Global ETD Search

201	Overlapping Projections of Neighboring Direct and Indirect Pathway Neostriatal Neurons to Globus Pallidus External Segment / 線条体の隣接した直接路・間接路ニューロンからの淡蒼球外節投射は重複する Okamoto, Shinichiro 24 November 2021 (has links) 京都大学 / 新制・論文博士 / 博士(医学) / 乙第13453号 / 論医博第2246号 / 新制\|\|医\|\|1055(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授渡邉大, 教授林康紀, 教授高橋淳 / 学位規則第4条第2項該当 / Doctor of Medical Science / Kyoto University / DFAM basal ganglia direct pathway indirect pathway globus pallidus external segment axon projection 490
202	Cocaine- and Amphetamine-Regulated Transcript Peptide Attenuates Baroreflex in the Rat. Scruggs, Phouangmala C. 03 May 2003 (has links) (PDF) Cocaine- and amphetamine-regulated transcript (CART) was first identified in the rat striatum where levels were upregulated following cocaine or amphetamine administration. A dense plexus of CART-immunoreactive fibers is noted in the nucleus of the solitary tract (NTS). Results from tract-tracing and immunohistochemical studies suggest that the dense network of CARTp-fibers in the NTS may arise from nodose ganglia. The present study was undertaken to evaluate the hypothesis that CARTp may alter baroreceptor function in rats. Rats were intravenously administered phenylephrine every 10 min to elicit a baroreflex. CARTp (0.1- 3 nmol) by intracisternal or bilateral intra-NTS microinjection consistently attenuated the phenylephrineinduced bradycardia. In contrast, CARTp antibody potentiated the bradycardia produced from phenylephrine. Microinjection of saline, normal rabbit serum, or concomitant injection of CARTp and CART antibody into the NTS caused no significant change of phenylephrineinduced baroreflex. The result suggests that CARTp released from primary afferents may modulate baroreflex. Phenylephrine Nucleus of the solitary tract Nodose ganglia Baroreflex Medical Sciences Medicine and Health Sciences
203	Characterization of Sympathetic Ganglion Sensitivity to Substance P in a Genetic and a Non-Genetic Rat Model of Hypertension. Tompkins, John Daniel 03 May 2003 (has links) (PDF) Intravenous injection of substance P (SP) stimulates sympathetic ganglia to evoke a greater increase in renal sympathetic nerve activity, heart rate (HR) and blood pressure (BP) in hypertensive than normotensive rats due to upregulation of the NK1 receptor. These experiments were designed to determine the cellular basis for the enhanced ganglionic responsiveness to NK1 agonists in spontaneously hypertensive rats (SHR) in comparison to their normotensive counterparts, Wistar-Kyoto rats (WKY). Studies were also conducted to determine whether the increased ganglion responsiveness to SP in SHR is causally related to the increased BP or is a unique characteristic of this model of essential hypertension. Nerve recordings were made from the external carotid branch of the superior cervical ganglion (SCG) in pentobarbital anesthetized rats. Animals were treated with the ganglion blocking agent chlorisondamine (10.5 μmol/kg) and pre- and postganglionic SCG nerves were cut. SP (1.0 to 100 nmol/kg) evoked a greater increase in postganglionic nerve firing from the SCG of SHR vs. WKY. Intracellular microelectrode recordings were made from isolated SCG. Membrane properties were similar between strains. Picospritzer application of the NK1 agonist GR-73632 (100 μM, 1 s) caused slow depolarization and increased neuron excitability. Depolarization amplitude and duration were similar between strains, however, a greater percentage of neurons were depolarized by the NK1 agonist in SHR. To determine if the ganglion sensitivity to SP was correlated with blood pressure WKY were made hypertensive by unilateral nephrectomy and deoxycorticosterone acetate (DOCA)/salt treatment. Tail cuff BP was the same in treated WKY and untreated SHR. Increases in sympathetic nerve activity, HR and BP in response to SP (1.0 to 100 nmol/kg) were the same in treated and untreated WKY rats. In conclusion, SHR are more responsive to ganglion stimulation by NK1 agonists due to a greater number of responsive cells within their SCG rather than an enhanced responsiveness of individual neurons. The increased sympathetic nerve responsiveness to SP is an inherent characteristic and not an adaptive response of sympathetic ganglion neurons to hypertension. This enhanced action of SP at sympathetic ganglia may contribute to the elevated sympathetic outflow observed in this model of hypertension. DOCA sympathetic ganglia electrophysiology substance P SHR hypertension Medical Sciences Medicine and Health Sciences
