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Çimlendirilmiş Pseudo-tahılların Bazı Besinsel Özelliklerindeki Değişimler

Year 2024, , 39 - 50, 30.06.2024
https://doi.org/10.47137/usufedbid.1404354

Abstract

Bitkisel besin grubunda yer alan pseudo tahıllar yüksek besin değerleri ve gluten içermemeleri nedeniyle son yıllarda sağlık uzmanları ve gıda üreticilerinin dikkatini çekmektedir. Yüksek kaliteli bitkisel protein kaynağı olarak pseudo-tahılların tüketimi için birçok araştırma gerçekleştirilmektedir. Bitkisel kaynaklı gıdalarda bulunan besin bileşenlerinin biyo-yararlılık ve biyo-erişebilirlik özellikleri birçok etkene bağlı olarak sınırlanmaktadır. Besin bileşenlerinin biyo-yararlılık ve biyo-erişebilirlik özelliklerini arttırabilmek için birçok gıda işleme yöntemi kullanılmaktadır. Söz konusu yöntemlerden biri de tahılların çimlendirme işlemidir. Çimlendirmeyle pseudo-tahıllardaki makro, mikro ve anti besin bileşenlerinde çeşitli değişimler gözlemlenmektedir. Bu çalışmada bazı pseudo-tahılların çimlendirilmesiyle meydana gelen besinsel değişimler kısaca tartışılmıştır

Ethical Statement

Makale araştırma ve yayın etiğine uygun olarak hazırlanmıştır. OG çalışmanın konusu seçme, araştırma, yazma, inceleme ve düzenleme aşamalarında danışman olarak katkıda bulunmuştur. Yazarlar arasında herhangi bir kişisel ve finansal çıkar çatışması bulunmamaktadır.

