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dc.contributor.authorBazan Colque, Ronel Joel
dc.date.accessioned2023-12-22T01:44:48Z-
dc.date.available2023-12-22T01:44:48Z-
dc.date.issued2020-02-06
dc.identifier.citationBAZÁN COLQUE, Ronel Joel. Produção e caracterização físico-química de flocos por extrusão à base de arroz e farinha integral de banana. 2020. 90 f. Dissertação (Mestrado em Ciência e Tecnologia de Alimentos) - Instituto de Tecnologia, Departamento de Tecnologia de Alimentos, Universidade Federal Rural do Rio de Janeiro, Seropédica, RJ. 2020.por
dc.identifier.urihttps://rima.ufrrj.br/jspui/handle/20.500.14407/10905-
dc.description.abstractA inclusão de farinha de banana verde inteira nas novas formulações de alimentos por extrusão contribui como veículo para promover o bem-estar e saúde do consumidor. Assim, o presente trabalho teve como objetivo obter e avaliar as características físico-químicas e sensoriais dos flocos a partir de misturas de farinha de banana verde inteira e farinha de arroz por extrusão. A banana é uma cultura amplamente consumida em todo o mundo, mas, por ser um alimento altamente perecível, cerca de 40 a 50% da produção é perdida durante as etapas da cadeia de produção dessa fruta. O processamento da farinha pode ser parte da solução para essas perdas pós-colheita. A indústria de farinha de banana no Brasil gera uma quantidade de resíduos de casca para o ambiente, o uso integral de bananas no processamento de farinha pode reduzir a contaminação atualmente. Banana e arroz são uma excelente fonte de alimento para a produção de produtos por extrusão, com a possibilidade de obter um cereal matinal nutritivo, funcional e sem glúten para pessoas que são intolerantes ao glúten. Foi avaliado o efeito das condições de extrusão nas propriedades físico-químicas de flocos de misturas de banana verde com casca e arroz. As misturas de banana e arroz foram processadas em um extrusor de laboratório com um único parafuso, variando a proporção de farinha de banana verde inteira (FBVi, 50 – 70%), umidade do processo (UP, 27 – 33%) e temperatura do barril da extrusora (TB, 80 – 100 °C). Foram avaliadas a energia mecânica específica (EME), dureza, composição centesimal, índice de solubilidade em água (ISA), índice de absorção de água (IAA) e viscosidade de pasta. O EME variou de 171,60 a 344,98 kJ/ kg. Os extrudados foram laminados, cortados manualmente e secos com 6% de umidade. A dureza variou de 97,02 a 292,21 N, sendo a mais adequada a menor dureza para cereais matinais. Uma porção dos flocos foi moída, para a composição centesimal e fibra alimentar. Os flocos representam alimentos saudáveis, com alto teor de fibras (6,25 – 7,51%) e minerais (1,89 – 2.69%). O ISA variou de 4,81 – 8,62%, o IAA variou de 2,9 – 5,4 g de água. g-1. A viscosidade de pasta mostrou conversão parcial do amido. A proporção de FBVi e UP foram as condições que mais afetaram significativamente (p < 0,05) o processo. Para o segundo experimento, foi avaliado o impacto da extrusão e assadura nas propriedades físicas e tecnológicas de flocos de diferentes fontes de amido. Foram utilizadas farinhas de grits de milho, arroz branco e banana verde das variedades figo, prata e da terra. Foi usada uma extrusora de parafuso único. Os extrudados foram laminados, cortados manualmente, secos a 15% de umidade e assados a diferentes tempos (3, 4, 5 e 6 minutos), avaliando-se as propriedades físicas (umidade, cor, textura, espessura e densidade) e tecnológicas (ISA, IAA e viscosidade de pasta). A umidade desejável variou de 5,24 a 3,33% nos tempos de 5 e 6 minutos de assadura. Baixa dureza e maior crocancia ocorreram nas amostras cozidas entre 5 e 6 minutos. Maiores espessuras e densidades mais baixas dos flocos ocorreram aos 5 minutos de assadura. No caso das propriedades tecnológicas, o processo de extrusão mostrou efeito significativo (p < 0,05), em comparação como o processo de assadura. Flocos de banana verde (com e sem casca) e arroz branco foram processados nas melhores condições de processamento, com minerais avaliados (o potássio foi mais relevante nos flocos), levantamento de atributos, o que nos permite conhecer as características do produto e a vida útil na tigela mostrando pouca perda de dureza e pouco ganho de peso durante a imersão no leite.por
dc.description.sponsorshipCAPES - Coordenação de Aperfeiçoamento de Pessoal de Nível Superiorpor
dc.formatapplication/pdf*
dc.languageporpor
dc.publisherUniversidade Federal Rural do Rio de Janeiropor
dc.rightsAcesso Abertopor
dc.subjectCereal matinalpor
dc.subjectflocospor
dc.subjecttecnologia de extrusãopor
dc.subjectfibra alimentarpor
dc.subjectbananapor
dc.subjectBreakfast cerealeng
dc.subjectflakeseng
dc.subjectextrusion technologyeng
dc.subjectdietary fibreeng
dc.titleProdução e caracterização físico-química de flocos por extrusão à base de arroz e farinha integral de bananapor
dc.title.alternativeProduction and physicochemical characterization of flakes by extrusion based on rice and whole banana floureng
dc.typeDissertaçãopor
dc.description.abstractOtherThe inclusion of whole green banana flour in new extrusion food formulations contributes as a vehicle to promote consumer well-being and health. Thus, the present work aimed to obtain and evaluate the physical-chemical and sensory characteristics of the flakes from mixtures of whole green banana flour and extruded rice flour. The banana is a crop widely consumed worldwide, but because it is a highly perishable food, about 40 to 50% of production is lost during the stages of the production chain of this fruit. Flour processing can be part of the solution to these post-harvest losses. The banana flour industry in Brazil generates a quantity of peel residues for the environment, the full use of bananas in flour processing can reduce contamination today. Banana and rice are an excellent source of food for the production of products by extrusion, with the possibility of obtaining a nutritious, functional and gluten-free breakfast cereal for people who are gluten intolerant. The effect of extrusion conditions on the physicochemical properties of flakes of mixtures of green banana with peel