204	Retrograde Labelling and Visualization of the Intrinsic Autonomic Ganglia of the Rat Liver Negrete, Kennan J 01 January 2020 (has links) The purpose of this study was to use retrograde tracing techniques to examine hepatic neuroanatomy in the rat model, with special emphasis upon the identification of previously undiscovered intrahepatic parasympathetic ganglia. Retrograde analysis was performed using Fluoro-Gold (FG) tracer injections of both male and female Sprague-Dawley rats. To accurately examine the neural connectivity of both the vasculature and the parenchyma, the FG-labelled livers were divided into two groups. In the first, vessel trees were extracted via dissection and whole-mounted for bright field and confocal visualization. Left lateral lobes taken from the male and female liver that constituted the second group were sectioned, and slices from various layers of tissue were fixed to slides and visualized. The results indicated the presence of several large, fluorescent structures bearing a strong resemblance to parasympathetic ganglia. However, the images were not detailed enough to properly differentiate true ganglia from similar paraganglia. Regardless, the importance of this experiment lies in its attempt to revisit an understudied field in neuroscience, and the findings of this study could potentially provide a starting point for further inquiry. rat hepatic innervation intrahepatic ganglia confocal microscopy Fluoro-Gold tracer Neuroscience and Neurobiology
205	Regional Contributions to Neuronal Diversity in the Developing Mouse Telencephalon Qin, Shenyue 15 December 2017 (has links) No description available. Developmental Biology Gsx2 cis-regulation ventral telencephalon basal ganglia olfactory bulb neurogenesis
206	Neural Circuits Underlying Learning and Consolidation Lindsey, John William January 2024 (has links) In this work, we develop models of neural circuits and plasticity rules that underlie different forms of learning and memory, with a focus on learning processes that involve multiple brain regions. We begin by surveying the literature on synaptic plasticity rules and implementations of learning algorithms in the brain. Each subsequent chapter presents a model of how a specific aspect of learning is implemented biologically, based on experimental evidence and normative considerations. We first focus on the neural basis of reinforcement learning in the basal ganglia. We show that in order to enable effective learning when control of behavior is distributed across multiple regions (``off-policy reinforcement learning''), classic models of dopamine activity must be adapted to include an additional action-sensitive component. We also show that the known plasticity rules of direct and indirect-pathway striatal projection neurons are inconsistent with existing models of striatal codes for action. We propose and find experimental support for a new model of striatal activity driven by efferent input. This model is functionally compatible with striatal plasticity rules and enables simultaneous multiplexing of action-selection and learning signals, a necessary ingredient for off-policy reinforcement learning. We next use an off-policy reinforcement learning model to explain a new experimental finding about the conditions under which learned motor skills are consolidated to be driven by the dorsolateral striatum in rats. We then shift our focus to consider consolidation more broadly, proposing a general model of the advantages of systems in which memories and learned behaviors are consolidated from short-term to long-term learning pathways. In particular, our model proposes that such architectures enable selective filtering of the set of experiences used for learning, which can be essential in noisy environments with many extraneous stimuli. In the appendices, we explore other factors relevant to learning algorithms, including the interaction between multiple sensory modalities, and the problem of credit assignment in multi-layer neural networks. In summary, this work presents a varied set of models of different forms of learning in the brain, emphasizing the cooperative role of plasticity rules and multi-regional circuit architecture in producing functionally useful synaptic weight updates. Neurosciences Neural circuitry Basal ganglia Reinforcement learning Motor learning Rats Synapses
207	Pesticides and pesticide combinations on brain neurochemistry Aguilar, Carolina 31 August 2004 (has links) Pesticides have been suggested to play a role in the development of many neurodegerative diseases including Parkinson's disease and Alzheimer's disease. Additionally, it has been suggested that exposure to pesticides and other environmental chemicals during the early stages of life could result in an increased vulnerability to such substances that could lead to neurotoxicity and degeneration late in life. We hypothesized that exposure to mixtures of certain pesticides could change neurotransmitter levels and cellular oxidative stress and that this would be greater in mice exposed early and later in life than mice exposed only as adults. We studied the effects of permethrin (PR) (a pyrethroid type I) and endosulfan (EN) (an organochlorine) on the levels of catecholamines, indolamines, acetylcholinesterase, lipid peroxidation and α-synuclein in the brain of mice. These pesticides have different structures but both are known to modify the kinetics of voltage-sensitive ion channels and calcium ion flux/homeostasis that could affect the release of several neurotransmitters. The study consisted of two experiments: In the first experiment, adult C57Bl/6 mice (7-9 months old) were injected, intraperitoneally, with the following treatments: EN 4.3, 2.15 mg/kg; PR 