Efeito das fibras alimentares frutano de agave, maltodextrina resistente e celulose em dietas à base de glúten na digestibilidade e utilização de nitrogênio in vivo
Barra lateral de artigos
Conteúdo do artigo principal
Resumo
A ingestão de fibras alimentares melhora o processo de digestão e diminui os níveis de glicose e colesterol. No entanto, pode diminuir a digestibilidade das proteínas. A celulose é uma fibra insolúvel da parede celular das plantas. A maltodextrina resistente é uma fibra solúvel que precede o amido resistente. Agavin é uma fibra solúvel obtida a partir de caules e mezontle de agave. Considerando que o consumo de dietas com proteínas de baixa qualidade aumenta ano a ano, esta pesquisa teve como objetivo avaliar o consumo de 5 % de celulose, Agavin e maltodextrina resistente na digestibilidade das proteínas e a utilização de nitrogênio para crescimento em dietas com 10 % de glúten e caseína por ensaio in vivo usando ratos Sprague Dawley. O consumo de alimentos, o peso ganho e a excreção fecal foram medidos a cada três dias durante 14 dias. O valor nutricional e a melhor aceitação da caseína desencadearam um maior aumento de peso dos ratos. A ausência de proteína causou menor consumo de alimentos e perda de peso dos ratos. As dietas à base de glúten causaram ingestão alimentar intermediária e baixo ganho de peso dos ratos. Zero ou 5 % de fibra alimentar não causou efeito relevante no peso dos ratos. Assim, o consumo de 5 % de fibra alimentar pode ajudar a melhorar os hábitos nutricionais sem afetar a ingestão de nitrogênio para o crescimento. Finalmente, o Agavin como fibra dietética representa uma opção adequada para a indústria do agave.
Downloads
Detalhes do artigo
Este trabalho está licenciado sob uma licença Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.
Os autores mantêm os direitos autorais e concedem à revista o direito de primeira publicação do trabalho sob uma licença Creative Commons (BY-NC-ND) que permite que outros compartilhem com reconhecimento de autoria e publicação inicial nesta revista. Os autores estão autorizados a celebrar contratos adicionais separados para a distribuição não exclusiva da versão do trabalho publicado nesta revista. Autores estão autorizados a divulgar seus trabalhos eletronicamente.
Referências
ABELLÁN RUIZ, M.S.; BARNUEVO ESPINOSA, M.D.; CONTRERAS FERNÁNDEZ, C.J.; LUQUE RUBIA, A.J.; SÁNCHEZ AYLLÓN, F.; ALDEGUER GARCÍA, M.; GARCÍA SANTAMARÍA, C. and LÓPEZ ROMÁN, F.J. (2016) Digestion-resistant maltodextrin effects on colonic transit time and stool weight: a randomized controlled clinical study. European Journal of Nutrition, 55 (8), 2389–2397.
ADAMS, S.; SELLO, C.T.; QIN, G.X.; CHE, D. and HAN, R. (2018) Does dietary fiber affect the levels of nutritional components after feed formulation? Fibers, 6 (2).
ALFARO, V. (2005) Specification of laboratory animal use in scientific articles: Current low detail in the journals’ instructions for authors and some proposals. Methods and Findings in Experimental and Clinical Pharmacology, 27 (7), 495-504.
ALFAWAZ, H.; NAEEF, A.F.; WANI, K.; KHATTAK, M.N.K.; SABICO, S.; ALNAAMI, A.M. and AL-DAGHRI, N.M. (2019) Improvements in glycemic, micronutrient, and mineral indices in arab adults with pre-diabetes post-lifestyle modification program. Nutrients, 11 (11), 2775.
ALLSOPP, P.; POSSEMIERS, S.; CAMPBELL, D.; OYARZÁBAL, I.S.; GILL, C. and ROWLAND, I. (2013) An exploratory study into the putative prebiotic activity of fructans isolated from Agave angustifolia and the associated anticancer activity. Anaerobe, 22, 38–44.
AOAC (2000) Official Methods of Analysis. 17th Edition, The Association of Official Analytical Chemists, Gaithersburg, MD, USA.
DE ALUJA, A.S. (2002) Animales de laboratorio y la Norma Oficial Mexicana (NOM-062-ZOO-1999). Gaceta Médica de México, 138 (3), 295-8.
ANDERSON, J.W.; BAIRD, P.; DAVIS, R.H.; FERRERI, S.; KNUDTSON, M.; KORAYM, A.; WATERS, V. and WILLIAMS, C.L. (2009) Health benefits of dietary fiber. Nutrition Reviews, 7: 188–205.
BENDER, A.E. and DOELL, B.H. (1957) Biological evaluation of proteins: a new aspect. British Journal of Nutrition, 11 (2), 140–148.
