Global ETD Search

101	Neural mechanism of play fighting – neural circuitry, vasopressin, and CRH – in juvenile golden hamsters Cheng, Shao-Ying 19 October 2009 (has links) Play fighting is common in juvenile mammals as a peri-pubertal form of agonistic behavior preceding adult aggressive behavior. In golden hamsters, play fighting peaks in early puberty around postnatal day 35 (P-35), and gradually matures into adult aggression in late puberty. Though extensively studied, the neural mechanisms underlying play fighting remains poorly understood. My dissertation focuses on identifying the neural circuitry and neural transmitter systems that mediate this behavior in juvenile golden hamsters. Based on behavioral similarities between the offensive components of play fighting and adult aggression, I predicted that the neural circuitries mediating both behaviors shared common components. This possibility was tested by quantifying the immunolabeling of c-Fos expression in juvenile hamsters after the consummation of play fighting. In support of my hypothesis, I found that areas previously associated with offensive aggression in adult hamsters, including the ventrolateral hypothalamus (VLH), the posterior dorsal part of the medial amygdala (MePD), and the bed nucleus of the stria terminalis (BST), also showed enhanced c-Fos expression after play fighting, which supported my hypothesis. Vasopressin (AVP) facilitates aggression in adult hamsters. Therefore, I hypothesized that AVP also activates play fighting. To test my hypothesis, juvenile male golden hamsters were tested for play fighting after they received central microinjections of an AVP V1A-receptor antagonist into the anterior hypothalamus (AH). Also, immunocytochemistry was performed to identify possible AVP neurons associated with this behavior. I found that the AVP antagonist selectively inhibited the attack components of play fighting in experimental animals. In addition, AVP cells in the nucleus circularis (NC) and the medial division of the supraoptic nucleus (mSON), which were associated with offensive aggression, also showed increased c-Fos activity after play fighting. Together, these results show that AVP facilitates offensive behaviors throughout hamster development, from play fighting in juveniles to aggression in adults. A recent study shows that oral administration of a CRH receptor antagonist inhibits aggression in adult hamsters. Therefore, I predicted that CRH plays a similar role in play fighting. To test my prediction, juvenile hamsters were tested for play fighting after central microinjections of a CRH receptor antagonist. I found that microinjections of the CRH receptor antagonist within the lateral septum (LS) resulted in an inhibition of several aspects of play fighting. The possible source of CRH affecting the behavior was tested through combined immunocytochemistry to CRH and c-Fos. I found CRH neurons in the diagonal band of Broca (DBB), an area with extensive connections with the LS, were particularly activated in association with play fighting. In conclusion, I find that shared neural elements participating in the “vertebrate social behavior neural network” are associated with both aggression and play fighting in hamsters. This circuitry is activated before the onset of puberty and is affected by rising levels of steroid hormones during the developmental period leading to adult behaviors. Within the circuitry, vasopressin release in the AH appears to control the activation of play fighting attacks. In contrast, CRH release in the LS affects a broader range of aspects of play fighting, including not just consummatory aspects of the behavior, but apparently also appetitive components in the form of contact duration. / text Golden hamsters Play fighting Neural circuitry Vasopressin Corticotropin-Releasing Hormone (CRH) Juvenile mammals Adult aggressive behavior Neural transmitters
102	Papel do hipotálamo lateral e tálamo anterior nas respostas contextuais na derrota social. / Role of the lateral hypothalamus and anterior thalamus in memory in social defeat. Júnior, Miguel José Rangel 19 September 2017 (has links) Relações entre machos de roedores muitas vezes se dão com a manifestação de comportamentos agressivos, em um embate em que se define um perdedor e um ganhador. O macho perdedor, de acordo com experimentos realizados no laboratório, apresenta comportamentos de defesa (avaliação de risco) quando exposto ao contexto da derrota social. Na expressão da defesa condicionada, estruturas do hipotálamo lateral devem ser importantes, que são também mobilizadas durante o confronto. No hipotálamo lateral destacamos a a parte