150, 15 mg/kg and their mixtures EN 4.3 + PR 150 and EN 2.15 + PR 15 mg/kg. Mice were sacrificed 24 hrs after the last injection. In the second experiment, doses consisted of EN 0.7, 1.4 mg/kg, PR 1.5, 15 mg/kg and their mixtures EN 0.7 + PR 1.5 mg/kg and EN 1.4 + PR 15 mg/kg were given to juvenile mice intraperitoneally daily during a period of two weeks from postnatal day 5 to 19. Mice were then, left undisturbed with their dams. Re-challenge was performed when mice were 7-9 months old and dosages of EN 4.3, 2.15 mg/kg, PR 150, 15 mg/kg and their mixtures, EN 4.3 + PR 150 and EN 2.15 + PR 15 mg/kg were given intraperitoneally every other day during a period of two weeks to match the treatments when pesticide exposure was only as adults. Mice were sacrificed 24 hrs after the last injection. The corpora striatum was extracted and analyzed by HPLC for catecholamines (dopamine, DOPAC, homovalinic acid and norepinephrine) and indolamines (serotonin and 5-HIAA). In general low doses of permethrin and endosulfan alone and in combination (EN 2.15 + PR 15 mg/kg) altered the levels of catecholamines and indolamines in both studies with adult mice and mice dosed as juveniles and re-challenged as adults. Catecholamine and indolamines levels were affected to a greater extent in the adult mice than in mice dosed as juveniles and re-challenged as adults, when compared to controls. Acetylcholinesterase was increased under both exposure situations but again adult mice seemed to be more affected than mice dosed as juveniles and re-challenged as adults. Because reactive oxygen species have been implicated in the development of Parkinson's disease, and are known to cause degradation of certain neurotransmitters, we monitored the levels of lipid peroxides in brain cortex as an indicator of free radical tissue damage. The peroxide levels were measured by thiobarbituric acid reactive products (TBARS). Increased levels of lipid peroxides were significant in the low dose treatment groups of the adult study. However, there seemed to be a pattern between the levels of dopamine and DOPAC in the striatum and the levels of peroxidation in cortex. The presence of dopamine metabolites appeared to be related to high levels of peroxidation within the basal ganglia and up-regulation of proteins such as α-synuclein. Western blots of α-synuclein in both experiments of the study showed intense double and triple bands that corresponded to aggregated α-synuclein. In general, when compared with controls, mice dosed as juveniles and re-challenged as adults did not alter the above parameters as much as mice dosed only as adults. Instead, the mice first dosed as juveniles seemed to develop an adaptation response to the later exposure of these pesticides. Taking all these results into account, early exposure and re-challenge with permethrin and endosulfan in this study appeared to induce a protective response against neurochemical changes in the brain of these mice. In addition, low doses of these pesticides and the low dose combination mixture seem to exert an effect on the parameters studied. Therefore, exposure to pesticides such as endosulfan and permethrin and their combinations could make a contribution towards the initiation or aggravation of biochemical neurodegenerative diseases such as Parkinson's and Alzheimer's diseases. / Master of Science Lewy body α-synuclein Alzheimer's disease Parkinson's disease basal ganglia. Neurotoxicology Pesticides
208	Striatum mosaic disassembling: shedding light on striatal neuronal type functions by selective ablation in genetic models / Etude du rôle de populations neuronales du striatum par ablation sélective dans des modèles murins transgéniques Durieux, Pierre 25 May 2010 (has links) The striatum represents the main input nucleus of the basal ganglia, a system of subcortical nuclei critically involved into motor control and motivational processes and altered in several conditions such as Parkinson’s diseases or drug addiction. The projection neurons of the striatum are GABAergic (γ-aminobutyric acid) medium-sized spiny neurons (MSNs), and account for the large majority of striatal neurons, while interneurons represent about 10% of striatal cells. The MSNs are subdivided into two subpopulations that form two main efferent pathways: the striatonigral and striatopallidal neurons. The striatonigral MSNs project to the entopeduncular nucleus (EP) and substancia nigra pars reticulata (SNr) (direct pathway) and co-express dopamine D1 receptors (D1R) and substance P neuropeptide (SP). On the other hand, striatopallidal MSNs project to the lateral globus pallidus (LGP) (indirect pathway) and co-express dopamine D2 receptor (D2R), adenosine A2A receptor (A2AR) and enkephalin (Enk). The D1R striatonigral and D2R striatopallidal MSNs are equal in number and shape and are mosaically distributed through all the striatum. The dorsal striatum is mainly involved in motor control and learning while the ventral striatum is crucial for motivational processes. In view of the still debating respective functions of projection D2R-striatopallidal and D1R-striatonigral neurons and striatal interneurons, both