Exportar registro bibliográfico


Hypercaloric diet-induced obesity and obesity-related metabolic disorders in experimental models (2019)

  • Authors:
  • Unidade: FCF
  • DOI: 10.1007/978-3-030-12668-1_8
  • Language: Inglês
  • Imprenta:
  • Source:
  • DOI
    Informações sobre o DOI: 10.1007/978-3-030-12668-1_8 (Fonte: oaDOI API)
    • Este periódico é de assinatura
    • Este artigo NÃO é de acesso aberto
    • Cor do Acesso Aberto: closed

    How to cite
    A citação é gerada automaticamente e pode não estar totalmente de acordo com as normas

    • ABNT

      CASTRO, Natália Pinheiro de; SILVA, Lívia Beatriz Aparecida Ribeiro; NOVAES, Gabriela Machado; ONG, Thomas Prates. Hypercaloric diet-induced obesity and obesity-related metabolic disorders in experimental models. In: Reviews on Biomarker Studies of Metabolic and Metabolism-Related Disorders, Advances in Experimental Medicine and Biology[S.l: s.n.], 2019. DOI: 10.1007/978-3-030-12668-1_8.
    • APA

      Castro, N. P. de, Silva, L. B. A. R., Novaes, G. M., & Ong, T. P. (2019). Hypercaloric diet-induced obesity and obesity-related metabolic disorders in experimental models. In Reviews on Biomarker Studies of Metabolic and Metabolism-Related Disorders, Advances in Experimental Medicine and Biology. Cham: Springer. doi:10.1007/978-3-030-12668-1_8
    • NLM

      Castro NP de, Silva LBAR, Novaes GM, Ong TP. Hypercaloric diet-induced obesity and obesity-related metabolic disorders in experimental models. In: Reviews on Biomarker Studies of Metabolic and Metabolism-Related Disorders, Advances in Experimental Medicine and Biology. Cham: Springer; 2019.
    • Vancouver

      Castro NP de, Silva LBAR, Novaes GM, Ong TP. Hypercaloric diet-induced obesity and obesity-related metabolic disorders in experimental models. In: Reviews on Biomarker Studies of Metabolic and Metabolism-Related Disorders, Advances in Experimental Medicine and Biology. Cham: Springer; 2019.

