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The Influence of the Basolateral Amygdala-medial Prefrontal Cortex Circuitry in Appetitive Cue Learning and ValuationKeefer, Sara Elizabeth January 2018 (has links)
Thesis advisor: Gorica D. Petrovich / Environmental cues that are neutral in respect to hunger and feeding can come to predict food through Pavlovian appetitive conditioning. These learned cues can drive food seeking and eating independent of physiological hunger leading to overeating and obesity. However, the food outcome, and thus the value of the cues, can change due to environmental alterations. A change in the values of learned cues requires altering behavioral responses to accurately reflect the cue’s new outcome. This behavioral flexibility is necessary to respond appropriately to changes in the environment and, as such, is an adaptive trait. The aim of this dissertation was to determine critical neural mechanisms specifically within the basolateral amygdala (BLA) and also with its interactions with the medial prefrontal cortex (mPFC) during behavioral flexibility when outcomes of learned appetitive cues change using the appetitive reversal learning paradigm. The main focus was on the BLA (Chapter 2) and its connection with the mPFC (Chapters 3 and 4) since both of these areas are critical in appetitive cue learning and valuation and subsequent behavioral modifications. The first study in this dissertation examined if separate neuronal ensembles within the BLA respond to different learned cues, a cue that signals food availability and a cue that does not. Additionally, we investigated if these potentially distinct neuronal ensembles are necessary during periods of behavioral flexibility when the value of the specific learned cues are changed during reversal learning. We determined that there are distinct neuronal ensembles within the BLA that respond to different learned cues, and that the cue-specific ensembles are necessary for updating the value of each specific cue (Chapter 2). Next, we examined a projection target of the BLA, the mPFC, to determine if BLA-projecting neurons are activated during learning (Chapter 3). Using retrograde tract tracing combined with Fos detection, we found recruitment of the anterior BLA to prelimbic area of the mPFC across cue-food learning, signifying that the BLA can inform the mPFC of the value of learned cues. Then to establish that communication between the BLA and mPFC is necessary for cue value learning and updating (Chapter 4), we functionally disconnected communication between these regions and examined appetitive learning using discriminative conditioning, reversal learning, and devaluation paradigms. We found impairments in cue value recall and subsequent updating of the cues’ values during reversal learning. Together, these studies indicate the BLA may be important in informing the mPFC of the value of learned cues, and their interaction is critical to optimally guide behavioral responding. The findings from these experiments are valuable for our understanding of the neural mechanisms that motivate eating behavior under the control of learned food cues and to understand the mechanisms necessary for behavioral flexibility when the outcomes of learned cues are changed. / Thesis (PhD) — Boston College, 2018. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Psychology.
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Efeitos do envelhecimento na atividade do córtex cerebral durante o andar usual, adaptativo e com tarefa dupla /Sousa, Priscila Nobrega de. January 2019 (has links)
Orientador: Rodrigo Vitório / Resumo: Introdução: Apesar dos correlatos neurais dos comprometimentos do andar associados ao envelhecimento não serem completamente compreendidos, estudos recentes apontam que idosos apresentam maior ativação do córtex pré-frontal (via indireta) durante o andar. Entretanto, os estudos existentes não consideram o processo de envelhecimento em um espectro mais amplo e, ao contrário, apresentam comparações limitadas a extremos de idade (adulto jovem X idoso). A compreensão da atividade neural do controle do andar no envelhecimento é importante para a identificação do momento em que as alterações inerentes ao envelhecimento afetam a atividade do córtex cerebral. Assim os objetivos deste estudo foram: (i) investigar os efeitos do envelhecimento na atividade do córtex pré-frontal (CPF) durante o andar usual, adaptativo e com tarefa dupla; e (ii) analisar a associação entre a atividade cortical e medidas do andar e de funções cognitivas. Materiais e Método: Noventa participantes foram avaliados, sendo 15 participantes sadios em cada grupo etário: 20-25, 30-35, 40-45, 50-55, 60-65 e 70-75 anos. Foram realizadas avaliações cognitivas, do andar e da atividade do CPF. Um sistema portátil de espectroscopia funcional de luz próxima ao infravermelho foi utilizado para o registro da atividade do CPF enquanto os participantes andavam em um circuito em três condições: andar usual, adaptativo (ultrapassagem de obstáculos) e com tarefa dupla. Um carpete com sensores de pressão foi posicionado em uma d... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: Introduction: Although the neural correlates of walking impairments associated with aging are not fully understood, recent studies indicate that the older adults present greater activation of the prefrontal cortex during walking. However, existing studies do not consider the aging process in a broader spectrum and, on the contrary, present limited comparisons to extremes of age (younger X older adult). Understanding the neural activity of walking control in aging is important to identify when the inherent changes in aging affect the activity of the cerebral cortex. Thus, the aims of this study were: (i) to investigate the effects of aging on the activity of the prefrontal cortex (PFC) during usual, adaptive and dual task walking; and (ii) to analyze the association of cortical activity with walk measures and cognitive functions. Materials and Methods: Ninety participants were evaluated, with 15 healthy participants in each age group: 20-25, 30-35, 40-45, 50-55, 60-65 and 70-75 years. Cognitive, walking and PFC activity assessments were performed. A portable near infrared functional spectroscopy system was used to record PFC activity while participants walked on a circuit in three conditions: usual, adaptive (obstacle avoidance) and dual task walking. A carpet with pressure sensors was positioned in one of the straight lines of the circuit to record walk parameters. ANCOVAs were used to analyze differences in oxyhemoglobin concentrations between groups and conditions; Two-way ... (Complete abstract click electronic access below) / Mestre
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Distinct representations of a novel anxiogenic environment in the ventral hippocampusBerry, Jack January 2021 (has links)
The ability to recognize dangerous situations and environments is crucial for survival, but overestimating risk can lead to pathological avoidance of normal activities, potentially leading to anxiety disorders. Many studies over the past several decades have begun to identify the brain regions underlying threat detection and anxiety behavior. In particular, the ventral hippocampus has emerged as a critical structure for emotional behaviors, including innate anxiety. Recent work from our lab and others has shown that ventral CA1 pyramidal neurons encode information about anxiety, and these CA1 neurons preferentially target downstream structures such as hypothalamus and medial prefrontal cortex. However, the neural representation of anxiogenic environments in the initial stage of the trisynaptic circuit— the dentate gyrus— is unknown. Here, I use Dock10-Cre and Drd2-Cre mouse lines to gain optical access to granule cells and mossy cells, respectively, in the ventral dentate gyrus. Calcium activity was recorded during free exploration of the elevated plus maze (EPM) and open field test (OFT). Single cell activity and population coding were analyzed for mossy cells, granule cells, and CA1 pyramidal neurons. I found that anxiety-related activity was present in granule cells and vCA1, however mossy cells encoded novelty and spatial position. Furthermore, chemogenetic inhibition of mossy cells did not disrupt behavior in the EPM or OFT, but did disrupt acquisition of a contextual fear memory. These findings support the notion that different features of an anxiogenic environment are encoded by different cell types, and that anxiety information is present at the earliest stage of the trisynaptic circuit.
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An investigation of the neural circuitry of cued alcohol behaviors in P and Wistar ratsMcCane, Aqilah Maryam 12 1900 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Alcohol-paired cues invigorate alcohol-seeking and drinking behaviors in both rodents and individuals with alcohol use disorder (AUD). Additionally, genetic susceptibility plays a key role in alcohol addiction behaviors. Alcohol preferring (P) rats model both genetic vulnerability and symptoms of AUD. The basolateral amygdala (BLA), prefrontal cortex (PFC), hippocampus (HC) and nucleus accumbens (NA) are important brain regions involved in cued alcohol seeking. These regions are interconnected and their functional connections are hypothesized to be critical in the expression of motivated behaviors. Electrophysiological recordings in these four regions were collected in P rats engaged in a cued alcohol task. Data were filtered in the theta band (5-11 Hz) and segregated by behavioral epoch. The phase locking index γ was computed and used to measure strength of phase locking between signals from any two brain regions. The cross correlation between the amplitude of two signals was used to determine directionality. PFC-NA synchrony increased after stimuli presentation and remained elevated, relative to baseline synchrony. PFC-NA synchrony was also stronger for trials in which the animal made three or more lever presses (rewarded; R), compared to trials in which the animal responded fewer than three times (not-rewarded; NR). During lever pressing, PFC-BLA, NA-HC and PFC-HC synchrony was stronger after presentation of the DS+, in R compared to NR trials. NA-HC and PFC-BLA synchrony was stronger when responses were withheld in extinction, relative to conditioning. These data inform our knowledge of how corticolimbic connections are involved in cued ethanol seeking behaviors.
