ABSTRACT
Introduction: Inhibition of pituitary gonadotropin secretion in men by testosterone (T) is principally mediated by aromatization to estrogen (E), which inhibits hypothalamic secretion of gonadotropin-releasing hormone (GnRH). Material and Methods: Longitudinal clinical investigation unit-based evaluation of the clinical and biochemical response to E-receptor blockade. Initial monotherapy with 50 mg of clomiphene citrate (CC) daily for a period of 9 months, with diurnal morning peak testosterone and luteinizing hormone (LH) levels evaluated at three-month intervals thereafter. Th e patient then resumed hormone replacement therapy (HRT) using T cream with adjuvant CC therapy. Main Outcome Measures were Baseline and stimulated T and LH levels; eff ect on sexual function. Result(S): CC therapy resulted in complete normalization of pulsatile gonadotropin secretion, serum T level, and sexual function. Conclusion(S): Isolated hypogonadotropic hypogonadism (IHH) may result from an acquired defect of enhanced hypothalamic sensitivity to E-mediated negative feedback. Whereas direct T replacement therapy can further suppress endogenous gonadotropin secretion, treating IHH men with gonadotropins can stimulate endogenous T secretion and enhance fertility potential. Reversal of gonadotropin defi ciency with CC was found to have a similar biological eff ect.
Subject(s)
Clomiphene/administration & dosage , Clomiphene/analogs & derivatives , Clomiphene/therapeutic use , Gonadotropins, Pituitary/deficiency , Hormone Replacement Therapy/methods , Hormone Replacement Therapy/statistics & numerical data , Humans , Hypogonadism/drug therapy , Hypogonadism/epidemiology , Hypothalamus/physiology , MaleABSTRACT
OBJECTIVE: To evaluate the modulation of the hypothalamus-pituitary-adrenal axis (HPA) on prolactin secretion in rats after adrenalectomy (ADX). MATERIALS AND METHODS: Plasma corticosterone, ACTH, and prolactin concentrations were measured by radioimmunoassay in rats after bilateral ADX in the short- (3 hours and 1day) and long-term (3, 7, and 14 days). RESULTS: Animals that underwent ADX showed undetectable corticosterone levels and a triphasic ACTH response with a transient increase (3h), a decrease (1d), and further increase in the long-term after ADX. Sham animals showed a marked increase in corticosterone and ACTH levels three hours after surgery, with a decrease to basal levels thereafter. Plasma prolactin levels were not changed after ADX. CONCLUSION: There are different points of equilibrium in the HPA axis after the glucocorticoid negative feedback is removed. Prolactin plasma secretion is not altered in the short or long- term after ADX, suggesting that the peptidergic neurons essential for prolactin release are not activated after ADX.
OBJETIVO: Avaliar a modulação do eixo hipotálamo-hipófise-adrenal (HHA) sobre a secreção de prolactina após adrenalectomia (ADX). MATERIAIS E MÉTODOS: Quantificamos por RIE corticosterona, ACTH e prolactina plasmáticos em ratos após curtos (3 horas e 1 dia) e longos (3, 7 e 14 dias) períodos de ADX bilateral. RESULTADOS: Animais ADX mostraram níveis indetectáveis de corticosterona. As concentrações plasmáticas de ACTH apresentaram resposta trifásica: aumento transitório (3h), diminuição (1d) e novo aumento após longos períodos de ADX. Animais Sham mostraram aumento de corticosterona/ACTH após três horas de cirurgia, diminuindo posteriormente aos níveis basais. As concentrações plasmáticas de prolactina não se alteraram após ADX. CONCLUSÃO: Existem diferentes pontos de equilíbrio do eixo HHA após a remoção da retroalimentação negativa exercida pelos glicocorticoides. A secreção de prolactina não se alterou após curtos/longos períodos de ADX, sugerindo que os neurônios peptidérgicos essenciais para a liberação de prolactina não estão ativados durante os diferentes períodos de ADX.
Subject(s)
Animals , Male , Rats , Adrenalectomy/methods , Hypothalamus/physiology , Pituitary-Adrenal System/physiology , Prolactin , Corticosterone/blood , Glucocorticoids/physiology , Postoperative Period , Prolactin/blood , Radioimmunoassay , Rats, Wistar , Time FactorsABSTRACT
Human growth is a complex process regulated by several genes, most of which are unknown. Recently, our knowledge regarding the etiology of genetically determined causes of short stature has greatly increased, so molecular analysis is becoming essential for the diagnosis of growth retardation. The advances in our understanding of the molecular mechanisms involved in the function of the somatotrophic axis have resulted in a dramatic enhancement of our ability to diagnose and treat growth disorders. We hope that in the next few years improved methods for identifying specific abnormalities which cause short stature will expand our ability to diagnose other causes of growth retardation, and reduce the proportion of patients with "idiopathic" short stature.
