Antinocicepção induzida pelo estresse de restrição no peixe Leporinus macrocephalus / Restraint stress-induced antinociception in the fish Leporinus macrocephalus

Wolkers, Carla Patricia Bejo

26 March 2014

A atribuição da percepção da dor pelos peixes é um assunto controverso no meio científico. Alguns autores associam a percepção da dor a estruturas neocorticais que estão ausentes em peixes. Entretanto, estudos recentes têm demonstrado que os peixes são capazes de perceber e responder a estímulos nocivos de maneira semelhante ao que é observado em mamíferos, sendo estas respostas sensíveis à administração de morfina. Além disso, estudos pioneiros de nosso laboratório demonstraram a existência de um sistema analgésico endógeno em peixes. O objetivo deste estudo foi avaliar se este sistema analgésico endógeno pode ser ativado pelo estresse. A natureza neuroquímica deste sistema e a participação de uma região telencefálica, o telencéfalo dorsomedial (Dm), na modulação da antinocicepção também foram investigados. Nossos dados demonstram que o estresse de restrição de 3 e 5 minutos de duração inibe a resposta comportamental à injeção subcutânea de formalina a 3% na região da nadadeira adiposa no peixe Leporinus macrocephalus, sugerindo que este procedimento é capaz de ativar um sistema antinociceptivo endógeno. Além disso, a antinocicepção induzida pelo estresse de restrição de 3 e 5 min é de curta duração, sendo observada apenas por 5 min após o término da restrição. A análise da natureza neuroquímica da antinocicepção induzida pelo estresse de restrição revelou participação do sistema opióde e canabinoide na modulação desta resposta. O tratamento prévio com injeção intraperitoneal de naloxona (30 mg.kg-1), um antagonista opioide não seletivo, bloqueou a antinocicepção induzida pela restrição de 3 min de duração, mas não foi capaz de inibir a antinocicepção induzida pela restrição de 5 min de duração. Já o tratamento prévio com injeção intraperitoneal de AM251 (3 mg.kg-1), um antagonista de receptores canabinoides tipo 1, bloqueou a antinocicepção induzida pelo estresse de restrição de 3 e 5 min de duração, sugerindo que o sistema canabinoide desempenha um papel fundamental na antinocicepção induzida por esta modalidade de estresse na espécie estudada. Nosso estudo também demonstrou que a região do telencéfalo dorsomedial está envolvida na modulação da antinocicepção induzida pelo estresse de restrição no peixe L. macrocephalus. A microinjeção de midazolan (40 e 80 nmol), um agonista de receptores benzodiazepínicos, no telencéfalo Dm bloqueou a antinocicepção induzida pela restrição de 3 e 5 min de duração. Além disso, o tratamento prévio com flumazenil (80 e 160 nmol), um antagonista específico de receptores benzodiazepínicos, inibiu os efeitos do tratamento com midazolan, demonstrando que o bloqueio da antinocicepção promovido pelo midazolan ocorre pela ativação específica dos receptores benzodiazepínicos. Juntos estes resultados trazem novas perspectivas acerca do entendimento sobre a percepção nociceptiva em peixes. Este é o primeiro trabalho que traz evidências acerca da existência de um sistema de modulação da dor ativado pelo estresse e demonstra a participação de uma região encefálica específica na modulação desta antinocicepção. Estes resultados indicam que as vias analgésicas endógenas em peixes são ativadas de maneira semelhante aos mamíferos, sugerindo que estes animais possuem um processamento complexo da informação nociceptiva. / The assignment of pain perception by fish is controversial among scientists. Some authors associate the pain perception to neocortical structures that are absent in fish. However, recent studies have shown that fish are able to perceive and respond to noxious stimuli, similar to observed in mammals, and this responses are sensitive to morphine administration. Furthermore, pioneering studies from our laboratory have demonstrated the existence of an endogenous analgesic system in fish. This study aimed to evaluate if this endogenous analgesic system can be activated by stress, the neurochemical nature of this system and involvement of a telencephalic region, the dorsomedial (Dm) telencephalon, in the antinociception modulation. Our data demonstrate that 3 and 5 min of restraint stress inhibits the behavioral response to subcutaneous injection of formalin 3 % in the adipose fin in the fish Leporinus macrocephalus, suggesting that this procedure can activate an endogenous antinociceptive system. Furthermore, stress-induced antinociception induced by 3 and 5 min of restraint is short, with the antinociceptive effects being observed only for 5 min after the restriction. The analysis of the neurocheamical nature of antinociception induced by restraint stress revealed the involvement of opioid and cannabinoid systems in the modulation of this response. The pre-treatment with intraperitoneal injection of naloxone (30 mg.kg-1), a non-selective opioid receptors antagonist, blocked the antinociception induced by 3 min of restraint, but was not able to inhibit the antinociception induced by 5 min of restraint. The pre-treatment with intraperitoneal injection of AM251 ( 3 mg.kg-1), a type 1 cannabinoid receptors antagonist, blocked the stress-induced antinociception promoted by 3 and 5 min of restraint, suggesting that the cannabinoid system plays a critical role in this type of stress-induced antinociception in the studied species. Our study also showed that the dorsomedial telencephalon is involved in the modulation of stress-induced antinociception in fish L. macrocephalus. The microinjection of midazolan (40 and 80 nmol), a benzodiazepine receptors agonist, in the Dm blocked the stress-induced antinociception promoted by 3 and 5 min of restraint. Furthermore, pre-treatment with flumazenil (80 and 160 nmol), a benzodiazepine receptors selective antagonist, inhibited the effects of the midazolan treatment, demonstrating that the antinociception blockade by midazolan is promoted by specific activation of benzodiazepine receptors. Together these results provide new insights on the understanding of nociceptive perception in fish. This is the first study that demonstrates evidence for the existence of a pain modulation system activated by stress in fish and demonstrates the involvement of a specific brain region in the modulation of this antinociception. These results indicate that the endogenous analgesic pathways in fish are activated in a similar manner to mammals, suggesting that these animals have a complex processing of nociceptive information.

