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Dissecting the Effects of Different Pain Modalities and Oxycodone on Prodynorphin Expressing Neurons in the Mouse Prelimbic CortexZhou, Shudi 11 1900 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Currently, changes to endogenous opioid circuits in various pain
modalities, including surgical and neuropathic pain, remain unclear. Dynorphin,
which is released by prodynorphin-expressing neurons (Pdyn+ neurons), is the
endogenous opioid ligand to kappa opioid receptors (KOR). Moreover, a recent
study has shown an increase in prodynorphin (Pdyn) mRNA expression in the
prelimbic cortex (PL) in a mouse model of chronic pain. However, alterations in
the activity of PL Pdyn-expressing neurons (PLPdyn+ neurons) in postoperative
and chronic pain have never been explored. Firstly, I found that the population of
PLPdyn+ neurons consists of both pyramidal and inhibitory subtypes. Secondly, I
found that one day after surgical incision of the mouse hind paw, the excitability
of pyramidal PLPdyn+ neurons was increased in both male and female mice, while
the excitability of inhibitory PLPdyn+ neurons was unchanged. However, when
postoperative pain behavior subsided, inhibitory PLPdyn+ neurons were
hyperexcitable in male mice, while pyramidal PLPdyn+ neurons were hypoexcitable
in female mice. Lastly, I dissected electrophysiological changes to PLPdyn+
neurons in the spared nerve injury (SNI) model of chronic neuropathic pain. At
both early and late stages of SNI pain development, increased excitability of
pyramidal PLPdyn+ neurons was detected in both male and female mice. However,
in both male and female mice, the excitability of inhibitory PLPdyn+ neurons decreased 3 days after SNI but was conversely increased when measured 14
days after SNI. My findings suggest that different subtypes of PLPdyn+ neurons
manifest distinct alterations in the development of different pain modalities in a
sex-specific manner.
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Efeitos cardiovasculares causados pela microinjeção de angiotensina II no córtex pré-límbico de ratos / Cardiovascular effects induced by angiotensin II microinjection in the prelimbic cortex of ratsNogari, Bruna Muza 17 April 2015 (has links)
Estudos relatam alterações cardiovasculares após a estimulação química ou elétrica do córtex pré-límbico (PL) em ratos. O sistema renina-angiotensina (SRA) central está envolvido na regulação do sistema cardiovascular, tendo como um dos principais componentes ativos desse sistema a angiotensina II (ANGII). Além disso, foi demonstrada a presença de um sistema SRA funcional no PL, com a presença de peptídeos e receptores angiotensinérgicos. Sendo assim, o objetivo do presente estudo foi investigar se a estimulação do PL com ANG II induz respostas cardiovasculares mediadas por ativação do sistema nervoso simpático ou por liberação de vasopressina. A microinjeção de ANGII no PL de ratos não anestesiados causou resposta pressora e bradicardíaca de forma dose-dependente. O pré-tratamento sistêmico com o bloqueador ganglionar, pentolínio (5mg/Kg), não alterou a resposta pressora, mas bloqueou a resposta bradicárdiaca causada pela microinjeção de ANGII no PL, sugerindo que o sistema nervoso simpático não medeia a resposta pressora. Além disso, o pré-tratamento sistêmico com antagonista dos receptores vasopressinérgicos do tipo V1, o dTyr(CH2)5(Me)AVP (50 g/kg), bloqueou as respostas cardiovasculares causadas pela microinjeção de ANGII no PL, demonstrando o envolvimento do mecanismo vasopressinérgico humoral na mediação destas respostas. Centralmente, o pré-tratamento do PL com o antagonista AT1, candesartan, bloqueou a resposta cardiovascular induzida pela microinjeção de ANGII, assim como o pré-tratamento com CGP42112A, antagonista AT2, foi capaz de atenuar as respostas cardiovasculares induzidas pela microinjeção de ANGII, sugerindo o envolvimento de ambos os receptores no desencadeamento dessas respostas cardiovasculares. Foi investigada a participação do sistema noradrenérgico no desencadeamento das respostas cardiovasculares à ANGII, através da administração local de um antagonista de receptores 1- adrenérgicos, o WB4101; o qual foi efetivo em reduzir a resposta pressora sem alterar a resposta bradicardíaca à ANGII. Em conclusão, a administração de ANGII no PL de ratos não-anestesiados, através da estimulação de receptores AT1 e AT2, evoca respostas pressoras e bradicardíacas mediadas por liberação sistêmica de vasopressina, envolvendo também a participação do sistema noradrenérgico do PL. / Previous studies have reported cardiovascular responses after chemical or electrical stimulation