Global ETD Search

1	The effects of cholinergic and dopaminergic neurons on hippocampal learning and memory processes Tang, Sze-Man Clara January 2018 (has links) Dysfunction of cholinergic and dopaminergic systems has been implicated in memory function de cits that are core pathology and associated features of several neurological disorders. However, in order to develop more effective treatments, it is crucial to better understand how different aspects of learning and memory are modulated by these neuromodulatory systems. Using optogenetic stimulation or silencing, this thesis aims to investigate the effects of cholinergic and dopaminergic modulation on various hippocamal learning and memory processes. To understand how these neuromodulatory systems modulate hippocampal network activity, I first examined their effects on hippocampal local field potentials in urethane-anaesthetised mice. I demonstrated that optogenetic cholinergic activation suppressed slow oscillations, shifting brain activity to a state dominated by theta and gamma oscillations. In contrast, dopaminergic activation suppressed gamma oscillations. Second, to directly probe the effects of neuromodulation on different stages of spatial learning, I acutely activated or inactivated cholinergic or dopaminergic neurons during various behavioural tasks. My findings suggested that cholinergic activation, solely during the reward phase of a long-term spatial memory task, slowed place learning, highlighting the importance of temporally-precise neuromodulation. Moreover, dopaminergic stimulation may enhance place learning of a food rewarded task, supporting a role for dopamine in spatial learning. In addition, I tested the effects of cholinergic and dopaminergic modulation on reversal learning and found that cholinergic inactivation and dopaminergic activation appear to impair this process. Together, these findings emphasise the importance of cholinergic and dopaminergic modulation in learning and memory. They suggest that precise timing of neuromodulator action is critical for optimal learning and memory performance, and that acetylcholine and dopamine support complementary processes that allow for effective learning and adaptation to changing environments.
2	Altered hippocampal fast oscillations and GABAergic circuits in neuregulin 1 over-expressing mice Nissen, Wiebke January 2012 (has links) Neuregulin 1 (NRG1) is a growth factor implicated in neurodevelopment and postnatal maintenance of synaptic circuits. Its gene has been associated with schizophrenia, and the expression of the type I isoform (NRG1tyI) is increased in patients’ brains. Earlier behavioural phenotyping of mice over-expressing NRG1tyI revealed impairment in hippocampus-dependent spatial working memory. This present work investigates the effects of increased NRG1tyI expression on hippocampal network functioning in these mice. Fast network oscillations, specifically at gamma frequencies, were studied in CA3 hippocampal slices in a carbachol model using cellular and extracellular microelectrode recording techniques. The peak frequency of field potential oscillations was significantly reduced in slices from NRG1tyI mice compared to wild-type littermates. In addition, NRG1tyI mouse slices were more prone to develop epileptiform activity. During rhythmic activity, the balance of phasic excitation and inhibition was significantly altered in principal cells of NRG1tyI mice. Inhibitory synaptic input was more sustained, while excitatory synaptic currents were kinetically unchanged but larger and more variable in amplitude. Together, these data suggest altered functioning of the GABAergic inhibitory circuits that generate and maintain gamma oscillations. Because parvalbumin-expressing (PV+) interneurons are a major target of NRG1 signalling, the inhibition from PV+ interneurons to pyramidal cells was examined next. Channelrhodopsin-2-mediated photostimulation of PV+ cell axons failed to show changes in GABAergic inhibition of CA3 pyramidal cells in NRG1tyI mice. However, synaptic miniature glutamatergic neurotransmission was reduced in identified PV+ basket cells (BCs) and axo-axonic cells (AACs) but not in pyramidal cells. The change was expressed postsynaptically, affecting NMDA receptor- but not AMPA receptor-mediated currents. The data suggest that NRG1tyI over-expression results in alterations in PV+ interneuron types, particularly at the glutamatergic synapses that excite these cells. These changes and the altered gamma oscillations are already evident in late adolescence — before the age at which cognitive deficits are detectable. 612.8
3	Modulation of Spontaneous Neural Network Bursting in Newborn Rat Brain Slices by Extracellular Calcium, Methylxanthines, and Opioids Kantor, Chase M Unknown Date No description available. Methylxanthines Opioids Early Network Oscillations (ENO) Neonate Calcium Imaging Hippocampus Cortex Calcium Giant Depolarizing Potentials (GDP) Caffeine