justadorsomedial do hipotálamo lateral (LHAjd) que tem conexões com o sistema septo-hipocampal e projeta-se liga ao prémamilar dorsal (PMD), crítico para a expressão de comportamentos de defesa. Por outro lado, o PMD, que é uma estrutura altamente mobilizada durante o confronto social, tem conexões com o núcleo anteromedial do tálamo (AMv), estrutura já conhecida pela sua importância na aquisição da memória contextual e espacial. Assim, no presente trabalho, investigamos o papel do LHAjd na expressão e do AMv na aquisição da defesa condicionada na derrota social. Nos animais com lesão do LHAjd, observamos diminuição nos comportamentos de avaliação de risco durante exposição ao contexto. Nos animais com lesão do AMv o mesmo efeito. Dado os efeitos das lesões no AMv, elaboramos um paradigma para estudo em camundongos, a fim de se realizar inativações pontuais com farmacogenética nos neurônios glutamatérgicos em animais transgênicos durante a derrota social. Foi observado o mesmo padrão em camundongos transgênicos vGlut2-cre inativados com farmacogenética, não havendo influência nos comportamentos durante a derrota social. Inativações antes do contexto não causaram efeito na defesa condicionada. As inativações durante a derrota, no entanto, não tiveram efeito quando o residente agressivo está na exposição ao contexto. Os dados sugerem que o LHAjd tem papel na expressão da defesa condicionada, enquanto que o AMv tem papel na aquisição da defesa condicionada ao contexto, mas não no reconhecimento do residente agressivo. / Male rodents may interact aggressively, and from the agonistic encounter, it results a winner and a defeated animal. Accordingingly, the defeated male shows defensive behaviors (risk assessment) to the social defeat-related context. Contextual responses are known to rely on hippocampal processing, and one of the main targets of the hippocampal system is the justodorsomedial part of lateral hypothalamus (LHAjd), which projects to dorsal premamillary nucleus (PMD), known to be involved in the expression of social defensive behaviors. Notably, PMD, a hypothalamic site highly responsive to the social defeat, in turn, projects to the ventral part of thalamic anteromedial nucleus (AMv), previously shown to be involved in the acquistion of spatial and contextual memory to predatory threats. Thus, in present study, we investigated the role of LHAjd in expression and of AMv in acquisition of social defeat conditioned defensive behaviors. In LHAjd lesioned animals, we observed a decrease in risk assessment behaviors during exposute to the social defeat associated context , but not during the social defeat itself, suggesting a role in the expression of contextual but not in the innate social defeat. In AMv lesioned animals, we observed that the animals lost contextual defensive response, suggesting a role in the acquisition and/or expression of contextual responses. Next, using pharmacogetic inhibition, we investigated in vGlut2-cre transgenic mice the role of the AMV in the acquisition and expression of contextual defensive behavior. We have found that AMV inactivation prior to the social defeaf, but not prior to the exposure to the social defeat related context, was able to decrease contextual responses in animals tested withot the presence of the male aggressor, but not in the situation where the male aggressor was present. Overall, our results suggest that the LHAjd has a role in the expression of conditioned defense, and that the AMV is involved in the acquisision of contextual fear responses, but not in social recognition of aggressive male. Anterior thalamus Circuitaria neural Context Contexto Derrota social Hipotálamo lateral Lateral hypothalamus Neural circuitry Social defeat Tálamo anterior
103	New perspectives on learning, inference, and control in brains and machines Merel, Joshua Scott January 2016 (has links) The work presented in this thesis provides new perspectives and approaches for problems that arise in the analysis of neural data. Particular emphasis is placed on parameter fitting and automated analysis problems that would arise naturally in closed-loop experiments. Part one focuses on two brain-computer interface problems. First, we provide a framework for understanding co-adaptation, the setting in which decoder updating and user learning occur simultaneously. We also provide a new perspective on intention-based parameter fitting and tools to extend this approach to higher dimensional decoders. Part two focuses on event inference, which refers to the decomposition of observed timeseries data into interpretable events. We present application of event inference methods on voltage-clamp recordings as well as calcium imaging, and describe extensions to allow for combining data across modalities or trials. Machine learning Human-machine systems Brain-computer interfaces Neural circuitry Neurosciences Statistics
