Global ETD Search

1	Role of the Nucleus Accumbens and Mesolimbic Dopamine System in Modulating the Memory of Social Defeat in Male Syrian Hamsters (Mesocricetus auratus) Luckett, Cloe 12 August 2014 (has links) Psychological stressors such as social stress and bullying are prevalent in today’s society. Disorders such as PTSD, depression and social anxiety disorder can be either caused or exacerbated by social stress and treatment options are not always effective in providing relief for these disorders. Our laboratory studies a form of social stress termed conditioned defeat, whereby a defeated Syrian hamster no longer displays species-typical territorial aggression but instead is submissive and defensive toward an intruder in its own cage. We hypothesized that the nucleus accumbens is a necessary component of the circuit mediating the acquisition and expression of conditioned defeat and that dopamine is necessary within the nucleus accumbens for inducing memory processes as well as expression of behavioral responses to stressful situations. We also hypothesized that defeat activates dopaminergic and/or nondopaminergic neurons in the ventral tegmental area (VTA) and that dopamine released by neurons projecting from the VTA to the nucleus accumbens and basolateral amygdala (BLA) increases neuronal activation of these structures during defeat. We found that dopamine, but not GABA, modulates memory of social defeat within the nucleus accumbens. However, GABA does affect the expression of behavioral responses to social defeat. Defeat also increased Fos activation of non-dopaminergic neurons, but it did not increase activation of dopaminergic neurons. Baclofen infusion into the VTA prior to defeat, which was hypothesized to specifically inhibit dopaminergic neurons, did not affect Fos activation within the nucleus accumbens and the basolateral amygdala. These experiments determined that dopamine does modulate memory of social defeat within the nucleus accumbens, but it is currently unclear what the source of this dopamine is. Future experiments are planned to determine this source of dopamine that could be a target of treatment for disorders that are caused or exacerbated by social stress. Nucleus accumbens conditioned defeat mesolimbic dopamine system
2	Ontogenetic and mechanistic explanations of within-sex behavioral variation in a lizard with temperature- dependent sex determination Huang, Victoria 25 February 2014 (has links) The leopard gecko (Eublepharis macularius) is a reptile species in which embryonic temperature contributes both to sex determination and within- sex polymorphisms. Its life history makes the leopard gecko a model system for seeking ontogenic and proximate explanations for within-sex variation in sexually dimorphic behavior and neurophysiology, necessary attributes for reproductive success. For my dissertation I have incorporated the role of androgens that potentially modulate incubation temperature effects on behavioral and brain variation, which I approached using embryo and adult leopard geckos. First, I found that that the bias of same-sex clutch siblings is primarily incubation temperature- dependent and any maternal or genetic effects on same-sex clutch siblings are secondary. Second, I found that testosterone concentrations in the yolk-albumen were higher in eggs of late development than early development at 26 °C, a female-producing incubation temperature, but did not differ from eggs incubated at another female-biased temperature. This increase in testosterone concentrations during the temperature sensitive period in putative females is a finding opposite of reported trends in most other reptiles studied to date. Further, I found that the embryonic environment influences male sociosexual investigation in the absence of gonadal hormones. Lastly, in adult males of 32.5 °C, a male-biased incubation temperature, I found that the phosphoprotein DARPP-32 that is activated by the D1 dopamine receptor in limbic brain regions is correlated to this sociosexual investigatory behavior. Neurons immunopositive for phosphorylated DARPP-32 were not only less dense in the nucleus accumbens of males who spent more time with other males, but also more dense in the preoptic area of males who spent more time with females. The use of phosphorylated DARPP-32 as marker for sociosexual exposure is novel in a lizard species. Taken together, in support of previous studies, these results show that differences in embryonic environment stem primarily from incubation temperature, can explain behavioral differences in adulthood in the absence of hormones, and, in concert with hormonal manipulation, can influence neuronal marker sensitivity to sociosexual exposure. / text Behavior Reptile Androgens Yolk Mesolimbic pathway Temperature-dependent sex determination