and rice was evaluated. The banana and rice mixtures were processed in a laboratory extruder with a single screw, varying the proportion of whole green banana flour (FBVi, 50 - 70%), process moisture (UP, 27 - 33%) and temperature of the extruder barrel (TB, 80 - 100 °C). Specific mechanical energy (EME), hardness, chemical composition, water solubility index (ISA), water absorption index (IAA) and paste viscosity were evaluated. The EME ranged from 171.60 to 344.98 kJ/ kg. The extrudates were laminated, cut manually and dried with 6% moisture. The hardness ranged from 97.02 to 292.21 N, the most suitable being the lowest hardness for breakfast cereals. A portion of the flakes was ground, for the proximate composition and dietary fiber. The flakes represent healthy foods, with high fiber content (6.25 - 7.51%) and minerals (1.89 - 2.69%). The ISA varied from 4.81 - 8.62%, the IAA varied from 2.9 - 5.4 g of water. g-1. The paste viscosity showed partial conversion of the starch. The proportion of FBVi and UP were the conditions that most significantly affected (p < 0.05) the process. For the second experiment, the impact of extrusion and roasting on the physical and technological properties of flakes from different sources of starch was evaluated. Corn grits, white rice and green bananas of the fig, silver and earth varieties were used. A single screw extruder was used. The extrudates were laminated, cut manually, dried at 15% humidity and baked at different times (3, 4, 5 and 6 minutes), evaluating the physical (moisture, color, texture, thickness and density) and technological properties (ISA, IAA and paste viscosity). The desirable humidity ranged from 5.24 to 3.33% at 5 and 6 minutes of roasting. Low hardness and greater crispness occurred in samples cooked between 5 and 6 minutes. Higher thicknesses and lower densities of the flakes occurred at 5 minutes of roasting. In the case of technological properties, the extrusion process showed a significant effect (p < 0.05), in comparison with the roasting process. Green banana flakes (with and without peel) and white rice were processed in the best processing conditions, with evaluated minerals (potassium was more relevant in the flakes), survey of attributes, which allows us to know the product characteristics and life useful in the bowl showing little loss of hardness and little weight gain during immersion in milk.eng
dc.contributor.advisor1Ascheri, José Luís Ramírez
dc.contributor.advisor1ID105.290.788-13por
dc.contributor.advisor1Latteshttp://lattes.cnpq.br/1891994321882753por
dc.contributor.referee1Ascheri, José Luís Ramírez
dc.contributor.referee2Barbosa Júnior, José Lucena
dc.contributor.referee3Torrezan, Renata
dc.creator.ID064.803.367-80por
dc.creator.IDhttps://orcid.org/0000-0003-4374-9911por
dc.creator.Latteshttp://lattes.cnpq.br/4606489620975633por
dc.publisher.countryBrasilpor
dc.publisher.departmentInstituto de Tecnologiapor
dc.publisher.initialsUFRRJpor
dc.publisher.programPrograma de Pós-Graduação em Ciência e Tecnologia de Alimentospor
dc.relation.references*** CAPÍTULO I **** AGAMA-ACEVEDO, E.; ISLAS-HERNÁNDEZ, J. J.; PACHECO-VARGAS, G.; OSORIO-DÍAZ, P.; BELLO-PÉREZ, L. A. Starch digestibility and glycemic index of cookies partially substituted with unripe banana flour. LWT - Food Science and Technology, 46, n. 1, p. 177-182, 2012. AGAMA-ACEVEDO, E.; NUÑEZ-SANTIAGO, M. C.; ALVAREZ-RAMIREZ, J.; BELLO-PÉREZ, L. A. Physicochemical, digestibility and structural characteristics of starch isolated from banana cultivars. Carbohydrate Polymers, 124, p. 17-24, 2015. AGAMA-ACEVEDO, E.; SAÑUDO-BARAJAS, J. A.; VÉLEZ DE LA ROCHA, R.; GONZÁLEZ-AGUILAR, G. A.; BELLO-PERÉZ, L. A. Potential of plantain peels flour (Musa paradisiaca L.) as a source of dietary fiber and antioxidant compound. CyTA - Journal of Food, 14, n. 1, p. 117-123, 2015. ALAM, M. S.; KAUR, J.; KHAIRA, H.; GUPTA, K. Extrusion and Extruded Products: Changes in Quality Attributes as Affected by Extrusion Process Parameters: A Review. Critical Reviews in Food Science and Nutrition, 56, n. 3, p. 445-473, 2016. ALBERTSON, A. M.; FRANKO, D. L.; THOMPSON, D. R.; TUTTLE, C.; HOLSCHUH, N. M. Ready-to-Eat Cereal Intake is Associated with an Improved Nutrient Intake Profile among Food Insecure Children in the United States. Journal of Hunger & Environmental Nutrition, 8, n. 2, p. 200-220, 2013. ALKARKHI, A. F. M.; RAMLI, S. b.; YONG, Y. S.; EASA, A. M. Comparing physicochemical properties of banana pulp and peel flours prepared from green and ripe fruits. Food Chemistry, 129, n. 2, p. 312-318, 2011. ALVES, P. L. d. S.; BERRIOS, J. D. J.; PAN, J.; ASCHERI, J. L. R. Passion fruit shell flour and rice blends processed into fiber-rich expanded extrudates. CyTA - Journal of Food, 16, n. 1, p. 901-908, 2018. ANDRADE, B. A.; PERIUS, D. B.; DE MATTOS, N. V.; DE MELLO LUVIELMO, M.; MELLADO, M. S. Production of unripe banana flour (Musa spp) for application in whole wheat bread. Brazilian Journal of Food Technology, 21, 2018. ANUNCIAÇÃO, P. C.; CARDOSO, L. d. M.; GOMES, J. V. P.; DELLA LUCIA, C. M.; CARVALHO, C. W. P.; GALDEANO, M. C.; QUEIROZ, V. A. V.; ALFENAS, R. d. C. G.; MARTINO, H. S. D.; PINHEIRO-SANT'ANA, H. M. Comparing sorghum and wheat whole grain breakfast cereals: Sensorial acceptance and bioactive compound content. Food Chemistry, 221, p. 984-989, 2017. ANVISA. Regulamento técnico para produtos de cereais, amidos, farinhas e farelos. RDC n° 263, de 22 de setembro de 2005. ANVISA. Resolução da Diretoria Colegiada, n°54, de 12 de nov. de 2012. ANVISA. Legislação por categoria de produto: Farinhas. 2018. Disponível em: http://portal.anvisa.gov.br/legislacao#/visualizar/27619. Accesso em: 14/10/2018. ASCHERI, D. P. R.; CAVALCANTE, L. H.; ASCHERI, J. L. R.; DE CARVALHO, C. W. P. Physical-chemical characterization of pre-cooked mixed rice flour and barley bagasse. Seminario: Ciencias Agrarias, 37, n. 2, p. 737-750, 2016. ASP, N.