4	Resonanzverhalten und Netzwerkoszillationen in der hippokampalen Formation der Ratte in vitro Boehlen, Anne 06 September 2010 (has links) Rhythmische neuronale Aktivität spielt vermutlich eine wichtige Rolle in der Informationsverarbeitung im zentralen Nervensystem. Oszillationen neuronaler Netze sind heterogen, von der Hirnregion und ihrer Funktion abhängig und werden entsprechend ihrer Frequenz eingeteilt. Für ihre Entstehung sind über die Verschaltung der Neuronen und der synaptischen Übertragung hinaus insbesondere die Erregbarkeit und Oszillationseigenschaften einzelner Neurone von Bedeutung. Bestimmte Zellen der hippokampalen Formation wie zum Beispiel Sternzellen (SC) der Schicht II des Entorhinalkortex zeigen oszillatorische Aktivität und antworten verstärkt auf Stimuli einer bestimmten Frequenz – sie sind resonant. Beide Phänomene werden auf spezifische spannungsabhängige Leitfähigkeiten in der Membran zurückgeführt. Es stellte sich heraus, dass die Resonanzfrequenz von SCs durch das Muster der vorhandenen Leitfähigkeiten bestimmt wird und von der Position der Zelle entlang der dorso-ventralen Achse abhängt. Dieser Gradient ist bereits in frühen Entwicklungsstadien nachweisbar. Im Zuge der weiteren Entwicklung werden SCs weniger erregbar und der Bereich der Resonanzfrequenz dehnt sich nach dorsal aus. Pharmakologische Experimente ergaben, dass die Resonanz von SCs von HCN-Kanälen abhängt und von Kv7-Kanälen moduliert wird. Außerdem konnten zwei, bisher unbekannte Klassen von oszillatorischen Interneuronen beschrieben werden, deren Resonanz ebenfalls im Theta-Bereich liegt und auf ähnliche Leitfähigkeiten zurückgeführt werden kann. Weitere, auch CA1-Pyramidenzellen einschließende Experimente ergaben, dass HCN-Kanäle die allgemeine Voraussetzung für Resonanz zu sein scheinen während Kv7-Kanäle potente Modulatoren darstellen. Die pharmakologische Blockade dieser Kanäle unterbrach Netzwerkoszillation im Hippokampus. Dies unterstützt die These, dass bestimmte Leitfähigkeiten Neuronen Resonanzeigeschaften verleihen und somit wiederum Netzwerkoszillationen unterstützen. / Rhythmic neuronal activity is thought to be crucial for information processing in the brain. Neuronal network oscillations are heterogeneous, vary with brain region and type of information processed. They are classified according to their frequency content. Their generation relies on network circuitry, synaptic transmission and neuronal properties. Oscillatory behavior of individual cells has been particularly implicated. Different cell types within the hippocampal formation such as layer II stellate cells (SC) of the medial entorhinal cortex display oscillatory activity and are resonant, i.e., respond preferentially to stimuli of a given frequency. Voltage dependent ionic conductances have been suggested to give rise to these phenomena. It was found that resonance of SCs is defined by the composition of voltage-dependent channels embedded in their membrane and changes with their position along the dorsal-ventral axis. This gradient of SC properties develops during early postnatal life. During the transition to adulthood cells become less excitable and the range of resonance frequencies expands in the dorsal direction. Pharmacological experiments reveal the resonance of SCs to depend strongly on HCN-channels and to be modulated by Kv7-channels. Also, two previously unknown classes of oscillating interneurons were identified in the stratum radiatum of the CA1 region. These are targeted by neurons from the dentate gyrus, display frequency preferences in the theta range which relies on similar membrane conductances. Further experiments including CA1 pyramidal cells suggested HCN-channels to be the primary global requirement for resonance whereas Kv7-channels appear to be effective modulators. Pharmacological blockade of these channels disrupted ongoing network oscillations in the hippocampus. This supports the notion that specific ion channels support rhythmic activity of individual cells and in turn of entire networks. Resonanz hippokampale Formation Membranpotentialoszillatonen Netzwerkoszillationen spannungsabhängige Ionenkanäle resonance hippocampal formation membrane potential oscillations network oscillations voltage-dependent ion channels 570 Biowissenschaften, Biologie 32 Biologie YG 1700 ddc:570
5	Regulation and functions of burst firing: the role of KCNQ3 potassium channels in vivo Gao, Xiaojie 07 December 2020 (has links) Ionenkanäle leiten Ionenströme über neuronale Membranen, wodurch Aktionspotentiale erzeugt und weitergeleitet werden. Sie spielen eine zentrale Rolle bei der Regulierung der Erregbarkeit und des Aktivierungsverhaltens von Neuronen. KCNQs sind eine wichtige Familie von spannungsgesteuerten Kaliumkanälen; ihre Dysfunktion kann zu verschiedenen neurologischen Krankheiten führen, einschließlich Erkrankung an Epilepsie und Taubheit. Es wurde gezeigt, dass KCNQ2 und KCNQ3 den M-Strom verantwortlich sind. Letzterer ist für die Regulierung des repetitiven Feuerns von Pyramidenzellen entscheidend. Im Gegensatz zu KCNQ2, ist die funktionelle Bedeutung von KCNQ3 noch nicht aufgeklärt. In dieser Arbeit zeigen wir mittels extrazellulärer Elektrophysiologie in vivo, dass bei konstitutiven Kcnq3 Knockoutmäusen die hippokampalen Pyramidenzellen vermehrt burstartig feuern. Außerdem weisen diese Tiere eine verminderte Spike-Frequenz-Anpassung