    Referências citadas na obra
    Ng M, Fleming T, Robinson M et al (2014) Global, regional, and national prevalence of overweight and obesity in children and adults during 1980–2013: a systematic analysis for the global burden of disease study 2013. Lancet 384:766–781
    Hubert HB, Feinleib M, McNamara PM, Castelli WP (1983) Obesity as an independent risk factor for cardiovascular disease: a 26-year follow-up of participants in the Framingham heart study. Circulation 67:968–977
    Sacco MR, de Castro NP, Euclydes VLV, Souza JM, Rondó PH (2013) Birth weight, rapid weight gain in infancy and markers of overweight and obesity in childhood. Eur J Clin Nutr 67:1147–1153
    Hariri N, Thibault L (2010) High-fat diet-induced obesity in animal models. Nutr Res Rev 23:270–299
    Heitmann BL, Lissner L (1995) Dietary underreporting by obese individuals–is it specific or non-specific? BMJ 311:986–989
    Ong TP, Guest PC (2018) Nutritional programming effects on development of metabolic disorders in later life. Methods Mol Biol 1735:3–17
    Fenton PF, Dowling MT (1953) Studies on obesity. J Nutr 49:319–331
    Buettner R, Schölmerich J, Bollheimer LC (2007) High-fat diets: modeling the metabolic disorders of human obesity in rodents. Obesity (Silver Spring) 15:798–808
    Mickelsen O, Takahashi S, Craig C (1955) Experimental obesity. J Nutr 57:541–554
    Woods SC, D’Alessio DA, Tso P, Rushing PA, Clegg DJ, Benoit SC et al (2004) Consumption of a high-fat diet alters the homeostatic regulation of energy balance. Physiol Behav 83:573–578
    Fontelles CC, Guido LN, Rosim MP, Andrade Fde O, Jin L, Inchauspe J et al (2016) Paternal programming of breast cancer risk in daughters in a rat model: opposing effects of animal- and plant-based high-fat diets. Breast Cancer Res 18:71. https://doi.org/10.1186/s13058-016-0729-x
    Hariri N, Gougeon R, Thibault L (2010) A highly saturated fat-rich diet is more obesogenic than diets with lower saturated fat content. Nutr Res 30:632–643
    Masi LN, Martins AR, Crisma AR, do Amaral CL, Davanso MR, Serdan TDA et al (2017) Combination of a high-fat diet with sweetened condensed milk exacerbates inflammation and insulin resistance induced by each separately in mice. Sci Rep 7:3937. https://doi.org/10.1038/s41598-017-04308-1
    de Oliveira Andrade F, Fontelles CC, Rosim MP, de Oliveira TF, de Melo Loureiro AP, Mancini-Filho J et al (2014) Exposure to lard-based high-fat diet during fetal and lactation periods modifies breast cancer susceptibility in adulthood in rats. J Nutr Biochem 25:613–622
    Olsen MK, Johannessen H, Cassie N, Barrett P, Takeuchi K, Kulseng B et al (2017) Steady-state energy balance in animal models of obesity and weight loss. Scand J Gastroenterol 52:442–449
    Blaak EE, Saris WH (1996) Postprandial thermogenesis and substrate utilization after ingestion of different dietary carbohydrates. Metabolism 45:1235–1242
    Zeeni N, Dagher-Hamalian C, Dimassi H, Faour WH (2015) Cafeteria diet-fed mice is a pertinent model of obesity-induced organ damage: a potential role of inflammation. Inflamm Res 64:501–512
    Bayol SA, Simbi BH, Fowkes RC, Stickland NC (2010) A maternal “junk food” diet in pregnancy and lactation promotes nonalcoholic fatty liver disease in rat offspring. Endocrinology 151:1451–1461
    Johnson AR, Wilkerson MD, Sampey BP, Troester MA, Hayes DN, Makowski L (2016) Cafeteria diet-induced obesity causes oxidative damage in white adipose. Biochem Biophys Res Commun 473:545–550
    Lalanza JF, Caimari A, del Bas JM, Torregrosa D, Cigarroa I, Pallàs M et al (2014) Effects of a post-weaning cafeteria diet in young rats: metabolic syndrome, reduced activity and low anxiety-like behaviour. PLoS One 9:e85049. https://doi.org/10.1371/journal.pone.0085049