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Role of Synapsin II in Neurodevelopment: Delineating the Role of Developmental Medial Prefrontal Cortical Synapsin II Reductions in the Pathophysiology of SchizophreniaTan, Mattea 11 1900 (has links)
Synapsins are primarily neuron-specific proteins critical for neurotransmission, synaptogenesis and synapse maintenance. Synapsin II has been specifically linked with increased susceptibility towards developing schizophrenia. Reduced synapsin II mRNA levels were found in the dorsolateral prefrontal cortex (PFC) of patients with schizophrenia. Moreover, synapsin II knockdown in the medial PFC (mPFC) of the adult rat was previously shown to cause schizophrenia-like behaviour and altered expression levels of vesicular proteins involved in glutamatergic and GABAergic signaling within the mPFC.
The study of schizophrenia in recent years has shifted to focus on neurodevelopmental players which influence disease outcome. This study was designed to establish the link between neurodevelopmental dysregulation of synapsin II and schizophrenia. Specific knockdown of synapsin II was performed in the mPFC at postnatal day (PD) 7 and PD 17-23. Schizophrenia-like behavioural abnormalities were assessed at pre-pubertal (PD 32-35) and post-pubertal (PD 65-70) stages. Protein estimation of vesicular transporters involved in glutamate, GABA, and dopamine neurotransmitter systems were also assessed in the mPFC.
Results from this study indicate (1) synapsin II knockdown during PD 17-23, but not PD 7, caused lasting schizophrenia-like abnormalities (2) abnormalities exhibited permanence at pre-pubertal and post-pubertal stages, and manifested as a function of brain development, (3) behavioural abnormalities were reminiscent of symptoms in established animal models of schizophrenia (i.e. deficits in prepulse inhibition, social withdrawal, locomotor hyperactivity), (4) neurodevelopmental synapsin II alterations induced hypoactive glutamatergic activity through decreased synapsin IIa expression levels (pre-pubertal) and decreased VGLUT-2 expression levels (post-pubertal), and (5) acute olanzapine treatment effectively attenuated schizophrenia-like abnormalities through normalized synapsin IIa expression levels (pre-pubertal) and increased GAD65/67 expression levels (post-pubertal).
Results show the causal link between synapsin II expression during critical neurodevelopmental stages and schizophrenia. Additionally, evidence has been provided for the face, construct, and predictive validities of this newly developed animal model of schizophrenia. / Thesis / Doctor of Philosophy (PhD)
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The Evil Inside : A Systematic Review of Structural Differences in PsychopathyRehn Åstrand, Diana, Vedin, Julia January 2023 (has links)
The purpose of this systematic review was to characterize further the structural differences in the prefrontal cortex, limbic and paralimbic regions and amygdala alone in psychopaths. Psychopathy is a multifaceted personality disorder characterized by interpersonal and affective traits like lack of empathy, guilt or remorse, shallow affect, and carelessness, as well as behavioral traits such as impulsivity, and poor behavioral control. In recent years, the interest in the neuroanatomical differences in psychopaths has grown. This review aims to understand the prefrontal cortex, limbic and paralimbic areas, and how these regions differ between psychopathic patients and healthy controls. By systematically screening articles that used magnetic resonance imaging (MRI) and voxel based morphometry (VBM) the studies in this review examined people with psychopathic traits. To assess for psychopathy, the most used assessment tool, the Psychopathy Checklist-Revised (PCL-R) was used. Results show that the higher the PCL-R scores of the offenders, the less gray matter volume was found in the superior parts of the prefrontal cortex, limbic and paralimbic areas. Additionally, amygdala deficits in individuals with psychopathy were found. This systematic review may benefit in the way that if we increase our understanding of psychopathy and pave the way forthe creation of effective psychopathic treatments it could prevent future acts of violence. The link between a structural brain anomaly and psychopathy may have a profound clinical, legal, and scientific impact. A psychopathy diagnosis may serve as a precursor to severe societal violence.
