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Revising the Role of the Ventrolateral Periaqueductal Gray in the Fear Circuit:Wright, Kristina M. January 2021 (has links)
Thesis advisor: Michael A. McDannald / Thesis advisor: John P. Christianson / The ability to accurately evaluate and respond to threats is vital to survival. Disruptions in neural circuits of fear give rise to maladaptive threat responding, and have clinical implications in fear and anxiety disorders. To better inform therapeutic interventions, it is imperative that roles for regions classically associated with fear continue to be refined, and that novel nodes are incorporated into what is most certainly a larger fear circuit. In the canonical view, threat estimates are generated at the level of the amygdala and sent to the ventrolateral periaqueductal gray (vlPAG), which organizes an appropriate behavioral response, most notably freezing. Despite a multitude of studies successfully linking the vlPAG and Pavlovian fear behavior, evidence of a direct neural correlate for fear expression in the vlPAG is lacking. By contrast, a role for the caudal substantia nigra (cSN) in fear, stands apart from its canonical associations with movement and reward processes. Although there is new interest in examining a role for the nigra in fear modulation, this is essentially an uncharted area of discovery. The goals of this dissertation are three-fold. First, to propose a role for vlPAG activity in threat estimation, a function previously restricted to the upstream amygdala. Second, to scrutinize vlPAG neural activity using a novel multi-cue Pavlovian procedure and identify the long-anticipated, direct neural correlate for fear expression. Third, to present causal evidence supporting the cSN as a potential node in a circuit that most certainly extends beyond regions canonically associated with fear. / Thesis (PhD) — Boston College, 2021. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Psychology.
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Papel da Neurotransmissão Noradrenérgica da Substância Cinzenta Periaquedutal Dorsal na Modulação de Comportamentos Defensivos Relacionados aos Transtornos de Ansiedade Generalizada e de PânicoCARVALHO, J. J. V. 19 July 2016 (has links)
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Previous issue date: 2016-07-19 / A substância cinzenta periaquedutal dorsal (SCPD) é uma estrutura mesencefálica envolvida na mediação de comportamentos defensivos associados aos transtornos de ansiedade generalizada (TAG) e de pânico (TP). Existem evidências que indicam um envolvimento da neurotransmissão noradrenérgica da SCPD na modulação da ansiedade, no entanto, não existe evidência sobre sua participação nos ataques de pânico. Neste sentido, o objetivo do presente estudo foi investigar a participação da neurotransmissão noradrenérgica da SCPD na mediação de comportamentos defensivos relacionados ao TAG e ao TP em animais testados no labirinto em T elevado (LTE), um modelo animal que associa a resposta de esquiva inibitória ao TAG e a resposta de fuga ao TP. Para tal, ratos Wistar receberam a administração intra-SCPD de noradrenalina (10, 30 ou 60 nmoles/0,1μL) ou salina e foram testados no LTE. Adicionalmente, investigamos o efeito do pré-tratamento intra-SCPD com os antagonistas não seletivos de receptores alfa e beta-adrenérgicos, fentolamina e propranolol, respectivamente, no efeito da injeção de noradrenalina na mesma estrutura. Nossos resultados mostram que a administração intra-SCPD de noradrenalina na maior dose prejudicou a aquisição da esquiva inibitória, sugerindo um efeito do tipo ansiolítico, porém não apresentou efeito sobre a resposta de fuga no LTE. Além disso, a injeção de noradrenalina não alterou a atividade locomotora dos animais no teste do campo aberto, sugerindo que o efeito ansiolítico não foi devido a um aumento na atividade exploratória. Os resultados mostram ainda que o pré-tratamento intra-SCPD de fentolamina ou propranolol atenuou o efeito do tipo ansiolítico da noradrenalina. Assim, o presente estudo sugere um envolvimento da neurotransmissão noradrenérgica na SCPD, via receptores alfa e beta-adrenérgicos, em reações defensivas associadas com o TAG, mas não com o TP em animais submetidos ao LTE.