-G.; BJÖRCK, I. Nutritional properties of extruded foods. In: Mercier, C., Linko, P., Harper, J.M. (Eds.), Extrusion Cooking. Amer. Assoc. of Cereal Chemists Inc., St. Paul, MN, USA. 1989. AURORE, G.; PARFAIT, B.; FAHRASMANE, L. Bananas, raw materials for making processed food products. Trends in Food Science & Technology, 20, n. 2, p. 78-91, 2009. AWOLU, O. O.; OLUWAFERANMI, P. M.; FAFOWORA, O. I.; OSEYEMI, G. F. Optimization of the extrusion process for the production of ready-to-eat snack from rice, cassava and kersting's groundnut composite flours. LWT - Food Science and Technology, 64, n. 1, p. 18-24, 2015. BELLO-PÉREZ, L. A.; AGAMA-ACEVEDO, E.; OSORIO-DÍAZ, P.; UTRILLA-COELLO, R. G.; GARCÍA-SUÁREZ, F. J. Chapter 22 - Banana and Mango Flours. In: PREEDY, V. R.; WATSON, R. R., et al (Ed.). Flour and Breads and their Fortification in Health and Disease Prevention. San Diego: Academic Press, 2011. p. 235-245. BERRIOS, J. D.; ASCHERI, J. L. R.; LOSSO, J. N. Extrusion Processing of Dry Beans and Pulses. In: Dry Beans and Pulses Production, Processing and Nutrition. 1 ed. ed. Arnes: Iowa State University Press: Processing and Nutrition (eds M. Siddiq and M. A. Uebersax), 2013. v. v.1, p. 191-203. BEZERRA, C. V.; AMANTE, E. R.; DE OLIVEIRA, D. C.; RODRIGUES, A. M. C.; DA SILVA, L. H. M. Green banana (Musa cavendishii) flour obtained in spouted bed – Effect of drying on physico-chemical, functional and morphological characteristics of the starch. Industrial Crops and Products, 41, p. 241-249, 2013. BHATTACHARYA, S. Extrusion Technology and Glass Transition. In: Non-Equilibrium States and Glass Transitions in Foods: Processing Effects and Product-Specific Implications: Elsevier Inc., 2016. p. 137-152. BOLANHO, B. C.; DANESI, E. D. G.; BELÉIA, A. D. Characterization of flours made from peach palm (Bactris gasipaes Kunth) by-products as a new food ingredient. Journal of Food and Nutrition Research, 53(1), p. 51-59, 2014. BORGES, A. d. M.; PEREIRA, J.; JÚNIOR, A. S.; PEREIRA DE LUCENA, E. M.; CESAR DE SALES, J. Estabilidade da pré-mistura de bolo elaborada com 60% de farinha de banana verde. Ciência e Agrotecnologia, 34, n. 1, p. 173-181, 2010. BORGES, A. L.; SOUZA, A. d. S.; MATOS, A. P. d.; LEDO, C. A. d. S.; RITZINGER, C. H. S. P.; ALMEIDA, C. O. d.; ALVES, É. J.; VIANA, E. d. S.; COELHO, E. F.; SOUZA, F. V. D.; MATSUURA, F. C.; NETO, F. P. L.; SEREJO, J. A. d. S.; SILVEIRA, J. R. S.; SOUZA, L. d. S.; POIANI, L. M.; LIMA, M. B.; PEREIRA, M. E. C.; FANCELLI, M.; MATSUURA, M. I. d. S. F.; WASZCZYNSKJ, N.; FILHO, P. E. M.; GODOY, R. C. B. d.; SILVA, S. d. O. e.; MEDINA, V. M.; CORDEIRO, Z. J. M. Banana: O produtor pergunta, a Embrapa responde. 2 ed. Embrapa, Brasília, 2012. CALDWELL, E. F.; MCKEEHEN, J. D.; KADAN, R. S. Breakfast Cereals. In: Reference Module in Food Science: Elsevier, 2016. CAMIRE, M. E.; CAMIRE, A.; KRUMHAR, K. Chemical and nutritional changes in foods during extrusion. Critical Reviews in Food Science and Nutrition, 29, n. 1, p. 35-57, 1990. CASTELO-BRANCO, V. N.; GUIMARÃES, J. N.; SOUZA, L.; GUEDES, M. R.; SILVA, P. M.; FERRÃO, L. L.; MIYAHIRA, R. F.; GUIMARÃES, R. R.; FREITAS, S. M. L.; REIS, M. C. d.; ZAGO, L. The use of green banana (Musa balbisiana) pulp and peel flour as an ingredient for tagliatelle pasta. Brazilian Journal of Food Technology, 20, 2017. CLIFTON, P.; KEOGH, J. Starch. In: CABALLERO, B.; FINGLAS, P. M., et al (Ed.). Encyclopedia of Food and Health. Oxford: Academic Press, 2016. p. 146-151. CORDOBA, L. d. P.; DA SILVA, R. G.; GOMES, D. d. S.; SCHNITZLER, E.; WASZCZYNSKYJ, N. Brazilian green banana. Journal of Thermal Analysis and Calorimetry, 2018. DA SILVA CONCEIÇÃO, A.; MATSUMOTO, K.; BAKRY, F.; BERND-SOUZA, R. B. Plant regeneration from long-term callus culture of AAA-group dessert banana. Pesquisa Agropecuaria Brasileira, 33, n. 8, p. 1291-1296, 1998. DALBHAGAT, C. G.; MAHATO, D. K.; MISHRA, H. N. Effect of extrusion processing on physicochemical, functional and nutritional characteristics of rice and rice-based products: A review. Trends in Food Science & Technology, 85, p. 226-240, 2019. DE BARROS MESQUITA, C.; LEONEL, M.; FRANCO, C. M. L.; LEONEL, S.; GARCIA, E. L.; DOS SANTOS, T. P. R. Characterization of banana starches obtained from cultivars grown in Brazil. International Journal of Biological Macromolecules, 89, p. 632-639, 2016. DE JESUS FILHO, M.; DO CARMO, L. B.; DELLA LUCIA, S. M.; SARAIVA, S. H.; COSTA, A. V.; OSÓRIO, V. M.; TEIXEIRA, L. J. Q. Banana liqueur: Optimization of the alcohol and sugar contents, sensory profile and analysis of volatile compounds. LWT, 97, p. 31-38, 2018. DELGADO-NIEBLAS, C.; RUIZ-BELTRÁN, K.; SÁNCHEZ-LIZÁRRAGA, J.; ZAZUETA-MORALES, J. d. J.; AGUILAR-PALAZUELOS, E.; CARRILLO-LÓPEZ, A.; CAMACHO-HERNÁNDEZ, I. L.; QUINTERO-RAMOS, A. Effect of extrusion on physicochemical, nutritional and antioxidant properties of breakfast cereals produced from bran and dehydrated naranjita pomace. CyTA - Journal of Food, 17, n. 1, p. 240-250, 2019. DOS ANJOS, A. S.; BARBOSA, J. L. J.; MARTINS, M. I. J. B. Farinha de banana verde como ingrediente funcional em produtos alimentícios. Ciência Rural, 45, n. 12, 2015. DOS SANTOS, P. A.; CALIARI, M.; SOARES SOARES JÚNIOR, M.; SOARES SILVA, K.; FLEURY VIANA, L.; GONÇALVES CAIXETA GARCIA, L.; SIQUEIRA DE LIMA, M. Use of agricultural by-products in extruded gluten-free breakfast cereals. Food Chemistry, 297, p. 124956, 2019. EMBRAPA. O cultivo da banana. 2. ed. re. e aum. ed. Brasilia: Empresa Brasileira de Pesquisa Agropecuaria, Centro Nacional de Pesquisa de Mandioca e Fruticultura Tropical, 1998. EMBRAPA. Empresa Brasileira de Pesquisa Agropecuária. 2018. Disponível em: http://www.agencia.cnptia.embrapa.br/Agencia40/AG01/Abertura.html. Acesso em: 13/10/2018. EMERY, E. A.; AHMAD, S.; KOETHE, J. D.; SKIPPER, A.; PERLMUTTER, S.; PASKIN, D. L. Banana Flakes Control Diarrhea in Enterally Fed Patients. Nutrition in Clinical Practice, 12, n. 2, p. 72-75, 1997. FAO. Banana cultivars. 2018. Disponível em: http://www.fao.org/economic/est/est-commodities/bananas/bananafacts/en/#.W3GQ6-gzbIW. Acesso em: 14/08/2018. FAO/WHO, Food and Agriculture Organization/ World Health Organization. Report of the 27th Session of the Codex Committee on Nutrition and Foods for Special Dietary Uses. Bonn, Germany. 2018. Acesso em: 13/10/2018. FAOSTAT. Crops and livestock products., 2016. Disponível em: http://www.fao.org/faostat/en/#data/TP. Acesso em: 08/11/2018. FAOSTAT. Agriculture Organization of the United Nations Statistics Division. Data-Crops-Production. 