Antinocicepção

Antinociception

Canabinoid system

Dorsomedial telencephalon

Estresse

Opioid system

Sistema canabinóide

Sistema opióide

Stress

Telencéfalo dorsomedial

Antinocicepção induzida pelo estresse de restrição no peixe Leporinus macrocephalus / Restraint stress-induced antinociception in the fish Leporinus macrocephalus

Carla Patricia Bejo Wolkers

26 March 2014

A atribuição da percepção da dor pelos peixes é um assunto controverso no meio científico. Alguns autores associam a percepção da dor a estruturas neocorticais que estão ausentes em peixes. Entretanto, estudos recentes têm demonstrado que os peixes são capazes de perceber e responder a estímulos nocivos de maneira semelhante ao que é observado em mamíferos, sendo estas respostas sensíveis à administração de morfina. Além disso, estudos pioneiros de nosso laboratório demonstraram a existência de um sistema analgésico endógeno em peixes. O objetivo deste estudo foi avaliar se este sistema analgésico endógeno pode ser ativado pelo estresse. A natureza neuroquímica deste sistema e a participação de uma região telencefálica, o telencéfalo dorsomedial (Dm), na modulação da antinocicepção também foram investigados. Nossos dados demonstram que o estresse de restrição de 3 e 5 minutos de duração inibe a resposta comportamental à injeção subcutânea de formalina a 3% na região da nadadeira adiposa no peixe Leporinus macrocephalus, sugerindo que este procedimento é capaz de ativar um sistema antinociceptivo endógeno. Além disso, a antinocicepção induzida pelo estresse de restrição de 3 e 5 min é de curta duração, sendo observada apenas por 5 min após o término da restrição. A análise da natureza neuroquímica da antinocicepção induzida pelo estresse de restrição revelou participação do sistema opióde e canabinoide na modulação desta resposta. O tratamento prévio com injeção intraperitoneal de naloxona (30 mg.kg-1), um antagonista opioide não seletivo, bloqueou a antinocicepção induzida pela restrição de 3 min de duração, mas não foi capaz de inibir a antinocicepção induzida pela restrição de 5 min de duração. Já o tratamento prévio com injeção intraperitoneal de AM251 (3 mg.kg-1), um antagonista de receptores canabinoides tipo 1, bloqueou a antinocicepção induzida pelo estresse de restrição de 3 e 5 min de duração, sugerindo que o sistema canabinoide desempenha um papel fundamental na antinocicepção induzida por esta modalidade de estresse na espécie estudada. Nosso estudo também demonstrou que a região do telencéfalo dorsomedial está envolvida na modulação da antinocicepção induzida pelo estresse de restrição no peixe L. macrocephalus. A microinjeção de midazolan (40 e 80 nmol), um agonista de receptores benzodiazepínicos, no telencéfalo Dm bloqueou a antinocicepção induzida pela restrição de 3 e 5 min de duração. Além disso, o tratamento prévio com flumazenil (80 e 160 nmol), um antagonista específico de receptores benzodiazepínicos, inibiu os efeitos do tratamento com midazolan, demonstrando que o bloqueio da antinocicepção promovido pelo midazolan ocorre pela ativação específica dos receptores benzodiazepínicos. Juntos estes resultados trazem novas perspectivas acerca do entendimento sobre a percepção nociceptiva em peixes. Este é o primeiro trabalho que traz evidências acerca da existência de um sistema de modulação da dor ativado pelo estresse e demonstra