3	Cognitive Neurostimulation: Learning to Volitionally Invigorate Mesolimbic Reward Network Activation MacInnes, Jeff January 2015 (has links) <p>The brain’s dopaminergic system is critical to adaptive behaviors, and is centrally implicated in various pathologies. For decades, research has aimed at better characterizing what drives the mesolimbic dopamine system and the resulting influence on brain physiology and behavior in both humans and animals. To date, the dominant modes of research have relied on extrinsic approaches: pharmacological manipulations, direct brain stimulation, or delivering behavioral incentives in laboratory tasks. A critical open question concerns whether individuals can modulate activation within this system volitionally. That is, can individuals use self-generated thoughts and imagery to invigorate this system on their own? This process can be referred to as “cognitive neurostimulation” -- a precise and non-invasive stimulation of neural systems via cognitive and behavioral strategies. And if not, can they be taught to do so? Recent technological advances make it feasible to present human participants with information about ongoing neural activations in a fast and spatially precise manner. Such feedback signals might enable individuals to eventually learn to control neural systems via fine-tuning of behavioral strategies. The studies described herein investigate whether individuals can learn to volitionally invigorate activation within the mesolimbic reward network. We demonstrate that under the right training context, individuals can successfully learn to generate cognitive states that elicit and sustain activation in the ventral tegmental area (VTA), the source of dopamine production within the mesolimbic network. Although participants were explicitly trained to increase VTA activation, multiple mesolimbic regions exhibited increased connectivity during and after training. Together, these findings suggest new frameworks for aligning psychological and biological perspectives, and for understanding and harnessing the power of neuromodulatory systems.</p> / Dissertation Neurosciences Psychology Dopamine fMRI Mesolimbic Motivation neurofeedback Reward
4	Morphine-induced Locomotion and Dopamine Efflux in Mice: Role of M5 Muscarinic Receptors and Cholinergic Inputs to the Ventral Tegmental Area Stephan, Steidl 26 February 2009 (has links) M5 muscarinic receptors are associated with dopamine neurons of the ventral tegmental area (VTA) and substantia nigra, and provide an important excitatory input to the mesolimbic dopamine system. Here, I studied locomotion induced by systemic morphine (3, 10, 30 mg/kg, i.p.) in M5 knockout mice of the C57Bl/6 (B6) and CD1 x 129SvJ (129) background strains. M5 knockout mice of both strains showed reduced locomotion in response to 30 mg/kg morphine, while only B6 M5 knockout mice showed reduced locomotion in response to 10 mg/kg morphine. In B6 wild-type mice VTA pre-treatment with the non subtype-selective muscarinic receptor antagonist atropine (3 mg per side), but not the non subtype-selective nicotinic receptor antagonist mecamylamine (5 mg per side), reduced locomotion in response to 30 mg/kg (i.p.) morphine to a similar extent as systemic M5 knockout, suggesting that the reduced morphine-induced locomotion in M5 knockout mice was due to the loss of M5 receptors on VTA dopamine neurons. By contrast, in M5 knockout mice, either intra-VTA atropine or mecamylamine alone increased locomotion by almost 3 times relative to saline, and potentiated morphine-induced locomotion. Therefore, in M5 knockout mice, more clearly than in wild-type mice, blockade of either VTA muscarinic or nicotinic receptors activated locomotion. Infusions of morphine (50 ng) into the VTA increased nucleus