2019. Disponível em: http://www.fao.org/faostat/en/#data/QC. Acesso em: 09/08/2019. GAMLATH, S. Impact of ripening stages of banana flour on the quality of extruded products. International Journal of Food Science & Technology, 43, n. 9, p. 1541-1548, 2008. GHATTAS, L. A.; HANNA, L. M.; EL-SHEBINI, S. M.; TAPOZADA, S. T. Effect of daily consumption of a variety of grains on some of type 2 diabetic complications. Polish Journal of Food and Nutrition Science, 58, p. 503-506, 2008. GIBSON, S. A.; O'SULLIVAN, K. R. Breakfast cereal consumption patterns and nutrient intakes of British schoolchildren. Journal of the Royal Society of Health, 115, n. 6, p. 366-370, 1995. GODOY, R. C. Cereal extrusado, free glúten, formulado com subprodutos de arroz e quinoa. 2013. 80 f. Dissertação (Mestrado em Ciência e Tecnologia de Alimentos) - Universidade Federal de Goiás, Goiânia. 2013. GOMES, A. A. B.; FERREIRA, M. E.; PIMENTEL, T. C. Bread with flour obtained from green banana with its peel as partial substitute for wheat flour: Physical, chemical and microbiological characteristics and acceptance. International Food Research Journal, 23, n. 5, p. 2214-2222, 2016. GONDIM, T. M. d. S.; CAVALCANTE, M. d. J. B. Como produzir banana. Embrapa Acre-Documentos (INFOTECA-E): Rio Branco: Embrapa Acre-Documentos 44: 31 p. 2001. GUY, R. Extrusion Cooking: Technology and Applications. 1st, NW: Wood head Publishing Limited and CRC Press, Inc., Boca Raton, 200, p. 2001.2022-2025, 2001. HARPER, J. M.; CLARK, J. P. Food extrusion. Critical Reviews in Food Science and Nutrition, 11, n. 2, p. 155-215, 1979. IBGE - Instituto Brasileiro de Geografia e Estatística. Levantamento Sistemático da Produção Agrícola, LSPA. 2018. Disponível em: www.sidra.ibge.gov.br/bda/agric. Acesso em: 13/10/2018. ILO, S.; LIU, Y.; BERGHOFER, E. Extrusion Cooking of Rice Flour and Amaranth Blends. LWT - Food Science and Technology, 32, n. 2, p. 79-88, 1999. KADAN, R. S.; CALDWELL, E. F. CEREALS | Breakfast Cereals. In: CABALLERO, B. (Ed.). Encyclopedia of Food Sciences and Nutrition (Second Edition). Oxford: Academic Press, 2003. p. 1023-1027. KAUR, K. D.; JHA, A.; SABIKHI, L.; SINGH, A. K. Significance of coarse cereals in health and nutrition: a review. Journal of food science and technology. 51, n. 8, p. 1429-1441, 2014. KUMARI, R.; SINGH, K.; SINGH, R.; BHATIA, N.; NAIN, M. J. Development of healthy ready-to-eat (RTE) breakfast cereal from popped pearl millet. Indian Journal of Agricultural Sciences. v. 89, n. 5, p. 877-881, 2019. MARQUART, L.; PHAM, A.-T.; LAUTENSCHLAGER, L.; CROY, M.; SOBAL, J. Beliefs about Whole-Grain Foods by Food and Nutrition Professionals, Health Club Members, and Special Supplemental Nutrition Program for Women, Infants, and Children Participants/State Fair Attendees. Journal of the American Dietetic Association, 106, n. 11, p. 1856-1860, 2006. MASKAN, M.; ALTAN, A. Advances in food extrusion technology. CRC press, 2016. 1439815216. MCAULEY, J. A.; HOOVER, J. L. B.; KUNKEL, M. E.; ACTON, J. C. Relative Protein Efficiency Ratios for Wheat-Based Breakfast Cereals. 52, n. 4, p. 1111-1112, 1987. MENON, R. Banana Breeding. In: MOHANDAS, S. e RAVISHANKAR, K. V. (Ed.). Banana: Genomics and Transgenic Approaches for Genetic Improvement. Singapore: Springer Singapore, 2016. p. 13-34. MORENO, C. R.; FERNÁNDEZ, P. C. R.; RODRÍGUEZ, E. O. C.; CARRILLO, J. M.; ROCHÍN, S. M. Changes in Nutritional Properties and Bioactive Compounds in Cereals During Extrusion Cooking. In: Extrusion of Metals, Polymers and Food Products: IntechOpen, 2017. NAYAK, B.; BERRIOS, J. D. J.; POWERS, J. R.; TANG, J. Effect of Extrusion on the Antioxidant Capacity and Color Attributes of Expanded Extrudates Prepared from Purple Potato and Yellow Pea Flour Mixes. Journal of Food Science, 76, n. 6, p. C874-C883, 2011. OLIVEIRA, L. C.; ALENCAR, N. M. M.; STEEL, C. J. Improvement of sensorial and technological characteristics of extruded breakfast cereals enriched with whole grain wheat flour and jabuticaba (Myrciaria cauliflora) peel. LWT, 90, p. 207-214, 2018. OLIVEIRA, L. C.; ROSELL, C. M.; STEEL, C. J. Effect of the addition of whole-grain wheat flour and of extrusion process parameters on dietary fibre content, starch transformation and mechanical properties of a ready-to-eat breakfast cereal. International Journal of Food Science & Technology, 50, n. 6, p. 1504-1514, 2015. OLIVEIRA, L. d. C. Propriedades antioxidantes e características físicas, sensoriais e nutricionais de cereal matinal extrusado elaborado com farinha de trigo em grão inteiro e casca de jabuticaba (Myrciaria cauliflora). 2015. 250 f. Tese (doutorado) - Universidade Estadual de Campinas, Faculdade de Engenharia de Alimentos, Campinas, São Paulo. 2015 PACHECO-DELAHAYE, E.; MALDONADO, R.; PÉREZ, E.; SCHROEDER, M. Production and characterization of unripe plantain (Musa paradisiaca L.) flours. Interciencia, 33, n. 4, 2008. PALMER, J. K. BANANA PRODUCTS. In: INGLETT, G. E. e CHARALAMBOUS, G. (Ed.). Tropical Food: Chemistry and Nutrition: Academic Press, 1979. p. 625-635. PAREEK, S. Chapter 3 - Nutritional and Biochemical Composition of Banana (Musa spp.) Cultivars. In: SIMMONDS, M. S. J. e PREEDY, V. R. (Ed.). Nutritional Composition of Fruit Cultivars. San Diego: Academic Press, 2016. p. 49-81. PREEDY, V. R.; WATSON, R. R.; PATEL, V. B. Flour and breads and their fortification in health and disease prevention. Academic press, 2011. 