of the prelimbic cortex (PL) in rats. The central renin-angiotensin system (RAS) is involved in the regulation of the cardiovascular system, being angiotensin II (ANG II) one of the major active components of this system. Furthermore, there are angiotensinergic receptors and peptides in the PL, indicating the presence of a functional RAS in this brain area. Thus, the aim of this study was to investigate if the PL stimulation with ANG II induces cardiovascular responses mediated by activation of the sympathetic nervous system or through the release of vasopressin. ANG II microinjection into the PL of anesthetized rats caused pressor and bradycardiac responses, in a dose-dependent manner. Systemic pretreatment with the ganglionic blocker pentolinium (5 mg / kg) did not affect the pressor response, but blocked the bradycardiac response induced by ANG II, suggesting that the sympathetic nervous system does not mediate the pressor response. Furthermore, systemic pretreatment with the V1-vasopressinergic receptor antagonist, dTyr (CH2) 5 (Me) AVP (50 mg / kg) blocked the cardiovascular responses caused by the microinjection of ANG II into the PL, demonstrating the involvement of the humoral vasopressinergic mechanism in the mediation of these responses. PL pretreatment with the AT1 antagonist candesartan blocked the cardiovascular response induced by the microinjection of ANG II, while PL pretreatment with CGP42112A, an AT2 antagonist, attenuated the cardiovascular responses induced by microinjection of ANG II, suggesting the local involvement of both receptors in triggering these cardiovascular responses. We also investigated the participation of the local noradrenergic system in the triggering of cardiovascular responses to ANG II pretreating the PLwith the 1- adrenergic receptor antagonist WB4101. The pretreatment with WB4101 reduced the pressor response without changing the bradycardiac response. In summary, administration ANG II into the PL of non-anesthetized rats evoked pressor and bradycardiac responses mediated by local stimulation of AT1 and AT2 receptors, with concomitant involvement PL noradrenergic mechanisms, and systemic release of vasopressin.
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Brain Derived Neurotrophic Factor Modulates Behavioral and Brain Responses to Social StressJeffress, Elizabeth 11 May 2015 (has links)
Social stress is a prevalent factor in society that can cause or exacerbate neuropsychiatric disorders including depression and posttraumatic stress disorder. According to the National Institutes of Health, 6.9% of adults in this country currently suffer from depression, and 4.1% suffer from an anxiety disorder. Unfortunately, current treatments are ineffective in reducing or alleviating symptoms in a majority of these patients. Thus, it is critical to understand how social stress changes in brain and behavior so that we might develop alternative treatments. Brain derived neurotrophic factor (BDNF), which binds to tyrosine kinase B (TrkB) receptors, plays a role in fear learning and in behavioral responses to stress, although we do not currently know whether BDNF promotes or prevents these responses. The purpose of this project was to understand how BDNF alters brain and behavior in response to social stress using a model of social stress in Syrian hamsters, termed conditioned defeat (CD). CD refers to the marked increase in submissive and defensive behavior following social defeat. Specific Aim (SA) 1 tested the hypothesis that BDNF, via TrkB receptors, promotes CD learning. Instead, we found that BDNF and a selective TrkB receptor agonist reduced CD and that a TrkB receptor antagonist enhanced CD. SA 2 tested the hypothesis that the behavioral response observed following systemic administration of TrkB-active drugs is mediated via their action in specific nodes of the neural circuit underlying CD. Unfortunately, the vehicle in which these drugs are dissolved independently activates immediate early gene expression making interpretation of these data impossible. Finally, SA 3 tested the hypothesis that BDNF alters defeat-induced neural activation at least in part by acting in the medial prefrontal cortex (mPFC). We demonstrated that BNDF microinjected into the mPFC site-specifically altered defeat-induced neural activation in the CD neural circuit supporting this hypothesis. Overall, these data suggest that BDNF acts to prevent social stress-induced changes in behavior, at least in part via the basolateral amygdala and the mPFC, and that BDNF-active drugs might be a useful avenue to pursue to discover new treatments for patients that suffer from stress-related neuropsychiatric disorders.