    Zeeni N, Daher C, Fromentin G, Tome D, Darcel N, Chaumontet C (2013) A cafeteria diet modifies the response to chronic variable stress in rats. Stress 16:211–219
    Castro L, Gao X, Moore AB, Yu L, Di X, Kissling GE et al (2016) A high concentration of genistein induces cell death in human uterine leiomyoma cells by autophagy. Expert Opin Environ Biol 5(Suppl 1). https://doi.org/10.4172/2325-9655.S1-003
    Berridge KC, Ho C-Y, Richard JM, DiFeliceantonio AG (2010) The tempted brain eats: pleasure and desire circuits in obesity and eating disorders. Brain Res 1350:43–64
    Martire SI, Maniam J, South T, Holmes N, Westbrook RF, Morris MJ (2014) Extended exposure to a palatable cafeteria diet alters gene expression in brain regions implicated in reward, and withdrawal from this diet alters gene expression in brain regions associated with stress. Behav Brain Res 265:132–141
    Sampey BP, Vanhoose AM, Winfield HM, Freemerman AJ, Muehlbauer MJ, Fueger PT et al (2011) Cafeteria diet is a robust model of human metabolic syndrome with liver and adipose inflammation: comparison to high-fat diet. Obesity 19:1109–1117
    Reichelt AC, Morris MJ, Westbrook RF (2014) Cafeteria diet impairs expression of sensory-specific satiety and stimulus-outcome learning. Front Psychol 5:852. https://doi.org/10.3389/fpsyg.2014.00852
    Saper CB, Chou TC, Elmquist JK (2002) The need to feed: homeostatic and hedonic control of eating. Neuron 36:199–211
    Nilsson C, Raun K, Yan F, Larsen MO, Tang-Christensen M (2012) Laboratory animals as surrogate models of human obesity. Acta Pharmacol Sin 33:173–181
    Bortolin RC, Vargas AR, Gasparotto J, Chaves PR, Schnorr CE, Martinello KB et al (2018) A new animal diet based on human Western diet is a robust diet-induced obesity model: comparison to high-fat and cafeteria diets in term of metabolic and gut microbiota disruption. Int J Obes 42:525–534
    Moore BJ (1987) The cafeteria diet—an inappropriate tool for studies of thermogenesis. J Nutr 117:227–231
    Maioli TU, Gonçalves JL, Miranda MCG, Martins VD, Horta LS, Moreira TG et al (2016) High sugar and butter (HSB) diet induces obesity and metabolic syndrome with decrease in regulatory T cells in adipose tissue of mice. Inflamm Res 65:169–178
    Samuelsson A-M, Matthews PA, Argenton M, Christie MR, McConnell JM, Jansen EH et al (2007) Diet-induced obesity in female mice leads to offspring hyperphagia, adiposity, hypertension, and insulin resistance: a novel murine model of developmental programming. Hypertension 51:383–392
    Crescenzo R, Bianco F, Mazzoli GA, Cancelliere R, di Fabio GA et al (2015) Fat quality influences the obesogenic effect of high fat diets. Nutrients 7:9475–9491
    Aller EEJG, Abete I, Astrup A, Martinez JA, van Baak MA (2011) Starches, sugars and obesity. Nutrients 3:341–369
    Lennerz B, Lennerz JK (2018) Food addiction, high-glycemic-index carbohydrates, and obesity. Clin Chem 64:64–71
    Alfaradhi MZ, Fernandez-Twinn DS, Martin-Gronert MS, Musial B, Fowden A, Ozanne SE (2014) Oxidative stress and altered lipid homeostasis in the programming of offspring fatty liver by maternal obesity. Am J Physiol Regul Integr Comp Physiol 307:R26–R34. https://doi.org/10.1152/ajpregu.00049.2014
    Roberts JS, Perets RA, Sarfert KS, Bowman JJ, Ozark PA, Whitworth GB et al (2017) High-fat high-sugar diet induces polycystic ovary syndrome in a rodent model. Biol Reprod 96:551–562
    Barnard DE, Lewis SM, Teter BB, Thigpen JE (2009) Open- and closed-formula laboratory animal diets and their importance to research. J Am Assoc Lab Anim Sci 48:709–713
    Ble-Castillo JL, Aparicio-Trapala MA, Juárez-Rojop IE, Torres-Lopez JE, Mendez JD, Aguilar-Mariscal H et al (2012) Differential effects of high-carbohydrate and high-fat diet composition on metabolic control and insulin resistance in normal rats. Int J Environ Res Public Health 9:1663–1676