104	Postsynaptic mechanisms of plasticity at developing mossy fiber-CA3 pyramidal cell synapses. / CUHK electronic theses & dissertations collection January 2009 (has links) Ho, Tsz Wan. / Thesis (Ph.D.)--Chinese University of Hong Kong, 2009. / Includes bibliographical references (leaves 125-165). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstract also in Chinese. Hippocampus (Brain) Neural circuitry Neurotransmitter receptors Synapses Mossy Fibers, Hippocampal--chemistry Pyramidal cells--chemistry Receptors, AMPA--chemistry Synapses--chemistry
105	Visual rehabilitation and reorganization: case studies of cortical plasticity in patients with age-related macular degeneration Main, Keith Leonard 06 October 2010 (has links) The extent to which cortical maps may reorganize in adult humans is a significant and topical debate in visual neuroscience. Though there are conflicting findings, evidence from humans and animals indicates that the topography of the visual cortex may change after retinal deafferentation. Remarkably, this reorganization seems to be possible in adults, whose brains are less amenable to plastic change. If adult visual reorganization is legitimate, an understanding of its causes and consequences could be profound considering the millions suffering from age-related visual disorders. This dissertation explores whether visual training may yield a reorganization of sensory maps in the adult visual cortex. It describes research in which patients, diagnosed with age-related macular degeneration (AMD), underwent visual rehabilitation therapy. Functional brain scans and behavioral tests were conducted pre and post training. These interventions generated valuable knowledge regarding whether "reorganized" activity is a true rewiring of feed forward cortical processes or an artifact of attentional feedback. The rehabilitation training produced demonstrable differences in activation patterns along the primary visual cortex (V1), but sparse improvement in the behavioral tests. In contrast, there was significant improvement in fixation tests which assessed oculomotor control. These results suggest that the nature of reorganized activity has more to do with attentional mechanisms than feed forward reorganization. Future investigations could benefit from examining the brain sites that govern visual attention in the frontal and parietal cortices. These areas may have more to do with visual adaptation in AMD patients than V1. Rehabilitation Cortical reorganization Plasticity Macular degeneration Low vision Retinal degeneration Neural networks (Neurobiology) Neuroplasticity Neural circuitry Adaptation Self-organizing systems
106	Non-Boolean characterization of Homer1a intranuclear transcription foci Li Witharana, Wing Kar January 2011 (has links) Activity-induced immediate-early gene (IEG) transcription foci can be labelled with fluorescent probes, permitting high temporal and spatial resolution in mapping neuronal circuits. Previous quantification approaches have assumed a Boolean function of transcription foci, assuming that cells are either active or inactive. Due to multiple amplification steps in the in situ hybridization process, it was thought that information relating to magnitudes of firing rates was lost. However, the current data suggest that transcription foci actually exhibit non-Boolean intensity and size values which vary according to behavioural condition. Systematic characterization of transcription foci intensity and size revealed incremental variations such that: home-cage < one-environment exposure < five-environment exposure < maximal electroconvulsive shock. Visual differences in transcription foci may result from a quantifiable relationship between spiking patterns and transcription rates. The exact stoichiometry between neuronal spiking and transcription is not yet clear, but these results suggest that Boolean applications of IEG imaging may neglect accurate neuronal activation properties. / xvi, 125 leaves : ill. ; 29 cm Scaffold proteins -- Research Neuroplasticity Transcription factors Neural circuitry Hippocampus (Brain) Rats as laboratory animals Fluorescence in situ hybridization Dissertations, Academic