in motor control and learning of skills and habits but also in more cognitive processes such as motivation, we were interested in the development of models allowing the removal of selective striatum neuronal populations in adult animal brain. Because of the mosaical organisation of the striatum, a targeting of specific neuronal type, with techniques such as chemical lesions or surgery, is still impossible. Taking advantage of new transgenic approaches, the goal of the present work was to generate and/or to initiate the characterization of genetic models in which a selective subtype of striatal neuron can be ablated in an inducible way. We used a transgenic approach in which mice express a monkey diphtheria toxin (DT) receptor (DTR) in D2R-striatopallidal or D1R-striatonigral neurons. Local stereotactic injections of DT can then induce selective neuronal ablation in functionally different striatal areas.<p>We first investigated functions of D2R-striatopallidal neurons in motor control and drug reinforcement by their selective ablation in the entire striatum or restricted to the ventral striatum. This DTR strategy produced selective D2R striatopallidal MSN ablation with integrity of the other striatal neurons as well as the striatal dopaminergic function. D2R MSN ablation in the entire striatum induced permanent hyperlocomotion while ventral striatum-restricted ablation increased amphetamine place preference.<p>We next compared respective roles of D2R-striatopallidal and D1R-striatonigral neurons in motor control and skill learning in functionally different striatum subregions.<p>Finally, to target nitrergic interneurons of the striatum, we developed a bacterial artificial chromosome genetic strain in which the cre-recombinase expression is under the control of the neuronal nitric oxide gene promoter.<p><p>Altogether, those results show that DTR expression and DT local injections is an efficient and flexible strategy to ablate selective striatum neuronal types with spatial resolution. We provide the first direct experimental evidences that D2R striatopallidal neurons inhibit both locomotor and drug-reinforcement processes and that D2R and D1R MSNs in different striatum subregions have distinct functions in motor control and motor skill learning. Those results strongly support a cell-type and topographic functional organization of the striatum and underscore the need for characterization of the specific cellular and molecular modifications that are induced in D2R and D1R MSNs during drug-reinforcement or procedural learning.<p> / Doctorat en Sciences médicales / info:eu-repo/semantics/nonPublished Médecine pathologie humaine Drug addiction Basal ganglia Basal ganglia -- Effect of drugs on Toxicomanie Noyaux gris centraux procedural learning apprentissage procédural noyaux de la base dépendance aux drogues contrôle moteur motor control drug addiction striatum
209	Mathematical Models of Basal Ganglia Dynamics Dovzhenok, Andrey A. 12 July 2013 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / Physical and biological phenomena that involve oscillations on multiple time scales attract attention of mathematicians because resulting equations include a small parameter that allows for decomposing a three- or higher-dimensional dynamical system into fast/slow subsystems of lower dimensionality and analyzing them independently using geometric singular perturbation theory and other techniques. However, in most life sciences applications observed dynamics is extremely complex, no small parameter exists and this approach fails. Nevertheless, it is still desirable to gain insight into behavior of these mathematical models using the only viable alternative – ad hoc computational analysis. Current dissertation is devoted to this latter approach. Neural networks in the region of the brain called basal ganglia (BG) are capable of producing rich activity patterns. For example, burst firing, i.e. a train of action potentials followed by a period of quiescence in neurons of the subthalamic nucleus (STN) in BG was shown to be related to involuntary shaking of limbs in Parkinson’s disease called tremor. The origin of tremor remains unknown; however, a few hypotheses of tremor-generation were proposed recently. The first project of this dissertation examines the BG-thalamo-cortical loop hypothesis for tremor generation by building physiologically-relevant mathematical model of tremor-related circuits with negative delayed feedback. The dynamics of the model is explored under variation of connection strength and delay parameters in the feedback loop using computational methods and data analysis techniques. The model is shown to qualitatively reproduce the transition from irregular physiological activity to pathological synchronous dynamics with varying parameters that are affected in Parkinson’s disease. Thus, the proposed model provides an explanation for the basal ganglia-thalamo-cortical loop mechanism of tremor generation. Besides tremor-related bursting activity BG structures in Parkinson’s disease also show increased synchronized activity in the beta-band (10-30Hz) that ultimately causes other