auf und die Wahrscheinlichkeit des Burst-Feuerns während zwei verschiedener Oszillationen – Theta gegen Nicht-Theta – kann nicht mehr unterscheiden werden. Des Weiteren zeigen Kcnq3-Knockout- Pyramidenzellen während der Theta-Oszillation weder eine dominante Phasenpräferenz, noch eine Koordination ihrer Burst-Feuerung. Die Thetawellen Phasenpräzision tritt weiterhin bei dem vorübergehend verstärkten Feuern auf. Das räumliche selektive Feuern von mutmaßlichen Ortszellen blieb auch bei den Knockout-Mäusen erhalten, aber es ist hauptsächlich vom Burst- Feuern abhängig. Diese Studie zeigt, dass der KCNQ3-Ionenkanal eine wichtige Rolle bei der Regulierung der neuronalen Erregbarkeit und der Informationsverarbeitung spielt, und gibt damit Einblicke in die Bedeutsamkeit der KCNQ3-Ionenkanäle bezüglich der neurologischen Störungen. / Ion channels conduct ion flows across neuronal membrane whereby action potential is generated and propagated. They play a central role in regulating the excitability and firing behavior of a neuron. Among them, the KCNQs present a prominent family of voltage-gated potassium channels. Dysfunction of KCNQ2–5 channels can lead to varied neurological diseases including early onset epilepsy and deafness. In cortex and hippocampus, KCNQ2 and KCNQ3 have been demonstrated to underlie the non-inactivating M-current critical for controlling the repetitive firing of pyramidal cells. However, the functional significance of KCNQ3, unlike that of KCNQ2, remains elusive. Here, by applying in vivo extracellular electrophysiology in Kcnq3 constitutive knockout mice and the wild-type littermates, we find that hippocampal pyramidal cells lacking KCNQ3 exhibit increased burst firing. Moreover, the spike frequency adaptation of their bursts is diminished, and the burst propensity during two different field oscillations – theta versus non-theta – becomes indistinguishable. During theta oscillations, Kcnq3 knockout pyramidal cells no longer display unimodal phase preference and do not coordinate their burst firing. But phase advancement along successive theta cycles continues to occur at times of transiently intensified firing. The selective firing of place cells is largely preserved in the knockout while mainly relying on bursts. These results suggest that KCNQ3 channels indeed play a significant and specific role in regulating the neurons’ excitability and information processing, thus providing crucial mechanistic insights into the relevance of the KCNQ3 channels in neurological disorders. KCNQ3 in vivo Elektrophysiologie Burst Feuerung Netzwerk Oszillationen KCNQ3 in vivo electrophysiology burst firing network oscillations 570 Biowissenschaften; Biologie WE 5460 WW 4120 ddc:570
6	The role of interneuronal networks in hippocampal ripple oscillations Leiva, José Ramón Donoso 05 December 2016 (has links) Hippokampale Sharp Wave-Ripples (SWRs) sind elektrografische Ereignisse, die für die Konsolidierung von Erinnerungen eine Rolle spielen. Eine SWR ist durch eine schnelle Oszillation (>90 Hz, ''ripple'') charakterisiert, die sich mit der langsameren ''sharp wave'' ( / Hippocampal sharp wave-ripples (SWRs) are electrographic events that have been implicated in memory consolidation. A SWR is characterized by a fast (> 90 Hz) oscillation, the ripple, superimposed on a slow (< 30 Hz) sharp wave. In vivo, the fast component can express frequencies either in the ripple range (140-200 Hz) or fast-gamma range (90-140 Hz). Episodes in both bands exhibit intra-ripple frequency accommodation (IFA). In vitro, ripples are frequency-resistant to GABA modulators. These features constrain the type of mechanisms underlying the generation of the fast component. A prominent hypothesis proposes that a recurrent network of parvalbumin-immunoreactive basket cells (PV+BC) is responsible of setting the ripple frequency. The focus of the present thesis is on testing to which extent the PV+BC network can account for the aforementioned features of SWRs, which remain unexplained. Here, I simulated and analyzed a physiologically constrained in silico model of the PV+BC network in CA1 under different conditions of excitatory drive. The response of the network to transient excitation exhibits both IFA in the ripple band and frequency resistance to GABA modulators. The expression of IFA in the fast gamma band requires the involvement of pyramidal cells in a closed loop with the PV+BC network. The model predicts a peculiar relationship between the instantaneous frequency of ripples and the time course of the excitatory input to CA1. This prediction was confirmed in an in vitro model of SWRs. Additionally, I study the involvement of oriens lacunosum-moleculare interneurons (O-LM) during SWRs in vitro. I characterize the excitatory currents received by O-LM cells during SWRs and investigate the factors that determine their recruitment. Hippokampus Sharp wave-ripples schnelle Gamma-Oszillationen Netzwerk-Oszillationen GABAerge Medikamente Hippocampus network oscillations Sharp wave-ripples fast-gamma GABAergic drugs 570 Biowissenschaften, Biologie 32 Biologie WW 4200 WW 2940 ddc:570

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