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Efeitos cardiovasculares causados pela microinjeção de angiotensina II no córtex pré-límbico de ratos / Cardiovascular effects induced by angiotensin II microinjection in the prelimbic cortex of ratsBruna Muza Nogari 17 April 2015 (has links)
Estudos relatam alterações cardiovasculares após a estimulação química ou elétrica do córtex pré-límbico (PL) em ratos. O sistema renina-angiotensina (SRA) central está envolvido na regulação do sistema cardiovascular, tendo como um dos principais componentes ativos desse sistema a angiotensina II (ANGII). Além disso, foi demonstrada a presença de um sistema SRA funcional no PL, com a presença de peptídeos e receptores angiotensinérgicos. Sendo assim, o objetivo do presente estudo foi investigar se a estimulação do PL com ANG II induz respostas cardiovasculares mediadas por ativação do sistema nervoso simpático ou por liberação de vasopressina. A microinjeção de ANGII no PL de ratos não anestesiados causou resposta pressora e bradicardíaca de forma dose-dependente. O pré-tratamento sistêmico com o bloqueador ganglionar, pentolínio (5mg/Kg), não alterou a resposta pressora, mas bloqueou a resposta bradicárdiaca causada pela microinjeção de ANGII no PL, sugerindo que o sistema nervoso simpático não medeia a resposta pressora. Além disso, o pré-tratamento sistêmico com antagonista dos receptores vasopressinérgicos do tipo V1, o dTyr(CH2)5(Me)AVP (50 g/kg), bloqueou as respostas cardiovasculares causadas pela microinjeção de ANGII no PL, demonstrando o envolvimento do mecanismo vasopressinérgico humoral na mediação destas respostas. Centralmente, o pré-tratamento do PL com o antagonista AT1, candesartan, bloqueou a resposta cardiovascular induzida pela microinjeção de ANGII, assim como o pré-tratamento com CGP42112A, antagonista AT2, foi capaz de atenuar as respostas cardiovasculares induzidas pela microinjeção de ANGII, sugerindo o envolvimento de ambos os receptores no desencadeamento dessas respostas cardiovasculares. Foi investigada a participação do sistema noradrenérgico no desencadeamento das respostas cardiovasculares à ANGII, através da administração local de um antagonista de receptores 1- adrenérgicos, o WB4101; o qual foi efetivo em reduzir a resposta pressora sem alterar a resposta bradicardíaca à ANGII. Em conclusão, a administração de ANGII no PL de ratos não-anestesiados, através da estimulação de receptores AT1 e AT2, evoca respostas pressoras e bradicardíacas mediadas por liberação sistêmica de vasopressina, envolvendo também a participação do sistema noradrenérgico do PL. / Previous studies have reported cardiovascular responses after chemical or electrical stimulation of the prelimbic cortex (PL) in rats. The central renin-angiotensin system (RAS) is involved in the regulation of the cardiovascular system, being angiotensin II (ANG II) one of the major active components of this system. Furthermore, there are angiotensinergic receptors and peptides in the PL, indicating the presence of a functional RAS in this brain area. Thus, the aim of this study was to investigate if the PL stimulation with ANG II induces cardiovascular responses mediated by activation of the sympathetic nervous system or through the release of vasopressin. ANG II microinjection into the PL of anesthetized rats caused pressor and bradycardiac responses, in a dose-dependent manner. Systemic pretreatment with the ganglionic blocker pentolinium (5 mg / kg) did not affect the pressor response, but blocked the bradycardiac response induced by ANG II, suggesting that the sympathetic nervous system does not mediate the pressor response. Furthermore, systemic pretreatment with the V1-vasopressinergic receptor antagonist, dTyr (CH2) 5 (Me) AVP (50 mg / kg) blocked the cardiovascular responses caused by the microinjection of ANG II into the PL, demonstrating the involvement of the humoral vasopressinergic mechanism in the mediation of these responses. PL pretreatment with the AT1 antagonist candesartan blocked the cardiovascular response induced by the microinjection of ANG II, while PL pretreatment with CGP42112A, an AT2 antagonist, attenuated the cardiovascular responses induced by microinjection of ANG II, suggesting the local involvement of both receptors in triggering these cardiovascular responses. We also investigated the participation of the local noradrenergic system in the triggering of cardiovascular responses to ANG II pretreating the PLwith the 1- adrenergic receptor antagonist WB4101. The pretreatment with WB4101 reduced the pressor response without changing the bradycardiac response. In summary, administration ANG II into the PL of non-anesthetized rats evoked pressor and bradycardiac responses mediated by local stimulation of AT1 and AT2 receptors, with concomitant involvement PL noradrenergic mechanisms, and systemic release of vasopressin.