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Oscillations memory and Alzheimer's diseaseFox, Sarah January 2014 (has links)
Damage precipitating cognitive decline in Alzheimer's disease (AD) begins long before behavioural alterations become clinically apparent. At this prodromal stage, communication between networks of neurons connecting different brain regions starts to break down; setting in motion a chain of events leading to clinical AD. A significant challenge facing Alzheimer's researchers today is finding a cheap, easy-to-perform test capable of detecting prodromal AD. Such a test would afford significant benefits to patients, including a chance of early intervention. Perhaps, more importantly, it would also aid development and testing of novel therapies aimed at combating AD before it causes irreversible damage. Since oscillations in electrical field activity are important for facilitating connectivity across the brain and have been seen to alter in AD, this work studied how oscillations and regional connectivity are affected in the AD brain. Specifically, local field oscillations were recorded from the hippocampus and prelimbic cortex (regions implicated in memory formation and maintenance) in a double transgenic AD model - the TASTPM mouse. Here, periods of predominant theta activity were assessed both spontaneously, under urethane anaesthesia and following electrical induction through dorsal periaqueductal gray (dPAG) stimulation. From these recordings, spectral power and connectivity between regions was assessed using both a traditional measure of functional connectivity (inter-region correlation) and through a novel information theoretic approach measuring effective connectivity (transfer entropy).Perhaps the most prominent finding from this study was the observation that young TASTPM mice, at an age prior to overt cognitive decline or plaque deposition, showed significant alterations in measures of both functional and effective connectivity. This suggests that such measures may be used as biomarkers predictive of prodromal AD and, as such, may be used to aid development of drugs targeted towards treatment of prodromal AD.This study also uncovered a number of interesting observations concerning hippocampal/prelimbic connectivity. Firstly, although spectral power and inter-regional correlation peaked at ∼ 3Hz, information flow between these structures was strongest at ∼6Hz. This suggests that low and high-band theta activity may fulfil separate functions. Secondly, at theta frequencies, information flowed predominantly from the prelimbic cortex to the hippocampus. However, during lower frequency activity, information flowed predominantly in the opposite direction. Suggesting that separate frequency bands may be important for routing information flow between these structures. Finally, the strength of information transfer was seen to oscillate at approximately double the frequency of its carrier signal, perhaps suggesting locking of information transfer to certain phases of an underlying oscillation. Therefore, oscillations may structure information transfer by temporal windowing and frequency-locked routing; processes which can be studied using measures of effective connectivity such as transfer entropy.
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Periaqueductal Gray Glia Modulate Morphine Tolerance Development via Soluble Tumor Necrosis Factor SignalingEidson, Lori 11 May 2015 (has links)
Each year, over 50 million Americans suffer from persistent pain, including debilitating headaches, joint pain, and severe back pain. Although morphine is amongst the most effective analgesics available for the management of severe pain, prolonged morphine treatment results in decreased analgesic efficacy (i.e., tolerance). Despite significant headway in the field, the mechanisms underlying the development of morphine tolerance are not well understood. The midbrain ventrolateral periaqueductal gray (vlPAG) is a primary neural substrate for the analgesic effects of morphine, as well as for the development of morphine tolerance. A growing body of literature indicates that activated glia (i.e., microglia and astrocytes) facilitate pain transmission and oppose morphine analgesia, making these cells important potential targets in the treatment of chronic pain. Morphine affects glia by binding to the innate immune receptor toll-like receptor 4 (TLR4), leading to the release of proinflammatory cytokines and opposition of morphine analgesia. Despite the established role of the vlPAG as an integral locus for the development of morphine tolerance, to date, no studies have examined the role of glia activation within this region. Additionally, the role of TLR4 in the development of tolerance has not been elucidated. This dissertation seeks to address the lack of knowledge regarding the role of vlPAG glia and TLR4 in the development of morphine tolerance by (1) Characterizing the effects of chronic morphine and peripheral inflammatory pain on vlPAG glial cell activity; (2) Investigating the role of glia activation within the vlPAG in the development of morphine tolerance; (3) Characterizing the role of the glial receptor TLR4 within the vlPAG in the development of morphine tolerance; and (4) Characterizing the glia to neuron signaling mechanisms involved in the development of morphine tolerance. These experiments, together, provide novel information about the mechanism by which central nervous system glia regulate morphine tolerance, and identify a potential therapeutic target for the enhancement of analgesic efficacy in the clinical treatment of chronic pain.
