corticosterone and Obesity studies

Obesity: A status with BODY WEIGHT that is grossly above the recommended standards, usually due to accumulation of excess FATS in the body. The standards may vary with age, sex, genetic or cultural background. In the BODY MASS INDEX, a BMI greater than 30.0 kg/m2 is considered obese, and a BMI greater than 40.0 kg/m2 is considered morbidly obese (MORBID OBESITY).

Research Excerpts

Excerpt	Relevance	Reference
"Male rats of SL-water group presented on PND88: glucose intolerance, higher adiposity, plasma triglycerides, free fatty acids, total and low-density lipoprotein (LDL) cholesterol and corticosterone."	8.12	Lactation overnutrition-induced obesity impairs effects of exogenous corticosterone on energy homeostasis and hypothalamic-pituitary-adrenal axis in male rats. ( de Andrade, FG; de Souza, CF; Leite, CM; Lopes, GM; Martins, AB; Stopa, LRS; Uchoa, ET; Wunderlich, ALM; Zaia, CTBV; Zaia, DAM, 2022)
"Therefore ARC corticosterone, regulated by 11βHSD1, may play a role in food intake and body weight regulation."	7.96	Effects of corticosterone within the hypothalamic arcuate nucleus on food intake and body weight in male rats. ( Buckley, NW; Cai, M; Cheetham, S; Counsell, JR; Dhillo, WS; Farooq, G; Fernandes-Freitas, I; Gardiner, J; Izzi-Engbeaya, C; Ma, Y; Mirza, Z; Murphy, K; Norton, M; Ratnasabapathy, R; Richardson, E; Seckl, J, 2020)
" However, in VAT, GCs induce DNL, higher palmitic acid (PA), macrophage infiltration, and proinflammatory cytokine levels, accompanied by systemic nonesterified fatty acid (NEFA) elevation, hyperinsulinemia, and higher homeostatic model assessment for insulin resistance (HOMA-IR) levels compared with diet-induced obesity."	7.96	Long-term hypercortisolism induces lipogenesis promoting palmitic acid accumulation and inflammation in visceral adipose tissue compared with HFD-induced obesity. ( García-Eguren, G; Giró, O; Hanzu, FA; Sala-Vila, A; Vega-Beyhart, A, 2020)
"MCF7 breast cancer cells were incubated with increasing concentrations of corticosterone (CORT) to investigate the direct effects."	7.81	The direct and indirect effects of corticosterone and primary adipose tissue on MCF7 breast cancer cell cycle progression. ( Connor, MK; Riddell, MC; Shpilberg, Y, 2015)
" This study assessed the effects of the association between obesity and chronic stress on the temporal pattern of serum levels of adipogenic markers and corticosterone in rats."	7.80	Obesity and chronic stress are able to desynchronize the temporal pattern of serum levels of leptin and triglycerides. ( Caumo, W; Cioato, SG; de Macedo, IC; de Oliveira, C; de Oliveira, CM; de Souza, A; Marques Filho, PR; Medeiros, LF; Scarabelot, VL; Torres, IL, 2014)
"Although food-dependent energy intake was increased by telmisartan and telmisartan + ramipril compared with ramipril or controls, body weight gain, abundance of fat and plasma leptin levels were decreased."	7.78	Double blockade of angiotensin II (AT(1) )-receptors and ACE does not improve weight gain and glucose homeostasis better than single-drug treatments in obese rats. ( Jöhren, O; Miesel, A; Müller-Fielitz, H; Raasch, W; Vogt, FM, 2012)
" We recently developed a lentivirus (LV) vector that produces an insulin receptor (IR) antisense RNA sequence (IRAS) that when injected into the hypothalamus selectively decreases IR signaling in hypothalamus, resulting in increased body weight, peripheral adiposity and plasma leptin levels."	7.77	Obesity/hyperleptinemic phenotype adversely affects hippocampal plasticity: effects of dietary restriction. ( Evans, AN; Grillo, CA; Macht, VA; Mott, DD; Piroli, GG; Reagan, LP; Sakai, RR; Scott, KA; Wilson, SP, 2011)
"Chronic leptin treatment in diet-induced obese rats accelerates dietary obesity."	7.74	Synergy between leptin therapy and a seemingly negligible amount of voluntary wheel running prevents progression of dietary obesity in leptin-resistant rats. ( Cheng, KY; Matheny, M; Rogrigues, E; Scarpace, PJ; Shapiro, A; Tümer, N; Zhang, Y; Zolotukhin, S, 2008)
"Neuropeptide Y (NPY) stimulates feeding and weight gain, but deletion of the NPY gene does not affect food intake and body weight in mice bred on a mixed genetic background."	7.73	Neuropeptide Y deficiency attenuates responses to fasting and high-fat diet in obesity-prone mice. ( Ahima, RS; Elmquist, JK; Hawkins, EJ; Hileman, SM; Imai, Y; Patel, HR; Qi, Y, 2006)
" Oral administration of the Y1 antagonist (30 and 100 mg x kg(-1), once daily for 2 weeks) significantly suppressed the daily food intake and body weight gain in Zucker fatty rats accompanied with a reduction of fat cell size and plasma corticosterone levels."	7.71	Blockade of body weight gain and plasma corticosterone levels in Zucker fatty rats using an orally active neuropeptide Y Y1 antagonist. ( Fukami, T; Fukuroda, T; Gomori, A; Hata, M; Hidaka, M; Ihara, M; Ishihara, A; Ishii, Y; Kanatani, A; Kanesaka, M; Kanno, T; Kobayashi, M; Mashiko, S; Murai, T; Okada, M; Sato, NA; Tanaka, T; Tominaga, Y; Watanabe, K, 2002)
" The infusion abolished endogenous corticosterone output and produced hyperinsulinemia, hypertriglyceridemia, and hyperleptinemia, three salient abnormalities of obesity syndromes."	7.70	Induction of obesity and hyperleptinemia by central glucocorticoid infusion in the rat. ( Boss, O; Cusin, I; Jeanrenaud, B; Ricquier, D; Rohner-Jeanrenaud, F; Stricker-Krongrad, A; Zakrzewska, KE, 1999)
"To investigate whether chronic administration of the long-acting glucagon-like peptide-1 receptor agonist exendin-4 can elicit sustained reductions in food intake and body weight and whether its actions require an intact leptin system."	7.70	Central exendin-4 infusion reduces body weight without altering plasma leptin in (fa/fa) Zucker rats. ( Al-Barazanji, KA; Arch, JR; Buckingham, RE; Tadayyon, M, 2000)
"Neuropeptide Y (NPY) in the hypothalamus plays an important role in the regulation of food intake and body weight and seems to be implicated in the etiology of obesity."	7.69	Adrenalectomy prevents the obesity syndrome produced by chronic central neuropeptide Y infusion in normal rats. ( Cusin, I; Jeanrenaud, B; Rohner-Jeanrenaud, F; Sainsbury, A, 1997)
"We have investigated the possible involvement of endogenous corticosteroids in the maintenance of hypertension in aged lean and obese Zucker rats using the type II corticosteroid antagonist mifepristone."	7.69	Effects of the glucocorticoid II receptor antagonist mifepristone on hypertension in the obese Zucker rat. ( Clapham, JC; Turner, NC, 1997)
"The lethal yellow (AY/a) mouse has a defect in proopiomelanocortin (POMC) signaling in the brain that leads to obesity, and is resistant to the anorexigenic effects of the hormone leptin."	7.69	Independent and additive effects of central POMC and leptin pathways on murine obesity. ( Blaydon, KM; Boston, BA; Cone, RD; Varnerin, J, 1997)
"The effect of mifepristone (RU 486), a blocker of type II glucocorticoid receptors on the development of obesity that follows the feeding of a high-fat (HF) diet to Osborne-Mendel (OM) rats, has been investigated."	7.68	Mifepristone (RU 486), a blocker of type II glucocorticoid and progestin receptors, reverses a dietary form of obesity. ( Bray, GA; Okada, S; York, DA, 1992)
" NPY injected into the paraventricular nucleus and other regions causes hyperphagia, obesity, and increased secretion of insulin, glucagon, ACTH, and corticosterone."	7.68	Altered neuropeptide Y concentrations in specific hypothalamic regions of obese (fa/fa) Zucker rats. Possible relationship to obesity and neuroendocrine disturbances. ( Cotton, SJ; Holloway, B; Mayers, R; McCarthy, HD; McKibbin, PE; McMillan, S; Williams, G, 1991)
"Hair corticosterone was higher in HF mice than in CON (P<0."	5.91	High fat diet induces obesity, alters eating pattern and disrupts corticosterone circadian rhythms in female ICR mice. ( Casey, T; Fernández-Juricic, E; Gonzalez, M; Han-Hallett, Y; Rajput, P; Teeple, K, 2023)
"Corticosterone (CORT) was administered to mice for 8 weeks."	5.72	Corticosterone induces obesity partly ( Cao, L; Li, S; Li, T; Li, Y; Lu, J; Wang, G; Xu, T; Zhang, M, 2022)