References

  • Gong X, An Q, Le L, Geng F, Jiang L, Yan H, Xiang D, Peng L, Zou L, Zhao C, Wan Y. Prospects of cereal protein-derived bioactive peptides: Sources, bioactivities diversity, and production, Critical Reviews in Food Science and Nutrition, 2022;62(11):2855-2871.
  • Malik AM and Singh A. Pseudocereals proteins-A comprehensive review on its isolation, composition and quality evaluation techniques, Food Chemistry Advances, 2022;1:100001.
  • Kaur H, Shams R, Dash KK, Dar AH. A comprehensive reiew of pseudo-cereals: Nutritional profile, phytochemicals constituents and potential health promoting benefits, Applied Food Research, 2023;3(2):100351.
  • Hao Y, Hong Y, Guo H, Qin P, Huang A, Ren G. Transcriptomic and metabolomic landscape of quinoa during seed germination, BMC Plant Biology, 2022;22(1):1-13.
  • Elson CO, Cong Y, Qi F, Hershberg RM, Targan SR. Molecular approaches to the role of the microbiota in inflammatory bowel disease, Annals of the New York Academy of Sciences, 2006;1072(1): 39-51.
  • Turnbaugh PJ, Hamady M, Yatsunenko T, Cantarel BL, Duncan A, Ley RE, Sogin ML, Jones WJ, Roe BA, Affourtit JP, Egholm M, Henrissat B, Heath AC, Gordon JI. A core gut microbiome in obese and lean twins, Nature, 2009;457(7228):480-484.
  • Dogi CA, Galdeano CM and Perdigón G. Gut immune stimulation by non-pathogenic Gram (+) and Gram (−) bacteria. Comparison with a probiotic strain, Cytokine, 2008;41(3):223-231.
  • Rivera-Piza A and Lee SJ. Effects of dietary fibers and prebiotics in adiposity regulation via modulation of gut microbiota, Applied Biological Chemistry, 2020;63(1):1-12.
  • Beukema M, Faas MM and de Vos P. The effects of different dietary fiber pectin structures on the gastrointestinal immune barrier: impact via gut microbiota and direct effects on immune cells, Experimental & Molecular Medicine, 2020;52(9):1364-1376.
  • Sjögren YM, Tomicic S, Lundberg A, Böttcher MF, Björkstén B, Sverremark‐Ekström E, Jenmalm MC. Influence of early gut microbiota on the maturation of childhood mucosal and systemic immune responses: gut microbiota and immune responses, Clinical & Experimental Allergy, 2009;39(12):1842-1851.
  • Mir NA, Riar CS and Singh S. Nutritional constituents of pseudo cereals and their potential use in food systems: A review, Trends in Food Science & Technology, 2018;75:170–180.
  • Hitache Z, Al-Dalali S, Pei H, Cao X. Review of the health benefits of cereals and pseudocereals on human gut microbiota, Food and Bioprocess Technology, 2023;16(11):2382-2399.
  • Suárez-Estrella D, Bresciani A, Lametti S, Marengo M, Pagani AM, Marti A. Effect of sprouting on proteins and starch in quinoa (Chenopodium quinoa Willd.), Plant Foods for Human Nutrition, 2020;75(4):635-641.
  • Kraevska S, Stetsenko N and Korol O. Comparing between the amino acid composition of flax seeds before and after germination, Agrobiodiversity for Improving Nutrition, Health and Life Quality, 2017;1:253-257.
  • Wu F, Yang N, Touré A, Jin Z, Xu X. Germinated brown rice and its role in human health, Critical Reviews in Food Science and Nutrition, 2013;53(5):451-463.
  • Benincasa P, Falcinelli B, Lutts S, Stagnari F, Galieni A. Sprouted grains: A comprehensive review, Nutrients, 2019;11(2):421.
  • Le L, Gong X, An Q, Xiang D, Zou L, Peng L, Wu X, Tan M, Nie Z, Wu Q, Zhao G, Wan Y. Quinoa sprouts as potential vegetable source: Nutrient composition and functional contents of different quinoa sprout varieties, Food Chemistry, 2021;357:129752.
  • Atudorei D and Codina GG. Perspectives on the use of germinated legumes in the bread making process, a review, Applied Sciences, 2020;10(18):6244.
  • Dhillon B, Choudhary G and Sodhi NS. A study on physicochemical, antioxidant and microbial properties of germinated wheat flour and its utilization in breads, Journal of Food Science Technology, 2020;57(8):2800-2808.
  • Liu S, Wang W, Lu H, Shu Q, Zhang Y, Chen Q. New perspectives on physiological, biochemical and bioactive components during germination of edible seeds: A review, Trends in Food Science and Technology, 2022;123:187-197.
  • Lan Y, Zhang W, Liu F, Wang L, Yang X, Ma S, Wang Y, Liu X. Recent advances in physiochemical changes, nutritional value, bioactivities, and food applications of germinated quinoa: A comprehensive review, Food Chemistry, 2023;426:136390.
  • Suárez-Estrella D, Bresciani A, Iametti S, Marengo M, Pagani MA, Marti A. Effect of sprouting on proteins and starch in quinoa (Chenopodium quinoa Willd.), Plant Foods for Human Nutrition, 2020;75(4):635-641.
  • Hernández-García Y, Melgar-Lalanne G, Tellez-Medina DI, Ruiz-May E, Salgado-Cruz AP, Andrade-Velásquez A, Dorantes-Alvarez L, Lopez-Hernandez D and Gomez MPS. Scavenging peptides, antioxidant activity, and hypoglycemic activity of a germinated amaranth (Amaranthus hypochondriacus L.) beverage fermented by Lactiplantibacillus plantarum, Journal of Food Biochemistry, 2022;46(7):14139.
  • Devrajan N, Prakash P and Jindal N. Some physico-chemical properties of germinated and ungerminated buck wheat (Fagopyrum esculentum Dur), International Journal of Science, Environment and Technology, 2017;6(2):1491-1501.
  • Thakur P, Kumar K, Ahmed N, Chauhan D, Rizvi KUEH, Ocak S, Singh TP, Dhaliwal HS. Effect of soaking and germination treatments on nutritional, anti-nutritional and bioactive properties of amaranth (Amaranthus hypochondriacus L.), quinoa (Chenopodium quinoa L.) and buckwheat (Fagopyrum esculentum L.), Current Research in Food Science, 2021;4:917-925.
  • Beltrán-Orozco MC, Martínez-Olguín A and Robles-Ramírez MC. Changes in the nutritional composition and antioxidant capacity of chia seeds (Salvia hispanica L.) during germination process, Food Science Biotechnology, 2020;29(6):751.
  • Demir B and Bilgiçli N. Changes in chemical and anti-nutritional properties of pasta enriched with raw and germinated quinoa (Chenopodium quinoa Willd.) flours, Journal of Food Science and Technology, 2020;57(10):3884-3892.