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Envolvimento da neurotransmissão angiotensinérgica do córtex pré-límbico na modulação de respostas autonômicas, hormonal e status oxidativo evocados pelo estresse de restrição em ratos / Involvement of angiotensinergic neurotransmission in prelimbic cortex on the modulation of autonomic, hormonal and oxidative status evoked by restraint stress in ratsSilva, Taíz Francine Brasil da 04 July 2016 (has links)
O córtex pré-límbico (PL) é uma importante área límbica envolvida em vários processos funcionais correlatos ao estresse, tais como respostas cardiovasculares, hormonais e comportamentais. O modelo de estresse de restrição (ER) foi padronizado na literatura como uma situação aversiva capaz de promover aumento da pressão arterial e frequência cardíaca, queda da temperatura cutânea e estimulação do eixo hipotálamo-pituitária-adrenal (HPA). Trabalhos da literatura evidenciaram que ratos submetidos ao ER apresentavam aumento da atividade neuronial no PL, sugerindo que essa estrutura module respostas ao ER. Assim, a inibição temporária de sinapses no PL potencializou a resposta taquicárdica induzida pelo ER, sem alterar a resposta pressora. Além do controle cardiovascular, outros trabalhos demonstraram que o PL também participa do controle hormonal durante o ER. O ER agudo também está envolvido com a produção de espécies reativas de oxigênio (EROs), fator que pode estar envolvido nas alterações a longo prazo observadas após exposição a uma situação aversiva. O sistema renina angiotensina (SRA) central modula respostas cardiovasculares, inclusive aquelas induzidas por situações aversivas, além de ter um papel reconhecido na produção de EROs. Além disso, foi demonstrado que o PL possui SRA funcional com presença dos peptídeos a ele relacionados. Baseado nos fatos mencionados acima, a hipótese do presente projeto é que a neurotransmissão angiotensinérgica do PL está envolvida na modulação de respostas autonômicas (aumento de pressão arterial e frequência cardíaca, e queda da temperatura cutânea) e hormonal (aumento plasmático de corticosterona) evocadas pelo ER, e que essa via envolveria a formação de EROs. A microinjeção do inibidor da enzima conversora de angiotensina (ECA) lisinopril no PL, nas doses de 0,5 e 1nmol/100nL, reduziu a resposta pressora, sendo a dose de 1nmol/100nL de lisinopril também capaz de reduzir a resposta taquicárdica induzida pelo ER; porém nenhuma dose utilizada ocasionou mudanças na queda da temperatura cutânea evocada pelo ER. O pré-tratamento do PL com o antagonista de receptores do subtipo AT1 candesartan reduziu o efeito pressor induzido pelo ER, porém não alterou a resposta taquicárdica e queda da temperatura cutânea associadas ao ER. Por sua vez, o pré-tratamento com o antagonista de receptores do subtipo AT2, PD123177, reduziu a resposta taquicárdica sem alterar a resposta pressora e a queda da temperatura cutânea evocadas pelo ER. Em adição, o estresse de restrição agudo e os pré-tratamentos realizados não foram capazes de alterar a atividade da enzima NADPH oxidase no PL. Em conclusão, os presentes resultados sugerem a participação do SRA na modulação da resposta cardiovascular ao ER, através da ativação de receptores AT1, e AT2 do PL, afetando respectivamente, o componente vascular e o cardíaco da resposta autonômica causada pelo ER. Além disso, os resultados da atividade da enzima NADPH oxidase no PL sugerem que o ER agudo, os receptores AT1, AT2 e a ECA não modulam o status oxidativo local. / The prelimbic cortex is an important limbic structure involved in several stressrelated functional processes, such as cardiovascular, hormonal and behavior responses. Restraint stress (RS) was standardized in literature as an aversive situation able to promote blood pressure and heart rate increases, reduction in tail temperature and stimulation of the hypothalamic-pituitary-adrenal axis (HPA). Previous studies demonstrated that rats submitted to RS exhibited increased neuronal activity in the PL, suggesting that this structure modulates RS-evoked responses. Temporary, synaptic temporary inhibition in the PL markedly increased the RS-evoked tachycardiac response, without affecting the pressor one. Beyond cardiovascular control, other studies demonstrated that PL also participates in hormonal control during RS. Acute RS is also involved in the production of reactive oxygen species (ROS), which could be involved in long- term changes observed after exposure to an aversive situation. The central renin-angiotensin system (RAS) modulates cardiovascular responses, including those induced by aversive situations. In addition, this system has a well-known role in ROS production. Furthermore, the presence of angiotensinergic peptides in PL has also been demonstrated, suggesting the existence of a functional RAS in this structure. Based on the facts mentioned above, the hypothesis of the present study was that the angiotensinergic neurotransmission in PL is involved in the modulation of autonomic responses (blood pressure and heart rate increase, and reduction in tail temperature) evoked by RS, and this pathway would involve ROS formation. Microinjection of lisinopril (0.5 and 1nmol/100nL), an inhibitor of angiotensinconverting enzyme (ACE), into PL reduced the pressor response, and the dose 1nmol/nL was also able to reduce the tachycardiac response induced by RS; however, none of doses changed the reduction in tail temperature evoked by RS. PL treatment with candesartan, an AT1 receptors antagonist, reduced the RS-evoked pressor response, but did not affect the RS-evoked tachycardiac response and reduction in tail temperature. In addition, pretreatment with PD123177, an AT2 receptors antagonist, reduced the RS-evoked tachycardiac response, without affecting the pressor response or the RS-evoked reduction in tail temperature. In addition, neither acute RS or local treatments affected NADPH oxidase activity in the PL. In conclusion, the present results suggests the involvement of the central RAS in the modulation of the cardiovascular responses caused by RS, through the activation of both AT1 and AT2 receptors in the PL. The PL AT1 receptors modulating the vascular, and the AT2 modulating the cardiac component of RS-evoked autonomic response. Furthermore, our study suggests that neither acute RS or local AT1, AT2 and ACE affect oxidative status in the PL.