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PROACTIVE VERSUS REACTIVE CONTROL STRATEGIES DIFFERENTIALLY MEDIATE ALCOHOL SEEKING IN WISTARS AND P RATSMitchell David Morningstar (8098238), Christopher C. Lapish (14822623) 18 May 2023 (has links)
<p>Problematic alcohol consumption develops concurrently with deficits in decision-making. These deficits may be due to alterations in dorsal medial prefrontal cortex (dmPFC) neural activity, as it is essential for the evaluation and implementation of behavioral strategies. In this study, we hypothesized that differences in cognitive control would be evident between Wistars and alcohol-preferring P rats. Cognitive control can be split into proactive and reactive components. Proactive control maintains goal-directed behavior independent of a stimulus whereas reactive control elicits goal-directed behavior at the time of a stimulus. Specifically, it was hypothesized that Wistars would show proactive control over alcohol-seeking whereas P rats </p>
<p>would show reactive control over alcohol-seeking. Proactive control in our rodent model is defined as responding to distal task cues whereas reactive control is responding to proximal cues. This was tested in rodents performing a 2-way Cued Access Protocol (2CAP) that facilitates measurements of alcohol seeking and drinking. Congruent sessions were the typical, default 2CAP sessions that consisted of the CS+ being on the same side as alcohol access. These were compared with incongruent sessions where alcohol access was opposite of the CS+. Wistars exhibited an increase in incorrect approaches during the incongruent sessions, which was not detectable in P rats. A trial-by-trial analysis indicated that the increases in incorrect responses </p>
<p>was explained by Wistars utilizing the previously learned task-rule, whereas the P rats did not. </p>
<p>This motivated the subsequent hypothesis that neural activity patterns corresponding to proactive control would be observable in Wistars but not P rats. Principal Component Analysis indicated that neural ensembles in the dmPFC of Wistars exhibited decreased activity to the cue light in incongruent sessions whereas P rat ensembles displayed increased activity at timepoints associated with the onset and end of alcohol access. Overall, it was observed that P rats showed the most differences in neural activity at times relevant for alcohol delivery; specifically, when the sipper came into the apparatus and left. Conversely, Wistars showed differences prior to approach as evidenced by both differences in cue-related activity as well as differences in </p>
<p>spatial-strategies. Together, these results support our hypothesis that Wistars are more likely to engage proactive cognitive control strategies whereas P rats are more likely to engage reactive cognitive control strategies. Although P rats were bred to prefer alcohol, differences in cognitive control phenotypes may have concomitantly occurred that are of clinical relevance.</p>
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Distribution of astrocytes in the prefrontal and visual cortices of the middle-aged rhesus monkeyCastro Mendoza, Paola B. 30 January 2023 (has links)
Neuroscience research has been largely focused on neurons, while an equally important cell type, glia, was sidelined until recently. Astrocytes are star-shaped glial cells responsible for a variety of homeostatic processes of the central nervous system in addition to participating in synaptogenesis and neuronal signal transmission. A variety of immunohistochemical markers have been utilized to visualize these cells in the brain including glial fibrillary acidic protein (GFAP), vimentin, and aldehyde dehydrogenase 1 family member L1 (ALDH1L1). The current study makes use of a multiplex immunohistochemistry protocol developed in collaboration with General Electric to stain rhesus monkey brain tissue samples from the lateral prefrontal cortex (LPFC; n=5) and the primary visual cortex (V1; n=4) with a large number of markers, including GFAP, vimentin, and ALDH1L1 as well as neuronal, microglial, and oxidative stress markers. Using algorithms and manual cell classification, we were able to obtain neuronal and astrocytic counts and use these to estimate astrocyte-to-neuron ratios (ANRs) of the individual brain areas