a participação de uma região encefálica específica na modulação desta antinocicepção. Estes resultados indicam que as vias analgésicas endógenas em peixes são ativadas de maneira semelhante aos mamíferos, sugerindo que estes animais possuem um processamento complexo da informação nociceptiva. / The assignment of pain perception by fish is controversial among scientists. Some authors associate the pain perception to neocortical structures that are absent in fish. However, recent studies have shown that fish are able to perceive and respond to noxious stimuli, similar to observed in mammals, and this responses are sensitive to morphine administration. Furthermore, pioneering studies from our laboratory have demonstrated the existence of an endogenous analgesic system in fish. This study aimed to evaluate if this endogenous analgesic system can be activated by stress, the neurochemical nature of this system and involvement of a telencephalic region, the dorsomedial (Dm) telencephalon, in the antinociception modulation. Our data demonstrate that 3 and 5 min of restraint stress inhibits the behavioral response to subcutaneous injection of formalin 3 % in the adipose fin in the fish Leporinus macrocephalus, suggesting that this procedure can activate an endogenous antinociceptive system. Furthermore, stress-induced antinociception induced by 3 and 5 min of restraint is short, with the antinociceptive effects being observed only for 5 min after the restriction. The analysis of the neurocheamical nature of antinociception induced by restraint stress revealed the involvement of opioid and cannabinoid systems in the modulation of this response. The pre-treatment with intraperitoneal injection of naloxone (30 mg.kg-1), a non-selective opioid receptors antagonist, blocked the antinociception induced by 3 min of restraint, but was not able to inhibit the antinociception induced by 5 min of restraint. The pre-treatment with intraperitoneal injection of AM251 ( 3 mg.kg-1), a type 1 cannabinoid receptors antagonist, blocked the stress-induced antinociception promoted by 3 and 5 min of restraint, suggesting that the cannabinoid system plays a critical role in this type of stress-induced antinociception in the studied species. Our study also showed that the dorsomedial telencephalon is involved in the modulation of stress-induced antinociception in fish L. macrocephalus. The microinjection of midazolan (40 and 80 nmol), a benzodiazepine receptors agonist, in the Dm blocked the stress-induced antinociception promoted by 3 and 5 min of restraint. Furthermore, pre-treatment with flumazenil (80 and 160 nmol), a benzodiazepine receptors selective antagonist, inhibited the effects of the midazolan treatment, demonstrating that the antinociception blockade by midazolan is promoted by specific activation of benzodiazepine receptors. Together these results provide new insights on the understanding of nociceptive perception in fish. This is the first study that demonstrates evidence for the existence of a pain modulation system activated by stress in fish and demonstrates the involvement of a specific brain region in the modulation of this antinociception. These results indicate that the endogenous analgesic pathways in fish are activated in a similar manner to mammals, suggesting that these animals have a complex processing of nociceptive information.