    Panchal SK, Poudyal H, Iyer A, Nazer R, Alam MA, Diwan V et al (2011) High-carbohydrate, high-fat diet–induced metabolic syndrome and cardiovascular remodeling in rats. J Cardiovasc Pharmacol 57:611–624
    Zubiría M, Gambaro S, Rey M, Carasi P, Serradell MLÁ, Giovambattista A (2017) Deleterious metabolic effects of high fructose intake: the preventive effect of lactobacillus kefiri administration. Nutrients 9:470. https://doi.org/10.3390/nu9050470
    Kohli R, Kirby M, Xanthakos SA, Softic S, Feldstein AE, Saxena V et al (2010) High-fructose, medium chain trans fat diet induces liver fibrosis and elevates plasma coenzyme Q9 in a novel murine model of obesity and nonalcoholic steatohepatitis. Hepatology 52:934–944
    Wong SK, Chin K-Y, Suhaimi FH, Ahmad F, Ima-Nirwana S (2018) The effects of a modified high-carbohydrate high-fat diet on metabolic syndrome parameters in male rats. Exp Clin Endocrinol Diabetes 126:205–212
    Storlien LH, Higgins JA, Thomas TC, Brown MA, Wang HQ, Huang XF et al (2000) Diet composition and insulin action in animal models. Br J Nutr 83(Suppl 1):S85–S90
    Castonguay TW, Hirsch E, Collier G (1981) Palatability of sugar solutions and dietary selection? Physiol Behav 27:7–12
    Sclafani A, Xenakis S (1984) Sucrose and polysaccharide induced obesity in the rat. Physiol Behav 32:169–174
    Oron-Herman M, Kamari Y, Grossman E, Yeger G, Peleg E, Shabtay Z et al (2008) Metabolic syndrome: comparison of the two commonly used animal models. Am J Hypertens 21:1018–1022
    London E, Lala G, Berger R, Kohli AA, Renner M, Jackson A et al (2007) Sucrose access differentially modifies 11β-Hydroxysteroid Dehydrogenase-1 and Hexose-6-Phosphate dehydrogenase message in liver and adipose tissue in rats. J Nutr 137:2616–2621
    Goodson S, Halford JC, Jackson HC, Blundell JE (2001) Paradoxical effects of a high sucrose diet: high energy intake and reduced body weight gain. Appetite 37:253–254
    Lomba A, Milagro FI, García-Díaz DF, Campión J, Marzo F, Martínez JA et al (2009) A high-sucrose isocaloric pair-fed model induces obesity and impairs NDUFB6 gene function in rat adipose tissue. J Nutrigenet Nutrigenomics 2:267–272
    Toida S, Takahashi M, Shimizu H, Sato N, Shimomura Y, Kobayashi I (1996) Effect of high sucrose feeding on fat accumulation in the male Wistar rat. Obes Res 4:561–568
    Lawton CL, Blundell JE (1992) The effect of d-fenfluramine on intake of carbohydrate supplements is influenced by the hydration of the test diets. Behav Pharmacol 3:517–523
    Blundell JE, Hill AJ (1988) Do serotoninergic drugs decrease energy intake by reducing fat or carbohydrate intake? Effect of d-fenfluramine with supplemented weight-increasing diets. Pharmacol Biochem Behav 31:773–778
    Westwater ML, Fletcher PC, Ziauddeen H (2016) Sugar addiction: the state of the science. Eur J Nutr 55:55–69
    Abete I, Parra MD, Zulet MA, Martínez JA (2006) Different dietary strategies for weight loss in obesity: role of energy and macronutrient content. Nutr Res Rev 19:5. https://doi.org/10.1079/NRR2006112
    Barrett P, Mercer JG, Morgan PJ (2016) Preclinical models for obesity research. Dis Model Mech 9:1245–1255
    Mittwede PN, Clemmer JS, Bergin PF, Xiang L (2016) Obesity and critical illness. Shock 45:349–358
    Zhang Y, Proenca R, Maffei M, Barone M, Leopold L, Friedman JM (1994) Positional cloning of the mouse obese gene and its human homologue. Nature 372:425–432
    Huszar D, Lynch CA, Fairchild-Huntress V, Dunmore JH, Fang Q, Berkemeier LR et al (1997) Targeted disruption of the melanocortin-4 receptor results in obesity in mice. Cell 88:131–141
    Church C, Moir L, McMurray F, Banks GT, Teboul L, Wells S et al (2010) Overexpression of Fto leads to increased food intake and results in obesity. Nat Genet 42:1086–1092