0123808871. QAMAR, S.; SHAIKH, A. Therapeutic potentials and compositional changes of valuable compounds from banana- A review. Trends in Food Science & Technology, 79, p. 1-9, 2018. QIAN, H.; ZHANG, H. 22 - Rice flour and related products. In: BHANDARI, B.; BANSAL, N., et al (Ed.). Handbook of Food Powders: Woodhead Publishing, 2013. p. 553-575. REKHA, A. History, Origin, Domestication, and Evolution. In: MOHANDAS, S. e RAVISHANKAR, K. V. (Ed.). Banana: Genomics and Transgenic Approaches for Genetic Improvement. Singapore: Springer Singapore, 2016. p. 3-11. RIAZ, M. N.; ASIF, M.; ALI, R. Stability of Vitamins during Extrusion. Critical Reviews in Food Science and Nutrition, 49, n. 4, p. 361-368, 2009. RIEDL, K. M.; HAGERMAN, A. E. Tannin−Protein Complexes as Radical Scavengers and Radical Sinks. Journal of Agricultural and Food Chemistry, 49, n. 10, p. 4917-4923, 2001. ROSENTRATER, K. A.; EVERS, A. D. Chapter 9 - Breakfast cereals. In: ROSENTRATER, K. A. e EVERS, A. D. (Ed.). Kent's Technology of Cereals (Fifth Edition): Woodhead Publishing, 2018. p. 623-655. SALDIVAR, S. O. S. Cereals: Types and Composition. In: CABALLERO, B.; FINGLAS, P. M., et al (Ed.). Encyclopedia of Food and Health. Oxford: Academic Press, 2016. p. 718-723. SANTOS, I. L. Desenvolvimento de cereal matinal extrusado à base de farinha de milho (Zea mays), e pupunha (Bactris gasipaes Kunth). 2014. 128 f. Dissertação (Mestrado em Ciência de Alimentos) - Universidade Federal do Amazonas, Manaus. 2014. SARAWONG, C.; SCHOENLECHNER, R.; SEKIGUCHI, K.; BERGHOFER, E.; NG, P. K. W. Effect of extrusion cooking on the physicochemical properties, resistant starch, phenolic content and antioxidant capacities of green banana flour. Food Chemistry, 143, p. 33-39, 2014. SARWAR, M. H.; SARWAR, M. F.; SARWAR, M.; QADRI, N. A.; MOGHAL, S. J. J. o. c.; OILSEEDS. The importance of cereals (Poaceae: Gramineae) nutrition in human health: A review. Journal of cereals and oilseeds. 4, n. 3, p. 32-35, 2013. SILVA, E. M. M. d.; ASCHERI, J. L. R.; ASCHERI, D. P. R. Quality assessment of gluten-free pasta prepared with a brown rice and corn meal blend via thermoplastic extrusion. LWT - Food Science and Technology, 68, p. 698-706, 2016. SILVA, P.; ASSIS, G.; CARVALHO, A.; SIMÕES, M. J. E. A. O. Desenvolvimento e caracterização de cereal matinal extrudado de mandioca enriquecido com concentrado proteico de soro de leite. 2011. SIMMONDS, N. W.; SHEPHERD, K. The taxonomy and origins of the cultivated bananas. Botanical Journal of the Linnean Society, 55, n. 359, p. 302-312, 1955. SIMMONDS, N. W.; WEATHERUP, S. T. C. Numerical taxonomy of the wild bananas (Musa). New Phytologist, 115, n. 3, p. 567-571, 1990. SINGH, S.; GAMLATH, S.; WAKELING, L. Nutritional aspects of food extrusion: a review. International Journal of Food Science & Technology, 42, n. 8, p. 916-929, 2007. SINGHAL, P.; KAUSHIK, G. Therapeutic Effect of Cereal Grains: A Review. Critical Reviews in Food Science and Nutrition, 56, n. 5, p. 748-759, 2016. TACO. Tabela brasileira de composição de alimentos: NEPA. UNICAMP. Campinas - São Paulo: 161 p. 2011. THOMAS, R. G.; PEHRSSON, P. R.; AHUJA, J. K. C.; SMIEJA, E.; MILLER, K. B. Recent Trends in Ready-to-eat Breakfast Cereals in the U.S. Procedia Food Science, 2, p. 20-26, 2013. THOMPSON, A. K. 10 - Banana (Musa spp.). In: YAHIA, E. M. (Ed.). Postharvest Biology and Technology of Tropical and Subtropical Fruits: Woodhead Publishing, 2011. p. 216-244e. USMAN, G. O.; OKAFOR, G. I. Organoleptic properties and perception of maize, African yam bean, and defatted coconut flour-based breakfast cereals served in conventional forms. Food Science & Nutrition, 4(5), 716-722. 2016. VASANTHAN, T.; GAOSONG, J.; YEUNG, J.; LI, J. Dietary fiber profile of barley flour as affected by extrusion cooking. Food Chemistry, 77, n. 1, p. 35-40, 2002. WALTER, M.; MARCHEZAN, E.; DE AVILA, L. A. J. C. R. Arroz: composição e características nutricionais. Ciência Rural, 38, n. 4, p. 1184-1192, 2008. WHALEN, P.; BASON, M.; BOOTH, R.; WALKER, C.; WILLIAMS, P. Measurement of extrusion effects by viscosity profile using the Rapid Visco Analyser. Cereal Foods World, v. 42, n. 6, p. p. 469-475, 1997. WILES, N. L. The nutritional quality of South African ready-to-eat breakfast cereals. South African Journal of Clinical Nutrition, 30, n. 4, p. 93-100, 2017. WILLIAMS, P. G. The Benefits of Breakfast Cereal Consumption: A Systematic Review of the Evidence Base. Advances in Nutrition, 5, n. 5, p. 636S-673S, 2014. WÓJTOWICZ, A.; MITRUS, M.; ONISZCZUK, T.; MOŚCICKI, L.; KRĘCISZ, M.; ONISZCZUK, A. Selected Physical Properties, Texture and Sensory Characteristics of Extruded Breakfast Cereals based on Wholegrain Wheat Flour. Agriculture and Agricultural Science Procedia, 7, p. 301-308, 2015. WU, G.; ASHTON, J.; SIMIC, A.; FANG, Z.; JOHNSON, S. K. Mineral availability is modified by tannin and phytate content in sorghum flaked breakfast cereals. Food Research International, 103, p. 509-514, 2018. YAP, M.; FERNANDO, W. M. A. D. B.; BRENNAN, C. S.; JAYASENA, V.; COOREY, R. The effects of banana ripeness on quality indices for puree production. LWT - Food Science and Technology, 80, p. 10-18, 2017. YU, L.; RAMASWAMY, H. S.; BOYE, J. Twin-screw Extrusion of Corn Flour and Soy Protein Isolate (SPI) Blends: A Response Surface Analysis. Food and Bioprocess Technology, 5, n. 2, p. 485-497, 2012. ŽILIĆ, S.; MOGOL, B. A.; AKıLLıOĞLU, G.; SERPEN, A.; DELIĆ, N.; GÖKMEN, V. Effects of extrusion, infrared and microwave processing on Maillard reaction products and phenolic compounds in soybean. Journal of the Science of Food and Agriculture.94, n. 1, p. 45-51, 2014. *** CAPÍTULO II **** AGUSTIA, F. C.; ROSYIDAH, S.; SUBARDJO, Y. P.; RAMADHAN, G. R.; BETADITYA, D. Formulation of Flakes made from mocaf-black rice-tapioca high in protein and dietary fiber by soy and jack bean flour addition. IOP Conference Series: Earth and Environmental Science, 255, p. 012019, 2019. ALVES, P. L. d. S.; BERRIOS, J. D. J.; PAN, J.; ASCHERI, J. L. R. Passion fruit shell flour and rice blends processed into fiber-rich expanded extrudates. CyTA - Journal of Food, 16, n. 1, p. 901-908, 2018. ANDERSON, J. C.; CONWAY, H. F.; PFEIFER, V. F.; GRIFFIN, E. L. Gelatinization of corn grits by roll and extrusion cooking. Cereal Science Today, 14(1), 4–12. 1969. ANDRADE, B. A.; PERIUS, D. B.; DE MATTOS, N. V.; DE MELLO LUVIELMO, M.; MELLADO, M. S. Production of unripe banana flour (Musa spp.) for application in whole wheat bread. Brazilian Journal of Food Technology, 21, 2018. ANTON, A. A.; LUCIANO, F. B. Instrumental texture evaluation of extruded snack foods: A review. Ciencia y Tecnologia Alimentaria, 5, n. 4, p. 245-251, 2007. ANVISA. Regulamento Técnico Sobre Rotulagem Nutricional De Alimentos Embalados. Resolução - RDC Nº 360, de 23 de dezembro de 2003. 