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Análise eletrofisiológica multi-unitária da matéria cinzenta periaquedutal dorsal e camadas intermediárias e profundas do colículo superior de ratos durante ameaça predatória. / Multi-unitary electrophysiological analysis of the dorsal periaqueductal gray and the intermediate and deep layers of the superior colliculus of rats during predatory threat.Maia, Ricardo Gabriel Oliveira 24 September 2018 (has links)
A circuitaria neuro-anatômica envolvida com a organização de respostas de medo inclui muitos sítios subcorticais diferentes, dois dos quais são a região dorsal da matéria cinzenta periaquedutal (dPAG) e as camadas intermediárias e profundas do colículo superior (i/dlSC). Este estudo investigou como as células destas duas regiões mudam de atividade em um rato que foi colocado diante de seu predador, o gato, comparado com outras situações onde o risco menor. 11 ratos wistar machos passaram por cirurgia para implantação de um microdriver contendo 8 tetrodos, que detectou 39 células na dPAG de 7 ratos e 44 células nas i/dlSC de 4 ratos. A atividade das células foi registrada em uma condição de base e em quatro condições experimentais distintas: o rato confinado, o rato diante de uma novidade, diante de um predador e diante do contexto predatório. Os dados coletados foram analisados por scripts de MATLAB e cada célula foi classificada para sua responsividade às condições experimentais, à mudança do comportamento do rato, à velocidade e à posição do rato no aparato. Na dPAG as células se mostraram mais responsivas a condição do gato do que as demais condições experimentais, tanto em número de células como em aumento de atividade celular. Uma quantidade menor de células mostrou-se responsiva a mudanças de comportamento, particularmente os comportamentos de defesa. Nas i/dlSC as células também se mostraram mais responsivas para o gato, seguido do contexto, em ambos os casos com diminuição de atividade celular, que foi mais intensa no gato. Uma quantidade menor de células pareceu responder de forma similar para as diferentes mudanças comportamentais. Interpretamos esses dados propondo que a dPAG possui uma função sinalizadora de medo, fortemente ativada durante o gato, e que as i/dlSC são inibidas diante do gato a fim de evitar a captação de estímulos irrelevantes para lidar com a situação de risco. / The neuroanatomical circuitry involved with the organization of fear responses includes a great number of subcortical sites, two of which are the dorsal periaqueductal gray (dPAG) and the intermediate and deep layers of the superior colliculus (i/dlSC). This study investigated how the cellular activity in these regions changed in a rat that was exposed to one of its predators, a cat, when compared with lower risk situations. 11 male wistar rats underwent surgery to implant a microdriver containing 8 tetrodes, which detected 39 cells in the dPAG of 7 rats and 44 cells in the i/dlSC of 4 rats. Cell activity was registered in a basal condition and then again in for experimental conditions: the rat confined in a smaller space, the rat facing a novel stimulus, the rat facing a cat and the rat facing the predatory context. Collected data was analyzed using MATLAB and each cell was classified according to its responsivity to the experimental conditions, to the rats switches in behavior, to the rats speed and position in the experimental apparatus. In the dPAG, cells were shown to be more responsive to the cat condition over the other conditions, both in terms of number of responsive cells and intensity of increase in firing activity. A smaller number of cells were responsive to behavior switching, being especially sensitive to the initiation of defensive behaviors. In the i/dlSC, cells were more responsive to the cat, followed by the predatory context, in both cases with a general reduction of cellular activity that was more intensive for the cat. A smaller number of cells was responsive in similar ways for behavior switching across experimental conditions. We interpret this data by proposing that the dPAG acts signaling a state of fear, particularly during a high risk situation, and the i/dlSC are inhibited during riskier situations so as to block irrelevant environmental stimuli.