"Obesity is a disease that has become a serious public health issue worldwide, and chronic stressors, which are a problem for modern society, cause neuroendocrine changes with alterations in food intake."	5.38	Cafeteria diet-induced obesity plus chronic stress alter serum leptin levels. ( Caumo, W; Cioato, SG; Macedo, IC; Medeiros, LF; Oliveira, C; Oliveira, CM; Rozisky, JR; Santos, VS; Scarabelot, VL; Silva, FR; Souza, A; Torres, IL, 2012)
"Leptin is a member of the IL-6 cytokine family and is primarily produced by adipose tissue."	5.35	Leptin acts in the periphery to protect thymocytes from glucocorticoid-mediated apoptosis in the absence of weight loss. ( Roberts, MR; Trotter-Mayo, RN, 2008)
"Obesity is an increasing socio-economic health problem."	5.35	Diet-induced obesity alters behavior as well as serum levels of corticosterone in F344 rats. ( Behrendt, P; Bode, FJ; Brabant, G; Buchenauer, T; Horn, R; Nave, H; Stephan, M, 2009)
"Leptin treatment of ob/ob mice markedly increased hepatic 11beta-HSD1 activity and mRNA expression."	5.32	Leptin activation of corticosterone production in hepatocytes may contribute to the reversal of obesity and hyperglycemia in leptin-deficient ob/ob mice. ( Friedman, TC; Li, R; Li, X; Liu, Y; Nakagawa, Y; Ohzeki, T; Wang, Y, 2003)
"Neuropeptide Y (NPY) is a powerful orexigenic neurotransmitter."	5.32	Chronic neuropeptide Y infusion into the lateral ventricle induces sustained feeding and obesity in mice lacking either Npy1r or Npy5r expression. ( Aubert, ML; Palmiter, RD; Pedrazzini, T; Raposinho, PD; White, RB, 2004)
"Male rats of SL-water group presented on PND88: glucose intolerance, higher adiposity, plasma triglycerides, free fatty acids, total and low-density lipoprotein (LDL) cholesterol and corticosterone."	4.12	Lactation overnutrition-induced obesity impairs effects of exogenous corticosterone on energy homeostasis and hypothalamic-pituitary-adrenal axis in male rats. ( de Andrade, FG; de Souza, CF; Leite, CM; Lopes, GM; Martins, AB; Stopa, LRS; Uchoa, ET; Wunderlich, ALM; Zaia, CTBV; Zaia, DAM, 2022)
" Metformin is shown to lower body weight and adiposity, but the underlying mechanism is unclear."	4.02	Metformin effectively restores the HPA axis function in diet-induced obese rats. ( Balasubramanian, P; Herdt, TH; MohanKumar, PS; MohanKumar, SMJ; Shin, AC; Suryadevara, P; Zyskowski, J, 2021)
"Carbonyl reductase 1 (Cbr1), a recently discovered contributor to tissue glucocorticoid metabolism converting corticosterone to 20β-dihydrocorticosterone (20β-DHB), is upregulated in adipose tissue of obese humans and mice and may contribute to cardiometabolic complications of obesity."	4.02	Carbonyl reductase 1 amplifies glucocorticoid action in adipose tissue and impairs glucose tolerance in lean mice. ( Allan, E; Beck, KR; Bell, RMB; Coutts, A; Denham, SG; Fawkes, A; Homer, NZM; Houtman, R; Koerner, MV; Lee, P; Meijer, OC; Miguelez-Crespo, A; Morgan, RA; Murphy, L; Nixon, M; Odermatt, A; Sharp, MGF; Villalobos, E; Walker, BR, 2021)
"Obesity and mild unmedicated metabolic risk factors alter the circulating steroid profile and bias the estimation of reference limits for testosterone, dihydrotestosterone, cortisol and corticosterone."	3.96	Impact of age, body weight and metabolic risk factors on steroid reference intervals in men. ( Baccini, M; Di Dalmazi, G; Fanelli, F; Fazzini, A; Gambineri, A; Mezzullo, M; Pagotto, U; Pelusi, C; Repaci, A; Vicennati, V, 2020)
"Therefore ARC corticosterone, regulated by 11βHSD1, may play a role in food intake and body weight regulation."	3.96	Effects of corticosterone within the hypothalamic arcuate nucleus on food intake and body weight in male rats. ( Buckley, NW; Cai, M; Cheetham, S; Counsell, JR; Dhillo, WS; Farooq, G; Fernandes-Freitas, I; Gardiner, J; Izzi-Engbeaya, C; Ma, Y; Mirza, Z; Murphy, K; Norton, M; Ratnasabapathy, R; Richardson, E; Seckl, J, 2020)
" However, in VAT, GCs induce DNL, higher palmitic acid (PA), macrophage infiltration, and proinflammatory cytokine levels, accompanied by systemic nonesterified fatty acid (NEFA) elevation, hyperinsulinemia, and higher homeostatic model assessment for insulin resistance (HOMA-IR) levels compared with diet-induced obesity."	3.96	Long-term hypercortisolism induces lipogenesis promoting palmitic acid accumulation and inflammation in visceral adipose tissue compared with HFD-induced obesity. ( García-Eguren, G; Giró, O; Hanzu, FA; Sala-Vila, A; Vega-Beyhart, A, 2020)
" Here we reported that long-term corticosterone (CORT) exposure in mice induced weight gain, dyslipidemia as well as hyperglycaemia and systemic insulin resistance."	3.91	Glucocorticoid-induced insulin resistance is related to macrophage visceral adipose tissue infiltration. ( Bruno, F; Do, TTH; Guillaume, D; Héloïse, D; Marie, G; Marion, B; Marthe, M, 2019)
" A murine model of corticosterone treatment resulted in increased hypothalamic expression of the melanocortin antagonist AgRP in parallel with obesity and hyperglycemia."	3.91	Metabolic Abnormalities of Chronic High-Dose Glucocorticoids Are Not Mediated by Hypothalamic AgRP in Male Mice. ( Adamson, A; Allen, TJ; Coll, AP; Davies, A; Harno, E; Humphreys, N; Sefton, C; Shoop, R; White, A; Wray, JR, 2019)
"Chronic corticosterone treatment led to insulin resistance, fasting hyperinsulinaemia, increased adiposity and dyslipidaemia in male, but not female mice."	3.91	Androgens sensitise mice to glucocorticoid-induced insulin resistance and fat accumulation. ( Cavanagh, LL; Gasparini, SJ; Henneicke, H; Kim, S; Seibel, MJ; Swarbrick, MM; Thai, LJ; Tu, J; Weber, MC; Zhou, H, 2019)
" In a mouse model for diet-induced obesity, rhythmicity of circulating corticosterone levels was disturbed."	3.88	Selective Glucocorticoid Receptor Antagonist CORT125281 Activates Brown Adipose Tissue and Alters Lipid Distribution in Male Mice. ( Hunt, H; Koorneef, LL; Kroon, J; Meijer, OC; Mol, IM; Rensen, PCN; Sips, HCM; van de Velde, NM; van den Heuvel, JK; Verzijl, CRC, 2018)
"Both treatments induced obesity but only Ob-MSG showed altered behavioral parameters, which is related to increased concentration of corticosterone and hypothalamic ERK1 and 2 activation."	3.85	Altered behavior of adult obese rats by monosodium l-glutamate neonatal treatment is related to hypercorticosteronemia and activation of hypothalamic ERK1 and ERK2. ( Andreazzi, AE; de Caires Júnior, LC; de Freitas Mathias, PC; Gonçalves, CF; González Garcia, RM; Guimarães, ED; Macedo de Almeida, M; Mourao-Júnior, CA; Musso, CM; Paes, ST; Pettersen, KG; Torrezan, R, 2017)
" Nine-month-old HF male offspring was normoglycemic but showed mild glucose intolerance, hyperinsulinemia, and hypercorticosteronemia."	3.83	Depot- and sex-specific effects of maternal obesity in offspring's adipose tissue. ( Breton, C; Deracinois, B; Eberlé, D; Gabory, A; Guinez, C; Junien, C; Laborie, C; Lecoutre, S; Lesage, J; Panchenko, PE; Vieau, D, 2016)
" Using a mouse model of excess corticosterone exposure, we found that the ability of glucocorticoids to increase adiposity, weight gain, hormonal dysregulation, hepatic steatosis, and dyslipidemia was reduced or reversed in mice lacking the cannabinoid CB1 receptor as well as mice treated with the global CB1 receptor antagonist AM251."	3.81	A peripheral endocannabinoid mechanism contributes to glucocorticoid-mediated metabolic syndrome. ( Bowles, NP; Hill, MN; Hillard, CJ; Karatsoreos, IN; Kunos, G; Li, X; Li, Z; Makriyannis, AM; McEwen, BS; Schwartz, GJ; Tamashiro, KL; Vemuri, VK; Wood, JA, 2015)
"MCF7 breast cancer cells were incubated with increasing concentrations of corticosterone (CORT) to investigate the direct effects."	3.81	The direct and indirect effects of corticosterone and primary adipose tissue on MCF7 breast cancer cell cycle progression. ( Connor, MK; Riddell, MC; Shpilberg, Y, 2015)
" We evaluated (1) the profile of basal circulating corticosterone across the life-course from weaning (postnatal day-PND 21), young adult PND 110, adult PND 450, mature adult PND 650 to aged phase PND 850 in a well-characterized homogeneous rat colony to determine existence of significant changes in trajectory in the second half of life; (2) sex differences; and (3) whether developmental programming of offspring by exposure to maternal obesity during development alters the later-life circulating corticosterone trajectory."	3.81	Aging, glucocorticoids and developmental programming. ( Nathanielsz, PW; Reyes-Castro, LA; Zambrano, E, 2015)