Antinocicepção

Estresse

Sistema canabinóide

Sistema opióide

Telencéfalo dorsomedial

Antinociception

Canabinoid system

Dorsomedial telencephalon

Opioid system

Stress

Role of the Prefrontal Cortex to Dorsomedial Striatum Projections in Compulsive Alcohol Drinking

Meredith Rose Bauer (9636125)

03 January 2024

<p dir="ltr">Compulsive alcohol drinking is a defining feature of alcohol use disorder and is characterized as drinking alcohol despite knowledge of negative consequences. This behavior is hypothesized to be due to a disruption in the decision-making process. Decision making relies on a balance between goal-directedness and habit systems to efficiently execute behavior. An important distinction between compulsive and non-compulsive individuals is the ability to withhold drinking in the face of a negative consequence. The dorsomedial striatum (DMS) and dorsomedial prefrontal cortex (dmPFC) are brain regions necessary for goal directed behavior where the dmPFC is important for cognitive control and behavioral inhibition while the DMS is important for action selection. Importantly, the dmPFC sends a glutamatergic input to the DMS. We hypothesize this input is a behavioral control which is necessary to withhold action selection. Thus, in order to maintain non-compulsive alcohol use, the dmPFC and DMS need to work together to orchestrate inhibition of action selection in the face of negative consequences. Previous research shows a causal role for both the dmPFC and DMS in preventing compulsive alcohol drinking and a role for the projections from the dmPFC to DMS in behavioral inhibition. However, no research has demonstrated a role for this circuit’s activity in prevention of compulsive alcohol use. The current experiment tested the hypothesis that inhibiting the glutamatergic projection from the dmPFC to the DMS will cause non-compulsive Wistar rats to drink alcohol compulsively.</p>

Behavioural neuroscience

alcohol

dorsomedial striatum

prefrontal cortex

compulsive

quinine

Distribution of FABP7 in Neural Tissue of Socially Defeated Adult Anolis Carolinensis

Cañete, Carmenada L.

06 May 2012

Due to its significance in many cellular functions, fatty acid binding protein 7 (FABP7) has become a rising topic of interest for many scientists. Immunocytochemistry was used to map the distribution of FABP7 and test whether the amount of FABP7 immunoreactivity (FABP7-IR) differed in animals that were defeated in a fight, as compared to control animals that did not engage in any social interaction. The male green anole was used as the subject because its natural tendency to establish social classes within its species provides an ideal model to observe for variation in FABP7-IR. The results showed FABP7-IR in cells and fibers of the cortex, hypothalamus, thalamus, medial preoptic area, dorsoventricular ridge, amygdala, suprachiasmatic nucleus, nucleus accumbens, nucleus rotundus, habenular area, tectum, dorsal noradrenergic and lateral forebrain bundles, and lining the third and lateral ventricles. Qualitative observation suggested higher FABP7 levels in socially defeated males than controls in all areas.

Fatty acid binding protein 7

Anolis carolinensis

Subordinate

Immunocytochemistry

Dorsomedial thalamus

Medial cortex

The role of ionotropic glutamate receptors in the dorsomedial hypothalamus in the increase in core body temperature evoked by interoceptive and exteroceptive stresses in rats

Moreno, Maria.