Subject(s)
Humans , Body Height/genetics , Growth Hormone/genetics , Growth Disorders/diagnosis , Growth Disorders/genetics , Insulin-Like Growth Factor I/physiology , Insulin-Like Growth Factor I/genetics , Pituitary Gland/physiology , Hypothalamus/physiology , Growth Hormone-Releasing Hormone/physiology , Growth Hormone-Releasing Hormone/genetics , Growth Hormone/physiology , MutationABSTRACT
Current estimates suggest that over 1 billion people are overweight and over 300 million people are obese. Weight gain is due to an imbalance between energy expenditure and dietary intake. This review discusses the hypothalamic control of appetite and highlights key developments in research that have furthered our understanding of the complex pathways involved. Nuclei within the hypothalamus integrate peripheral signals such as adiposity and caloric intake to regulate important pathways within the central nervous system controlling food intake and energy expenditure. Firmly established pathways involve the orexigenic NPY/AgRP and the anorexigenic POMC/CART neurons in the arcuate nucleus (ARC) of the hypothalamus. These project from the ARC to other important hypothalamic nuclei, including the paraventricular, dorsomedial, ventromedial and lateral hypothalamic nuclei. In addition there are many projections to and from the brainstem, cortical areas and reward pathways, which modulate food intake.
As estimativas atuais sugerem que mais de 1 bilhão de pessoas apresentam sobrepeso e 300 milhões são obesas. O ganho de peso representa um desequilíbrio entre o gasto energético e o consumo alimentar. Esta revisão discute o controle hipotalâmico do apetite e destaca os pontos-chave no desenvolvimento de pesquisas para ampliar o nosso entendimento dos complexos mecanismos envolvidos nesta regulação. Núcleos situados no hipotálamo integram uma série de sinais com o sistema nervoso central controlando a ingestão alimentar e o gasto energético. As vias mais estabelecidas envolvem os neurônios orexigênicos NPY/AgRP e os neurônios anorexigênicos POMC/CART no núcleo arqueado (ARC) do hipotálamo. Esses neurônios se projetam do ARC para outros importantes núcleos hipotalâmicos, tais quais: paraventricular, dorsomedial, ventromedial e lateral. Além disso, existem várias projeções que vão e vem do tronco cerebral, das áreas corticais e das vias de retroalimentação que modulam o consumo alimentar.
Subject(s)
Humans , Appetite Regulation/physiology , Feeding Behavior/physiology , Hypothalamus/physiology , Obesity/physiopathology , Arcuate Nucleus of Hypothalamus/physiology , Gastrointestinal Hormones/physiology , Obesity/metabolism , Obesity/therapyABSTRACT
Obesity is currently a worldwide pandemic. It affects more than 300 million humans and it will probably increase over the next 20 years. The consumption of calorie-rich foods is responsible for most of the obesity cases, but not all humans exposed to high-calorie diets develop the disease. This fact has prompted researchers to investigate the mechanisms linking the consumption of high-calorie diets to the generation of an imbalance between energy intake and expenditure. According to recent studies, the exposure to fat-rich diets induces an inflammatory response in the hypothalamic areas involved in the control of feeding and thermogenesis. The inflammatory process damages the neuronal circuitries that maintain the homeostatic control of the body's energy stores, therefore favoring body mass gain. This review will focus on the main advances obtained in this field.
Obesidade é hoje um grave problema de saúde pública no mundo. Mais de 300 milhões de pessoas são obesas e esse número deve crescer substancialmente nos próximos 20 anos. As dietas ricas em calorias são a principal causa de obesidade, porém, nem todos os indivíduos expostos a dietas altamente calóricas se tornam obesos. Tal fato estimulou pesquisadores a investigarem os mecanismos que ligam o consumo de dietas ricas em calorias ao desenvolvimento de um balanço inadequado entre consumo e gasto energético. De acordo com estudos recentes, o consumo de dietas ricas em gorduras induz a ativação de uma resposta inflamatória nas áreas do hipotálamo envolvidas com o controle da fome e da termogênese. Tal processo inflamatório lesa os circuitos neuronais que mantêm o controle homeostático das reservas corporais de energia, favorecendo assim o ganho de massa adiposa. Esta revisão irá focar os principais avanços obtidos nesta área.