" This study assessed the effects of the association between obesity and chronic stress on the temporal pattern of serum levels of adipogenic markers and corticosterone in rats."	3.80	Obesity and chronic stress are able to desynchronize the temporal pattern of serum levels of leptin and triglycerides. ( Caumo, W; Cioato, SG; de Macedo, IC; de Oliveira, C; de Oliveira, CM; de Souza, A; Marques Filho, PR; Medeiros, LF; Scarabelot, VL; Torres, IL, 2014)
"Maternal phenotype during pregnancy and the end of lactation evidenced markedly elevated body fat and plasma corticosterone levels in HF dams."	3.80	Maternal obesity and high-fat diet program offspring metabolic syndrome. ( Beall, M; Desai, M; Han, G; Jellyman, JK; Lane, RH; Ross, MG, 2014)
"Hypothalamic inflammation is associated with insulin and leptin resistance, hyperphagia, and obesity."	3.79	Acute exercise suppresses hypothalamic PTP1B protein level and improves insulin and leptin signaling in obese rats. ( Carvalheira, JB; Chiarreotto-Ropelle, EC; Cintra, DE; de Souza, CT; Katashima, CK; Pauli, JR; Pauli, LS; Picardi, PK; Pimentel, GD; Prada, PO; Ropelle, ER; Silva, VR, 2013)
" At the end of the diet regimen, we assessed anxiety and depressive-like behaviour, corticosterone levels and biochemical changes in the midbrain and limbic brain regions."	3.79	Diet-induced obesity promotes depressive-like behaviour that is associated with neural adaptations in brain reward circuitry. ( Fulton, S; Sharma, S, 2013)
"Although food-dependent energy intake was increased by telmisartan and telmisartan + ramipril compared with ramipril or controls, body weight gain, abundance of fat and plasma leptin levels were decreased."	3.78	Double blockade of angiotensin II (AT(1) )-receptors and ACE does not improve weight gain and glucose homeostasis better than single-drug treatments in obese rats. ( Jöhren, O; Miesel, A; Müller-Fielitz, H; Raasch, W; Vogt, FM, 2012)
" Body weight remained elevated for more than 8 wk and was associated with elevated corticosterone and impaired glucose tolerance."	3.78	Hypothalamic Fkbp51 is induced by fasting, and elevated hypothalamic expression promotes obese phenotypes. ( Dunn-Meynell, A; Fan, X; Isoda, F; Janssen, W; Kleopoulos, SP; Levin, B; Mastaitis, J; McCrimmon, R; Mobbs, CV; Musatov, S; Sherwin, R; Yang, L; Yen, K, 2012)
" The main regulator of intracellular glucocorticoid levels are 11β-hydroxysteroid dehydrogenase type 1 (11β-HSD1), which converts inactive glucocorticoid into bioactive glucocorticoid such as cortisol in humans and corticosterone in rodents; therefore, the inhibition of 11β-HSD1 has considerable therapeutic potential for metabolic diseases including obesity and diabetes."	3.78	Benzofuran derivatives inhibit 11β-hydroxysteroid dehydrogenase type 1 activity in rat adipose tissue. ( Kiyonaga, D; Kobayashi, Y; Kogure, T; Miyata, O; Tagawa, N; Ueda, M; Wakabayashi, M; Yamaguchi, Y, 2012)
" Insulin resistance and glucose intolerance were determined along with tissue glycogen content."	3.78	Carbenoxolone treatment ameliorated metabolic syndrome in WNIN/Ob obese rats, but induced severe fat loss and glucose intolerance in lean rats. ( Acharya, V; Ayyalasomayajula, V; Koppala, SR; Nemani, H; Ponday, LR; Pothana, S; Prasad Sakamuri, SS; Prathipati, VK; Putcha, UK; Sukapaka, M; Veetill, GN, 2012)
" We recently developed a lentivirus (LV) vector that produces an insulin receptor (IR) antisense RNA sequence (IRAS) that when injected into the hypothalamus selectively decreases IR signaling in hypothalamus, resulting in increased body weight, peripheral adiposity and plasma leptin levels."	3.77	Obesity/hyperleptinemic phenotype adversely affects hippocampal plasticity: effects of dietary restriction. ( Evans, AN; Grillo, CA; Macht, VA; Mott, DD; Piroli, GG; Reagan, LP; Sakai, RR; Scott, KA; Wilson, SP, 2011)
"Body weight and food intake in pregnancy, lactation, and after weaning, plasma leptin, insulin, corticosterone and blood glucose concentrations on days 7, 13 and 18 of pregnancy, days 1, 10, 21 and 80 postpartum, glucose and insulin tolerance on pregnancy days 7 and 18 were measured in C57Bl/6J mice of a/a (normal metabolism) and A(y)/a genotypes."	3.76	Pregnancy and lactation have anti-obesity and anti-diabetic effects in A(y)/a mice. ( Bazhan, NM; Makarova, EN; Shevchenko, AY; Yakovleva, TV, 2010)
" In this study, we examined both short- (24 d) and long- (16 wk) term effects of early postnatal over- and underfeeding in rats on body weight, body composition, plasma hormones, adiposity markers, and hypothalamic neuropeptide Y content."	3.74	Early undernutrition leads to long-lasting reductions in body weight and adiposity whereas increased intake increases cardiac fibrosis in male rats. ( Burrell, LM; Cole, TJ; Dean, RG; Morris, MJ; Velkoska, E, 2008)
"Chronic leptin treatment in diet-induced obese rats accelerates dietary obesity."	3.74	Synergy between leptin therapy and a seemingly negligible amount of voluntary wheel running prevents progression of dietary obesity in leptin-resistant rats. ( Cheng, KY; Matheny, M; Rogrigues, E; Scarpace, PJ; Shapiro, A; Tümer, N; Zhang, Y; Zolotukhin, S, 2008)
"MSG rats developed increased adrenocortical function, hyperadiposity, hyperleptinemia, hyperinsulinemia and decreased peripheral insulin sensitivity."	3.73	Impact of transient correction of increased adrenocortical activity in hypothalamo-damaged, hyperadipose female rats. ( Camihort, G; Console, G; Gaillard, RC; Luna, G; Moreno, G; Perelló, M; Spinedi, E, 2006)
" To investigate the possible mechanisms of antipsychotic-induced metabolic effects, we studied the impact of chronic administration of a typical antipsychotic drug (haloperidol) and an atypical antipsychotic (risperidone) to male rats on food intake, body weight, adiposity, and the circulating concentrations of hormones and metabolites that can influence energy homeostasis."	3.73	Distinct endocrine effects of chronic haloperidol or risperidone administration in male rats. ( Dedova, I; Duffy, L; Herzog, H; Karl, T; Lee, NJ; Lin, EJ; Matsumoto, I; O'brien, E; Sainsbury, A; Slack, K, 2006)
"Neuropeptide Y (NPY) stimulates feeding and weight gain, but deletion of the NPY gene does not affect food intake and body weight in mice bred on a mixed genetic background."	3.73	Neuropeptide Y deficiency attenuates responses to fasting and high-fat diet in obesity-prone mice. ( Ahima, RS; Elmquist, JK; Hawkins, EJ; Hileman, SM; Imai, Y; Patel, HR; Qi, Y, 2006)
" Concomitant with neuroendocrine defects such as decreased linear growth and infertility with accompanying increased corticosterone levels, this CNS knockout recapitulates the unique phenotype of db/db and ob/ob obese models and distinguishes them from other genetic models of obesity."	3.72	Disruption of neural signal transducer and activator of transcription 3 causes obesity, diabetes, infertility, and thermal dysregulation. ( Fu, XY; Gao, Q; Horvath, TL; Morino, K; Neschen, S; Shulman, GI; Wolfgang, MJ, 2004)
" We investigated the effect of inhibition of 11beta-HSD with glycyrrhetinic acid (GE), an effective 11beta-HSD inhibitor, on body weight regulation in obese Zucker rats, which have a defect in the leptin receptor gene."	3.72	Different responsiveness in body weight and hepatic 11beta-hydroxysteroid dehydrogenase (11beta-HSD) type 1 mrna to 11beta-HSD inhibition by glycyrrhetinic acid treatment in obese and lean zucker rats. ( Fujisawa, Y; Li, RS; Nakagawa, Y; Nakanishi, T; Ohzeki, T, 2004)
"The higher CSF-to-serum leptin ratio in the S5B/P1 rats, the enhanced suppression of food intake and body weight with leptin injections, and the higher STAT-3 activity in these animals suggest that S5B/P1 rats are more sensitive to leptin than OM rats."	3.72	Effects of diet and time of the day on serum and CSF leptin levels in Osborne-Mendel and S5B/Pl rats. ( Bray, GA; Ishihara, Y; Kageyama, A; Kageyama, H; White, CL; York, DA, 2004)