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Envolvimento da neurotransmissão angiotensinérgica do córtex pré-límbico na modulação de respostas autonômicas, hormonal e status oxidativo evocados pelo estresse de restrição em ratos / Involvement of angiotensinergic neurotransmission in prelimbic cortex on the modulation of autonomic, hormonal and oxidative status evoked by restraint stress in ratsTaíz Francine Brasil da Silva 04 July 2016 (has links)
O córtex pré-límbico (PL) é uma importante área límbica envolvida em vários processos funcionais correlatos ao estresse, tais como respostas cardiovasculares, hormonais e comportamentais. O modelo de estresse de restrição (ER) foi padronizado na literatura como uma situação aversiva capaz de promover aumento da pressão arterial e frequência cardíaca, queda da temperatura cutânea e estimulação do eixo hipotálamo-pituitária-adrenal (HPA). Trabalhos da literatura evidenciaram que ratos submetidos ao ER apresentavam aumento da atividade neuronial no PL, sugerindo que essa estrutura module respostas ao ER. Assim, a inibição temporária de sinapses no PL potencializou a resposta taquicárdica induzida pelo ER, sem alterar a resposta pressora. Além do controle cardiovascular, outros trabalhos demonstraram que o PL também participa do controle hormonal durante o ER. O ER agudo também está envolvido com a produção de espécies reativas de oxigênio (EROs), fator que pode estar envolvido nas alterações a longo prazo observadas após exposição a uma situação aversiva. O sistema renina angiotensina (SRA) central modula respostas cardiovasculares, inclusive aquelas induzidas por situações aversivas, além de ter um papel reconhecido na produção de EROs. Além disso, foi demonstrado que o PL possui SRA funcional com presença dos peptídeos a ele relacionados. Baseado nos fatos mencionados acima, a hipótese do presente projeto é que a neurotransmissão angiotensinérgica do PL está envolvida na modulação de respostas autonômicas (aumento de pressão arterial e frequência cardíaca, e queda da temperatura cutânea) e hormonal (aumento plasmático de corticosterona) evocadas pelo ER, e que essa via envolveria a formação de EROs. A microinjeção do inibidor da enzima conversora de angiotensina (ECA) lisinopril no PL, nas doses de 0,5 e 1nmol/100nL, reduziu a resposta pressora, sendo a dose de 1nmol/100nL de lisinopril também capaz de reduzir a resposta taquicárdica induzida pelo ER; porém nenhuma dose utilizada ocasionou mudanças na queda da temperatura cutânea evocada pelo ER. O pré-tratamento do PL com o antagonista de receptores do subtipo AT1 candesartan reduziu o efeito pressor induzido pelo ER, porém não alterou a resposta taquicárdica e queda da temperatura cutânea associadas ao ER. Por sua vez, o pré-tratamento com o antagonista de receptores do subtipo AT2, PD123177, reduziu a resposta taquicárdica sem alterar a resposta pressora e a queda da temperatura cutânea evocadas pelo ER. Em adição, o estresse de restrição agudo e os pré-tratamentos realizados não foram capazes de alterar a atividade da enzima NADPH oxidase no PL. Em conclusão, os presentes resultados sugerem a participação do SRA na modulação da resposta cardiovascular ao ER, através da ativação de receptores AT1, e AT2 do PL, afetando respectivamente, o componente vascular e o cardíaco da resposta autonômica causada pelo ER. Além disso, os resultados da atividade da enzima NADPH oxidase no PL sugerem que o ER agudo, os receptores AT1, AT2 e a ECA não modulam o status oxidativo local. / The prelimbic cortex is an important limbic structure involved in several stressrelated functional processes, such as cardiovascular, hormonal and behavior responses. Restraint stress (RS) was standardized in literature as an aversive situation able to promote blood pressure and heart rate increases, reduction in tail temperature and stimulation of the hypothalamic-pituitary-adrenal axis (HPA). Previous studies demonstrated that rats submitted to RS exhibited increased neuronal activity in the PL, suggesting that this structure modulates RS-evoked responses. Temporary, synaptic temporary inhibition in the PL markedly increased the RS-evoked tachycardiac response, without affecting the pressor one. Beyond cardiovascular control, other studies demonstrated that PL also participates in hormonal control during RS. Acute RS is also involved in the production of reactive oxygen species (ROS), which could be involved in long- term changes observed after exposure to an aversive situation. The central