Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0020175 (hunger)
5,670 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Although a high prevalence of overweight is present in elderly people, the main concern in the elderly is the reported decline in food intake and the loss of the motivation to eat. This suggests the presence of problems associated with the regulation of energy balance and the control of food intake. A reduced energy intake causing body weight loss may be caused by social or physiological factors, or a combination of both. Poverty, loneliness, and social isolation are the predominant social factors that contribute to decreased food intake in the elderly. Depression, often associated with loss or deterioration of social networks, is a common psychological problem in the elderly and a significant cause of loss of appetite. The reduction in food intake may be due to the reduced drive to eat (hunger) resulting from a lower need state, or it arises because of more rapidly acting or more potent inhibitory (satiety) signals. The early satiation appears to be predominantly due to a decrease in adaptive relaxation of the stomach fundus resulting in early antral filling, while increased levels and effectiveness of cholecystokinin play a role in the anorexia of aging. The central feeding drive (both the opioid and the neuropeptide Y effects) appears to decline with age. Physical factors such as poor dentition and ill-fitting dentures or age-associated changes in taste and smell may influence food choice and limit the type and quantity of food eaten in older people. Common medical conditions in the elderly such as gastrointestinal disease, malabsorption syndromes, acute and chronic infections, and hypermetabolism often cause anorexia, micronutrient deficiencies, and increased energy and protein requirements. Furthermore, the elderly are major users of prescription medications, a number of which can cause malabsorption of nutrients, gastrointestinal symptoms, and loss of appetite. There is now good evidence that, although age-related reduction in energy intake is largely a physiologic effect of healthy aging, it may predispose to the harmful anorectic effects of psychological, social, and physical problems that become increasingly frequent with aging. Poor nutritional status has been implicated in the development and progression of chronic diseases commonly affecting the elderly. Protein-energy malnutrition is associated with impaired muscle function, decreased bone mass, immune dysfunction, anemia, reduced cognitive function, poor wound healing, delayed recovery from surgery, and ultimately increased morbidity and mortality. An increasing understanding of the factors that contribute to poor nutrition in the elderly should enable the development of appropriate preventive and treatment strategies and improve the health of older people.
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PMID:Eating habits and appetite control in the elderly: the anorexia of aging. 1283 2

Aging is associated with a reduction in appetite and food intake, predisposing to protein-energy malnutrition. The causes of this "anorexia of aging" are largely unknown. To investigate possible contributions of enhanced satiating effects of cholecystokinin (CCK) and reduced stimulation of food intake by ghrelin, eight undernourished older women [age, 80.4 +/- 2.6 yr; body mass index (BMI), 16.9 +/- 0.57 kg/m(2)], eight well-nourished older women (age, 77 +/- 0.9 yr; BMI, 23.7 +/- 0.8 kg/m(2)), and eight well-nourished young women (age, 22 +/- 1.3 yr; BMI, 20.5 +/- 0.4 kg/m(2)), in randomized order, ate on 1 d a 280-kCal preload and on the other no preload, 90 min before an ad libitum meal. At baseline the undernourished, but not the well-nourished, older subjects were less hungry (P < 0.05) than young subjects. Before and after the preload, plasma CCK levels were higher (P < 0.05) in the older than young subjects, with no difference between the older groups. Plasma ghrelin concentrations were higher in the undernourished than both well-nourished groups and decreased similarly after the preload in all groups. The preload suppressed food intake in the well-nourished older and young subjects (P < 0.05), but was without effect in the undernourished old. These observations suggest that reduced basal hunger, rather than increased meal-induced satiety, contributes to the anorexia of aging and that changes in CCK and ghrelin are unlikely to be responsible.
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PMID:Appetite, food intake, and plasma concentrations of cholecystokinin, ghrelin, and other gastrointestinal hormones in undernourished older women and well-nourished young and older women. 1291 64