DAHL, W.J. and STEWART, M.L. (2015) Position of the Academy of Nutrition and Dietetics: Health Implications of Dietary Fiber. Journal of the Academy of Nutrition and Dietetics, 115 (11), 1861–1870.
DARRAGH, A.J. and HODGKINSON, S.M. (2000) Quantifying the Digestibility of Dietary Protein [online]. The Journal of Nutrition, 130 (7), 1850S-1856S. Available from: https://academic.oup.com/jn/article-abstract/130/7/1850S/4686199
FALCÓN-VILLA, M.R.; BARRÓN-HOYOS, J.M. and CINCO-MOROYOQUI, F.J. (2014) Commercial Breakfast Cereals Available in Mexican Markets and their Contribution in Dietary Fiber, β-Glucans and Protein Quality by Rat Bioassays. Plant Foods for Human Nutrition, 69 (3), 222–227.
FEDDERN, V.; BADIALE-FURLONG, E. and DE SOUZA-SOARES, L.A. (2008) Biological response to different diets of fermented and unfermented mixtures of flour and cereal brans. International Journal of Food Science and Technology, 43 (11), 1945–1952.
FAO/WHO (1991) FOOD AND AGRICULTURE ORGANIZATION OF THE UNITED NATIONS., WORLD HEALTH ORGANIZATION., and JOINT FAO/WHO EXPERT CONSULTATION ON PROTEIN QUALITY EVALUATION. Protein quality evaluation: report of the Joint FAO/WHO Expert Consultation, Bethesda, Md., USA 4-8 December 1989. Food and Agriculture Organization of the United Nations. Paper 51. Available from: https://www.academia.edu/40342518/Protein_quality_evaluation_Report_of_Joint_FAO_WHO_Expert_Consultation_51_FOOD_AND_AGRICUL_TURE_ORGANIZATION_OF_THE_UNITED_NATIONS
FRANCO-ROBLES, E. and LÓPEZ, M.G. (2016) Agavins increase neurotrophic factors and decrease oxidative stress in the brains of high-fat diet-induced obese mice. Molecules, 21 (8), 998.
GARCÍA MONTALVO, I.A.; MÉNDEZ DÍAZ, S.Y.; AGUIRRE GUZMÁN, N.; SÁNCHEZ MEDINA, M.A.; MATÍAS PÉREZ, D. and PÉREZ CAMPOS, E. (2018) Increasing consumption of dietary fiber complementary to the treatment of metabolic syndrome. Nutricion Hospitalaria, 35 (3), 582–587.
GARCÍA-CURBELO, Y.; AYALA, L.; BOCOURT, R.; ALBELO, N.; NUÑEZ, O.; RODRÍGUEZ, Y. and LÓPEZ, M.G. (2018) Agavins as prebiotic. Their influence on lipid metabolism of pigs Agavinas como prebióticos: su influencia en el metabolismo lipídico de cerdos. Cuban Journal of Agricultural Science, 52 (4), 395-400.
GOODMAN, B.E. (2010) Staying Current Insights into digestion and absorption of major nutrients in humans Goodman BE. Insights into digestion and absorption of major nutrients in humans. Advances in Physiology Education [online]. 34, 44–53. Available from: www.physiology.org/journal/advances
HENCHION, M.; HAYES, M.; MULLEN, A.M.; FENELON, M. and TIWARI, B. (2017) Future protein supply and demand: Strategies and factors influencing a sustainable equilibrium. Foods, 6 (7), 1–21.
JIN, J.; MA, H.; ZHOU, C.; LUO, M.; LIU, W.; QU, W.; HE, R.; LUO, L. and YAGOUB, A.E.G.A. (2015) Effect of degree of hydrolysis on the bioavailability of corn gluten meal hydrolysates. Journal of the Science of Food and Agriculture, 95 (12), 2501–2509.
JØRGENSEN, H.; ZHAO, X.Q.; THEIL, P.K.; GABERT, V.M. and BACH KNUDSEN, K.E. (2003) Energy metabolism and protein balance in growing rats fed different levels of dietary fibre and protein. Archives of Animal Nutrition, 57 (2), 83–98.
LALEG, K.; SALLES, J.; BERRY, A.; GIRAUDET, C.; PATRAC, V.; GUILLET, C.; DENIS, P.; TESSIER, F.J.; GUILBAUD, A.; HOWSAM, M.; BOIRIE, Y.; MICARD, V. and WALRAND, S. (2019) Nutritional evaluation of mixed wheat-faba bean pasta in growing rats: Impact of protein source and drying temperature on protein digestibility and retention. British Journal of Nutrition, 121 (5), 496–507.
LATTIMER, J.M. and HAUB, M.D. (2010) Effects of dietary fiber and its components on metabolic health. Nutrients, 2, 1266–1289.