renin-angiotensin system (RAS) modulates cardiovascular responses, including those induced by aversive situations. In addition, this system has a well-known role in ROS production. Furthermore, the presence of angiotensinergic peptides in PL has also been demonstrated, suggesting the existence of a functional RAS in this structure. Based on the facts mentioned above, the hypothesis of the present study was that the angiotensinergic neurotransmission in PL is involved in the modulation of autonomic responses (blood pressure and heart rate increase, and reduction in tail temperature) evoked by RS, and this pathway would involve ROS formation. Microinjection of lisinopril (0.5 and 1nmol/100nL), an inhibitor of angiotensinconverting enzyme (ACE), into PL reduced the pressor response, and the dose 1nmol/nL was also able to reduce the tachycardiac response induced by RS; however, none of doses changed the reduction in tail temperature evoked by RS. PL treatment with candesartan, an AT1 receptors antagonist, reduced the RS-evoked pressor response, but did not affect the RS-evoked tachycardiac response and reduction in tail temperature. In addition, pretreatment with PD123177, an AT2 receptors antagonist, reduced the RS-evoked tachycardiac response, without affecting the pressor response or the RS-evoked reduction in tail temperature. In addition, neither acute RS or local treatments affected NADPH oxidase activity in the PL. In conclusion, the present results suggests the involvement of the central RAS in the modulation of the cardiovascular responses caused by RS, through the activation of both AT1 and AT2 receptors in the PL. The PL AT1 receptors modulating the vascular, and the AT2 modulating the cardiac component of RS-evoked autonomic response. Furthermore, our study suggests that neither acute RS or local AT1, AT2 and ACE affect oxidative status in the PL.
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MEASURING GLUTAMATE AND OXYGEN IN BRAIN REWARD CIRCUITS IN ANIMAL MODELS OF COCAINE ABUSE AND DECISION-MAKINGBatten, Seth Richard 01 January 2019 (has links)
Drug-specific reward and associated effects on neural signaling are often studied between subjects, where one group self-administers drug and a separate group self-administers a natural reinforcer. However, exposure to drugs of abuse can cause long-term neural adaptations that can affect how an organism responds to drug reward, natural reward, and their reward-associated stimuli. Thus, to isolate drug-specific effects it is important to use models that expose the same organism to all of the aforementioned. Multiple schedules provide a means of dissociating the rewarding effects of a drug from the rewarding effects of food within a single animal. Further, drug users do not take drugs in isolation; rather, they are often faced with several concurrently available commodities (e.g. monetary goods, social relationships). Thus, using choice measures to assess the relative subjective value of drug reinforcers in both humans and animals promotes a translational understanding of mechanisms that govern drug-associated decision-making. Thus, in order to gain a more translational view of the neurobehavioral mechanisms that underlie drug-associated behavior, in the first study, glutamate was measured in the nucleus accumbens core (NAcC) and prefrontal cortex (PrL) in freely-moving rats as they behaved in a cocaine-food multiple schedule procedure. In the second study, oxygen dynamics were measured in the orbitofrontal cortex (OFC) of freely-moving rats as they behaved in a cocaine/food choice procedure. The results from the first study showed that, in the NAc and PrL, there was an increase in glutamate release when animals earned cocaine. Further, the number of glutamate peaks that occurred per cocaine lever press and per cocaine reinforcer was increased compared to food. In the second study, OFC oxygen dynamics were positively correlated with cocaine/food choice and generally tracked preference. Further, OFC oxygen dynamics were greater to cocaine related events. Taken together, these results showed the feasibility of combining electrochemical measurements with complex drug-related behavioral procedures. These results also highlight the importance of the PrL, NAcC, and OFC in the valuation of drug and non-drug commodities. Overall, these results add to our understanding of the neurobehavioral mechanisms that guide drug-associated behavior and create more precise experimental avenues to research potential treatments.