January 2010

Thesis (Ph.D.)--Indiana University, 2010. / Title from screen (viewed on March 3, 2010). Department of Pharmacology and Toxicology, Indiana University-Purdue University Indianapolis (IUPUI). Advisor(s): Joseph A. DiMicco, Sherry F. Queener, Daniel E. Rusyniak, Michael R. Vasko. Includes vitae. Includes bibliographical references (leaves 126-147).

<>.

Hunt, Joseph L.

January 2009

Thesis (Ph.D.)--Indiana University, 2009. / Title from screen (viewed on August 27, 2009). Department of Medical Neuroscience, Indiana University-Purdue University Indianapolis (IUPUI). Advisor(s): Joseph DiMicco. Includes vita. Non-Latin script record Includes bibliographical references (leaves 123-140).

Functional organization of the circadian timing system

Vujovic, Nina

04 February 2016

The circadian timing system establishes daily rhythms in behavior and physiology throughout the body, ensuring that functions like activity, sleep and hormone release are appropriately timed. Research suggests that his temporal synchrony within the body is quite important for health and survival. In mammals, the central circadian pacemaker in the suprachiasmatic nucleus (SCN) drives rhythms in behavior and physiology in large part by stimulating or inhibiting other brain regions responsible for these functions at the appropriate times of day. This timed signal is often indirect, i.e. relayed or possibly processed through a series of neurons in different brain regions before reaching the effector site. The subparaventricular zone (SPZ), a region adjacent to the SCN which is the main recipient of direct neuronal inputs from the SCN, is thought to be a critical relay for SCN signals, since loss of the SPZ results in loss of circadian rhythms in body temperature, activity and sleep/wakefulness. Another important relay site, the dorsomedial hypothalamic nucleus (DMH) gets direct input from both the SCN and SPZ and is critical for normal expression of various circadian rhythms.

Biology

Health sciences

circadian rhythms

dorsomedial hypothalamic nucleus

efferent

neuroanatomy

projections

subparaventricular zone

Generation of functional hippocampal neurons from self-organizing human embryonic stem cell-derived dorsomedial telencephalic tissue / ヒト胚性幹細胞由来の背内側終脳領域からの機能的な海馬神経細胞の生成

Sakaguchi, Hideya

23 March 2016

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第19568号 / 医博第4075号 / 新制||医||1013(附属図書館) / 32604 / 京都大学大学院医学研究科医学専攻 / (主査)教授 伊佐 正, 教授 渡邉 大, 教授 影山 龍一郎 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

hippocampus

medial pallium

choroid plexus

human embryonic stem cell

dorsomedial telencephalon

490

Potential Neural Mediators of Mom Power Parenting Intervention Effects on Maternal Intersubjectivity and Stress Resilience

Ho, S. Shaun, Muzik, Maria, Rosenblum, Katherine L., Morelen, Diana, Nakamura, Yoshio, Swain, James E.