" MTII delivered four times daily by intraperitoneal injection to C57BL/6J mice produced a dose-responsive effect on food intake, body weight, leptin, corticosterone, insulin, and free fatty acids."	3.71	Effects of acute and chronic administration of the melanocortin agonist MTII in mice with diet-induced obesity. ( Flier, JS; Mantzoros, CS; Moschos, S; Pierroz, DD; Ungsunan, L; Ziotopoulou, M, 2002)
" Oral administration of the Y1 antagonist (30 and 100 mg x kg(-1), once daily for 2 weeks) significantly suppressed the daily food intake and body weight gain in Zucker fatty rats accompanied with a reduction of fat cell size and plasma corticosterone levels."	3.71	Blockade of body weight gain and plasma corticosterone levels in Zucker fatty rats using an orally active neuropeptide Y Y1 antagonist. ( Fukami, T; Fukuroda, T; Gomori, A; Hata, M; Hidaka, M; Ihara, M; Ishihara, A; Ishii, Y; Kanatani, A; Kanesaka, M; Kanno, T; Kobayashi, M; Mashiko, S; Murai, T; Okada, M; Sato, NA; Tanaka, T; Tominaga, Y; Watanabe, K, 2002)
"Plasma leptin concentration is increased in hypertensive obese humans, but whether leptin contributes to the increased arterial pressure in obesity is not known."	3.70	Chronic leptin infusion increases arterial pressure. ( Brands, MW; Hall, JE; Shek, EW, 1998)
" These mice develop obesity that initially is due to decreased energy expenditure and later accompanied by hyperphagia despite increased levels of circulating leptin."	3.70	Severe leptin resistance in brown fat-deficient uncoupling protein promoter-driven diphtheria toxin A mice despite suppression of hypothalamic neuropeptide Y and circulating corticosterone concentrations. ( Flier, JS; Frederich, RC; Lowell, BB; Mantzoros, CS; Maratos-Flier, E; Qu, D, 1998)
"The present data indicate that testosterone plays a role in the development of obesity and NIDDM in young OLETF rats, but that changes of leptin production in white adipose tissue may not be important in the development of obesity in young OLETF rats."	3.70	Orchiectomy and response to testosterone in the development of obesity in young Otsuka-Long-Evans-Tokushima Fatty (OLETF) rats. ( Abe, Y; Ibuki, Y; Mori, M; Ohtani, KI; Sato, N; Shimizu, H; Takahashi, H; Tsuchiya, T; Uehara, Y, 1998)
" The infusion abolished endogenous corticosterone output and produced hyperinsulinemia, hypertriglyceridemia, and hyperleptinemia, three salient abnormalities of obesity syndromes."	3.70	Induction of obesity and hyperleptinemia by central glucocorticoid infusion in the rat. ( Boss, O; Cusin, I; Jeanrenaud, B; Ricquier, D; Rohner-Jeanrenaud, F; Stricker-Krongrad, A; Zakrzewska, KE, 1999)
" In both lean and obese rats, food deprivation led to a reduction in body weight that was accompanied by a reversible increase in plasma corticosterone levels."	3.70	Corticotropin-releasing hormone-binding protein in brain and pituitary of food-deprived obese (fa/fa) Zucker rats. ( Deshaies, Y; Picard, F; Richard, D; Timofeeva, E, 1999)
"To investigate whether chronic administration of the long-acting glucagon-like peptide-1 receptor agonist exendin-4 can elicit sustained reductions in food intake and body weight and whether its actions require an intact leptin system."	3.70	Central exendin-4 infusion reduces body weight without altering plasma leptin in (fa/fa) Zucker rats. ( Al-Barazanji, KA; Arch, JR; Buckingham, RE; Tadayyon, M, 2000)
" When administered to obese, hypercorticosteronemic Zucker rats, it causes a diminution of food intake and a reduction in their rate of weight gain."	3.69	The effect of DHEA given chronically to Zucker rats. ( Browne, E; Hilton, CW; Porter, JR; Svec, F; Wright, B, 1995)
"Neuropeptide Y (NPY) in the hypothalamus plays an important role in the regulation of food intake and body weight and seems to be implicated in the etiology of obesity."	3.69	Adrenalectomy prevents the obesity syndrome produced by chronic central neuropeptide Y infusion in normal rats. ( Cusin, I; Jeanrenaud, B; Rohner-Jeanrenaud, F; Sainsbury, A, 1997)
"The effect of fasting on hormonal and metabolic variables was evaluated in normal rats and in rats with obesity induced by neonatal treatment with monosodium glutamate (MSG)."	3.69	Hormonal and metabolic adaptations to fasting in monosodium glutamate-obese rats. ( Andrade, IS; do Nascimento, CM; Dolnikoff, MS; Hirata, AE; Ribeiro, EB, 1997)
"We have investigated the possible involvement of endogenous corticosteroids in the maintenance of hypertension in aged lean and obese Zucker rats using the type II corticosteroid antagonist mifepristone."	3.69	Effects of the glucocorticoid II receptor antagonist mifepristone on hypertension in the obese Zucker rat. ( Clapham, JC; Turner, NC, 1997)
"The lethal yellow (AY/a) mouse has a defect in proopiomelanocortin (POMC) signaling in the brain that leads to obesity, and is resistant to the anorexigenic effects of the hormone leptin."	3.69	Independent and additive effects of central POMC and leptin pathways on murine obesity. ( Blaydon, KM; Boston, BA; Cone, RD; Varnerin, J, 1997)
"We tested the hypothesis that hypercorticosteronemia causes the hypercholesterolemia in young developing "fatty" rats."	3.68	Is there a role for the adrenals in the development of hypercholesterolemia in Zucker fatty rats? ( Alarrayed, F; Hartman, AD; Porter, JR, 1992)
"The effect of mifepristone (RU 486), a blocker of type II glucocorticoid receptors on the development of obesity that follows the feeding of a high-fat (HF) diet to Osborne-Mendel (OM) rats, has been investigated."	3.68	Mifepristone (RU 486), a blocker of type II glucocorticoid and progestin receptors, reverses a dietary form of obesity. ( Bray, GA; Okada, S; York, DA, 1992)
" NPY injected into the paraventricular nucleus and other regions causes hyperphagia, obesity, and increased secretion of insulin, glucagon, ACTH, and corticosterone."	3.68	Altered neuropeptide Y concentrations in specific hypothalamic regions of obese (fa/fa) Zucker rats. Possible relationship to obesity and neuroendocrine disturbances. ( Cotton, SJ; Holloway, B; Mayers, R; McCarthy, HD; McKibbin, PE; McMillan, S; Williams, G, 1991)
"Whole brain concentrations of 3-hydroxybutyrate, glutamate and gamma-aminobutyric acid (GABA) have been measured in two strains of rats with differing susceptibility to obesity."	3.67	Brain 3-hydroxybutyrate, glutamate, and GABA in a rat model of dietary obesity. ( Bray, GA; Fisler, JS; Shimizu, H, 1989)
" To determine whether the return of hyperphagia was mediated by an action of the hormones on the central nervous system, food intake and body weight were monitored in anorexic GTG-treated obese adrenalectomized mice which received a single intracerebroventricular (icv) injection of very small amounts of adrenal glucocorticoids, including cortisone, corticosterone, and dexamethasone."	3.67	Central nervous system control of hyperphagia in hypothalamic obesity: dependence on adrenal glucocorticoids. ( Abrahamsen, S; Debons, AF; Tse, CS; Zurek, LD, 1986)
"Basal plasma levels of corticosterone and corticosteroid-binding globulin (CBG) have been investigated in Obese strain (OS) chickens afflicted with spontaneous autoimmune thyroiditis (SAT)."	3.67	Elevation of corticosteroid-binding globulin in obese strain (OS) chickens: possible implications for the disturbed immunoregulation and the development of spontaneous autoimmune thyroiditis. ( Fässler, R; Krömer, G; Schauenstein, K; Schwarz, S; Wick, G, 1986)
" The high corticosterone concentration in blood may account in part for development of obesity and other abnormalities in the ob/ob mouse."	3.67	Increased sensitivity of the genetically obese mouse to corticosterone. ( Himms-Hagen, J; Tokuyama, K, 1987)
"The contributions of insulin (IRI), glucagon (IRG), and corticosterone production to the glycemic changes associated with age and starvation were examined in 3 and 6 month old ob/ob and lean mice."	3.66	Starvation and age effects on glycoregulation and hormone levels of C57BL/6Job/ob mice. ( Cahn, PJ; Dubuc, PU; Ristimaki, S; Willis, PL, 1982)
"The relationship between obesity and influenza virus infection could be summarized by the following features: decreases in memory T-cell functionality and interferon (IFN)-α, IFN-β, and IFN-γ mRNA expression, increases in viral titer and infiltration, and impaired dendritic cell function in obese individuals."	2.49	Effect of adenovirus and influenza virus infection on obesity. ( Chun, SC; Hur, SJ; Kim, DH; Lee, SK, 2013)