    Kleinert M, Clemmensen C, Hofmann SM, Moore MC, Renner S, Woods SC et al (2018) Animal models of obesity and diabetes mellitus. Nat Rev Endocrinol 14:140–162
    Speakman J, Hambly C, Mitchell S, Król E (2007) Animal models of obesity. Obes Rev 8:55–61
    von Aulock S (2014) Number of animals used for experimental purposes lower in the European Union. ALTEX 31(1):1
    Iannaccone PM, Jacob HJ (2009) Rats! Dis Model Mech 2:206–210
    Kanasaki K, Koya D (2011) Biology of obesity: lessons from animal models of obesity. J Biomed Biotechnol 2011:1–11
    Kucera GT, Bortner DM, Rosenberg MP (1996) Overexpression of an Agouti cDNA in the skin of transgenic mice recapitulates dominant coat color phenotypes of spontaneous mutants. Dev Biol 173:162–173
    Coleman DL (1978) Obese and diabetes: two mutant genes causing diabetes-obesity syndromes in mice. Diabetologia 14:141–148
    Leibowitz SF, Alexander J, Dourmashkin JT, Hill JO, Gayles EC, Chang GQ (2005) Phenotypic profile of SWR/J and A/J mice compared to control strains: possible mechanisms underlying resistance to obesity on a high-fat diet. Brain Res 1047:137–147
    Levin BE, Dunn-Meynell AA (2000) Defense of body weight against chronic caloric restriction in obesity-prone and -resistant rats. Am J Physiol Regul Integr Comp Physiol 278:R231–R237
    Lin L, York DA, Bray GA (1996) Comparison of Osborne-Mendel and S5B/PL strains of rat: central effects of galanin, NPY, beta-casomorphin and CRH on intake of high-fat and low-fat diets. Obes Res 4:117–124
    Phillips MS, Liu Q, Hammond HA, Dugan V, Hey PJ, Caskey CJ et al (1996) Leptin receptor missense mutation in the fatty Zucker rat. Nat Genet 13:18–19
    Chua SC, White DW, Wu-Peng XS, Liu SM, Okada N, Kershaw EE et al (1996) Phenotype of fatty due to Gln269Pro mutation in the leptin receptor (Lepr). Diabetes 45:1141–1143
    Schwartz MW, Bergman RN, Kahn SE, Taborsky GJ Jr, Fisher LD, Sipols AJ et al (1991) Evidence for entry of plasma insulin into cerebrospinal fluid through an intermediate compartment in dogs. Quantitative aspects and implications for transport. J Clin Invest 88:1272–1281
    Coate KC, Kraft G, Shiota M, Smith MS, Farmer B, Neal DW et al (2015) Chronic overeating impairs hepatic glucose uptake and disposition. Am J Physiol Endocrinol Metab 308:E860–E867
    Stachowiak M, Szczerbal I, Switonski M (2016) Genetics of adiposity in large animal models for human obesity-studies on pigs and dogs. Prog Mol Biol Transl Sci 140:233–270
    Bauer SA, Arndt TP, Leslie KE, Pearl DL, Turner PV (2011) Obesity in rhesus and cynomolgus macaques: a comparative review of the condition and its implications for research. Comp Med 61:514–526
    Harwood HJ, Listrani P, Wagner JD (2012) Nonhuman Primates and other animal models in diabetes research. J Diabetes Sci Technol 6:503–514
    Tacutu R, Thornton D, Johnson E, Budovsky A, Barardo D, Craig T et al (2018) Human ageing genomic resources: new and updated databases. Nucleic Acids Res 46:D1083–D1090
    Ashrafi K, Chang FY, Watts JL, Fraser AG, Kamath RS, Ahringer J et al (2003) Genome-wide RNAi analysis of Caenorhabditis elegans fat regulatory genes. Nature 421:268–272. https://doi.org/10.1038/nature01279
    Pospisilik JA, Schramek D, Schnidar H et al (2010) Drosophila genome-wide obesity screen reveals hedgehog as a determinant of brown versus white adipose cell fate. Cell 140:148–160. https://doi.org/10.1016/j.cell.2009.12.027
    Trinh I, Boulianne GL (2013) Modeling obesity and its associated disorders in drosophila. Physiology 28:117–124. https://doi.org/10.1152/physiol.00025.2012
    Watts JL (2009) Fat synthesis and adiposity regulation in Caenorhabditis elegans. Trends Endocrinol Metab 20:58–65. https://doi.org/10.1016/j.tem.2008.11.002

Digital Library of Intellectual Production of Universidade de São Paulo     2012 - 2021