Subject(s)
Animals , Humans , Energy Intake/physiology , Energy Metabolism/physiology , Hypothalamic Diseases/physiopathology , Hypothalamus/physiology , Obesity/etiology , Body Composition , Body Mass Index , Diet , Dietary Fats/adverse effects , Dietary Fats/metabolism , Eating/physiology , Hypothalamic Diseases/etiology , Leptin/physiology , Limbic Encephalitis/etiology , Limbic Encephalitis/physiopathology , Obesity/metabolism , Thermogenesis/physiologyABSTRACT
The central nervous system regulates energy intake and expenditure through a complex network of neurotransmitters and neuromodulators. It is of great interest to understand the relevance of these systems to the physiological control of energy balance and to the disturbances of obesity. The present paper discusses some of the methods to address this field used at the laboratory of Endocrine Physiology of Universidade Federal de São Paulo. Initially, different experimental models of rat obesity are presented, namely the hypothalamic induced monosodium glutamate model, the Zucker genetic model, and the dietary model. The principles of brain microdialysis are also presented, the technique applied to obtain representative samples of the extracellular fluid of brain sites involved in feeding control. The microdialysate levels of serotonin, an important anorexigenic neurotransmitter, are determined by HPLC with electrochemical detection. The immunoblot technique (Western blot) is used to determine hypothalamic levels of proteins relevant to the anorexigenic effect of serotonin and to analyze the acute activation of the insulin signaling cascade in the hypothalamus. The final section addresses the potential applications of proteomics in the study of the central control of feeding.
O sistema nervoso central controla a ingestão e o gasto de energia por meio de um complexo circuito de neurotransmissores e neuromoduladores. É de grande interesse entender a relevância fisiológica destes sistemas e o papel que desempenham nos distúrbios da obesidade. No presente artigo, discutem-se alguns dos métodos que têm sido utilizados no laboratório de Fisiologia Endócrina da Universidade Federal de São Paulo, em estudos neste campo. Inicialmente, são apresentados alguns modelos de obesidade experimental em ratos, como a obesidade hipotalâmica induzida por glutamato monossódico, o modelo genético Zucker e também obesidades induzidas por dieta. Comenta-se, em seguida, sobre os princípios da microdiálise cerebral. Esta técnica é utilizada para obter amostras representativas do líquido extracelular de regiões cerebrais envolvidas no controle da ingestão alimentar. Os níveis de serotonina, um importante neurotransmissor anorexígeno, são medidos no dialisato por cromatografia líquida de alta pressão com detecção eletroquímica. Utiliza-se a técnica de immunoblot (Western blot) para determinar os níveis hipotalâmicos de proteínas importantes na ação anorexigênica da serotonina e também para analisar a ativação aguda da cascata de sinalização da insulina no hipotálamo. A seção final aborda o grande potencial da análise proteômica no estudo do controle central da ingestão.
Subject(s)
Animals , Rats , Hypothalamus/physiology , Eating/physiology , Microdialysis/methods , Obesity , RatsABSTRACT
Prenatal stimulations have been shown to have long-term effects on at reproductive activity. We evaluated the influence of the prenatal stress on the hypothalamic-pituitary-gonad (HPG) axis in male offsprings from mothers with high number of offsprings per litter (HNL) and low number of offsprings per litter (LNL) after hypothesizing that the number of offsprings per litter may modify the effect of the prenatal stress on the HPG of adult offsprings. Pregnant Wistar rats were used for this study. Immobilization (IMO) stress was used, 30 min, 3 times per week, from the 5th to 21st day of pregnancy. The weight of adrenal and gonads, and the corticosterone (COR), testosterone (TES) and luteinizing hormone (LH) plasmatic levels were analyzed in the male offspring at 30, 45 and 70 days of age. The offspring males coming from LNL showed a decrease in testicle weight and TES levels, without changes in the plasmatic LH levels. However, the offspring of HNL showed a decrease of LH levels. It is possible to conclude that in LNL prenatal stress would produce alterations to gonadal level, while in HNL the effect of stress would be evident at pituitary level.