"Obesity is associated with multiple alterations of the endocrine systems, including abnormal circulating blood hormone concentrations, due to changes in their pattern of secretion and/or metabolism, altered hormone transport, and/or action at the level of target tissues."	2.41	Adrenal and gonadal function in obesity. ( Gambineri, A; Pasquali, R; Vicennati, V, 2002)
"Although atherosclerosis was reduced in CD40AKO mice, plaques contained more activated T cells and larger necrotic cores."	1.91	Adipocytes control hematopoiesis and inflammation through CD40 signaling. ( Aarts, SABM; Atzler, D; Beckers, L; Bosmans, LA; Den Toom, M; Gijbels, MJJ; Kooijman, S; Lutgens, E; Poels, K; Reiche, ME; Rensen, PCN; Van Tiel, CM; Vos, WG; Weber, C, 2023)
" In line with this concept, chronic administration of a selective β3-AR agonist reproduced the beneficial metabolic effects of cold adaption during exposure to exogenous GCs."	1.91	Activation of β-adrenergic receptor signaling prevents glucocorticoid-induced obesity and adipose tissue dysfunction in male mice. ( Alexaki, VI; Baschant, U; Bornstein, SR; Dahl, A; Gado, M; Grafe, I; Heinrich, A; Henneicke, H; Hofbauer, LC; Perakakis, N; Rauner, M; Sameith, K; Swarbrick, MM; Wiedersich, D, 2023)
"Corticosterone levels were flattened by implanting mice with subcutaneous corticosterone-releasing pellets, resulting in constant circulating corticosterone levels."	1.62	A physiological glucocorticoid rhythm is an important regulator of brown adipose tissue function. ( Biermasz, NR; Fenzl, A; In Het Panhuis, W; Kiefer, FW; Kooijman, S; Koorneef, LL; Kroon, J; Meijer, OC; Mol, IM; Rensen, PCN; Schilperoort, M; Sips, HHCM; Tuckermann, JP; van den Berg, R; van den Heuvel, JK; van der Sluis, RJ; van Doeselaar, L; van Trigt, N; Verzijl, CRC; Vettorazzi, S, 2021)
"Overweight and obesity are a worldwide pandemic affecting billions of people."	1.51	Association of high-fat diet with neuroinflammation, anxiety-like defensive behavioral responses, and altered thermoregulatory responses in male rats. ( Abreu, AR; Campos, GSV; Chianca, DA; Chírico, MTT; De Menezes, RCA; Figueiredo, AB; Lima, PM; Lowry, CA; Noronha, SSR; Silva, FCS, 2019)
"In corticosterone-treated wild-type and UCP1 knockout mice housed at 30°C, obesity also develops to the same extent."	1.51	Glucocorticoid-Induced Obesity Develops Independently of UCP1. ( Boulet, N; Brooks, K; Cannon, B; Carlsson, B; Fischer, AW; Jaiprakash, A; Luijten, IHN; Nedergaard, J; Shabalina, IG, 2019)
" We hypothesized that surgically induced IUGR combined with an HFD would increase adiposity and glucocorticoids more than in non-IUGR offspring combined with the same HFD, findings that would persist despite weaning to a regular diet."	1.48	Intrauterine growth restriction combined with a maternal high-fat diet increased adiposity and serum corticosterone levels in adult rat offspring. ( Callaway, CW; McKnight, RA; Yu, B; Zinkhan, EK, 2018)
"Nonalcoholic fatty liver disease (NAFLD), a common prelude to cirrhosis and hepatocellular carcinoma, is the most common chronic liver disease worldwide."	1.46	Thermoneutral housing exacerbates nonalcoholic fatty liver disease in mice and allows for sex-independent disease modeling. ( Aronow, BJ; Cappelletti, M; Chan, CC; Divanovic, S; Giles, DA; Graspeuntner, S; Haslam, DB; Hogan, SP; Iwakura, Y; Kahn, CR; Karns, R; Karp, CL; Klarquist, J; Lawson, MJ; Moreno-Fernandez, ME; Mukherjee, R; Reynaud, D; Rupp, J; Shanmukhappa, SK; Sheridan, R; Sina, C; Softic, S; Stankiewicz, TE; Steinbrecher, KA; Stemmer, K; Sünderhauf, A; Wu, D, 2017)
"Weight gain was similar across the three diets while visceral fat mass was elevated by the two HFDs."	1.46	Saturated high-fat feeding independent of obesity alters hypothalamus-pituitary-adrenal axis function but not anxiety-like behaviour. ( Alquier, T; Daneault, C; Décarie-Spain, L; Fulton, S; Hryhorczuk, C; Rosiers, CD; Sharma, S, 2017)
"Obesity and type 2 diabetes have become a major public health problem worldwide."	1.46	Elevated Steroid Hormone Production in the db/db Mouse Model of Obesity and Type 2 Diabetes. ( Bornstein, SR; Brown, N; Brunssen, C; Eisenhofer, G; Frenzel, A; Hofmann, A; Jannasch, A; Mittag, J; Morawietz, H; Peitzsch, M; Weldon, SM, 2017)
"Obesity was established by cafeteria (CAF) feeding for 8 wk prior to mating and throughout pregnancy."	1.43	Obesity Disrupts the Rhythmic Profiles of Maternal and Fetal Progesterone in Rat Pregnancy. ( Clarke, MW; Crew, RC; Mark, PJ; Waddell, BJ, 2016)
" However, current glucocorticoid replacement regimes are inadequate because doses sufficient to suppress excess androgens almost invariably induce adverse metabolic effects."	1.43	ABCC1 confers tissue-specific sensitivity to cortisol versus corticosterone: A rationale for safer glucocorticoid replacement therapy. ( Andrew, R; Elfick, AP; Homer, NZ; Livingstone, DE; Mackenzie, SD; Mole, DJ; Morgan, RA; Mouras, R; Nixon, M; Reynolds, RM; Stimson, RH; Taylor, AI; Walker, BR, 2016)
"Obesity is a major risk factor for the development of type 2 diabetes and other debilitating diseases."	1.42	Changes in morphology and function of adrenal cortex in mice fed a high-fat diet. ( Bornstein, SR; Chavakis, T; Eaton, S; Eisenhofer, G; Lamounier-Zepter, V; Mateska, I; Peitzsch, M; Swierczynska, MM, 2015)
"Obesity is a chronic disease that has been associated with chronic stress and hypercaloric diet (HD) consumption."	1.42	Hypercaloric diet modulates effects of chronic stress: a behavioral and biometric study on rats. ( Caumo, W; de Macedo, IC; de Souza, IC; Filho, PR; Oliveira, Cd; Oliveira, CM; Quevedo, AS; Silva, FR; Torres, IL; Vercelino, R, 2015)
"Once obesity is established, DIO rats strongly defend their increased body weight against caloric restriction."	1.40	Regulation of expression of relaxin-3 and its receptor RXFP3 in the brain of diet-induced obese rats. ( Guèvremont, G; Lenglos, C; Mitra, A; Timofeeva, E, 2014)
"Behavioral modifications for the treatment of obesity, including caloric restriction, have notoriously low long-term success rates relative to bariatric weight-loss surgery."	1.40	Weight loss by calorie restriction versus bariatric surgery differentially regulates the hypothalamo-pituitary-adrenocortical axis in male rats. ( Benoit, SC; Egan, AE; Grayson, BE; Hakala-Finch, AP; Herman, JP; Kekulawala, M; Laub, H; Ressler, IB; Seeley, RJ; Ulrich-Lai, YM; Woods, SC, 2014)
"Nonalcoholic fatty liver disease (NAFLD) has been associated with glucocorticoid excess and androgen deficiency, yet in the majority of patients with steatohepatitis, circulating cortisol and androgen levels are normal."	1.39	Loss of 5α-reductase type 1 accelerates the development of hepatic steatosis but protects against hepatocellular carcinoma in male mice. ( Armstrong, MJ; Dowman, JK; Hopkins, LJ; Hübscher, SG; Lavery, GG; Morgan, SA; Nasiri, M; Newsome, PN; Nikolaou, N; Oprescu, A; Reynolds, GM; Tomlinson, JW; van Houten, EL; Visser, JA, 2013)
"Male obesity is associated with reduced sperm motility and morphology and increased sperm DNA damage and oxidative stress; however, the reversibility of these phenotypes has never been studied."	1.38	Diet and exercise in an obese mouse fed a high-fat diet improve metabolic health and reverse perturbed sperm function. ( Bakos, HW; Lane, M; Owens, JA; Palmer, NO; Setchell, BP, 2012)
"Obesity is a disease that has become a serious public health issue worldwide, and chronic stressors, which are a problem for modern society, cause neuroendocrine changes with alterations in food intake."	1.38	Cafeteria diet-induced obesity plus chronic stress alter serum leptin levels. ( Caumo, W; Cioato, SG; Macedo, IC; Medeiros, LF; Oliveira, C; Oliveira, CM; Rozisky, JR; Santos, VS; Scarabelot, VL; Silva, FR; Souza, A; Torres, IL, 2012)
"Metabolic syndrome is a condition that typically includes central obesity, insulin resistance, glucose intolerance, dyslipidemia, and hypertension."	1.38	Anatomic, hematologic, and biochemical features of C57BL/6NCrl mice maintained on chronic oral corticosterone. ( Cassano, AE; Karatsoreos, IN; Penraat, KA; Rasmussen, S; White, JR; Wilson, CD, 2012)