The stimulation of exocrine pancreatic secretion that has been attributed by Pavlov exclusively to various reflexes (nervism), was then found that it depend also on numerous enterohormones, especially cholecystokinin (CCK) and secretin, released by duodeno-jejunal mucosa and originally believed to act via an endocrine pathway. Recently, CCK and other enterohormones were found to stimulate the pancreas by excitation of sensory nerves and triggering vago-vagal and entero-pancreatic reflexes. Numerous neurotransmitters and neuropeptides released by enteric nervous system (ENS) of gut and pancreas have been also implicated in the regulation of exocrine pancreas. This article was designed to review the contribution of vagal nerves and entero-hormones, especially CCK and other enterohormones, involved in the control of appetitive behavior such as leptin and ghrelin and pancreatic polypeptide family (peptide YY and neuropeptide Y). Basal secretion shows periodic fluctuations with peals controlled by ENS and by motilin and Ach. Plasma ghrelin, that is considered as hunger hormone, increases under basal conditions, while plasma leptin falls to the lowest level. Postprandial pancreatic secretion, classically divided into cephalic, gastric and intestinal phases, involves predominantly CCK, which under physiological conditions acts almost entirely by activation of vago-vagal reflexes to stimulate the exocrine pancreas, being accompanied by the fall in plasma ghrelin and increase of plasma leptin, reflecting feeding behavior. We conclude that the major role in postprandial pancreatic secretion is played by vagus and gastrin in cephalic and gastric phases and by vagus in conjunction with CCK and secretin in intestinal phase. PP, PYY somatostatin, leptin and ghrelin that affect food intake appear to participate in the feedback control of postprandial pancreatic secretion via hypothalamic centers.
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PMID:Brain-gut axis in pancreatic secretion and appetite control. 1456 70

The discovery of the adiposity signal leptin a decade ago revolutionised our understanding of the hypothalamic mechanisms underpinning the central control of ingestive behaviour. Subsequently, the structure and function of various hypothalamic peptide systems (Neuropeptide Y (NPY), Orexins, Melanocortins, Cocaine and Amphetamine Regulating Transcript (CART), Galanin/Galanin Like Peptides (GALP) and endocannabinoids) have been characterised in detail in rodent models. The therapeutic benefit of targeting these systems remains to be discovered. More is becoming known about the pharmacological potential of peripheral, meal-induced, episodic endogenous peptides. Hormones such as Cholecystokinin (CCK), Gastrin Releasing Peptides (GRP), Glucagon-Like Peptide I (GLP-1) Enterostatin, Amylin, Peptide YY (PYY) and Ghrelin are released prior to, during and/or after a meal, controlling intake and subjective feelings of appetite (hunger and satiety). In addition, there is an expanding body of literature detailing the effects of a wide variety of drugs on human appetite and food intake. Some of these drugs act upon CNS monoamine systems such as Serotonin (5-HT). Dopamine (DA) and Noradrenaline (NA), have long been implicated in appetite regulation. Detailed examination of both the effect of agonising endogenous gut peptide systems and the effect of various monoaminergic drugs on the expression of human appetite can provide a greater understanding of mechanisms underpinning normal appetite regulation. However, such an understanding must be based on knowledge of the effect of the treatment on meal size, eating rate, meal pattern, food choice and the subjective experience of appetite flux (hunger and satiety), and notjust food intake.
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PMID:The pharmacology of human appetite expression. 1505 9

This review's objective is to give a critical summary of studies that focused on physiologic measures relating to subjectively rated appetite, actual food intake, or both. Biomarkers of satiation and satiety may be used as a tool for assessing the satiating efficiency of foods and for understanding the regulation of food intake and energy balance. We made a distinction between biomarkers of satiation or meal termination and those of meal initiation related to satiety and between markers in the brain [central nervous system (CNS)] and those related to signals from the periphery to the CNS. Various studies showed that physicochemical measures related to stomach distension and blood concentrations of cholecystokinin and glucagon-like peptide 1 are peripheral biomarkers associated with meal termination. CNS biomarkers related to meal termination identified by functional magnetic resonance imaging and positron emission tomography are indicators of neural activity related to sensory-specific satiety. These measures cannot yet serve as a tool for assessing the satiating effect of foods, because they are not yet feasible. CNS biomarkers related to satiety are not yet specific enough to serve as biomarkers, although they can distinguish between extreme hunger and fullness. Three currently available biomarkers for satiety are decreases in blood glucose in the short term (<5 min), which have been shown to be involved in meal initiation; leptin changes during longer-term (>2-4 d) negative energy balance; and ghrelin concentrations, which have been implicated in both short-term and long-term energy balance. The next challenge in this research area is to identify food ingredients that have an effect on biomarkers of satiation, satiety, or both. These ingredients may help consumers to maintain their energy intake at a level consistent with a healthy body weight.
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PMID:Biomarkers of satiation and satiety. 1515 23