accumbens dopamine efflux in urethane-anesthetized wild-type mice. Either M5 knockout or pre-treatment with VTA scopolamine (50 ug) in wild-type mice blocked accumbal dopamine efflux in response to VTA morphine. Therefore, M5 receptors are critical for excitation of dopamine neurons by intra-VTA morphine, suggesting that the reduced locomotion produced by systemic morphine in M5 knockout mice was, in part, due to loss of M5-mediated excitation of VTA dopamine neurons by opiates. The locomotion data also show that in the absence of M5 receptors, cholinergic afferents to mesolimbic dopamine neurons are inhibitory. This supports and extends the conclusions from many studies that non-M5 muscarinic receptors inhibit, and M5 receptors excite, dopamine neurons. Loss of M5-mediated excitation results in reduced acute effects of opiates. acetylcholine mesolimbic dopamine opiates nicotinic exploration electrochemistry 0349
5	Morphine-induced Locomotion and Dopamine Efflux in Mice: Role of M5 Muscarinic Receptors and Cholinergic Inputs to the Ventral Tegmental Area Stephan, Steidl 26 February 2009 (has links) M5 muscarinic receptors are associated with dopamine neurons of the ventral tegmental area (VTA) and substantia nigra, and provide an important excitatory input to the mesolimbic dopamine system. Here, I studied locomotion induced by systemic morphine (3, 10, 30 mg/kg, i.p.) in M5 knockout mice of the C57Bl/6 (B6) and CD1 x 129SvJ (129) background strains. M5 knockout mice of both strains showed reduced locomotion in response to 30 mg/kg morphine, while only B6 M5 knockout mice showed reduced locomotion in response to 10 mg/kg morphine. In B6 wild-type mice VTA pre-treatment with the non subtype-selective muscarinic receptor antagonist atropine (3 mg per side), but not the non subtype-selective nicotinic receptor antagonist mecamylamine (5 mg per side), reduced locomotion in response to 30 mg/kg (i.p.) morphine to a similar extent as systemic M5 knockout, suggesting that the reduced morphine-induced locomotion in M5 knockout mice was due to the loss of M5 receptors on VTA dopamine neurons. By contrast, in M5 knockout mice, either intra-VTA atropine or mecamylamine alone increased locomotion by almost 3 times relative to saline, and potentiated morphine-induced locomotion. Therefore, in M5 knockout mice, more clearly than in wild-type mice, blockade of either VTA muscarinic or nicotinic receptors activated locomotion. Infusions of morphine (50 ng) into the VTA increased nucleus accumbens dopamine efflux in urethane-anesthetized wild-type mice. Either M5 knockout or pre-treatment with VTA scopolamine (50 ug) in wild-type mice blocked accumbal dopamine efflux in response to VTA morphine. Therefore, M5 receptors are critical for excitation of dopamine neurons by intra-VTA morphine, suggesting that the reduced locomotion produced by systemic morphine in M5 knockout mice was, in part, due to loss of M5-mediated excitation of VTA dopamine neurons by opiates. The locomotion data also show that in the absence of M5 receptors, cholinergic afferents to mesolimbic dopamine neurons are inhibitory. This supports and extends the conclusions from many studies that non-M5 muscarinic receptors inhibit, and M5 receptors excite, dopamine neurons. Loss of M5-mediated excitation results in reduced acute effects of opiates. acetylcholine mesolimbic dopamine opiates nicotinic exploration electrochemistry 0349
6	Activation of ventral tegmental area dopaminergic neurons reverses pathological allodynia resulting from nerve injury or bone cancer Watanabe, Moe, Narita, Michiko, Hamada, Yusuke, Yamashita, Akira, Tamura, Hideki, Ikegami, Daigo, Kondo, Takashige, Shinzato, Tatsuto, Shimizu, Takatsune, Fukuchi, Yumi, Muto, Akihiro, Okano, Hideyuki, Yamanaka, Akihiro, Tawfik, Vivianne L, Kuzumaki, Naoko, Navratilova, Edita, Porreca, Frank, Narita, Minoru 22 January 2018 (has links) Chronic pain induced by nerve damage due to trauma or invasion of cancer to the bone elicits severe ongoing pain as well as hyperalgesia and allodynia likely reflecting adaptive changes within central circuits that amplify nociceptive signals. The present study explored the possible contribution of the mesolimbic dopaminergic circuit in promoting allodynia related to neuropathic and cancer pain. Mice with