"Leptin is a member of the IL-6 cytokine family and is primarily produced by adipose tissue."	1.35	Leptin acts in the periphery to protect thymocytes from glucocorticoid-mediated apoptosis in the absence of weight loss. ( Roberts, MR; Trotter-Mayo, RN, 2008)
"Obesity is an increasing socio-economic health problem."	1.35	Diet-induced obesity alters behavior as well as serum levels of corticosterone in F344 rats. ( Behrendt, P; Bode, FJ; Brabant, G; Buchenauer, T; Horn, R; Nave, H; Stephan, M, 2009)
"Obesity is associated with a flattening of the diurnal rhythm; plasma cortisol levels are slightly increased during the trough, although they are normal or low in the morning."	1.34	Hippocampal 11beta-hydroxysteroid dehydrogenase type 1 messenger ribonucleic acid expression has a diurnal variability that is lost in the obese Zucker rat. ( Bergström, SA; Burén, J; Loh, E; Mattsson, C; Olsson, T; Söderström, I, 2007)
"Leptin treatment of ob/ob mice markedly increased hepatic 11beta-HSD1 activity and mRNA expression."	1.32	Leptin activation of corticosterone production in hepatocytes may contribute to the reversal of obesity and hyperglycemia in leptin-deficient ob/ob mice. ( Friedman, TC; Li, R; Li, X; Liu, Y; Nakagawa, Y; Ohzeki, T; Wang, Y, 2003)
"Neuropeptide Y (NPY) is a powerful orexigenic neurotransmitter."	1.32	Chronic neuropeptide Y infusion into the lateral ventricle induces sustained feeding and obesity in mice lacking either Npy1r or Npy5r expression. ( Aubert, ML; Palmiter, RD; Pedrazzini, T; Raposinho, PD; White, RB, 2004)
"Insulin sensitivity was assessed by means of an intravenous glucose tolerance test (IVGTT)."	1.31	Excess portal venous long-chain fatty acids induce syndrome X via HPA axis and sympathetic activation. ( Benthem, L; Keizer, K; Kuipers, F; Scheurink, AJ; Steffens, AB; Strubbe, JH; Wiegman, CH, 2000)
"Obesity has been associated with alterations in glucocorticoid metabolism in both man and rodents, but the underlying mechanisms remain undefined."	1.31	Mechanisms of dysregulation of 11 beta-hydroxysteroid dehydrogenase type 1 in obese Zucker rats. ( Kenyon, CJ; Livingstone, DE; Walker, BR, 2000)
"I3vt leptin caused an increase in plasma corticosterone and plasma leptin levels relative to the control condition."	1.30	Central leptin stimulates corticosterone secretion at the onset of the dark phase. ( Burn, P; Campfield, LA; Donahey, JC; Scheurink, AJ; Seeley, RJ; Steffens, AB; Tenenbaum, R; Thiele, TE; van Dijk, G; Wilkinson, CW; Woods, SC, 1997)
"Leptin treatment improved tolerance to an oral glucose load (16% reduction in the area under the blood glucose curve) while lowering plasma insulin."	1.30	Effects of intracerebroventricular infusion of leptin in obese Zucker rats. ( al-Barazanji, KA; Arch, JR; Buckingham, RE; Gloger, IS; Haynes, A; Holmes, SD; McBay, DL; McHale, MT; Mossakowska, DE; Wang, XM, 1997)
"Leptin treatment of obese mice significantly lowered LPL activity to that of lean mice in all tissues examined."	1.30	Effects of leptin adipose tissue lipoprotein lipase in the obese ob/ob mouse. ( Deshaies, Y; Huang, Q; Picard, F; Richard, D, 1998)
"Hyperglycemia was rapidly induced in Avy/a females by dexamethasone (dex)."	1.29	Dexamethasone-induced hyperglycemia in obese Avy/a (viable yellow) female mice entails preferential induction of a hepatic estrogen sulfotransferase. ( Chapman, HD; Gill, AM; Leiter, EH; Powell, JG; Yen, TT, 1994)
"Neuropeptide Y (NPY) is a 36 amino-acid peptide."	1.29	Hypothalamic neuropeptide Y messenger ribonucleic acid levels in pre-obese and genetically obese (fa/fa) rats; potential regulation thereof by corticotropin-releasing factor. ( Bchini-Hooft van Huijsduijnen, OB; Jeanrenaud, B; Rohner-Jeanrenaud, F, 1993)
"Mannoheptulose did not inhibit insulin secretion from control obese rats; however at concentrations of 1."	1.29	Effect of adrenalectomy on the development of a pancreatic islet lesion in fa/fa rats. ( Chan, CB; Kibenge, MT, 1996)
"Corticosterone infusion was more effective in suppressing portal CRF levels in adrenalectomized obese compared to adrenalectomized lean rats."	1.28	Hypothalamic-pituitary-adrenal axis function in the Zucker obese rat. ( Hauger, RL; Plotsky, PM; Thrivikraman, KV; Watts, AG, 1992)
"Metformin markedly reduced also the hyperinsulinemia of the obese animals without altering their plasma glucose or pancreatic insulin content which may reflect an improved insulin sensitivity after metformin treatment."	1.28	Subchronic treatment with metformin produces anorectic effect and reduces hyperinsulinemia in genetically obese Zucker rats. ( Huupponen, R; Koulu, M; Pesonen, U; Rouru, J, 1992)
"Mifepristone treatment resulted in a threefold increase in plasma corticosterone levels in lean Zucker rats, but it did not change corticosterone secretion in obese animals."	1.28	Differential hypothalamic arginine vasopressin response to glucocorticoid receptor antagonism in lean and obese Zucker rats. ( Huupponen, R; Jolkkonen, J; Koulu, M; Pesonen, U, 1992)
"Treatment with mifepristone for 4 days (10 mg/kg orally twice daily) significantly (P less than 0."	1.28	The glucocorticoid antagonist mifepristone reveals abnormal regulation of the adrenocortical system in obese Zucker rats. ( Heikinheimo, O; Huupponen, R; Koulu, M; Pesonen, U, 1992)
"The mifepristone treatment significantly increased plasma corticosterone levels in lean animals, but not in obese animals."	1.28	Effects of repeated administration of mifepristone and 8-OH-DPAT on expression of preproneuropeptide Y mRNA in the arcuate nucleus of obese Zucker rats. ( Huupponen, R; Koulu, M; Pesonen, U; Rouru, J, 1991)
"Corticosterone treatment induced a greater and earlier increase in mRNA levels in adrenalectomized obese rats than in adrenalectomized lean rats."	1.28	Adrenalectomy in the Zucker fatty rat: effect on m-RNA for malic enzyme and glyceraldehyde 3-phosphate dehydrogenase. ( Bray, GA; Hainault, I; Lavau, M; York, DA, 1991)
"Corticosterone treatment of adrenalectomized animals enhanced both basal and postabsorptive insulin levels, but adrenalectomized rats with VMH lesions were hyperinsulinemic compared with animals with sham lesions only under the postabsorptive condition."	1.27	Hypothalamic hyperinsulinemia and obesity: role of adrenal glucocorticoids. ( Banta, AR; Bruce, BK; Frohman, LA; King, BM; Tharel, GN, 1983)
"Corticosterone excretion was further suppressed to levels not different from those in lean rats after 2 days of dexamethasone (40 micrograms/kg X day)."	1.27	Hypercorticosteronuria and diminished pituitary responsiveness to corticotropin-releasing factor in obese Zucker rats. ( Bode, HH; Calles-Escandon, J; Carr, DB; Cunningham, JJ; Garrido, F, 1986)
"The naloxone-treated young, obese and non-obese SHR (controls) exhibited marked reduction of the weight of their pituitary and adrenal glands, whereas the pituitary and adrenal glands of naloxone-treated mature, obese and non-obese/SHR were greatly increased in weight."	1.27	Anti-opiate (naloxone) suppression of Cushingoid degenerative changes in obese/SHR. ( McMurtry, JP; Wexler, BC, 1985)
"Whereas obesity was associated with only moderate glucose intolerance and insulin resistance in A/J mice, obese C57BL/6J mice showed clear-cut diabetes with fasting blood glucose levels of greater than 240 mg/dl and blood insulin levels of greater than 150 microU/ml."	1.27	Diet-induced type II diabetes in C57BL/6J mice. ( Cochrane, C; Feinglos, MN; Kuhn, CM; McCubbin, JA; Surwit, RS, 1988)
"Corticosterone-treated obese rats had higher basal and glucose-stimulated insulin levels than similarly treated lean animals, although plasma glucose concentrations did not differ between phenotypes."	1.27	The parasympathetic nervous system and glucocorticoid-mediated hyperinsulinaemia in the genetically obese (fa/fa) Zucker rat. ( Fletcher, JM; McKenzie, N, 1988)
" The median effective concentration (EC50) and the maximal corticosterone response per microgram of DNA of dose-response curves derived from lean and obese rats were not significantly different."	1.27	Responsiveness of isolated adrenocortical cells from lean and obese Zucker rats to ACTH. ( Davenport, WD; Porter, JR; White, BD, 1988)