9 p. 2003. AOAC. Official Methods of Analysis of the Association Analytical Chemists (18th edition). Gaithersburg: AOAC International. 2005. ASCHERI, D. P. R.; CAVALCANTE, L. H.; ASCHERI, J. L. R.; DE CARVALHO, C. W. P. Physical-chemical characterization of pre-cooked mixed rice flour and barley bagasse. Semina:Ciencias Agrarias, 37, n. 2, p. 737-750, 2016. ASCHERI, J. L. R.; COLQUE, R. J. B.; BORSOI, L. M.; ASCHERI, D. P. R.; AREVALO, A. M.; DA SILVA, E. M. M. Extrusion Cooking using Fruits Peels, Whole Cereals and Grains. Global Journal of Nutrition & Food Science. 1 (5): 1-2 p, 2019. AURORE, G.; PARFAIT, B.; FAHRASMANE, L. Bananas, raw materials for making processed food products. Trends in Food Science & Technology, 20, n. 2, p. 78-91, 2009. BASTO, G. J.; CARVALHO, C. W. P.; SOARES, A. G.; COSTA, H. T. G. B.; CHÁVEZ, D. W. H.; GODOY, R. L. d. O.; PACHECO, S. Physicochemical properties and carotenoid content of extruded and non-extruded corn and peach palm (Bactris gasipaes, Kunth). LWT - Food Science and Technology, 69, p. 312-318, 2016. BEMILLER, J. N.; HUBER, K. C. Carbohydrates. In S. Damodaran, K. L. Parkin, & O. R. Fennema (Eds.), Fennema’s foodchemistry (pp. 75–130) (4th ed.). Boca Raton: CRC Press. 2008. BERRIOS, J. D.; ASCHERI, J. L. R.; LOSSO, J. N. Extrusion Processing of Dry Beans and Pulses. In: Dry Beans and Pulses Production, Processing and Nutrition. 1 ed. ed. Arnes: Iowa State University Press: Processing and Nutrition (eds M. Siddiq and M. A. Uebersax), 2013. v. v.1, p. 191-203. BORAH, A.; LATA MAHANTA, C.; KALITA, D. J. J. o. F. S.; TECHNOLOGY. Optimization of process parameters for extrusion cooking of low amylose rice flour blended with seeded banana and carambola pomace for development of minerals and fiber rich breakfast cereal. Journal of Food Science and Technology, 53, n. 1, p. 221-232, 2016. BOUVIER, J.-M.; CAMPANELLA, O. H. Extrusion processing technology: food and non-food biomaterials. John Wiley & Sons, 2014. CARVALHO, A. V.; MATTIETTO, R. d. A.; BASSINELLO, P. Z.; KOAKUZU, S. N.; RIOS, A. d. O.; MACIEL, R. d. A.; CARVALHO, R. N. Processing and characterization of extruded breakfast meal formulated with broken rice and bean flour. Journal Food Science and Technology, 32, p. 515-524, 2012. CARVALHO, C. W. P.; TAKEITI, C. Y.; ONWULATA, C. I.; PORDESIMO, L. O. Relative effect of particle size on the physical properties of corn meal extrudates: Effect of particle size on the extrusion of corn meal. Journal of Food Engineering, 98, n. 1, p. 103-109, 2010. CHEN, F. L.; WEI, Y. M.; ZHANG, B.; OJOKOH, A. O. System parameters and product properties response of soybean protein extruded at wide moisture range. Journal of Food Engineering, 96, n. 2, p. 208-213, 2010. CHUNG, H.-J.; LIU, Q.; LEE, L.; WEI, D. Relationship between the structure, physicochemical properties and in vitro digestibility of rice starches with different amylose contents. Food Hydrocolloids, 25, n. 5, p. 968-975, 2011. DALBHAGAT, C. G.; MAHATO, D. K.; MISHRA, H. N. Effect of extrusion processing on physicochemical, functional and nutritional characteristics of rice and rice-based products: A review. Trends in Food Science & Technology, 85, p. 226-240, 2019. DE BRIER, N.; GOMAND, S. V.; JOYE, I. J.; PAREYT, B.; COURTIN, C. M.; DELCOUR, J. A. The impact of pearling as a treatment prior to wheat roller milling on the texture and structure of bran-rich breakfast flakes. LWT - Food Science and Technology, 62, n. 1, Part 2, p. 668-674, 2015. DOGAN, H.; KARWE, M. V. Physicochemical properties of quinoa extrudates. Food Science and Technology International, 9(2), 101–114. 2003. DOMENECH, T.; PEUVREL-DISDIER, E.; VERGNES, B. The importance of specific mechanical energy during twin screw extrusion of organoclay based polypropylene nanocomposites. Composites Science and Technology, 75, p. 7-14, 2013. DOS ANJOS, A. S.; BARBOSA, J. L. J.; MARTINS, M. I. J. B. Farinha de banana verde como ingrediente funcional em produtos alimentícios. Ciência Rural, 45, n. 12, 2015. DOS SANTOS, P. A.; CALIARI, M.; SOARES SOARES JÚNIOR, M.; SOARES SILVA, K.; FLEURY VIANA, L.; GONÇALVES CAIXETA GARCIA, L.; SIQUEIRA DE LIMA, M. Use of agricultural by-products in extruded gluten-free breakfast cereals. Food Chemistry, 297, p. 124956, 2019. EMERY, E. A.; AHMAD, S.; KOETHE, J. D.; SKIPPER, A.; PERLMUTTER, S.; PASKIN, D. L. Banana Flakes Control Diarrhea in Enterally Fed Patients. Nutrition in Clinical Practice, 12, n. 2, p. 72-75, 1997. FANG, Y.; ZHANG, B.; WEI, Y.; LI, S. Effects of specific mechanical energy on soy protein aggregation during extrusion process studied by size exclusion chromatography coupled with multi-angle laser light scattering. Journal of Food Engineering, 115, n. 2, p. 220-225, 2013. FAOSTAT. Agriculture Organization of the United Nations Statistics Division. Data-Crops-Production. 2019. Disponível em: http://www.fao.org/faostat/en/#data/QC. Acesso em: 09/08/2019. GARCIA-VALLE, D. E.; BELLO-PEREZ, L. A.; FLORES-SILVA, P. C.; AGAMA-ACEVEDO, E.; TOVAR, J. Extruded Unripe Plantain Flour as an Indigestible Carbohydrate-Rich Ingredient. Frontiers in nutrition, 6, p. 2-2, 2019. GUY, R. Extrusion Cooking: Technology and Applications. 1st, NW: Wood head Publishing Limited and CRC Press, Inc., Boca Raton, 200, p. 2001.2022-2025, 2001. HASLINDA, W. H.; CHENG, L. H.; CHONG, L. C.; AZIAH, A. A. N. Chemical composition and physicochemical properties of green banana (Musa acuminata × balbisiana Colla cv. Awak) flour. International Journal of Food Sciences and Nutrition, 60, n. sup4, p. 232-239, 2009. ILO, S.; LIU, Y.; BERGHOFER, E. Extrusion Cooking of Rice Flour and Amaranth Blends. LWT - Food Science and Technology, 32, n. 2, p. 79-88, 1999. KANG, L. N.; WEI, Y. M.; ZHANG, B. J. Effects of technological parameters on system pressure and torque in soy protein texturization by high moisture extrusion. Journal of the Chinese Cereals Oils Association, 22, n. 4, p. 43-49, 2007. KOWALSKI, R. J.; MEDINA-MEZA, I. G.; THAPA, B. B.; MURPHY, K. M.; GANJYAL, G. M. Extrusion processing characteristics of quinoa (Chenopodium quinoa Willd.) var. Cherry Vanilla. Journal of Cereal Science, 70, p. 91-98, 