  • Gómez-Favela MA, Gutierrez-Dorado R, Cuevas-Rodriguez EO, Canizalez-Roman VA, Leon-Sicairos CR, Milan-Carrillo J, Reyes-Moreno C. Improvement of chia seeds with antioxidant activity, GABA, essential amino acids and dietary fiber by controlled germination bioprocess, Plant Foods for Human Nutrition, 2017;72(4):345-352.
  • Poutanen KS, Karlund AO, Gomez-Gallego C, Johansson DP, Scheers NM, Marklinder IM, Eriksen AK, Silventoinen PC, Nordlund E, Sozer N, Hanhineva KJ, Kolehmainen RL. Grains – a major source of sustainable protein for health, Nutrition Reviews, 2022;80(6):1648-1663.
  • Khare B, Sangwan V and Rani V. Influence of sprouting on proximate composition, dietary fiber, nutrient availability, antinutrient, and antioxidant activity of flaxseed varieties, Journal of Food Processing Preservation, 2021;45(4):15344.
  • Hung PV, Trinh LND, Thuy NTX, Morita N. Changes in nutritional composition, enzyme activities and bioactive compounds of germinated buckwheat (Fagopyrum esculantum M.) under unchanged air and humidity conditions, International Journal of Food Science and Technology, 2021;56(7):3209-3217.
  • Correia I, Nunes A, Barros AS, Delgadillo I. Comparison of the effects induced by different processing methods on sorghum proteins, Journal of Cereal Science, 2010;51(1):146-151.
  • Agarwal A, Rizwana R, Tripathi AD, Kumar T, Sharma KP, Patel SKS. Nutritional and functional new perspectives and potential health benefits of quinoa and chia seeds, Antioxidant, 2023;12(7):1413.
  • Grancieri M, Martino HSD and Mejia EG. Chia seed (Salvia hispanica L.) as a source of proteins and bioactive peptides with health benefits: A review, Comprehensive Reviews in Food Science and Food Safety, 2019;18(2):480-499.
  • Paucar‐Menacho LM, Martínez‐Villaluenga C, Duenas M, Frias J, Penas E. Response surface optimisation of germination conditions to improve the accumulation of bioactive compounds and the antioxidant activity in quinoa, International Journal of Food Science and Technology, 2018;53(2):516-524.
  • Nemzer B and Al-Taher F. Analysis of fatty acid composition in sprouted grains, Foods, 2023;12(9):1853.
  • Omary MB, Fong C, Rothschild J, Finney P. Effects of germination on the nutritional profile of gluten‐free cereals and pseudocereals: a review, Cereal Chemistry, 2012;89(1):1-14.
  • Agregán R, Guzel N, Guzel M, Bangar SP, Zengin G, Kumar M, Lorenzo JM. The effects of processing technologies on nutritional and anti-nutritional properties of pseudocereals and minor cereal, Food and Bioprocess Technology, 2023;16(5):961-986.
  • Gamel TH, Linssen JP, Mesallam AS, Damir AA, Shekib LA. Effect of seed treatments on the chemical composition of two amaranth species: oil, sugars, fibres, minerals and vitamins, Journal of the Science of Food and Agriculture, 2006;86(1):82-89.
  • Pilco-Quesada S, Tian Y, Yang B, Repo-Carrasco-Valencia R, Suomela JP. Effects of germination and kilning on the phenolic compounds and nutritional properties of quinoa (Chenopodium quinoa) and kiwicha (Amaranthus caudatus), Journal of Cereal Science, 2020;94:102996.
  • Molska M, Reguła J, Rudzińska M, Świeca M. Fatty acids profile, atherogenic and thrombogenic health lipid indices of lyophilized buckwheat sprouts modified with the addition of Saccharomyces cerevisiae var. boulardii, Acta Scientiarum Polonorum Technologia Alimentaria, 2020;19(4):483-490.
  • Park SH and Morita N. Changes of bound lipids and composition of fatty acids in germination of quinoa seeds, Food Science and Technology Research, 2007;10(3):303-306.
  • Vrancheva R, Popova A, Mihaylova D, Krastanov A. Phytochemical analysis, in vitro antioxidant activity and germination capability of selected grains and seeds, Jordan Journal of Biological Sciences, 2020;13(3):337-342. Kaur H, Shams R, Dash KK, Dar AH. A comprehensive review of pseudo-cereals: Nutritional profile, phytochemicals constituents and potential health promoting benefits, Applied Food Research, 2023;3(2):100351.
  • Zhang G, Xu Z, Gao Y, Huang X, Zou Y, Yang T. Effects of germination on the nutritional properties, phenolic profiles, and antioxidant activities of buckwheat, Journal of Food Science, 2015;80(5):H1111-H1119.
  • Carciochi RA, Galván-D’Alessandro L, Vandendriessche P, Chollet S. Effect of germination and fermentation process on the antioxidant compounds of quinoa seeds, Plant Foods for Human Nutrition, 2016;71(4):361-367. Abdel-Aty AM, Elsayed AM, Salah HA, Bassuiny RI, Mohamed SA. Egyptian chia seeds (Salvia hispanica L.) during germination: Upgrading of phenolic profile, antioxidant, antibacterial properties and relevant enzymes activities, Food Science and Biotechnology, 2021;30:723-734.
  • Salgado VDSCN, Zago L, Fonseca END, Calderari MRDCM, Citelli M, Miyahira RF. Chemical composition, fatty acid profile, phenolic compound and antioxidant activity of raw, and germinated chia (Salvia hispanica L.) seeds, Plant Foods for Human Nutrition, 2023;78:735-741.
  • Ghafoor K, Juhaimi FA, Özcan MM, Uslu N, Ahmed IAM, Babiker EE. The effect of boiling, germination and roasting on bioactive properties, phenolic compounds, fatty acids and minerals of chia seed (Salvia hispanica L.) and oils, International Journal of Gastronomy and Food Science, 2022;27:100447.
  • De Ruiz ASC and Bressani R. Effect of germination on the chemical composition and nutritive value of amaranth grain, Cereal Chemistry, 1990;67(6):519-522.
  • Arslan A and Yalçın E. Pseudo-tahılların anti-besinsel bileşikleri ve azaltma yöntemleri, The Journal of Food, 2023;48(2):347-359.
  • Modgil R and Sood P. Effect of roasting and germination on carbohydrates and anti-nutritional constituents of indigenous and exotic cultivars of pseudo-cereal (Chenopodium), Journal of Life Sciences, 2017;9(1):64-70.
  • Ogbonna AC, Abuajah CI, Ide EO, Udofia US. Effect of malting conditions on the nutritional and anti-nutritional factors of sorghum grist, Food Technology, 2012;36(2):64–72.