107	Application of Cultured Neuronal Networks for Use as Biological Sensors in Water Toxicology and Lipid Signaling. Dian, Emese Emöke 08 1900 (has links) This dissertation research explored the capabilities of neuronal networks grown on substrate integrated microelectrode arrays in vitro to be applied to toxicological research and lipid signaling. Chapter 1 details the effects of chlorine on neuronal network spontaneous electrical activity and pharmacological sensitivity. This study demonstrates that neuronal networks can maintain baseline spontaneous activity, and respond normally to pharmacological manipulations in the present of three times the chlorine present in drinking water. The findings suggest that neuronal networks may be used as biological sensors to monitor the quality of water and the presence of novel toxicants that cannot be detected by conventional sensors. Chapter 2 details the neuromodulatory effects of N-acylethanolamides (NAEs) on the spontaneous electrical activity of neuronal networks. NAEs are a group of lipids that can mimic the effects of marijuana and can be derived from a variety of plant sources including soy lecithin. The most prominent NAEs in soy lecithin, palmitoylethanolamide (PEA) and linoleoylethanolamide (LEA), were tested individually and were found to significantly inhibit neuronal spiking and bursting activity. These effects were potentiated by a mixture of NAEs as found in a HPLC enriched fraction from soy lecithin. Cannabinoid receptor-1 (CB1-R) antagonists and other cannabinoid pathway modulators indicated that the CB1-R was not directly involved in the effects of NAEs, but that enzymatic degradation and cellular uptake were more likely targets. The results demonstrate that neuronal networks may also be a viable platform for the elucidation of biochemical pathways and drug mechanisms of action. Water quality. Water quality biological assessment. Water -- Pollution -- Toxicology. Neural circuitry. Lipids. neuronal networks microelectrode array pharmacology
108	Sensory Representation of Social Stimuli in Aromatase Expressing Neurons in the Medial Amygdala Gualtieri, Charles J 14 May 2021 (has links) The ability of animals to sense, interpret, and respond appropriately to social stimuli in their environment is essential for identifying and distinguishing between members of their own species. In mammals, social interactions both within and across species play a key role in determining if an animal will live to pass on its genes to the next generation or else be removed from the gene pool. The result of this selection pressure can be observed in specialized neural circuits that respond to social stimuli and orchestrate appropriate behavioral responses. This highly conserved network of brain structures is often referred to as the Social Behavior Network (SBN). The medial amygdala (MeA) is a central node in the SBN and has been shown to be involved in transforming information from olfactory sensory systems into social and defensive behavioral responses. Previous research has shown that individual neurons in the MeA of anesthetized mice respond selectively to different chemosensory social cues, a characteristic not observed in its upstream relay, the accessory olfactory bulb (AOB). However, the cause of this stimulus selectivity in the MeA is not yet understood. Here, I hypothesize that a subpopulation of neurons in the MeA that express the enzyme aromatase are involved in the sensory representation of social stimuli in awake, behaving animals. To test this hypothesis, I designed and built a novel behavioral apparatus that allows for discrete presentations of social stimuli in a highly controllable and reproducible environment. I then injected the adeno-associated virus (AAV) AAV-Syn-Flex-GCAMP6s into the MeA of Aromatase:Cre transgenic mice and implanted a fiber optic cannula slightly above the injection site. The combination of this transgenic mouse line and conditional AAV caused GCaMP6s expression to be exclusive to aromatase-expressing neurons. By coupling my novel behavioral apparatus to a fiber photometry system, I successfully recorded the moment-to-moment activity of aromatase neurons in the MeA of awake, behaving animals as they investigated various social stimuli. Aromatase neurons in the MeA of adult male mice respond strongly to conspecific social stimuli, including live adult mice, mouse pups, and mouse urine samples. Sniffing and investigative behaviors correlated strongly with increased GCaMP6s signal in aromatase neurons, reflecting increases in their neural activity. Interestingly, after repeated investigations of the same stimuli the activity of aromatase neurons gradually diminished. Presenting a novel stimulus following repeated investigations of a familiar stimulus reinstated some, but not all of the initial GCaMP6s signal. This points to the potential role that aromatase neurons may play in the habituation to social stimuli that are consistently present in their environment. Investigations of predator stimuli did not evoke significant responses from aromatase neurons, nor did investigations of non-social stimuli. These results demonstrate that aromatase expressing neurons in the MeA of awake, behaving animals encode the sensory representation of conspecific social stimuli, and their responses are highly selective to the type of stimulus presented. Medial Amygdala Social Behavior Aromatase GCaMP Fiber Photometry Neural Circuitry Behavioral Neurobiology Molecular and Cellular Neuroscience Systems Neuroscience