Subject(s)
Animals , Male , Female , Pregnancy , Rats , Corticosterone/blood , Pituitary Gland/physiology , Hypothalamus/physiology , Luteinizing Hormone/blood , Sexual Maturation , Stress, Physiological , Testis/physiology , Prenatal Exposure Delayed Effects/etiology , Litter Size , Rats, Wistar , Testosterone/bloodABSTRACT
Tendo em vista as mais recentes contribuições, as áreas corticais límbicas - originalmente denominadas em conjunto de grande lobo límbico -, além dos giros do cíngulo e parahipocampal, são constituídas pelas regiões mais posteriores do córtex fronto-orbitário e pelo córtex insular. Em contraposição ao restante do córtex cerebral, que se projeta sobre os gânglios da base (particularmente sobre as porções mais dorsais e mais extensas do striatum, constituídas fundamentalmente pelo núcleo caudado e pelo putame), as áreas corticais límbicas se caracterizam por se projetarem principalmente sobre o hipotálamo e também sobre a porção mais ventral do striatum (principalmente sobre o núcleo accumbens). Uma vez que todo o striatum se projeta para o globo pálido - e este para o tálamo, que se projeta para o córtex cerebral, constituindo-se, assim, circuitos córtico-subcorticais reentrantes -, tem-se que, enquanto as alças relacionadas com o striatum e o pallidum dorsais são responsáveis por atividades e rotinas motoras, as alças relacionadas com o striatum e o pallidum ventrais caracterizam circuitos córtico-subcorticais reentrantes e segregados que se relacionam particularmente com funções comportamentais. A amígdala estendida (amígdala centromedial, componente dorsal ou estria terminal, componente ventral e núcleo da estria terminal), por sua vez, também recebe aferências de todas as áreas corticais límbicas, é particularmente modulada pelas áreas corticais pré-frontais e, ao invés de se projetar sobre o striatum, projeta-se diretamente sobre o hipotálamo e o tronco encefálico. Ao receber também conexões diretas do tálamo, a amígdala estendida pode ainda desencadear respostas principalmente autonômicas, de forma inespecífica, porém rápida, através da ativação de centros do tronco encefálico. Os sistemas macro-anatômicos fronto-basais, estriatal-palidal ventral e amígdala estendida, em conjunto com o núcleo basal de Meynert e com o sistema septo-banda...
Considering the most recent contributions, the limbic cortical areas, originally known as the greater limbic lobe, besides the cingulated and the parahippocampal gyri also includes the insula and the posterior orbital cortex. In contrast to the nonlimbic cortical areas that project to the basal ganglia (particularly over the dorsal aspects of the striatum, constituted by the caudate nucleus and by the putamen), the limbic cortical areas are characterized by projecting to the hypothalamus and also to the ventral striatum (particularly to the nucleus accumbens). Once all the striatum projects to the globus pallidus which projects to the thalamus and then to the cortex, generating cortical-subcortical reentrant circuits, while the dorsal striatum and pallidum related cortico-subcortical loops are involved with motor activities, the ventral cortical-striatal-pallidal system is particularly related with behavior functions. The extended amygdala (central medial amygdala, stria terminalis or dorsal component, ventral component, and bed nucleus of stria terminalis) receives inputs primarily from the limbic cortical areas, is particularly modulated by the prefrontal cortex, and receives also direct connections from the thalamus that enables the amygdala to generate nonspecific and quick responses through its projections to the hypothalamus and to the brainstem. The ventral striatal-pallidal and the extended amygdala are then two basal forebrain macro-anatomical systems, that together with the basal nucleus of Meynert and with the septal-diagonal band system, constitute the main structures that are particularly connected with the limbic cortical areas, and that altogether project to the hypothalamus and to the brainstem which give rise to the autonomic, endocrine and somatosensory components of the emotional experiences, and that regulate the basic activities of drinking, eating, and related to the sexual behavior.
Subject(s)
Humans , Basal Ganglia/anatomy & histology , Behavior/physiology , Cerebral Cortex/anatomy & histology , Limbic System/anatomy & histology , Amygdala/anatomy & histology , Amygdala/physiology , Basal Ganglia/physiology , Cerebral Cortex/physiology , Globus Pallidus/anatomy & histology , Globus Pallidus/physiology , Hippocampus/anatomy & histology , Hippocampus/physiology , Hypothalamus/anatomy & histology , Hypothalamus/physiology , Limbic System/physiology , Parahippocampal Gyrus/anatomy & histology , Parahippocampal Gyrus/physiologyABSTRACT
O aumento da prevalência de obesidade em várias regiões do planeta vem se revelando como um dos mais importantes fenômenos clínico-epidemiológicos da atualidade. Fatores como a mudança do hábito alimentar e o estilo de vida sedentário, aliados a determinantes genéticos ainda pouco conhecidos, desempenham um papel relevante na patogênese desta doença. Nos últimos dez anos, desde o descobrimento do hormônio leptina, avanços consideráveis foram obtidos na caracterização dos mecanismos hipotalâmicos do controle da ingestão alimentar e da termogênese. Tais avanços têm revelado as particularidades de um sistema complexo e integrado, e têm oferecido novas perspectivas para abordagens terapêuticas farmacológicas específicas. Esta revisão apresenta os mais recentes avanços nesta área, tendo como foco a ação hipotalâmica da leptina e da insulina e explorando a hipótese de que a resistência à ação central destes hormônios possa ser o elo entre a obesidade e as outras condições clínicas nas quais a resistência à insulina desempenha um papel patogenético proeminente.