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Modulação opioidérgica na seleção comportamental após o parto / Opioidergic modulation of behavioral selection during lactationCruz, Aline de Mello 01 July 2009 (has links)
O tratamento com morfina ao final da prenhez, faz com que uma única dose dessa droga durante a lactação iniba o comportamento maternal e estimule a caça predatória. A intensidade dessa mudança comportamental depende da dose desafio de morfina utilizada. A exposição a drogas de abuso pode levar a um fenômeno denominado tolerância reversa, que consiste na exacerbação dos efeitos do tratamento agudo com um fármaco observada após a interrupção de um tratamento crônico. O objetivo deste estudo foi avaliar como os efeitos do pré-tratamento com morfina durante a gestação podem influenciar na seleção comportamental após o parto. Ratas foram expostas simultaneamente a filhotes e insetos, sendo observada a expressão dos comportamentos maternal e predatório. As ratas foram tratadas com injeções diárias de morfina (3,5 mg/Kg, s.c.) do 17º ao 21º dia de gestação, e desafiadas agudamente no 5o ou 6o dia de lactação com doses distintas de morfina (0,5, 1,0 e 1,5mg/Kg; grupos MM0,5, MM1,0 e MM1,5) ou salina (grupo MS). Grupos controle foram pré-tratados com salina e desafiados com morfina (0,5, 1,0 e 1,5mg/Kg; grupos SM0,5, SM1,0 e SM1,5) ou salina (grupo SS), respectivamente. Em seguida foram testadas no paradigma de escolha entre cuidar dos filhotes e caçar. Animais pré-tratados com morfina e desafiados com 1,0 mg/Kg tiveram parâmetros de comportamento maternal prejudicados e facilitação ao comportamento de caça de maneira significante, o que não foi observado nos animais desafiados com a dose de 0,5 mg/Kg. Animais desafiados com 1,5 mg/Kg de morfina tiveram prejuízo em relação ao comportamento maternal e facilitação do comportamento predatório tanto no grupo de fêmeas pré-tratadas com morfina, quanto com salina. Em ratas lactantes a exposição simultânea a filhotes e insetos permitiu revelar a existência de tolerância reversa à mudança comportamental induzida por estímulo opioidérgico. / Treatment of postpartum female rats with morphine inhibits maternal behavior. The same treatment also stimulates foraging in adult animals. Exposure to drugs of abuse may result in a progressive and enduring enhancement of their reinforcing effects. Puerperal treatment with morphine leads to reverse tolerance to this drug, ultimately influencing the effects of opiates on maternal behavior. The aim of the present study was to investigate whether abrupt withdrawal from repeated morphine treatment during late pregnancy may influence the effects of morphine on behavioral selection in lactating rats. Animals were exposed simultaneously to pups and insects, and the choice between taking care of the pups and hunting for insects was observed. Female Wistar rats were treated with morphine (3.5 mg/kg/day, subcutaneous [s.c.]) or saline for 5 days beginning on pregnancy day 17. On day 5 of lactation, animals were acutely challenged with morphine (0.5, 1.0, or 1.5 mg/kg, s.c.; MM0.5, MM1.0, and MM1.5 groups, respectively) or saline (MS group) and simultaneously tested for predatory hunting and maternal behavior. Control groups were pretreated with saline and challenged with morphine (SM0.5, SM1.0, and SM1.5 groups) or saline (SS group). Animals treated with morphine during late pregnancy and acutely challenged with 1.0 mg/kg morphine (MM1.0 group) exhibited significantly decreased maternal behavior and enhanced hunting. This effect was not evident for the 0.5 mg/kg dose. The 1.5 mg/kg morphine dose decreased maternal behavior and increased hunting in both the MM1.5 group and in animals acutely challenged with morphine after previous saline treatment (SM1.5 group). These results provide evidence of plasticity of the opioidergic role in behavioral selection during lactation.