parkinsonian symptoms like slowness of movement, rigidity etc. Suppression of excessively synchronous beta-band oscillatory activity is believed to suppress hypokinetic motor symptoms in Parkinson’s disease. Recently, a lot of interest has been devoted to desynchronizing delayed feedback deep brain stimulation (DBS). This type of synchrony control was shown to destabilize synchronized state in networks of simple model oscillators as well as in networks of coupled model neurons. However, the dynamics of the neural activity in Parkinson’s disease exhibits complex intermittent synchronous patterns, far from the idealized synchronized dynamics used to study the delayed feedback stimulation. The second project of this dissertation explores the action of delayed feedback stimulation on partially synchronous oscillatory dynamics, similar to what one observes experimentally in parkinsonian patients. We employ a computational model of the basal ganglia networks which reproduces the fine temporal structure of the synchronous dynamics observed experimentally. Modeling results suggest that delayed feedback DBS in Parkinson’s disease may boost rather than suppresses synchronization and is therefore unlikely to be clinically successful. Single neuron dynamics may also have important physiological meaning. For instance, bistability – coexistence of two stable solutions observed experimentally in many neurons is thought to be involved in some short-term memory tasks. Bistability that occurs at the depolarization block, i.e. a silent depolarized state a neuron enters with excessive excitatory input was proposed to play a role in improving robustness of oscillations in pacemaker-type neurons. The third project of this dissertation studies what parameters control bistability at the depolarization block in the three-dimensional conductance-based neuronal model by comparing the reduced dopaminergic neuron model to the Hodgkin-Huxley model of the squid giant axon. Bifurcation analysis and parameter variations revealed that bistability is mainly characterized by the inactivation of the Na+ current, while the activation characteristics of the Na+ and the delayed rectifier K+ currents do not account for the difference in bistability in the two models. Basal Ganglia Bistability delayed feedback deep brain stimulation Dopaminergic neuron Parkinson's disease Tremor Dopaminergic neurons Basal ganglia Parkinson's disease Bifurcation theory Delay differential equations Brain stimulation Nonlinear functional analysis Tremor
210	Functional characterisation of synuclein-based novel genetic mouse models Anwar, Sabina Zareen January 2011 (has links) Synucleins are highly conserved presynaptic proteins with unknown function. α-synuclein plays a key role regulating dopamine homeostasis and is intimately involved in Parkinson’s disease (PD) pathogenesis. However, the normal/pathological role of α-synuclein remains unidentified. Studies exploring its function are limited as current transgenic mouse models do not fully recapitulate PD pathology. This thesis reports the functional characterisation of two novel synuclein-based mouse models. I report the molecular and functional characterisation of transgenic mouse lines with wild-type or A30P-mutant human α-synuclein genomic locus carried within a bacterial artificial chromosome. SNCA-A30P<sup>+</sup>Snca-/- mice exhibited a highly physiologically relevant expression pattern of the transgene, including expression in the substantia nigra pars compacta (SNpc) and a specific, age-related loss of TH<sup>+</sup> cells in the SNpc, the key region of preferential cell loss in PD, compared with non-transgenic Snca -/- littermate controls. Analysis of dopamine signalling using fast-scan cyclic voltammetry (FCV) showed young adult SNCA-A30P<sup>+</sup>Snca-/- mice had an approximately 20&percnt; lower evoked extracellular dopamine concentration ([DA]o) compared with non-transgenic Snca -/- littermate controls, a decrease specific to the dorsal striatum. This difference diminished with age and could not be attributed to changes in dopamine reuptake/content. I detail the behavioural and neurochemical phenotype in mice lacking all three synucleins (α/β/γ). Functional compensation between synucleins emphasises the importance of studying their effects by removing all three proteins simultaneously. Triple-null mice exhibited hyperactivity in a novel environment reminiscent of a hyperdopaminergic-like phenotype, but showed no phenotype in anxiety or motor related tests. FCV revealed synuclein triple-null mice had a two-fold increase in [DA]o, specific to the dorsal striatum and not attributable to changes in dopamine reuptake/content, changes in striatal nicotinic receptor activity nor calcium-dependent changes in dopamine exocytosis. Together, the analysis from these two novel mouse models reveal synucleins play an important role in altering synaptic function in the dorsal striatum (the region selectively affected in PD) and contributes to growing evidence suggesting synucleins are negative regulators of synaptic dopamine release. 616.83307

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