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Recovery of function after lesions of the anterior thalamic nuclei: CA1 neuromorphologyHarland, Bruce January 2013 (has links)
The anterior thalamic nuclei (ATN) are a critical part of an extended hippocampal system that supports key elements of episodic memory. Damage or disconnection of the ATN is a component of clinical conditions associated with severe anterograde amnesisa such as the Korsakoff’s syndrome, thalamic stroke, and neurodegenerative disorders. Previous studies have demonstrated that the ATN and hippocampus are often interdependent, and that ATN damage can result in ‘covert pathology’ in ostensibly healthy distal regions of the extended hippocampal system. Adult male rats with neurotoxic bilateral ATN lesions or sham surgery were post-operatively housed in an enriched environment or standard housing after a lesion-induced spatial working memory deficit had been established. These rats were retested on cross-maze and then trained in radial-arm maze spatial memory tasks. Other enriched rats received pseudo-training only after the enrichment period. The detailed neuromorphology of neurons was subsequently examined in the hippocampal CA1. Soma characteristics were also examined in the retrosplenial granular b cortex and the prelimbic cortex. In Experiment 1, ATN lesions produced clear deficits in both the cross-maze and radial-arm maze tasks and reduced hippocampal CA1 dendritic complexity, length, and spine density, while increasing the average diameter of the dendrites. Post-operative enrichment reversed the ATN lesion-induced deficits in the cross-maze and radial-arm maze, and returned CA1 basal and apical spine density to a level comparable to that of sham standard housed trained rats. The sham enriched rats exhibited improved radial-arm maze performance and increased CA1 branching complexity and spine density in both basal and apical arbors compared to sham standard housed rats. The neuromorphological changes observed in the enriched ATN and sham rats may be in part responsible for the spatial working memory improvements observed. Experiment 2 provided support for this contention by demonstrating that the CA1 spine changes were explicitly relevant to spatial learning and memory, because trained enriched sham and ATN rats had increased spines, particularly in the basal tree when compared to closely comparable pseudo-trained enriched rats. Interestingly, spatial memory training increased the numbers of both thin and mushroom spines, whereas enrichment was only associated with an increase in thin spines. In Experiment 3, ATN lesions increased cell body size in layer II of the retrosplenial granular b cortex, whereas enrichment decreased cell body size in layer V of this region. Neither ATN lesions nor enrichment had any effect on cell body morphology in the prelimbic cortex. The current research provides some of the strongest evidence to date of ATN and hippocampal interdependence within the extended hippocampal system, and provides the first evidence of neuromorphological correlates of recovery after ATN lesions.
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Coordination des actions et des habitudes : approche neurocomportementale chez le rat / Coordination of actions and habits : a neurobehavioural approach in ratsTran-Tu-Yen, Delphine 10 December 2010 (has links)
: Mon travail de thèse a porté sur l’étude neurocomportementale des actions et des habitudes chez le Rat. En effet, lors d’un apprentissage opérant la réponse peut être acquise selon deux systèmes associatifs. Le premier dépend d’une représentation des conséquences de la réponse, le second d’une association plus « simple » entre le stimulus et la réponse. Un premier axe de recherche a consisté à étudier plusieurs paramètres du conditionnement, afin de déterminer leur influence sur le contrôle de la réponse instrumentale par un système plutôt que l’autre. Le deuxième axe de recherche a porté sur l’étude des substrats neuronaux impliqués dans l’acquisition et l’expression d’une action, par l’intermédiaire de techniques d’inactivation cérébrale et d’étude immuno-histochimique de l’expression génique de la protéine Fos. / Previous research has established that instrumental conditioning, in both primates and rats, is mediated by two concurrent associative systems. In early stages of training, instrumental response is thought to be mediated by an association between the action and the outcome (A-O). While training proceeds however, as the response becomes less sensible to the outcome value, it is conceived as being mediated by an association between thestimulus and the response (S-R). Recent evidences suggest that the both systems operate in tandem and/or competition from the beginning of training. This work aimed at studying the mechanisms that coordinate the control of the instrumental response by the goal-directedsystem or the habit system. A first batch of results indicates no effect of the amount of training sessions on the goal-directed nature of the conditioned instrumental response. Indeed,the outcome devaluations by CTA or selective satiety reduced the instrumental performances,independently of the training procedure applied. The instrumental responses resulting from our 3 training procedures depend of an actualized representation of their outcomes. A secondbatch of results indicates that information about the context of instrumental conditioning isincluded in the incentive representation of the outcome. Indeed, we observed no sensitivity tooutcome devaluation when devaluation occurred outside the training context. These results offer new original hypotheses about context encoding and the nature of instrumental responding. A third batch of experiments investigates the role of the prelimbic cortex in acquisition vs. expression of goal-directed instrumental behaviour, using reversible neuronal inactivation. The results show that the prelimbic cortex plays a transient but crucial role in theacquisition of goal-directed responding and that the A-O and S-R systems can operate in a competitive fashion early in training. Using ex-vivo imaging, a last batch of experiments aimed to study the temporal cerebral activation throughout instrumental training with a focuson prefrontal and striatal regions. Results show levels of Fos expression that vary with regions. At the beginning of conditioning, the density of Fos positive nuclei is high in the prefrontal regions. It decreases with training. Labelling is denser in the dorsomedial striatumthan in the dorsolateral striatum. The weak activation in the dorsolateral striatum appears consistent with the absence of habit. These data are in accordance with data of the literature concerning dynamics of activation in cortico-striatal circuits. Furthermore, they are in agreement with the suggestion that activity in the prelimbic cortex could promote the acquisition of goal-directed action by the induction of neuronal plasticity in the dorsal striatum.