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Papel dos mecanismos GABAérgicos do colículo inferior e da substância cinzenta periaquedutal na interface sensoriomotora do medo e ansiedade / Role of GABAergic mechanisms in the inferior colliculus and periaqueductal gray matter on the sensorimotor gating of fear and anxietySaito, Viviane Mitsuko Neves 19 May 2016 (has links)
As reações incondicionadas de defesa observadas em mamíferos são organizadas pelo Sistema Encefálico de Aversão (SEA), composto, entre outras estruturas, pela substância cinzenta periaquedutal dorsal (SCPd) e o colículo inferior (CI). Tem sido proposto que o CI seja parte do circuito sensoriomotor para os estímulos auditivos de natureza aversiva e a SCPd como a principal via de saída (output) do SEA para a elaboração de comportamentos defensivos. Ambas as estruturas são reguladas tonicamente pelo neurotransmissor inibitório ácido gama-aminobutírico (GABA). Este trabalho aborda a mediação química GABA/Benzodiazepínica (BZD) do processamento da informação aversiva no CI e das respostas de medo elaboradas pela SCPd. Grupos independentes de animais submetidos ao implante de quimitrodos (eletrodos acoplados a cânulas-guia para injeção de drogas) foram usados para avaliar no CI e SCPd os efeitos de injeções locais de muscimol (agonista de receptores GABA-A), semicarbazida (inibidor da síntese da enzima precursora do GABA descarboxilase do ácido glutâmico) ou midazolam (agonista BZD). Foram registrados potenciais evocados auditivos (PEA) no CI como medida eletrofisiológica da ativação neuronial, além da determinação dos limiares de congelamento e fuga, com o procedimento de estimulação elétrica (EE), tanto do CI quanto da SCPd. A mesma abordagem farmacológica com injeções de drogas intra-CI foi empregada em animais submetidos ao teste do Labirinto em Cruz Elevado (LCE), um modelo animal tradicional de ansiedade. Adicionalmente, investigou-se a participação de ambas as estruturas na expressão do comportamento de desligar uma luz de intensidade aversiva em um novo teste de medo incondicionado (Light Switch Off Test; LSOT) recentemente proposto pelo nosso grupo. Encontramos uma clara segregação funcional entre a porção dorsal e ventral do CI, sendo a última envolvida nos comportamentos defensivos. Mecanismos GABAérgicos em ambas as estruturas influenciam a amplitude do PEA e o congelamento pós-fuga da EE, sugerindo uma relação funcional entre as duas estruturas. Já no LSOT, os resultados indicam o envolvimento de mecanismos GABAérgicos do vCI, mas não da SCPd, na modulação da resposta incondicionada à luz em ratos. Os resultados obtidos permitem ampliar o conhecimento atual sobre a neurobiologia dos estados de medo e ansiedade, em uma abordagem integrada dos mecanismos de processamento das informações sensoriais e da expressão de reações de defesa. / Unconditioned defense reactions observed in mammals are organized by the Brain Aversive System, comprising, among other structures, the dorsal periaqueductal gray matter (dPAG) and the inferior colliculus (IC). It has been proposed that the IC is part of the sensorimotor circuitry that processes aversive auditory information and the dPAG is considered the main neural substrate for the expression of defensive behaviors. Both structures are tonically regulated by the inhibitory neurotransmitter gamma-aminobutyric acid (GABA). This work addresses the chemical mediation of GABA/Benzodiazepine (BZD) on aversive information processing in the IC and the elaboration of fear responses by dPAG. Independent groups of animals implanted with chemitrodes (electrodes attached to a guide cannula for drug injection) have been used to evaluate the IC and dPAG regarding the effects of local injections of GABAergic agents (muscimol, semicarbazide, and midazolam). Auditory evoked potentials (AEP) have been recorded in the IC as a measure of electrophysiological neuronal activation, in addition to determining the thresholds of defensive freezing and flight behaviors, using the electrical stimulation (EE) procedure in both IC and dPAG. The same pharmacological regimen of drug injections intra-dPAG and intra-CI have been applied to animals subjected to the elevated plus maze (EPM), a well-known animal model of anxiety, and also to a novel animal test for innate fear (Light Switch Off Test, LSOT) that has been developed and proposed by our group. We found a clear functional segregation between the dorsal and ventral portions of the IC, the latter being the specific collicular substrate of defensive behaviors. GABAergic mechanisms in both structures influence the amplitude of the AEP and post-stimulation freezing of EE, suggesting a functional link between the two structures. In the LSOT, our data indicate the involvement of GABAergic mechanisms of the ICv, but not the dPAG, in the modulation of the unconditioned response to light in rats. These original findings presented here contribute to broaden the current knowledge on the neurobiology of fear and anxiety, in an integrative approach of the mechanisms underlying sensory processing and the expression of defensive behaviors.