LERNER, A.; SHOENFELD, Y. and MATTHIAS, T. (2017) Adverse effects of gluten ingestion and advantages of gluten withdrawal in nonceliac autoimmune disease. Nutrition Reviews, 75 (12), 1046–1058.
LOPEZ, M.G.; MANCILLA-MARGALLI, N.A. and MENDOZA-DIAZ, G. (2003) Molecular Structures of Fructans from Agave tequilana Weber var. azul. Journal of Agricultural and Food Chemistry, 51 (27), 7835–7840.
MONTAÑEZ-SOTO, J.; VENEGAS-GONZÁLEZ, J.; VIVAR-VERA, M. and RAMOS-RAMÍREZ, E. (2011) Extracción, caracterización y cuantificación de los fructanos contenidos en la cabeza y en las hojas del Agave tequilana Weber AZUL. Bioagro, 23 (3), 199-206.
OPAZO-NAVARRETE, M.; TAGLE FREIRE, D.; BOOM, R.M. and JANSSEN, A.E.M. (2019) The Influence of Starch and Fibre on in Vitro Protein Digestibility of Dry Fractionated Quinoa Seed (Riobamba Variety). Food Biophysics, 14 (1), 49–59.
PIRMAN, T.; MIRAND, P.P.; SALOBIR, J.; PATUREAU MIRAND, P. and OREŠNIK, A. (2009) Effects of dietary pectin on protein digestion and metabolism in growing rats [online]. Acta Agriculturae Slovenica, 94 (2), 111-119. Available from: https://www.researchgate.net/publication/228351793.
RANINEN, K.; LAPPI, J.; MYKKÄNEN, H. and POUTANEN, K. (2011) Dietary fiber type reflects physiological functionality: Comparison of grain fiber, inulin, and polydextrose. Nutrition Reviews, 69 (1), 9–21.
RUCKER, R.B. and WATKINS, B.A. (2019) Inadequate diet descriptions: a conundrum for animal model research. Nutrition Research, 65: 1-3.
SANTIAGO-GARCÍA, P.A.; MELLADO-MOJICA, E.; LEÓN-MARTÍNEZ, F.M.; DZUL-CAUICH, J.G.; LÓPEZ, M.G. and GARCÍA-VIEYRA, M.I. (2021) Fructans (agavins) from Agave angustifolia and Agave potatorum as fat replacement in yogurt: Effects on physicochemical, rheological, and sensory properties. LWT- Food Science and Technology, 140, 110846.
DA SILVA, B.P.; DIAS, D.M.; DE CASTRO MOREIRA, M.E.; TOLEDO, R.C.L.; DA MATTA, S.L.P.; DELLA LUCIA, C.M.; MARTINO, H.S.D. and PINHEIRO-SANT’ANA, H.M. (2016) Chia Seed Shows Good Protein Quality, Hypoglycemic Effect and Improves the Lipid Profile and Liver and Intestinal Morphology of Wistar Rats. Plant Foods for Human Nutrition, 71 (3), 225–230.
SLAVIN, J.L., 2005. Dietary fiber and body weight. Nutrition, 21 (3), 411-418.
TAPSELL, L.C.; NEALE, E.P.; SATIJA, A. and HU, F.B. (2016) Foods, nutrients, and dietary patterns: Interconnections and implications for dietary guidelines. Advances in Nutrition, 7(3): 445–54.
THOMPSON, T.L.; SINGLETON, C.R.; SPRINGFIELD, S.E.; THORPE Jr, R.J. and ODOMS-YOUNG, A. (2020) Differences in nutrient intake and diet quality between non-Hispanic black and non-Hispanic white men in the United States. Public health reports, 135 (3), 334-342.
VERMA, A.K. and BANERJEE, R. (2010) Dietary fibre as functional ingredient in meat products: A novel approach for healthy living - A review. Journal of Food Science and Technology, 47 (3), 247-257.
WONG, K.H. and CHEUNG, P.C.K. (2003) Effect of fiber-rich brown seaweeds on protein bioavailability of casein in growing rats. International Journal of Food Sciences and Nutrition, 54 (4), 269–279.
ZHANG, W.; LI, D.; LIU, L.; ZANG, J.; DUAN, Q.; YANG, W. and ZHANG, L. (2013) The effects of dietary fiber level on nutrient digestibility in growing pigs [online]. Journal of Animal Science and Biotechnology, 4(1), 1-7. Available from: http://www.jasbsci.com/content/4/1/17
ZIMMERMANN, A.; VISSCHER, C. and KALTSCHMITT, M. (2021) Plant-based fructans for increased animal welfare: provision processes and remaining challenges. Biomass Conversion and Biorefinery, 1-19.