Timeframe	Studies, this research(%)	All Research%
pre-1990	69 (21.43)	18.7374
1990's	71 (22.05)	18.2507
2000's	72 (22.36)	29.6817
2010's	83 (25.78)	24.3611
2020's	27 (8.39)	2.80

Trial	Enrollment	Study Type	Start Date	Status
The Acute Response of Glucocorticoids Upon Food Intake[NCT04482738]	36 participants (Actual)	Observational	2020-05-14	Completed
Meal-regulated Substrate Metabolism, Influence of Obesity and IL-6[NCT04687540]	25 participants (Actual)	Interventional	2021-04-09	Completed
[information is prepared from clinicaltrials.gov, extracted Sep-2024]

Article	Year
Effect of adenovirus and influenza virus infection on obesity. Life sciences, 2013, Oct-11, Volume: 93, Issue:16 Topics: Adenovirus Infections, Human; Animals; CD8-Positive T-Lymphocytes; Cell Differentiation; Corticoster	2013
11β-Hydroxysteroid dehydrogenase type 1: relevance of its modulation in the pathophysiology of obesity, the metabolic syndrome and type 2 diabetes mellitus. Diabetes, obesity & metabolism, 2012, Volume: 14, Issue:10 Topics: 11-beta-Hydroxysteroid Dehydrogenase Type 1; Adipose Tissue; Animals; Anti-Inflammatory Agents; Athe	2012
Adrenal and gonadal function in obesity. Journal of endocrinological investigation, 2002, Volume: 25, Issue:10 Topics: Adipose Tissue; Adrenal Glands; Animals; Corticosterone; Gonadal Steroid Hormones; Humans; Hydrocort	2002
11beta-hydroxysteroid dehydrogenase type 1 and obesity. Frontiers of hormone research, 2008, Volume: 36 Topics: 11-beta-Hydroxysteroid Dehydrogenase Type 1; 11-beta-Hydroxysteroid Dehydrogenase Type 2; Adipose Ti	2008
Insulin, corticosterone and the autonomic nervous system in animal obesities: a viewpoint. Diabetologia, 1995, Volume: 38, Issue:8 Topics: Animals; Autonomic Nervous System; Cerebral Ventricles; Corticosterone; Insulin; Islets of Langerhan	1995
[Chemical determination of adrenal cortex steroids and its significance for the medical diagnosis]. Zeitschrift fur die gesamte innere Medizin und ihre Grenzgebiete, 1968, Mar-15, Volume: 23, Issue:6 Topics: 17-Hydroxycorticosteroids; 17-Ketosteroids; Adrenocortical Hyperfunction; Chemistry, Clinical; Corti	1968