and laminae as well as assess the relative intensity of the markers of interest between areas. Among our findings there was higher ANRs in LPFC compared to V1 gray matter as well as in layer 1 compared to layer 2 in both areas studied. There is also a higher density of astrocytes in layer 1 potentially due to the recognized lack of neurons in this layer. We found significantly higher intensities of GFAP across all gray matter layers in V1 compared to LPFC as well as higher intensities for TSPO and Cleaved Caspase-3 in some V1 layers compared to their LPFC counterparts. This higher intensity of V1 reactive astrocyte markers are potentially due to the increased number of neurons these astrocytes need to support as demonstrated by the low ANR seen in V1 when compared to LPFC. In order to further our knowledge of normal astrocyte properties in these brain areas, it is imperative that we confirm our counts with stereologic studies and include oligodendrocyte markers in our multiplex staining protocol in order to better assess glial numbers within our sections. Additionally, morphological studies assessing rhesus monkey astrocytes identified with a variety of markers is important as we have shown that no one marker stains all astrocytes even though most astrocytes express more than one marker at a time.
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PREFRONTAL CORTEX IN STRESS RELATED DISORDERS:CHARACTERIZING THE ROLE OF INHIBITORY GABAERGIC PARVALBUMIN INTERNEURONS IN STRESS RELATED ILLNESSESNawreen, Nawshaba 23 August 2022 (has links)
No description available.
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The role of the dopamine D4 receptor in modulating state-dependent gamma oscillationsFurth, Katrina Eileen 03 November 2016 (has links)
Rhythmic oscillations in neuronal activity display variations in amplitude (power) over a range of frequencies. Attention and cognitive performance correlate with increases in cortical gamma oscillations (40-70Hz) that are generated by the coordinated firing of glutamatergic pyramidal neurons and GABAergic interneurons, and are modulated by dopamine. In the medial prefrontal cortex (mPFC) of rats, gamma power increases during treadmill walking, or after administration of an acute subanesthetic dose of the NMDA receptor antagonist ketamine. Ketamine is also used to mimic symptoms of schizophrenia, including cognitive deficits, in healthy humans and rodents. Additionally, the ability of a drug to modify ketamine-induced gamma power has been proposed to predict its pro-cognitive therapeutic efficacy. However, the mechanism underlying ketamine-induced gamma oscillations is poorly understood. We hypothesized that gamma oscillations induced by walking and ketamine would be generated by a shared mechanism in the mPFC and one of its major sources of innervation, the mediodorsal thalamus (MD). Recordings from chronically implanted electrodes in rats showed that both treadmill walking and ketamine increased gamma power, firing rates, and spike-gamma LFP correlations in the mPFC. By contrast, in the MD, treadmill walking increased all three measures, but ketamine decreased firing rates and spike-gamma LFP correlations while increasing gamma power. Therefore, walking- and ketamine-induced gamma oscillations may arise from a shared circuit in the mPFC, but different circuits in the MD.
Recent work in normal animals suggests that dopamine D4 receptors (D4Rs) synergize with the neuregulin/ErbB4 signaling pathway to modulate gamma oscillations and cognitive performance. Consequently, we hypothesized that drugs targeting the D4Rs and ErbB receptors would show pro-cognitive potential by reducing ketamine-induced gamma oscillations in mPFC. However, when injected before ketamine, neither the D4R agonist nor antagonist altered ketamine’s effects on gamma power or firing rates in the mPFC, but the pan-ErbB antagonist potentiated ketamine’s increase in gamma power, and prevented ketamine from increasing firing rates. This indicates that D4Rs and ErbB receptors influence gamma power via distinct mechanisms that interact with NMDA receptor antagonism differently. Our results highlight the value of using ketamine-induced changes in gamma power as a means of testing novel pharmaceutical agents.
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