The peripheral physiological and central nervous mechanisms contributing to the control of eating present formidable challenges to experimental analysis. One of the most productive approaches to these challenges has been endocrinological. This review introduces the endocrine control of eating by considering three hormonal signals that have been hypothesized to control hunger or satiation, cholecystokinin CCK, leptin, and ghrelin. The roles of these molecules in humans and in rodents are considered against a set of criteria established in classical endocrinology for establishing physiological endocrine action. It is concluded that according to these criteria, CCK's satiating action in humans is the best-established physiological endocrine action. In contrast, support for endocrine actions of leptin in satiation and of ghrelin in hunger is incomplete, and areas urgently requiring further research are identified. Finally, a review of work on these three hormones suggests the utility of a new conceptual scheme for understanding the endocrine control of eating. This scheme distinguishes between endocrine, in which the stimuli for hormonal secretion and the effect of secretion on eating are tightly coupled, and endocrine effects, in which one or both of these links is uncoupled. The implications of this concept for research design and interpretation of data are discussed. A vast literature links endocrine systems to the control of eating behavior [Geary, N. Hunger and satiation. In: Martini, L., ed. Encyclopedia of endocrine diseases. San Diego, CA: Academic Press, 2004, in press.]. This is fortunate for ingestive science. Endocrinology is a well-developed discipline with an impressive armamentarium of intellectual and technical tools. In contrast, ingestive science, i.e., the study of eating, drinking, and drug use, is at a more rudimentary stage of development. My general thesis here is that the adaptation and application of some of the well-accepted intellectual tools of endocrinology is likely to accelerate progress in ingestive science. The organization of the review is threefold. First, the treatment of endocrine controls of eating is selective. Just three hormones, CCK, leptin, and ghrelin, are considered. It is not clear that these are the three most important endocrine controls of eating, but they are each certainly interesting candidates, and comparisons among them are instructive. Second, I argue for the utility of the application of classical endocrine criteria for the identification of physiological effects of hormones, as adapted to eating behavior. This is done by introducing these criteria, considering each hormone's status with respect to them, and identifying the areas where relevant evidence is currently available or is lacking. Third, I argue for the utility of making explicit the distinction between endocrine actions, in which the stimuli for hormonal secretion and the effect of secretion on eating are tightly coupled, and endocrine actions, in which these links are uncoupled. This concept is assembled inductively in the course of the review.
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PMID:Endocrine controls of eating: CCK, leptin, and ghrelin. 1523 77

The worldwide increase in the incidence of obesity is a consequence of a positive energy balance, with energy intake exceeding expenditure. The signalling systems that underlie appetite control are complex, and the present review highlights our current understanding of key components of these systems. The pattern of eating in obesity ranges from over-eating associated with binge-eating disorder to the absence of binge-eating. The present review also examines evidence of defects in signalling that differentiate these sub-types. The signalling network underlying hunger, satiety and metabolic status includes the hormonal signals leptin and insulin from energy stores, and cholecystokinin, glucagon-like peptide-1, ghrelin and peptide YY3-36 from the gastrointestinal tract, as well as neuronal influences via the vagus nerve from the digestive tract. This information is routed to specific nuclei of the hypothalamus and brain stem, such as the arcuate nucleus and the solitary tract nucleus respectively, which in turn activate distinct neuronal networks. Of the numerous neuropeptides in the brain, neuropeptide Y, agouti gene-related peptide and orexin stimulate appetite, while melanocortins and alpha-melanocortin-stimulating hormone are involved in satiety. Of the many gastrointestinal peptides, ghrelin is the only appetite-stimulating hormone, whereas cholecystokinin, glucagon-like peptide-1 and peptide YY3-36 promote satiety. Adipose tissue provides signals about energy storage levels to the brain through leptin, adiponectin and resistin. Binge-eating has been related to a dysfunction in the ghrelin signalling system. Moreover, changes in gastric capacity are observed, and as gastric capacity is increased, so satiety signals arising from gastric and post-gastric cues are reduced. Understanding the host of neuropeptides and peptide hormones through which hunger and satiety operate should lead to novel therapeutic approaches for obesity; potential therapeutic strategies are highlighted.
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PMID:Peripheral and central signals in the control of eating in normal, obese and binge-eating human subjects. 1538 23