corticosterone and Obesity

Research Excerpts

Research

Studies (322)

Authors

Clinical Trials (2)

Trial Overview

Reviews

Trials

Other Studies

Authors	Studies
Kelly, KP	1
Ellacott, KLJ	1
Chen, H	1
McGuinness, OP	1
Johnson, CH	1
de Souza, CF	1
Stopa, LRS	1
Martins, AB	1
Wunderlich, ALM	1
Lopes, GM	1
Zaia, DAM	1
Zaia, CTBV	1
de Andrade, FG	1
Leite, CM	1
Uchoa, ET	1
Morgan, SA	2
Gathercole, LL	1
Hassan-Smith, ZK	1
Tomlinson, J	1
Stewart, PM	1
Lavery, GG	2
Igual Gil, C	1
Coull, BM	1
Jonas, W	1
Lippert, RN	1
Klaus, S	1
Ost, M	1
Srivastava, RK	1
Ruiz de Azua, I	1
Conrad, A	1
Purrio, M	1
Lutz, B	1
Reiche, ME	2
Poels, K	2
Bosmans, LA	2
Vos, WG	2
Van Tiel, CM	2
Gijbels, MJJ	2
Aarts, SABM	2
Den Toom, M	2
Beckers, L	2
Weber, C	2
Atzler, D	2
Rensen, PCN	4
Kooijman, S	3
Lutgens, E	2
Teeple, K	1
Rajput, P	1
Gonzalez, M	1
Han-Hallett, Y	1
Fernández-Juricic, E	1
Casey, T	1
Martins, IP	1
Vargas, R	1
Saavedra, LPJ	1
Rickli, S	1
Matiusso, CCI	1
Pavanello, A	2
Casagrande, L	1
Pastre, MJ	1
Oliveira, JB	1
de Almeida, AM	1
de Souza, ACH	1
de Oliveira, JC	1
Malta, A	2
Mathias, PCF	1
Wang, G	1
Li, S	1
Li, Y	1
Zhang, M	1
Xu, T	1
Li, T	1
Cao, L	2
Lu, J	1
Yamazaki, H	1
Uehara, M	1
Yoshikawa, N	1
Kuribara-Souta, A	1
Yamamoto, M	1
Hirakawa, Y	1
Kabe, Y	1
Suematsu, M	1
Tanaka, H	1
Gado, M	1
Heinrich, A	1
Wiedersich, D	1
Sameith, K	1
Dahl, A	1
Alexaki, VI	1
Swarbrick, MM	2
Baschant, U	1
Grafe, I	1
Perakakis, N	1
Bornstein, SR	3
Rauner, M	1
Hofbauer, LC	1
Henneicke, H	2
Almehmadi, K	1
Fourman, S	1
Buesing, D	1
Ulrich-Lai, YM	2
Shahanoor, Z	1
Sultana, R	1
Savenkova, M	1
Karatsoreos, IN	3
Romeo, RD	1
Szalanczy, AM	1
Giorgio, G	1
Goff, E	1
Seshie, O	1
Grzybowski, M	1
Klotz, J	1
Geurts, AM	1
Redei, EE	1
Solberg Woods, LC	1
la Fleur, SE	2
Xu, J	1
Shao, X	1
Zeng, H	1
Wang, C	1
Li, J	1
Peng, X	1
Zhuo, Y	1
Hua, L	1
Meng, F	1
Han, X	1
Udagawa, H	1
Funahashi, N	1
Nishimura, W	1
Uebanso, T	1
Kawaguchi, M	1
Asahi, R	1
Nakajima, S	1
Nammo, T	1
Hiramoto, M	1
Yasuda, K	1
Tanaka, A	1
Takayama, K	1
Furubayashi, T	1
Mori, K	1
Takemura, Y	1
Amano, M	1
Maeda, C	1
Inoue, D	1
Kimura, S	1
Kiriyama, A	1
Katsumi, H	1
Miyazato, M	1
Kangawa, K	1
Sakane, T	1
Hayashi, Y	1
Yamamoto, A	1
Mezzullo, M	1
Di Dalmazi, G	1
Fazzini, A	1
Baccini, M	1
Repaci, A	1
Gambineri, A	2
Vicennati, V	2
Pelusi, C	1
Pagotto, U	1
Fanelli, F	1
Izzi-Engbeaya, C	1
Ma, Y	1
Buckley, NW	1
Ratnasabapathy, R	1
Richardson, E	1
Counsell, JR	1
Fernandes-Freitas, I	1
Norton, M	1
Farooq, G	1
Mirza, Z	1
Cai, M	1
Cheetham, S	1
Seckl, J	1
Murphy, K	1
Dhillo, WS	1
Gardiner, J	1
García-Eguren, G	1
Sala-Vila, A	1
Giró, O	1
Vega-Beyhart, A	1
Hanzu, FA	1
Bahlouli, W	1
Breton, J	1
Lelouard, M	1
L'Huillier, C	1
Tirelle, P	1
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Goichon, A	1
Bôle-Feysot, C	1
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Ribet, D	1
Déchelotte, P	1
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Shin, AC	3
Balasubramanian, P	2
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Sahagun, E	1
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Verzijl, CRC	2
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Fenzl, A	1
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Bell, RMB	1
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Miguelez-Crespo, A	1
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Chan, CC	1
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Lisboa, PC	1
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Svec, F	2
Hilton, CW	1
Wright, B	1
Browne, E	1
Porter, JR	4
Jeanrenaud, B	6
Black, MA	1
Bégin-Heick, N	1
Grekin, RJ	1
Vollmer, AP	1
Sider, RS	1
Pacak, K	1
McCarty, R	1
Palkovits, M	1
Cizza, G	1
Kopin, IJ	1
Goldstein, DS	1
Chrousos, GP	1
Wiesenfeld, P	1
Michaelis, OE	3
Rowland, NE	2
Blair, SC	1
Caterson, ID	1
Cooney, GJ	1
Gill, AM	1
Leiter, EH	2
Powell, JG	1
Chapman, HD	1
Yen, TT	1
Balkan, B	1
Strubbe, JH	2
Bruggink, JE	1
Steffens, AB	3
Fukushima, M	2
Nakai, Y	1
Tsukada, T	1
Usui, T	1
Nakaishi, S	1
Naito, Y	1
Tominaga, T	1
Senoo, K	1
Fukata, J	1
Ikeda, H	1
Bchini-Hooft van Huijsduijnen, OB	1
Rohner-Jeanrenaud, F	5
Kibenge, MT	2
Chan, CB	2
del Rey, A	1
Monge-Arditi, G	1
Klusman, I	1
Besedovsky, HO	1
Rivest, R	2
Naïmi, N	1
Rivest, S	1
Cusin, I	2
do Nascimento, CM	1
Andrade, IS	1
Hirata, AE	1
Dolnikoff, MS	1
Clapham, JC	1
Turner, NC	1
Graham, M	1
Shutter, JR	1
Sarmiento, U	1
Sarosi, I	1
Stark, KL	1
Widdowson, PS	1
Upton, R	1
Buckingham, R	1
Arch, J	1
Williams, G	2
van Dijk, G	1
Donahey, JC	1
Thiele, TE	1
Scheurink, AJ	2
Tenenbaum, R	1
Campfield, LA	1
Burn, P	1
Boston, BA	2
Blaydon, KM	1
Varnerin, J	1
Cone, RD	2
al-Barazanji, KA	4
Buckingham, RE	4
Arch, JR	4
Haynes, A	1
Mossakowska, DE	1
McBay, DL	1
Holmes, SD	1
McHale, MT	1
Wang, XM	1
Gloger, IS	1
Shek, EW	1
Brands, MW	1
Hall, JE	1
Leibowitz, SF	3
Akabayashi, A	2
Wang, J	3
Mantzoros, CS	3
Frederich, RC	1
Qu, D	1
Lowell, BB	1
Huang, Q	2
Ohtani, KI	1
Uehara, Y	1
Abe, Y	1
Takahashi, H	1
Tsuchiya, T	1
Sato, N	1
Ibuki, Y	1
Mori, M	1
Alexander, JT	2
Zheng, P	1
Yu, HJ	2
Dourmashkin, J	2
Grasa, MM	4
Cabot, C	5
Adán, C	2
Sanchis, D	2
Balada, F	2
Estruch, J	3
Fernández-López, JA	5
Remesar, X	5
Alemany, M	5
Arvaniti, K	1
Ricquier, D	2
Champigny, O	1
del Mar Grasa, M	1
Chae, HJ	1
Dinulescu, DM	1
Fan, W	1
McCall, K	1
Lamoreux, ML	1
Moore, KJ	1
Montagno, J	1
Picard, F	3
Deshaies, Y	5
Faggioni, R	1
Fantuzzi, G	1
Gabay, C	1
Moser, A	1
Dinarello, CA	1
Feingold, KR	1
Grunfeld, C	1
Virgili, J	1
Monserrat, C	1
Zakrzewska, KE	1
Stricker-Krongrad, A	1
Boss, O	1
Kintner, J	1
Flurkey, K	1
Beamer, WG	1
Naggert, JK	1
Mantha, L	1
Palacios, E	1
Yaswen, L	1
Diehl, N	1
Brennan, MB	1
Hochgeschwender, U	1
Tronche, F	1
Kellendonk, C	1
Kretz, O	1
Gass, P	1
Anlag, K	1
Orban, PC	1
Bock, R	1
Klein, R	1
Esteve, M	1
Vilà, R	1
Masanés, R	1
Boivin, A	1
Jones, GC	1
Smith, K	1
Jamieson, PM	1
Korner, J	1
Chua, SC	1
Williams, JA	1
Leibel, RL	1
Wardlaw, SL	1
Boules, M	1
Cusack, B	1
Zhao, L	1
Fauq, A	1
McCormick, DJ	1
Richelson, E	1
Tadayyon, M	3
Chen, AS	1
Marsh, DJ	1
Trumbauer, ME	1
Frazier, EG	1
Guan, XM	1
Yu, H	1
Rosenblum, CI	1
Vongs, A	1
Feng, Y	1
Metzger, JM	1
Strack, AM	1
Camacho, RE	1
Mellin, TN	1
Nunes, CN	1
Min, W	1
Fisher, J	1
Gopal-Truter, S	1
MacIntyre, DE	1
Chen, HY	1
Van der Ploeg, LH	1
Ziotopoulou, M	2
Makimura, H	1
Mizuno, TM	1
Roberts, J	1
Silverstein, J	1
Beasley, J	1
Benthem, L	1
Keizer, K	1
Wiegman, CH	1
Kuipers, F	1
Pham, J	1
Porter, J	1
Svec, D	1
Eiswirth, C	1
Lambert, PD	1
Anderson, KD	1
Sleeman, MW	1
Wong, V	1
Tan, J	1
Hijarunguru, A	1
Corcoran, TL	1
Murray, JD	1
Thabet, KE	1
Yancopoulos, GD	1
Wiegand, SJ	1
Nilsson, C	2
Larsson, BM	1
Jennische, E	2
Eriksson, E	2
Björntorp, P	2
Holmäng, A	2
Dahlgren, J	1
Ho, HP	1
Niklasson, A	1
Albertsson Wikland, K	1
Reizes, O	1
Lincecum, J	1
Wang, Z	1
Goldberger, O	1
Huang, L	1
Kaksonen, M	1
Ahima, R	1
Hinkes, MT	1
Barsh, GS	1
Rauvala, H	1
Bernfield, M	1
Masuzaki, H	1
Paterson, J	1
Shinyama, H	1
Mullins, JJ	1
Wallenius, V	1
Wallenius, K	1
Ahrén, B	1
Rudling, M	1
Carlsten, H	1
Dickson, SL	1
Ohlsson, C	1
Jansson, JO	1
Wakayama, T	1
Akutsu, H	1
Yamazaki, Y	1
Lachey, JL	1
Wortman, MD	1
D'Alessio, DA	1
Yanagimachi, R	1
Briscoe, C	1
Jenkins, O	1
Pierroz, DD	1
Ungsunan, L	1
Moschos, S	1
Ishihara, A	1
Kanatani, A	1
Okada, M	1
Hidaka, M	1
Tanaka, T	1
Mashiko, S	1
Gomori, A	1
Kanno, T	1
Hata, M	1
Kanesaka, M	1
Tominaga, Y	1
Sato, NA	1
Kobayashi, M	1
Murai, T	1
Watanabe, K	1
Ishii, Y	1
Fukuroda, T	1
Fukami, T	1
Ihara, M	1
Edwardson, JA	1
Hough, CA	1
Yukimura, Y	1
Wolfsen, AR	1
Koletsky, S	1
Snajdar, RM	1
Soseliia, GS	1
Goncharova, VN	1
Wangsness, PJ	1
Gahagan, JH	2
Plotsky, PM	1
Thrivikraman, KV	1
Watts, AG	1
Hauger, RL	1
Warwick, B	1
Suzuki, H	1
Romsos, DR	2
Walker, CD	1
Scribner, KA	1
Stern, JS	2
Langley, SC	3
Rouru, J	2
Huupponen, R	4
Pesonen, U	4
Koulu, M	4
Jolkkonen, J	1
Mohan, PF	1
Cleary, MP	1
Cherel, Y	1
Robin, JP	1
Heitz, A	1
Calgari, C	1
Le Maho, Y	1
Alarrayed, F	1
Hartman, AD	1
Heikinheimo, O	1
Okada, S	1
Brindley, DN	1
Hales, P	1
al-Sieni, AI	1
Zansler, CA	1
Richard, SM	1
Gutierrez, C	1
McKibbin, PE	1
Cotton, SJ	1
McMillan, S	1
Holloway, B	1
Mayers, R	1
McCarthy, HD	1
Lavau, M	2
Hainault, I	1
Carswell, N	1
Velasquez, MT	1
Kimmel, PL	1
Abraham, AA	1
Canary, JJ	1
Carlton, J	1
Guillaume-Gentil, C	1
Abramo, F	1
Bestetti, GE	1
Rossi, GL	1
White, BD	2
Corll, CB	1
Fletcher, JM	5
Haggarty, P	1
Wahle, KW	1
Reeds, PJ	1
Ellwood, KC	1
Bhathena, SJ	1
Spiegelman, BM	1
Lowell, B	1
Napolitano, A	1
Dubuc, P	1
Barton, D	1
Francke, U	1
Groves, DL	1
Cook, KS	1
Holt, SJ	1
Marchington, D	1
Cunningham, JJ	1
Calles-Escandon, J	1
Garrido, F	1
Carr, DB	1
Bode, HH	1
Wexler, BC	1
McMurtry, JP	1
Smith, RL	1
Surwit, RS	1
Kuhn, CM	1
Cochrane, C	1
McCubbin, JA	1
Feinglos, MN	1
McKenzie, N	1
Carlisle, HJ	1
Zurek, LD	1
Tse, CS	2
Abrahamsen, S	1
Fässler, R	3
Dietrich, H	2
Krömer, G	3
Schwarz, S	3
Brezinschek, HP	1
Wick, G	3
Tokunaga, K	1
Lupien, J	1
Kemnitz, JW	1
Davenport, WD	1
Schauenstein, K	2
Tokuyama, K	1
Himms-Hagen, J	1
Bazin, R	1
Planche, E	1
Dupuy, F	1
Krief, S	1
McGinnis, R	1
Walker, J	1
Margules, D	1
Grogan, CK	1
Kim, HK	1
Allars, J	1
Freedman, MR	1
Karl, HJ	1
Raith, L	1
Hollmann, M	1
Weinges, KF	1
Laudat, MH	1
Combret, Y	1
Laudat, P	1
Naeser, P	3
Savage, DC	1
Forsyth, CC	1
Cameron, J	1
Dunn, J	1
Arimura, A	1
Stahl, F	1
Dörner, G	1
Ito, Y	1
Meier, AH	1
Martin, DD	1
Wolff, GL	1
Flack, JD	1
Hackenberg, K	1
Zimmermann, H	1
Dressel, R	1
Daweke, H	1
Grüneklee, D	1
Liebermeister, H	1
Hüther, KJ	1
Ritzl, F	1
Nakashima, K	1
Knorr, D	1
Lauter, H	1
Busonera, G	1
Cattano, G	1
Benedetti, A	1
Sabeh, G	1
Alley, RA	1
Robbins, TJ	1
Narduzzi, JV	1
Kenny, FM	1
Danowski, TS	1
Zampa, GA	1
Geminiani, GD	1