The worldwide increase in the prevalence of obesity is becoming one of the most important clinical-epidemiological phenomena of the present days. Environmental factors such as changes in life-style and feeding behavior associated with poorly characterized genetic determinants are though to play the most important roles in the pathogenesis of this disease. During the last ten years, since the discovery of leptin, great advances were obtained in the characterization of the hypothalamic mechanisms involved in the control of food intake and thermogenesis. Such advances are unveiling a complex and integrated system and are opening a wide perspective for the finding of novel therapeutic targets for the treatment of this harming condition. This review will present some of the most recent findings in this field. It will be focused on the actions of leptin and insulin in the hypothalamus and will explore the hypothesis that hypothalamic resistance to the action of these hormones may play a role in the development of obesity and may act as a molecular link between obesity, type 2 diabetes mellitus and other clinical conditions on which insulin resistance plays an important pathogenetic role.
Subject(s)
Humans , Eating/physiology , Hypothalamus/physiology , Insulin Resistance/physiology , Leptin/physiology , Obesity/etiology , Thermogenesis/physiology , /etiology , Hypothalamus/metabolism , Life Style , Obesity/genetics , Obesity/metabolism , Transcription, Genetic/physiologyABSTRACT
La obesidad se considera una de las enfermedades más importantes en la medida que acarrea gran morbilidad y mortalidad. El conocimiento de los mecanismos que intervienen en la saciedad, el peso corporal y el gasto de energía ha permitido el descubrimiento de hormonas relacionadas con el eje gastrohipotalámico, encargado de regular la saciedad y otros procesos que participan en la obesidad. La ghrelina, una hormona de secreción predominantemente gástrica, dio luz para comprender estos mecanismos, pues se trata de una hormona que regula la saciedad y el peso corporal por medio de mecanismos centrales mediados por el neuropéptido Y y la proteína relacionada con el agutí. En este artículo se revisan los aspectos fundamentales de esta hormona y de sus efectos en diversos órganos y sistemas.
Obesity is currently considered one of the most important diseases worldwide due to its high morbidity and mortality rates. The mechanisms involved in the control of satiation, body weight and energy expenditure has led to the discovery of new hormones that participate in the gastrichypothalamic axis in charge of regulating satiation and other obesity-related processes. Ghrelin a novel hormone secreted mainly by gastric tissue, has shed some light on this mechanism. It is a hormone that regulates satiation and body weight by centrally mediated mechanisms, involving neuropeptide Y and Agouti associated proteins. The present review focuses on some important physiological aspects of this hormone.
Subject(s)
Humans , Stomach/physiology , Hypothalamus/physiology , Peptide Hormones/physiology , Ghrelin , Satiation/physiologyABSTRACT
Obesity has become a worldwide public health problem affecting millions of people. This is a chronic, stigmatized, and costly disease, rarely curable and is increasing in prevalence to a point today where we define obesity as an epidemic disease that not only in developed but also on developing countries. The pathogenesis of obesity is largely unknown, especially about energy regulatory mechanism that involved wide area of neuroendocrinology that is very interesting but very complex and makes internists "refuse" to learn. Obesity occurs through a longstanding imbalance between energy intake and energy expenditure, influenced by a complex biologic system that regulates appetite and adiposity. Obesity influences the pathogenesis of hypertension, type 2 diabetes, dyslipidemia, kidney, heart, and cerebrovascular disease. It is very wise for every internist to learn the pathogenesis and treatment of this worldwide diseases. Until now, the available treatments, including drugs, are palliative and are effective only while the treatment is being actively used; and besides so many side effects reported.