Peptide YY (PYY), an anorectic peptide, is secreted postprandially from the distal gastrointestinal tract. PYY(3-36), the major form of circulating PYY, binds to the hypothalamic neuropeptide Y Y2 receptor (Y2-R) with a high-affinity, reducing food intake in rodents and humans. Additional gastrointestinal hormones involved in feeding, including cholecystokinin, glucagon-like peptide 1, and ghrelin, transmit satiety or hunger signals to the brain via the vagal afferent nerve and/or the blood stream. Here we determined the role of the afferent vagus nerve in PYY function. Abdominal vagotomy abolished the anorectic effect of PYY(3-36) in rats. Peripheral administration of PYY(3-36) induced Fos expression in the arcuate nucleus of sham-operated rats but not vagotomized rats. We showed that Y2-R is synthesized in the rat nodose ganglion and transported to the vagal afferent terminals. PYY(3-36) stimulated firing of the gastric vagal afferent nerve when administered iv. Considering that Y2-R is present in the vagal afferent fibers, PYY(3-36) could directly alter the firing rate of the vagal afferent nerve via Y2-R. We also investigated the effect of ascending fibers from the nucleus of the solitary tract on the transmission of PYY(3-36)-mediated satiety signals. In rats, bilateral midbrain transections rostral to the nucleus of the solitary tract also abolished PYY(3-36)-induced reductions in feeding. This study indicates that peripheral PYY(3-36) may transmit satiety signals to the brain in part via the vagal afferent pathway.
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PMID:The role of the vagal nerve in peripheral PYY3-36-induced feeding reduction in rats. 1571 79

Ghrelin is an enteric peptide that is the only known circulating appetite stimulant. This feature of the hormone has garnered widespread attention, as reflected by more than 1000 scientific papers featuring ghrelin that have been published since the first reports of its orexigenic actions, approximately four years ago. In this review, we discuss data that support roles for ghrelin in the short-term regulation of pre-meal hunger and meal initiation, functioning as a unique orexigenic counterpart to short-acting gastrointestinal satiation factors, such as cholecystokinin (CCK). We also highlight evidence indicating that ghrelin satisfies recognized criteria to be viewed as a participant in long-term body-weight regulation--a potential anabolic counterpart to the traditional adiposity hormones, leptin and insulin. We then discuss the following controversial questions in ghrelin research and offer our opinions regarding these debates. (1) Is ghrelin synthesized within the brain? (2) How does ghrelin increase food intake? (3) Does des-acyl ghrelin have a physiologic function? (4) Are there receptors for ghrelin other than GHS-R1a? (5) Does ghrelin regulate insulin secretion? (6) Does ghrelin regulate gastrointestinal motility? (7) Can ghrelin or ghrelin-receptor agonists be used to treat wasting conditions? Finally, we offer a speculative model of ghrelin as a thrifty gene product that evolved to help animals consume and store fat well, thereby increasing their chances of survival during times of famine. We suggest that ghrelin is a "saginary" hormone, from the Latin, saginare, which means, "to fatten".
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PMID:Ghrelin and energy balance: focus on current controversies. 1577 86

Obesity, a condition already at epidemic proportions in the developed world, is largely attributable to an indulgent lifestyle. Biologically we feel hunger more acutely than feeling "full-up" (satiety). The discovery over a decade ago of leptin, an adiposity signal, revolutionised our understanding of hypothalamic mechanisms underpinning the central control of ingestive behaviour. The structure and function of many hypothalamic peptides (Neuropeptide Y (NPY), Melanocortins, Agouti related peptide (AGRP), Cocaine and amphetamine regulated transcript (CART), Melanin concentrating hormone (MCH), Orexins and endocannabinoids) have been characterised in rodent models. The pharmacological potential of several endogenous peripheral peptides released prior to, during and/or after feeding are being explored. Short-term signal hormones including Cholecystokinin (CCK), Ghrelin, Peptide YY (PYY(3-36)) and Glucagon-like peptide 1 (GLP-1) control meal size via pathways converging on the hypothalamus. Long-term regulation is provided by the main circulating hormones leptin and insulin. These systems among others, implicated in hypothalamic appetite regulation all provide potential "drugable" targets by which to treat obesity.
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PMID:The hypothalamus and obesity. 1577 92


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