2016. LAU, R.; CLUSKEY, M.; HOWES, E.; HAYES, P.; ROSS, A. Sensory Acceptance and Satiation Potential of Barley Flakes as a Breakfast Cereal Replacement for Oatmeal. Cereal Foods World, 61, p. 204-208, 2016. ONWULATA, C. I.; KONSTANCE, R. P. EXTRUDED CORN MEAL AND WHEY PROTEIN CONCENTRATE: EFFECT OF PARTICLE SIZE. Journal of Food Processing and Preservation, 30, n. 4, p. 475-487, 2006. PAULA, A. M.; CONTI-SILVA, A. C. Texture profile and correlation between sensory and instrumental analyses on extruded snacks. Journal of Food Engineering, 121, p. 9-14, 2014. QAMAR, S.; SHAIKH, A. Therapeutic potentials and compositional changes of valuable compounds from banana- A review. Trends in Food Science & Technology, 79, p. 1-9, 2018. RAYO, L. M.; CHAGURI E CARVALHO, L.; SARDÁ, F. A. H.; DACANAL, G. C.; MENEZES, E. W.; TADINI, C. C. Production of instant green banana flour (Musa cavendischii, var. Nanicão) by a pulsed-fluidized bed agglomeration. LWT - Food Science and Technology, 63, n. 1, p. 461-469, 2015. REBELLO, L. P. G.; RAMOS, A. M.; PERTUZATTI, P. B.; BARCIA, M. T.; CASTILLO-MUÑOZ, N.; HERMOSÍN-GUTIÉRREZ, I. Flour of banana (Musa AAA) peel as a source of antioxidant phenolic compounds. Food Research International, 55, p. 397-403, 2014. RUALES, J.; PÓLIT, P.; NAIR, B. M. Evaluation of the nutritional quality of flakes made of banana pulp and full-fat soya flour. Food Chemistry, 36, n. 1, p. 31-43, 1990. STOJCESKA, V.; AINSWORTH, P.; PLUNKETT, A.; İBANOĞLU, Ş. The effect of extrusion cooking using different water feed rates on the quality of ready-to-eat snacks made from food by-products. Food Chemistry, 114, n. 1, p. 226-232, 2009. TEBA, C. d. S.; SILVA, E. M. M. d.; CHÁVEZ, D. W. H.; CARVALHO, C. W. P.; ASCHERI, J. L. R. Effects of whey protein concentrate, feed moisture and temperature on the physicochemical characteristics of a rice-based extruded flour. Food Chemistry, 228, p. 287-296, 2017. VARGAS-SOLÓRZANO, J. W.; CARVALHO, C. W. P.; TAKEITI, C. Y.; ASCHERI, J. L. R.; QUEIROZ, V. A. V. Physicochemical properties of expanded extrudates from colored sorghum genotypes. Food Research International, 55, p. 37-44, 2014. ZHANG, W.; HOSENEY, R. C. Factors Affecting Expansion of Corn Meals with Poor and Good Expansion Properties. Cereal Chemistry, 75, n. 5, p. 639-643, 1998. *** CAPÍTULO III **** AMES, J. M. Applications of the Maillard reaction in the food industry. Food Chemistry, 62, n. 4, p. 431-439, 1998. ANDERSON, J. C.; CONWAY, H. F.; PFEIFER, V. F.; GRIFFIN, E. L. Gelatinization of corn grits by roll and extrusion cooking. Cereal Science Today, 14(1), 4–12. 1969. ANDRADE, B. A.; PERIUS, D. B.; MATTOS, N. V. d.; LUVIELMO, M. d. M.; MELLADO, M. S. Produção de farinha de banana verde (Musa spp.) para aplicação em pão de trigo integral. Brazilian Journal of Food Technology, 21, 2018. AOAC. Official Methods of Analysis of the Association Analytical Chemists. AOAC international, Gaithersburg, Maryland. 2005. ASCHERI, J. L. R.; COLQUE, R. J. B.; DE SOUSA, L. B. T.; ASCHERI, D. P. R.; DA SILVA, E. M. M. How does Extrusion Technology Help the Development of Foods with Better Nutritional Values? Global Journal of Nutrition & Food Science. 1: 1-2 p. 2019. BATTERMAN-AZCONA, S. J.; HAMAKER, B. R. Changes Occurring in Protein Body Structure and α-Zein During Cornflake Processing. Cereal chemistry. 75, n. 2, p. 217-221, 1998. BERRIOS, J. D.; ASCHERI, J. L. R.; LOSSO, J. N. Extrusion Processing of Dry Beans and Pulses. In: Dry Beans and Pulses Production, Processing and Nutrition. 1 ed. ed. Arnes: Iowa State University Press: Processing and Nutrition (eds M. Siddiq and M. A. Uebersax), 2013. v. v.1, p. 191-203. BHATTACHARYA, S. Roasting and Toasting Operations in Food: Process Engineering and Applications. In: Conventional and Advanced Food Processing Technologies, 2014. p. 221-248. BHATTACHARYA, S.; CHOUDHURY, G. S. Twin-screw extrusion of rice flour: Effect of extruder length-to-diameter ratio and barrel temperature on extrusion parameters and product characteristics. Journal of Food Processing and Preservation, 18, n. 5, p. 389-406, 1994. BISHARAT, G. I.; KATSAVOU, I. D.; PANAGIOTOU, N. M.; KROKIDA, M. K.; MAROULIS, Z. B. Investigation of functional properties and color changes of corn extrudates enriched with broccoli or olive paste. Food Science and Technology International, 21, n. 8, p. 613-630, 2014. BOUVIER, J.-M.; CAMPANELLA, O. H. Extrusion processing technology: food and non-food biomaterials. John Wiley & Sons, 2014. CALDWELL, E. F.; MCKEEHEN, J. D.; KADAN, R. S. Cereals: Breakfast Cereals. In: WRIGLEY, C.; CORKE, H., et al (Ed.). Encyclopedia of Food Grains (Second Edition). Oxford: Academic Press, 2016. p. 262-267. CHÁVEZ, D. W. H.; ASCHERI, J. L. R.; CARVALHO, C. W. P.; GODOY, R. L. O.; PACHECO, S. Sorghum and roasted coffee blends as a novel extruded product: Bioactive compounds and antioxidant capacity. Journal of Functional Foods, 29, p. 93-103, 2017. CHEN, F. L.; WEI, Y. M.; ZHANG, B.; OJOKOH, A. O. System parameters and product properties response of soybean protein extruded at wide moisture range. Journal of Food Engineering, 96, n. 2, p. 208-213, 2010. DOGAN, H.; KARWE, M. V. Physicochemical properties of quinoa extrudates. Food Science and Technology International, 9(2), 101–114. 2003. FANG, Y.; ZHANG, B.; WEI, Y.; LI, S. Effects of specific mechanical energy on soy protein aggregation during extrusion process studied by size exclusion chromatography coupled with multi-angle laser light scattering. Journal of Food Engineering, 115, n. 2, p. 220-225, 2013. FAST, R. B. Manufacturing technology of ready-to-eat cereals. In: Fast, R.B., Caldwell, E.F. (Eds.), Breakfast Cereals and How They Are Made. American Association of Cereal Chemists, St. Paul, Minnesota, USA, pp. 15–42. 1990. GUY, R. Extrusion Cooking: Technology and Applications. 