Subject(s)
Appetite Depressants/therapeutic use , Energy Metabolism , Ghrelin , Homeostasis , Humans , Hypothalamus/physiology , Insulin/physiology , Leptin/physiology , Obesity/drug therapy , Peptide Hormones/physiology , Sympathetic Nervous System/physiologyABSTRACT
Em animais anestesiados a EE do hipotálamo produz um padrão de ajustes cardiovasculares caracterizado por hipertensão arterial, taquicardia, vasodilatação muscular e vasoconstrição mesentérica, entretanto, os mecanismos periféricos envolvidos nestes ajustes cardiovasculares ainda não foram completamente esclarecidos. O presente estudo teve como objetivo caracterizar os mecanismos periféricos responsáveis pela redistribuição de fluxo sanguíneo produzidas pela EE do hipotálamo. Os resultados obtidos demonstraram que 1) em ratos anestesiados a EE do hipotálamo produziu hipertensão arterial, taquicardia, vasoconstrição no leito mesentérico e acentuada vasodilatação dos membros posteriores; 2) a combinação do bloqueio farmacológico de receptores a1 e a2 adrenérgicos com fentolamina mais adrenalectomia bilateral reduziu a vasoconstrição mesentérica e a vasodilatação dos membros posteriores. Nestes animais o bloqueio da síntese de NO com L-NAME provocou nova redução significante da vasodilatação dos membros posteriores; 3) a administração de L-NAME, previamente o bloqueio farmacológico com fentolamina mais adrenalectomia bilateral, reduziu as respostas de vasoconstrição mesentérica e de vasodilatação dos membros posteriores. Estes resultados sugerem a existência de pelo menos três possíveis mecanismos responsáveis pela vasodilatação dos membros posteriores induzida pela EE do hipotálamo: 1) ativação de receptores b-adrenérgicos por catecolaminas liberadas pela medula adrenal; 2) redução do tono vasoconstritor simpático e 3) um terceiro mecanismo que utiliza NO como mediador.
Subject(s)
Animals , Male , Rats , Electric Stimulation/methods , Hemodynamics , Hypothalamus/physiology , Nitric Oxide/physiology , Regional Blood Flow/physiology , Vasodilation/physiology , Adrenalectomy , Adjuvants, Anesthesia/pharmacology , Adrenergic alpha-Antagonists/pharmacology , Hemodynamics , Hindlimb/blood supply , NG-Nitroarginine Methyl Ester/pharmacology , Pentobarbital/pharmacology , Phentolamine/pharmacology , Rats, Wistar , Regional Blood Flow/drug effects , Vasodilation/drug effectsABSTRACT
Três sub-divisões hipotalâmicas são importantes no ciclo sono-vigília: o hipotálamo anterior (núcleos gabaérgicos e núcleos supraquiasmáticos), o hipotálamo posterior (núcleo túbero-mamilar histaminérgico) e o hipotálamo lateral (sistema hipocretinas). O sistema gabaérgico inibitório do núcleo pré-óptico ventro-lateral (VLPO) do hipotálamo anterior é responsável pelo início e manutenção do sono NREM. Os neurônios supraquiasmáticos (NSQs) do hipotálamo anterior são responsáveis pelo ritmo circadiano do ciclo sono-vigília. Os núcleos aminérgicos, histaminérgicos, as hipocretinas e núcleos colinérgicos do prosencéfalo basal apresentam-se ativos durante a vigília, inibindo o núcleo pré-óptico ventro-lateral, promovendo a vigília. O processo de inibição-estimulação é a base do modelo da interação recíproca entre os grupos de células wake-off-sleep-on e células wake-off-sleep-on reguladores do ciclo sono-vigília. O modelo da interação recíproca também se aplica aos núcleos colinérgicos (células REM-on) e aminérgicos (células REM-off) do tronco cerebral no controle temporal do sono REM-NREM.