08 December 2020

Stress resilience in parenting depends on the parent's capacity to understand subjective experiences in self and child, namely intersubjectivity, which is intimately related to mimicking other's affective expressions (i. e., mirroring). Stress can worsen parenting by potentiating problems that can impair intersubjectivity, e.g., problems of “over-mentalizing” (misattribution of the child's behaviors) and “under-coupling” (inadequate child-oriented mirroring). Previously we have developed Mom Power (MP) parenting intervention to promote maternal intersubjectivity and reduce parenting stress. This study aimed to elucidate neural mechanisms underlying the effects of MP with a novel Child Face Mirroring Task (CFMT) in functional magnetic-resonance-imaging settings. In CFMT, the participants responded to own and other's child's facial pictures in three task conditions: (1) empathic mirroring (Join), (2) non-mirroring observing (Observe), and (3) voluntary responding (React). In each condition, each child's neutral, ambiguous, distressed, and joyful expressions were repeatedly displayed. We examined the CFMT-related neural responses in a sample of healthy mothers (n = 45) in Study 1, and MP effects on CFMT with a pre-intervention (T1) and post-intervention (T2) design in two groups, MP (n = 19) and Control (n = 17), in Study 2. We found that, from T1 to T2, MP (vs. Control) decreased parenting stress, decreased dorsomedial prefrontal cortex (dmPFC) during own-child-specific voluntary responding (React to Own vs. Other's Child), and increased activity in the frontoparietal cortices, midbrain, nucleus accumbens, and amygdala during own-child-specific empathic mirroring (Join vs. Observe of Own vs. Other's Child). We identified that MP effects on parenting stress were potentially mediated by T1-to-T2 changes in: (1) the left superior-temporal-gyrus differential responses in the contrast of Join vs. Observe of own (vs. other's) child, (2) the dmPFC-PAG (periaqueductal gray) differential functional connectivity in the same contrast, and (3) the left amygdala differential responses in the contrast of Join vs. Observe of own (vs. other's) child's joyful vs. distressed expressions. We discussed these results in support of the notion that MP reduces parenting stress via changing neural activities related to the problems of “over-mentalizing” and “under-coupling.” Additionally, we discussed theoretical relationships between parenting stress and intersubjectivity in a novel dyadic active inference framework in a two-agent system to guide future research.

amygdala

Bayesian active inference

dorsomedial prefrontal cortex

empathy

intersubjectivity

PAG = periaqueductal gray

parenting intervention

parenting stress

Psychology

Role of the Dorsomedial Hypothalamus in Responses Evoked from the Preoptic Area and by Systemic Administration of Interleukin-1β

Hunt, Joseph L.

23 June 2009

Indiana University-Purdue University Indianapolis (IUPUI) / Recent studies in anesthetized rats suggest that autonomic effects relating to thermoregulation that are evoked from the preoptic area (POA) may be mediated through activation of neurons in the dorsomedial hypothalamus (DMH). Disinhibition of neurons in the DMH produces not only cardiovascular changes but also increases in plasma adrenocorticotropic hormone (ACTH) and locomotor activity mimicking those evoked by microinjection of muscimol, a GABAA receptor agonist and neuronal inhibitor, into the POA. Therefore, I tested the hypothesis that all of these effects evoked from the POA are mediated through neurons in the DMH by assessing the effect of bilateral microinjection of muscimol into the DMH on the changes evoked by microinjection of muscimol into the POA in conscious rats. In addition, I tested the hypothesis that neurons in the DMH mediate a specific response that is thought to signal through the POA, the activation of the HPA axis evoked by systemic administration of the inflammatory cytokine IL-1β. After injection of vehicle into the DMH, injection of muscimol into the POA elicited marked increases in heart rate, arterial pressure, body temperature, plasma ACTH and locomotor activity and also increased Fos expression in the hypothalamic paraventricular nucleus (PVN), a region known to control the release of ACTH from the adenohypophysis, and the raphe pallidus, a medullary region known to mediate POA-evoked sympathetic responses. Prior microinjection of muscimol into the DMH produced a modest depression of baseline heart rate, arterial pressure, and body temperature but completely abolished all changes evoked from the POA. Microinjection of muscimol just anterior to the DMH had no effect on POA-evoked autonomic and neuroendocrine changes. Inhibition of neuronal activity in the DMH only partially attenuated the increased activity of the HPA axis following systemic injections of IL-1β. Thus, neurons in the DMH mediate a diverse array of physiological and behavioral responses elicited from the POA, suggesting that the POA represents an important source of inhibitory tone to key neurons in the DMH. However, it is clear that the inflammatory cytokine IL-1β must employ other pathways that are DMH-, and possibly POA-, independent to activate the HPA axis.

dorsomedial hypothalamus

preoptic area

hypothalamus

paraventricular nucleus

Fos

body temperature

heart rate

ACTH

ACTH

Hypothalamus

Interleukin-1