1st, NW: Wood head Publishing Limited and CRC Press, Inc., Boca Raton, 200, p. 2001.2022-2025, 2001. JOGIHALLI, P.; SINGH, L.; SHARANAGAT, V. S. Effect of microwave roasting parameters on functional and antioxidant properties of chickpea (Cicer arietinum). LWT - Food Science and Technology, 79, p. 223-233, 2017. JOHNSON, J.; SCHUETTE, J. 10 - Breakfast cereals. In: BEEREN, C.; GROVES, K., et al (Ed.). Reducing Salt in Foods (Second Edition): Woodhead Publishing, 2019. p. 231-253. KANG, L. N.; WEI, Y. M.; ZHANG, B. J. Effects of technological parameters on system pressure and torque in soy protein texturization by high moisture extrusion. Journal of the Chinese Cereals Oils Association, 22, n. 4, p. 43-49, 2007. MARIOTTI, M.; ALAMPRESE, C.; PAGANI, M. A.; LUCISANO, M. Effect of puffing on ultrastructure and physical characteristics of cereal grains and flours. Journal of Cereal Science, 43, n. 1, p. 47-56, 2006. OWUSU-ANSAH, J.; VAN DE VOORT, F. R.; STANLEY, D. W. Textural and microstructural changes in corn starch as a function of extrusion variables. Canadian Institute of Food Science and Technology Journal, 17, n. 2, p. 65-70, 1984. RANI, P.; KUMAR, A.; PUROHIT, S. R.; RAO, P. S. Development of multigrain extruded flakes and their sensory analysis using fuzzy logic. Journal of Food Measurement and Characterization, 2019. STOJCESKA, V.; AINSWORTH, P.; PLUNKETT, A.; İBANOĞLU, Ş. The effect of extrusion cooking using different water feed rates on the quality of ready-to-eat snacks made from food by-products. Food Chemistry, 114, n. 1, p. 226-232, 2009. SUMITHRA, B.; BHATTACHARYA, S. Toasting of corn flakes: Product characteristics as a function of processing conditions. Journal of Food Engineering, 88, n. 3, p. 419-428, 2008. TEBA, C. d. S.; SILVA, E. M. M. d.; CHÁVEZ, D. W. H.; CARVALHO, C. W. P.; ASCHERI, J. L. R. Effects of whey protein concentrate, feed moisture and temperature on the physicochemical characteristics of a rice-based extruded flour. Food Chemistry, 228, p. 287-296, 2017. VARGAS-SOLÓRZANO, J. W.; CARVALHO, C. W. P.; TAKEITI, C. Y.; ASCHERI, J. L. R.; QUEIROZ, V. A. V. Physicochemical properties of expanded extrudates from colored sorghum genotypes. Food Research International, 55, p. 37-44, 2014. ZHANG, W.; LI, S.; ZHANG, B.; DRAGO, S. R.; ZHANG, J. Relationships between the gelatinization of starches and the textural properties of extruded texturized soybean protein-starch systems. Journal of Food Engineering, 174, p. 29-36, 2016. *** CAPÍTULO IV **** ANVISA, A. N. d. V. S. Resolução RDC n° 12, de 02 de janeiro de 2001. Aprova o Regulamento Técnico sobre padrões microbiológicos para alimentos. Brasil: Diário Oficial da União. 2001. ANVISA, A. N. d. V. S. Resolução RDC nº 269, de 23 de dezembro de 2005. Regulamento técnico sobre IDR de proteínas, vitaminas e minerais. 2005. AOAC. Official Methods of Analysis of the Association Analytical Chemists (18th edition). Gaithersburg: AOAC International. 2005. APHA, A. P. H. A. Compendium of Methods for the Microbiological Examination of Foods (4th. ed.). Washington: American Public Health Association. 2002. COX, S.; GUPTA, S.; ABU-GHANNAM, N. Effect of different rehydration temperatures on the moisture, content of phenolic compounds, antioxidant capacity and textural properties of edible Irish brown seaweed. LWT, 47, n. 2, p. 300-307, 2012. GODOY, R. C. Cereal extrusado, free glúten, formulado com subprodutos de arroz e quinoa. 2013. 80 f. Dissertação (Mestrado em Ciência e Tecnologia de Alimentos) - Universidade Federal de Goiás, Goiânia. 2013. JOHNSON, J.; SCHUETTE, J. 10 - Breakfast cereals. In: BEEREN, C.; GROVES, K., et al (Ed.). Reducing Salt in Foods (Second Edition): Woodhead Publishing, 2019. p. 231-253. LOUIE, J. C. Y.; DUNFORD, E. K.; WALKER, K. Z.; GILL, T. P. Nutritional quality of Australian breakfast cereals. Are they improving?. Appetite, 59, n. 2, p. 464-470, 2012. LOURES, M. M. R.; MINIM, V. P. R.; CERESINO, E. B.; CARNEIRO, R. C.; MINIM, L. A. J. S. C. A. Análise descritiva por ordenação na caracterização sensorial de iogurte diet sabor morango enriquecido com concentrado protéico do soro. Semina: Ciências Agrárias, 31, n. 3, p. 661-667, 2010. OCHOA-MARTÍNEZ, C. I.; AYALA-APONTE, A. Mathematical models of mass transfer in osmotic dehydration. Ciencia y Tecnologia Alimentaria, 4, n. 5, p. 330-342, 2005. OLIVEIRA, L. C.; ALENCAR, N. M. M.; STEEL, C. J. Improvement of sensorial and technological characteristics of extruded breakfast cereals enriched with whole grain wheat flour and jabuticaba (Myrciaria cauliflora) peel. LWT, 90, p. 207-214, 2018. OLIVEIRA, L. C.; ROSELL, C. M.; STEEL, C. J. J. I. Effect of the addition of whole‐grain wheat flour and of extrusion process parameters on dietary fibre content, starch transformation and mechanical properties of a ready‐to‐eat breakfast cereal. International journal of food science & technology, 50, n. 6, p. 1504-1514, 2015. OLIVEIRA, L. C.; SCHMIELE, M.; STEEL, C. J. Development of whole grain wheat flour extruded cereal and process impacts on color, expansion, and dry and bowl-life texture. LWT, 75, p. 261-270, 2017. SACCHETTI, G.; PITTIA, P.; PINNAVAIA, G. G. J. I. The effect of extrusion temperature and drying‐tempering on both the kinetics of hydration and the textural changes in extruded ready‐to‐eat breakfast cereals during soaking in semi‐skimmed milk. International journal of food science & technology, 40, n. 6, p. 655-663, 2005. SCHOLZ, M. B. d. S.; SILVA, J. V. N. d.; FIGUEIREDO, V. R. G. d.; KITZBERGER, C. S. G. Atributos sensoriais e características físico-químicas de bebida de cultivares de café do IAPAR. Coffe Science, 8, n. 1, p. 6-16, 2013. SHINAGAWA, F. B.; DELIZA, R.; ROSENTHAL, A.; ZARUR, M. A. J. C. R. Pressão hidrostática nos atributos sensoriais do néctar de mamão. Ciência Rural, 43, p. 1898-1904, 2013. TAKEUCHI, K. P.; SABADINI, E.; CUNHA, R. L. d. Análise das propriedades mecânicas de cereais matinais com diferentes fontes de amido durante o processo de absorção de leite. Ciência e Tecnologia de Alimentos, 25, p. 78-85, 2005. WILLIAMS, A. A.; LANGRON, S. P. J. J. The use of free‐choice profiling for the evaluation of commercial ports. Journal of the Science of Food and Agriculture, 35, n. 5, p. 558-568, 1984. WU, G.; ASHTON, J.; SIMIC, A.; FANG, Z.; JOHNSON, S. K. Mineral availability is modified by tannin and phytate content in sorghum flaked breakfast cereals. Food Research International, 103, p. 509-514, 2018.por
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