109	Over-Expression of BDNF Does Not Rescue Sensory Deprivation-Induced Death of Adult-Born Olfactory Granule Cells Unknown Date (has links) It is of interest to understand how new neurons incorporate themselves into the existing circuitry of certain neuronal populations. One such population of neurons is that which are born in the subventricular zone (SVZ) and migrate to the olfactory bulb where they differentiate into granule cells. Another area of interest is the role of brain-derived neurotrophic factor (BDNF) on the survival and overall health of these neurons. This study aimed to test whether or not BDNF is a survival factor for adult-born granule cells. Here were utilized a transgenic mouse model over-expressing BDNF under the α- calcium/calmodulin-dependent protein kinase II (CAMKIIα) promoter, and tested its effect on olfactory granule cells under sensory deprived conditions. Results from this experiment indicated that there was no significant difference in cell death or cell survival when comparing transgenic and wild type animals. We concluded that BDNF is not a survival factor for adult-born granule cells. / Includes bibliography. / Thesis (M.S.)--Florida Atlantic University, 2016. / FAU Electronic Theses and Dissertations Collection Cellular control mechanisms Mice as laboratory animals Neural circuitry Neuroplasticity Neurotransmitter receptors Sensory deprivation Sensory neurons -- Testing
110	The octopaminergic modulatory circuitry of the Drosophila larval mushroom body calyx Wong, Jin Yan Hilary January 2019 (has links) How are neuromodulatory networks organised to adapt sensory discrimination for different contexts? I hypothesised that neurons within a sensory circuit express different neuromodulatory receptors for differential modulation. Here I aimed to use the simple and genetically amenable Drosophila larval Mushroom Body (MB) calyx, a higher order processing area involved in learned odour discrimination, as a model to map octopamine (OA) neuromodulatory circuitry. I first identified olfactory projection neurons (PNs), a GABAergic feedback neuron and cholinergic extrinsic neurons as putative postsynaptic partners to OA neurons in the MB calyx using GFP reconstitution across synaptic partners. Next, I used novel EGFP-tagged OA receptors generated from recombination-mediated cassette exchange with MiMIC insertions in receptor genes to visualise endogenous expression patterns of OA receptors. Most notably, this is the first report of α2-adrenergic-like OA receptor localisation in any insect. For the first time, I showed that the α1-adrenergic-like OAMB localised to PN presynaptic terminals in the calyx; while Octβ1R localised diffusely in the calyx, resembling the innervation pattern of MB neuron dendrites. I detected EGFP-tagged Octα2R and Octβ2R in some PN cell bodies but not in neuron terminals - suggesting that Octα2R and Octβ2R may be expressed in some PNs, provided the misfolded fusion proteins are retained in the cell bodies of the neurons they are normally expressed in. Furthermore, I found that Octα2R and GABAAR fusion proteins localised to OA cell bodies but not to neuronal terminals, suggesting that OA neurons are subjected to inhibition, again given that these are not artefacts of the fusion proteins. To obtain tools to study OA modulation in the larval calyx, I then confirmed the expression patterns of driver lines that more specifically labelled calyx-innervating OA and extrinsic neurons, and tested the efficacy of three OAMB receptor knockdown lines. This initial attempt of mapping OA receptors, while subjected to further verification and development, is consistent with my hypothesis that a single neuromodulatory source can regulate multiple neuronal types in the same circuit through the distribution of different types of neuromodulatory receptors. This provides a new perspective in how the anatomical organisation of neuromodulation within a sensory network may translate to flexible outputs.

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