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Modulação opioidérgica na seleção comportamental após o parto / Opioidergic modulation of behavioral selection during lactationAline de Mello Cruz 01 July 2009 (has links)
O tratamento com morfina ao final da prenhez, faz com que uma única dose dessa droga durante a lactação iniba o comportamento maternal e estimule a caça predatória. A intensidade dessa mudança comportamental depende da dose desafio de morfina utilizada. A exposição a drogas de abuso pode levar a um fenômeno denominado tolerância reversa, que consiste na exacerbação dos efeitos do tratamento agudo com um fármaco observada após a interrupção de um tratamento crônico. O objetivo deste estudo foi avaliar como os efeitos do pré-tratamento com morfina durante a gestação podem influenciar na seleção comportamental após o parto. Ratas foram expostas simultaneamente a filhotes e insetos, sendo observada a expressão dos comportamentos maternal e predatório. As ratas foram tratadas com injeções diárias de morfina (3,5 mg/Kg, s.c.) do 17º ao 21º dia de gestação, e desafiadas agudamente no 5o ou 6o dia de lactação com doses distintas de morfina (0,5, 1,0 e 1,5mg/Kg; grupos MM0,5, MM1,0 e MM1,5) ou salina (grupo MS). Grupos controle foram pré-tratados com salina e desafiados com morfina (0,5, 1,0 e 1,5mg/Kg; grupos SM0,5, SM1,0 e SM1,5) ou salina (grupo SS), respectivamente. Em seguida foram testadas no paradigma de escolha entre cuidar dos filhotes e caçar. Animais pré-tratados com morfina e desafiados com 1,0 mg/Kg tiveram parâmetros de comportamento maternal prejudicados e facilitação ao comportamento de caça de maneira significante, o que não foi observado nos animais desafiados com a dose de 0,5 mg/Kg. Animais desafiados com 1,5 mg/Kg de morfina tiveram prejuízo em relação ao comportamento maternal e facilitação do comportamento predatório tanto no grupo de fêmeas pré-tratadas com morfina, quanto com salina. Em ratas lactantes a exposição simultânea a filhotes e insetos permitiu revelar a existência de tolerância reversa à mudança comportamental induzida por estímulo opioidérgico. / Treatment of postpartum female rats with morphine inhibits maternal behavior. The same treatment also stimulates foraging in adult animals. Exposure to drugs of abuse may result in a progressive and enduring enhancement of their reinforcing effects. Puerperal treatment with morphine leads to reverse tolerance to this drug, ultimately influencing the effects of opiates on maternal behavior. The aim of the present study was to investigate whether abrupt withdrawal from repeated morphine treatment during late pregnancy may influence the effects of morphine on behavioral selection in lactating rats. Animals were exposed simultaneously to pups and insects, and the choice between taking care of the pups and hunting for insects was observed. Female Wistar rats were treated with morphine (3.5 mg/kg/day, subcutaneous [s.c.]) or saline for 5 days beginning on pregnancy day 17. On day 5 of lactation, animals were acutely challenged with morphine (0.5, 1.0, or 1.5 mg/kg, s.c.; MM0.5, MM1.0, and MM1.5 groups, respectively) or saline (MS group) and simultaneously tested for predatory hunting and maternal behavior. Control groups were pretreated with saline and challenged with morphine (SM0.5, SM1.0, and SM1.5 groups) or saline (SS group). Animals treated with morphine during late pregnancy and acutely challenged with 1.0 mg/kg morphine (MM1.0 group) exhibited significantly decreased maternal behavior and enhanced hunting. This effect was not evident for the 0.5 mg/kg dose. The 1.5 mg/kg morphine dose decreased maternal behavior and increased hunting in both the MM1.5 group and in animals acutely challenged with morphine after previous saline treatment (SM1.5 group). These results provide evidence of plasticity of the opioidergic role in behavioral selection during lactation.