Subject(s)
Humans , Activity Cycles/physiology , Hypothalamus/physiology , Neurons/physiology , Neurotransmitter Agents/physiology , Sleep Stages/physiology , Wakefulness/physiology , Electromyography , ElectrophysiologyABSTRACT
The present study was carried out in five cats which did not attack the rats spontaneously. Predatory attack on an anaesthetized rat was elicited by electrical stimulation of extreme lateral regions of hypothalamus. These sites were stimulated at a current strength from 300-700 microa to evoke a predatory attack on an anaesthetized rat. The attack was accompanied by minimal affective display such as alertness, pupillary dilatation, and culminated in beck biting at higher current strength. A scoring system allowed the construction of stimulus response curves, which remained fairly constant when repeated over a period of 3-4 weeks. Microinfusions of norepineprine and clonidine in 4.0 and 5.0 microg dose respectively in locus ceruleus and adjoining tegmental fields facilitated the predatory attack and there was a significant reduction in the threshold current strength for the elicitation of affective and somatomotor components. Microinfusions of yohimbine, an alpha-2 blocker, in 5 microg dose completely blocked the predatory attach response as indicated by an increase in the threshold current strength for the affective components. The somatomotor components were completely inhibited and could not be elicited even when the current strength was increased to 1000 microA. The predatory attack behavior remained completely inhibited for almost two hours following microinfusion of yohimbine. During this period, the animal was extremely drowsy and reacted very slowly even to a painful stimulus such as pinching of tail. Microinfusions of propranalol (beta-blocker), practalol (beta-1 blocker), prazosin (alpha-1 antagonist), propylene glycol as well as saline in similar volumes (0.5 microl) as control failed to produce any blocking effect, thus indicating the involvement of alpha-2 adrenoceptive mechanisms in the modulation of predatory attack in this region of midbrain. The facilitatory effects of norepinephrine and clonidine were significant at P<0.01 and P<0.05 respectively with Wilcoxon's signed rank test. The inhibitory effects of yohimbine were significant at P<0.05. The present study indicates the involvement of alpha-2 adrenoceptive mechanisms in the facilitation of hypothalamically elicited predatory attack.
Subject(s)
Adrenergic alpha-Agonists/administration & dosage , Adrenergic alpha-Antagonists/pharmacology , Animals , Cats , Clonidine/pharmacology , Electric Stimulation , Electrodes, Implanted , Female , Hypothalamus/physiology , Locus Coeruleus/physiology , Male , Microinjections , Norepinephrine/administration & dosage , Predatory Behavior/physiology , Receptors, Adrenergic, alpha-2/antagonists & inhibitors , Sympathetic Nervous System/physiology , Yohimbine/pharmacologyABSTRACT
En la fisiopatología de la obesidad intervienen factores genéticos, sociales, metabólicos, endocrinos y neurológicos. Esta multifactoriedad junto al hecho que estos factores se interrelacionan a través de mecanismos muy complejos, que son sólo parcialmente conocidos, ha llevado a que la comprensión íntima de este trastorno resulte una tarea sumamente ardua. Por estos motivos, el conocimiento integral de esta afección plantea un desafío al que actualmente están abocados numerosos grupos de investigadores. El análisis de la obesidad como un trastorno neuroendocrino, propone el estudio de este fenómeno desde una visión particular que implica disfunciones en casi todos los órganos endocrinos y en el sistema nervioso central, fundamentalmente en la actividad hipotalámica. Estas alteraciones afectan principalmente a los ejes neuroendocrinos hipotálamo-hipofiso-adrenal, adipo-insular y al control hipotalámico, tanto de la ingesta de alimento como del almacenamiento y gasto energético. Este artículo plantea una actualización en este campo; en primer lugar, se realiza una breve descripción, en forma independiente, de los principales sistemas antes mencionados y luego una descripción de su funcionamiento normal integrado. Finalmente, se describen desregulaciones de estos mecanismos y se discute como ellas contribuirían al desarrollo y/o mantenimiento de la obesidad.
Subject(s)
Humans , Hypothalamus/physiology , Neurosecretory Systems/physiology , Obesity/physiopathology , Autonomic Nervous System/physiology , Endocrine Glands , Eating/physiology , Neurosecretory Systems/metabolism , Neurosecretory Systems/physiopathology , Obesity/complications , Obesity/metabolismABSTRACT
O nosso entendimento das bases neurofisiológicas da reaçäo emocional do medo baseia-se em grande parte nos estudos que envolvem respostas condicionadas a estímulos fisicamente aversivos, como, por exemplo, o choque elétrico nas patas. Enquanto este paradigma parece ser útil para avaliarmos os sistemas neurais envolvidos na resposta do, assim chamado, medo condicionado (que tipicamente tem se limitado à observaçäo da resposta de congelamento), este paradigma parece ter sérias limitaçöes para investigarmos as bases neurais das respostas de medo em circunstancias naturais. Trabalhos recentes utilizando técnicas de lesöes neurais bem como de mapeamento funcional em animais expostos a predadores naturais, ou somente ao odor destes predadores, revelam uma série de estruturas neurais como responsáveis pelas respostas de medo inato, bastante distintas daquelas previamente implicadas nas respostas de condicionamento aversivo. Como revisto no presente trabalho, entre estas estruturas temos distritos diferenciados da zona medial do hipotálamo; setores específicos da amídala e do sistema septo-hipocampal, envolvidos, respectivamente no processamento de pistas relacionadas à presença do predador e na análise contextual do ambiente; e setores da matéria cinzenta periaquedutal, já classicamente envolvidos na expressäo de respostas de defesa. Estas informaçöes podem ser potencialmente importantes para a análise e terapêutica de psicopatologias relacionadas aos distúrbios da reaçäo emocional de medo
Subject(s)
Animals , Cats , Rats , Nervous System Physiological Phenomena , Instinct , Fear/physiology , Food Chain , Hypothalamus/physiology , Amygdala/physiologyABSTRACT
Prof. BK Anand the living legend, is the founder of modern neurophysiology in India. His career spanned an era that marks the beginning of Brain Research in India. His contributions to understanding of brain functions began with the epoch making discovery of lateral hypothalamic area as the 'feeding center'. Subsequently it encompasses a wider range of studies from elucidation of the intricate mechanisms underlying ingestive behaviour to hypothalamic regulation of cardiovascular, respiratory, gastrointestinal activity and regulation of various physiological functions by limbic system. The following review gives an account of the contributions made by Prof Anand and his colleagues during twenty five years of his illustrious career. The publications resulted from his studies has not only stood as a testimony to understanding of the neural control of ingestive behaviour and limbic functions but also have been a sources of a great interest to those who pursue knowledge in this field.