ligation of the sciatic nerve or treated with intrafemoral osteosarcoma cells showed allodynia to a thermal stimulus applied to the paw on the injured side. Patch clamp electrophysiology revealed that the intrinsic neuronal excitability of ventral tegmental area (VTA) dopamine neurons projecting to the nucleus accumbens (N.Acc.) was significantly reduced in those mice. We used tyrosine hydroxylase (TH)-cre mice that were microinjected with adeno-associated virus (AAV) to express channelrhodopsin-2 (ChR2) to allow optogenetic stimulation of VTA dopaminergic neurons in the VTA or in their N.Acc. terminals. Optogenetic activation of these cells produced a significant but transient anti-allodynic effect in nerve injured or tumor-bearing mice without increasing response thresholds to thermal stimulation in sham-operated animals. Suppressed activity of mesolimbic dopaminergic neurons is likely to contribute to decreased inhibition of N.Acc. output neurons and to neuropathic or cancer pain-induced allodynia suggesting strategies for modulation of pathological pain states. Neuropathic pain cancer pain dopamine mesolimbic dopaminergic neurons optogenetics
7	An investigation of the neural circuitry of cued alcohol behaviors in P and Wistar rats McCane, 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. Alcohol-preferring rat mesolimbic circuit alcohol prefrontal cortex electrophysiology
8	Assessment of Ethanol and Nicotine Interactions in the Rat Model: Pharmacotherapeutics, Adolescence, and the Mesolimbic System Waeiss, Robert Aaron 09 1900 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / Alcohol use disorder (AUD) and nicotine dependence often result in serious health problems and are top contributors to preventable deaths worldwide. Co-addiction to alcohol and nicotine is the most common form of polysubstance abuse. Epidemiological studies indicate that more than 80% of individuals diagnosed with AUD concurrently use nicotine. The prevalence of alcohol and nicotine comorbidity may stem from interconnected mechanisms underlying these disorders. A better understanding of how these drugs interact and the biological basis behind the high comorbidity rates could generate key targets for the development of more effective treatments for AUD and nicotine dependence. The following experiments utilized four similar overall groups consisting of vehicle, ethanol (EtOH), nicotine (NIC), and EtOH+NIC. Chapter Two investigated the efficacy of naltrexone and varenicline, the pharmacological ‘gold standards’ for treating AUD and nicotine dependence, on voluntary drug intake by rats selectively bred for high EtOH drinking. The results indicated that the standard treatments for AUD and nicotine dependence were effective at reducing consumption of the targeted reinforcer but neither reduced EtOH+NIC co-use/abuse. Chapter Three examined the effects of peri-adolescent EtOH drinking on the ability of NIC infused into the posterior ventral tegmental area (pVTA) to stimulate dopamine release within the nucleus accumbens (NAc) shell during adulthood. The results suggest a cross-sensitization to NIC produced by peri-adolescent EtOH consumption demonstrated by a leftward and upward shift in the dose response curve. Chapter Four investigated the effects of intra-pVTA infusions on NAc shell neurochemistry, EtOH reward within the NAc shell, and the role of brain-derived neurotrophic factor (BDNF) on EtOH reward within that region. The data indicated that only EtOH+NIC significantly increased glutamate, dopamine, and BDNF in the NAc shell. Repeated pretreatment with EtOH+NIC also enhanced EtOH reward in the NAc shell and BDNF infusions were sufficient to recapitulate these findings. Collectively, the data indicate that concurrent exposure to EtOH and NIC results in unique neuroadaptations that promote future drug use. The failure to develop effective pharmacotherapeutics for AUD or nicotine dependence could be associated with examining potential targets in models that fail to reflect the impact of polydrug exposure. / 2020-04-03 Addiction Alcohol Mesolimbic pathway Nicotine Nucleus accumbens Ventral tegmental area