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The Impact of Neonatal Inflammatory Insult on Adult Somatosensory Processing: The Role of the Descending Nociceptive CircuitLaPrairie, Jamie L 29 October 2008 (has links)
The neonatal period represents a critical window of increased neurodevelopmental plasticity in the immature nervous system. Unlike other sensory modalities, which require appropriate stimulation for proper development, maturation of nociceptive circuitry in neonates typically occurs in the absence of noxious stimulation. Premature infants, however, are routinely exposed to multiple invasive medical procedures during neonatal intensive care treatment, which are largely performed in the absence of anesthetics or analgesics. To date, it is largely unknown how exposure to early noxious insult during this time of increased plasticity alters the development of the CNS and influences future nociceptive responses. As previous studies examining the impact of neonatal inflammatory insult on adult nociceptive responses have been conducted primarily in males, the potential adverse effects in females are unknown. Furthermore, the biological mechanisms underlying neonatal insult-induced deficits in nociceptive processing have yet to be elucidated. Therefore, this dissertation addressed the following questions: (1) Does neonatal inflammatory insult differentially alter male and female baseline somatosensory thresholds and response to re-inflammation in adulthood?; (2) Are neonatal inflammation-induced deficits in nociceptive responsiveness mediated by a potentiation in endogenous opioid tone?; and (3) Does pre-emptive morphine analgesia attenuate the behavioral consequences of neonatal inflammatory insult? Collectively, these studies will provide valuable information about the long-term consequences of neonatal noxious stimulation in males and females, which may lead to improved understanding and prevention of the lasting effects of repeated invasive interventions in premature infants in the NICU.
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Sex Differences in Morphine Analgesia and the Descending Modulation of PainLoyd, Dayna Ruth 21 August 2008 (has links)
Morphine is the most widely prescribed opiate for alleviation of persistent pain; however, it is becoming increasingly clear that morphine is less potent in women compared to men. Morphine primarily binds mu opioid receptors, which are densely localized in the midbrain periaqueductal gray (PAG). Anatomical and physiological studies conducted in the 1960s identified the PAG, and its projections to the rostral ventromedial medulla (RVM) and spinal cord dorsal horn, as an essential neural circuit mediating opioid-based analgesia. Remarkably, the majority of studies since then were conducted in males with the implicit assumption that this circuit was the same in females; this is not the case. It is now well established that morphine produces greater analgesia in males compared to females in a wide range of vertebrates, however, the mechanism(s) driving this sex difference is not clear. Our recent studies indicate that two factors appear to be contributing to the sexually dimorphic effects of morphine. First, there are sex differences in the anatomy and physiology of the descending inhibitory pathway on which morphine acts to produce analgesia. Specifically, the projections from the PAG to the RVM are sexually dimorphic and activated to a greater degree by both inflammatory pain and systemic morphine in males. In the absence of pain, the PAG-RVM circuit is activated to a greater degree in males compared to females, while this activation steadily declines during the development of tolerance in males only. We also have evidence of a sexually dimorphic expression of mu opioid receptor within the PAG that appears to contribute to sex differences in morphine potency. Microinjection of morphine directly into the PAG produces significantly greater analgesia in males, indicating that the PAG is sufficient for eliciting this sexually dimorphic behavior. Furthermore, mu opioid receptor-expressing PAG neurons are necessary for eliciting a sexually dimorphic response to morphine as lesioning mu opioid receptor-expressing neurons attenuates analgesia in males only. Together, these data indicate that the PAG-RVM pathway and mu opioid receptor expression in the PAG is sexually dimorphic and provides a primary mechanism for sex differences in morphine potency.
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