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La connectivité sur de longue distance détermine la plasticité intrinsèque des neurones prélimbiques induite par l’apprentissage / Long-range connectivity defines learning-induced intrinsic plasticity of prelimbic neuronsSzlapczynska, Maria 13 June 2014 (has links)
Le cortex préfrontal médian (mPFC) est nécessaire pour la formation desreprésentations contextuelles et l’expression de la mémoire suite au conditionnementde peur. Des études récentes ont montré des changements dépendants del’apprentissage dans l’excitabilité intrinsèque des neurones du mPFC. Il n’estcependant pas établit, si ces changements se font à l’échelle régionale ou s’ils sontspécifiques du type neuronal. La connectivité spécifique et les propriétés intrinsèquesde différents types neuronaux pourraient entrainer certaines populations neuronales àêtre préférentiellement impliquées dans le traitement de l’information au cours d’unetâche d’apprentissage. Dans ce projet, nous avons étudié cette hypothèse par l’étudede la plasticité de l’excitabilité intrinsèque dans la partie prélimbique (PL) du mPFCdans deux groupes neuronaux bien définis : ceux projetant vers l’amygdaleipsilatérale et ceux projetant vers le mPFC controlatéral. Nous avons utilisé à la fois leconditionnement à la peur contextuelle, un traçage rétrograde, et des enregistrementsélectrophysiologiques en cellule entière des neurones pyramidaux marqués chez lessouris mâles C57bl/6J adultes âgées de 2 à 3 mois. Nous montrons que l’excitabilitédes neurones projetant vers l’amygdale présentent des changements dépendants del’apprentissage, suite au conditionnement de peur contextuelle. En revanche,l’excitabilité des neurones projetant vers le mPFC controlatéral ne présente pas dedifférence entre les animaux entrainés et témoins. Ensemble, ces résultats indiquentque les changements induits par l’apprentissage dans l’excitabilité intrinsèque ne sontpas généralisés à tous les neurones du PL mais sont par contre définis par les ciblesdes neurones qui projettent sur de longues distances. / The medial prefrontal cortex (mPFC) is necessary for the formation of contextualrepresentations and memory expression following fear conditioning. Recent studieshave shown learning-dependent changes in the intrinsic excitability of mPFC neurons.It is not clear, however, whether these changes are region-wide or neuron-typespecific. The specific connectivity and intrinsic properties of different neuronal typescould cause certain neuronal populations to be preferentially involved in informationprocessing in a learning paradigm. In this project, we investigated this hypothesis bystudying the plasticity of intrinsic excitability in the prelimbic (PL) part of the mPFCin two defined neuronal groups: those projecting to the ipsilateral amygdala and thoseprojecting to the contralateral mPFC. We used contextual fear conditioning togetherwith retrograde tracing and whole-cell electrophysiological recordings of labelledpyramidal neurons in adult 2-3 month old male C56BL/6J mice. We show thatneurons projecting to the amygdala display learning-dependent changes in neuronalexcitability following contextual fear conditioning. In contrast, the excitability ofneurons projecting to the contralateral mPFC does not differ between trained andcontrol animals. Together, these results indicate that learning-induced changes inintrinsic excitability are not generalised across all PL neurons but instead are definedby the neurons’ long-range projection targets.
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