9	The role of the μ-opioid receptors in the mechanism of ethanol-stimulated mesolimbic dopamine release Job, Martin Olufemi 05 February 2010 (has links) The goal of this dissertation was to investigate the role of μ-opioid receptors in the mechanism of ethanol-stimulated dopamine release in the nucleus accumbens shell (NAcS) of rats. The underlying hypothesis is that blockade of the μ-opioid receptors leads to an attenuation of ethanol-stimulated mesolimbic dopamine release. We prepared ethanol-naïve male Long Evans rats (n = 95) for intravenous (i.v.) drug administration and in vivo microdialysis (in awake, freely moving animals), and analyzed our samples using HPLC and GC for dopamine and ethanol detection, respectively. In one set of experiments, we looked at the effects of naltrexone, a non-selective opioid antagonist, on ethanol-stimulated mesolimbic dopamine release. First of all, we checked to see if naltrexone affected basal dopamine levels in the NAcS. Thereafter, we looked for a dose of naltrexone (i.v.) that was effective in suppressing the release of dopamine in the NAcS evoked by morphine (1 mg/kg, i.v.). Subsequently, we checked to see if doses of naltrexone that inhibited morphine-evoked dopamine were also effective in attenuating dopamine release due to ethanol (1g/kg, 10% w/v, i.v.). To do this, we pretreated rats with naltrexone doses, followed 20 min later by morphine, ethanol or saline (all drugs were administered i.v.). In another set of experiments, we looked at the effect of β-funaltrexamine, a selective μ-opioid antagonist, on ethanol-stimulated dopamine release in the NAcS. Similarly to the previous set of experiments, we looked for a dose of β-funaltrexamine (s.c.) that was effective in suppressing the release of dopamine the NAcS evoked by morphine (1 mg/kg, i.v.), and checked to see if this dose of β-funaltrexamine was also effective in attenuating ethanol-stimulated dopamine release in the NAcS. For the β- funaltrexamine experiments, rats were pretreated with β-funaltrexamine (s.c.) 20- 25 h before i.v. infusions of saline, morphine and ethanol. Morphine increased dopamine release in the NAcS. Naltrexone and β- funaltrexamine significantly attenuated morphine-evoked dopamine release. Also, ethanol increased dopamine release in the NAcS. Naltrexone and β- funaltrexamine, at doses effective in attenuating morphine-evoked dopamine release, suppressed the prolongation, but not the initiation of dopamine release in the NAcS due to ethanol. Naltrexone and β-funaltrexamine did not affect the peak concentration and clearance of ethanol in the brain. The conclusion of this study is that the μ-opioid receptors are involved in a delayed component of ethanol-stimulated dopamine release in the NAcS in ethanol-naïve rats. This is the first study to show that the ethanol-stimulated dopamine response consists of a delayed μ-opioid mechanism. / text Opioid receptors Dopamine release Nucleus accumbens shell
10	Brain Signaling Mechanisms Through Which Dopamine Stimulates Maternal Behavior in Rats Zhang, Ke-You January 2008 (has links) Thesis advisor: Michael Numan / This paper will review research from our laboratory dealing with the neural basis of maternal behavior in rats. Specifically, my work investigates hypothalamic interaction with the mesolimbic dopamine system and the regulation of maternal responsiveness. Recent evidence has shown that increased dopamine activity in the nucleus accumbens, a major terminus of the mesolimbic dopamine pathway, results in a facilitation of maternal behavior in female rats who have been partially primed by hormones. However, the way in which dopamine and hormones act on these neural circuits is unclear. We hypothesize that one of these hormones, estradiol, acts on the MPOA and mesolimbic dopamine system through similar intracellular mechanisms as dopamine. My research goals are twofold: (1) to discern which G-protein coupled pathway dopamine utilizes to act in the nucleus accumbens and (2) to investigate whether estradiol is having rapid effects at the cell membrane and whether these effects are mediated by G-protein coupled receptors. / Thesis (BA) — Boston College, 2008. / Submitted to: Boston College. College of Arts and Sciences. / Discipline: Psychology. / Discipline: College Honors Program. Biology, Neuroscience maternal behavior dopamine mesolimbic dopamine pathway hormones hypothalamus MPOA

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