral tegmental area) show diverse expression of the molecular markers Calbindin, Calretinin, Aldh1a1, Sox6, Girk2, SatB1 and Otx2. It was found that selective expression of these markers is of use for discriminating between midbrain dopamine neurons that project to dorsal striatum or nucleus accumbens. To elucidate whether the diverse molecular marker expression would map onto dopamine neurons whose firing correlates with distinct behavioural events, midbrain dopamine neurons were recorded and labelled in head-fixed awake mice either exposed to neutral sensory stimuli or performing a classical conditioning paradigm. The population activity of midbrain dopamine neurons was not modulated by neutral sensory stimuli. Interestingly, fewer than 50% of identified dopamine neurons showed phasic firing increases following reward- predicting cue and/or reward delivery, despite the common assumption that most (if not all) midbrain dopamine neurons signal reward prediction errors. Instead, firing was modulated by other explanatory factors, such as licking, or showed no modulation during the task. Response types of midbrain dopamine neurons were not correlated with their anatomical location nor the selective or combinatorial expression of the markers Aldh1a1, Calbindin and Sox6. In conclusion, the first set of experiments identified how different genetic burdens can alter the in vivo firing of midbrain dopamine neurons, and provide new insights into how circuits can change in pathological or compensatory ways at early disease stages in Parkinson's. The second set of experiments revealed striking heterogeneity of midbrain dopamine neurons in the intact system, and established further a functional diversity in the response types of identified midbrain dopamine neurons that is only partially consistent with canonical reward prediction error signalling.
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Etude dynamique de la génération des oscillations Beta dans la maladie de Parkinson : approche électrophysiologique et optogénétique / Dynamic study of the generation of beta oscillations in Parkinson's diseaseDe la crompe de la boissiere, Brice 09 December 2016 (has links)
Les ganglions de la base (GB) forment une boucle complexe avec le cortex et le thalamus qui est impliquée dans la sélection de l’action et le contrôle du mouvement. Les activités oscillatoires synchronisées dans le réseau des GB ont été proposées comme pouvant jouer un rôle essentiel dans la coordination du flux de l’information au sein de ces circuits neuronaux. Ainsi, leur dérégulation dans le temps et l’espace pourrait devenir pathologique. Dans la maladie de Parkinson (MP), l’expression anormalement élevée d’oscillations neuronales comprises dans les gammes de fréquences beta (β, 10-30 Hz) serait la cause des déficits moteurs (akinétique et bradykinétique) de cette maladie. Cependant, les réseaux neuronaux à l’origine des oscillations β et l’implication physiopathologique de celles-ci restent encore inconnus. Le noyau sous-thalamique (NST) est un carrefour anatomique des GB situé au centre de réseaux potentiellement impliqués dans l’émergence de ces états hyper-synchronisés. L’objectif de cette thèse était de déterminer le rôle causal des principales entrées du NST (i.e. le cortex moteur, le globus pallidus, et le noyau parafasciculaire du thalamus) dans le maintien et la propagation des oscillations β. Pour cela, nous avons développé des approches de manipulation optogénétique combinées à des enregistrements électrophysiologiques in vivo dans un modèle rongeur de la MP. L’ensemble de nos travaux démontre la contribution respective des différents circuits neuronaux interrogés et souligne l’importance du globus pallidus dans le contrôle de la propagation et du maintien des oscillations β dans l’ensemble de la boucle des GB. / The basal-ganglia (BG) form a complex loop with the cortex and the thalamus that is involved in action selection and movement control. Synchronized oscillatory activities in basal-ganglia neuronal circuits have been proposed to play a key role in coordinating information flow within this neuronal network. If synchronized oscillatory activities are important for normal motor function, their dysregulation in space and time could be pathological. Indeed, in Parkinson’s disease (PD), many studies have reported an abnormal increase in the expression level of neuronal oscillations contain in the beta (β) frequency range (15-30 Hz). These abnormal β oscillations have been correlated with two mains symptoms of PD: akinesia/bradykinesia. However, which BG neuronal circuits generate those abnormal β oscillations, and whether they play a causal role in PD motor dysfunction is not known. The subthalamic nucleus (STN) is a key nucleus in BG that receives converging inputs from the motor cortex, the parafascicular thalamic nucleus and the globus pallidus. Here, we used a rat model of PD combined with in vivo electrophysiological recordings and optogenetic silencing to investigate how selective manipulation of STN inputs causally influence BG network dynamic. Our data highlight the causal role of the globus pallidus in the generation and propagation mechanisms of abnormal β-oscillations.
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