Subject(s)
Adaptation, Physiological , Affect/physiology , Altitude , Autonomic Nervous System/physiology , Endocrine System/innervation , Feeding Behavior/physiology , Hemostasis/physiology , History, 20th Century , Humans , Hypothalamus/physiology , India , Physiology/history , Yoga/historyABSTRACT
Cytokines are molecules that were initially discovered in the immune system as mediators of communication between various types of immune cells. However, it soon became evident that cytokines exert profound effects on key functions of the central nervous system, such as food intake, fever, neuroendocrine regulation, long-term potentiation, and behavior. In the 80's and 90's our group and others discovered that the genes encoding various cytokines and their receptors are expressed in vascular, glial, and neuronal structures of the adult brain. Most cytokines act through cell surface receptors that have one transmembrane domain and which transduce a signal through the JAK/STAT pathway. Of particular physiological and pathophysiological relevance is the fact that cytokines are potent regulators of hypothalamic neuropeptidergic systems that maintain neuroendocrine homeostasis and which regulate the body's response to stress. The mechanisms by which cytokine signaling affects the function of stress-related neuroendocrine systems are reviewed in this article.
Subject(s)
Humans , Axis, Cervical Vertebra/physiology , Central Nervous System/physiology , Endocrine System/physiology , Hypothalamic Hormones/physiology , Immune System/physiology , Interleukin-1/physiology , Adrenal Glands/physiology , Adrenal Glands/physiopathology , Axis, Cervical Vertebra/physiopathology , Central Nervous System/immunology , Central Nervous System/physiopathology , Hypothalamo-Hypophyseal System/physiology , Hypothalamo-Hypophyseal System/physiopathology , Hypothalamus/physiology , Hypothalamus/physiopathology , Pituitary Gland/physiology , Pituitary Gland/physiopathology , Pituitary-Adrenal System/physiology , Pituitary-Adrenal System/physiopathologyABSTRACT
BACKGROUND & OBJECTIVES: Amygdaloid nuclei and the hypothalamic structures are known to have intimate functional relationships. But to date the nature of this relationship has not been completely understood. In the present study, this relationship was evaluated. METHODS: Lesions were performed in basolateral nucleus of amygdala (BLA) and the ventromedial hypothalamus (VMH) in the same rats sequentially to evaluate both the individual, as well as combined effects of lesions of these two centres. Food intake, water intake and the body weight were studied before and after the lesions. RESULTS: The first lesion of BLA or VMH increased the food and water intake significantly (P < 0.01). But in the VMH lesioned rats, further lesioning of BLA, reduced the intensity of the hyperphagia. This suggested a kind of interrelationship between these centres, pointing out that intact BLA was instrumental in the development of VMH induced hyperphagia. To further assess the interactions of these two centres, three bottle free choice taste preference tests were undertaken by using sweet, salty solution along with tap water. The lesion of the BLA increased the intake of sweet tasting saccharin solution. This preference was retained even after the lesion of the VMH in the same rats. INTERPRETATION & CONCLUSION: Therefore it appeared as if the VMH neurons might not be involved in the sweet taste preference following BLA lesion, suggesting involvement of some other pathway for taste selection responses. But the development of full fledged VMH lesion induced hyperphagia could occur only in the presence of intact BLA.