Changes in Some Nutritional Properties of Germinated Pseudo-Cereals

Year 2024, , 39 - 50, 30.06.2024
https://doi.org/10.47137/usufedbid.1404354

Abstract

Pseudo-cereals which are a plant food group are taken notice of nutritionist and food producers because of their higher nutritional value and gluten free content. Several researches are conducted for consumption of pseudo-cereals as high-quality plant protein source. Bioavailability and bio-accessibility of nutritional components from plant-based foods are restricted depending certain factors. Several food processing techniques are used for improving bioavailability and bio-accessibility of nutritional components. One of the methods in question is the germination of cereals. Several changes in the macro, micro and anti-nutritional components in pseudo-cereals are observed with germination. In this review, the nutritional changes of pseudo-cereals occurring germination process are briefly discussed.

References

  • Gong X, An Q, Le L, Geng F, Jiang L, Yan H, Xiang D, Peng L, Zou L, Zhao C, Wan Y. Prospects of cereal protein-derived bioactive peptides: Sources, bioactivities diversity, and production, Critical Reviews in Food Science and Nutrition, 2022;62(11):2855-2871.
  • Malik AM and Singh A. Pseudocereals proteins-A comprehensive review on its isolation, composition and quality evaluation techniques, Food Chemistry Advances, 2022;1:100001.
  • Kaur H, Shams R, Dash KK, Dar AH. A comprehensive reiew of pseudo-cereals: Nutritional profile, phytochemicals constituents and potential health promoting benefits, Applied Food Research, 2023;3(2):100351.
  • Hao Y, Hong Y, Guo H, Qin P, Huang A, Ren G. Transcriptomic and metabolomic landscape of quinoa during seed germination, BMC Plant Biology, 2022;22(1):1-13.
  • Elson CO, Cong Y, Qi F, Hershberg RM, Targan SR. Molecular approaches to the role of the microbiota in inflammatory bowel disease, Annals of the New York Academy of Sciences, 2006;1072(1): 39-51.
  • Turnbaugh PJ, Hamady M, Yatsunenko T, Cantarel BL, Duncan A, Ley RE, Sogin ML, Jones WJ, Roe BA, Affourtit JP, Egholm M, Henrissat B, Heath AC, Gordon JI. A core gut microbiome in obese and lean twins, Nature, 2009;457(7228):480-484.
  • Dogi CA, Galdeano CM and Perdigón G. Gut immune stimulation by non-pathogenic Gram (+) and Gram (−) bacteria. Comparison with a probiotic strain, Cytokine, 2008;41(3):223-231.
  • Rivera-Piza A and Lee SJ. Effects of dietary fibers and prebiotics in adiposity regulation via modulation of gut microbiota, Applied Biological Chemistry, 2020;63(1):1-12.
  • Beukema M, Faas MM and de Vos P. The effects of different dietary fiber pectin structures on the gastrointestinal immune barrier: impact via gut microbiota and direct effects on immune cells, Experimental & Molecular Medicine, 2020;52(9):1364-1376.
  • Sjögren YM, Tomicic S, Lundberg A, Böttcher MF, Björkstén B, Sverremark‐Ekström E, Jenmalm MC. Influence of early gut microbiota on the maturation of childhood mucosal and systemic immune responses: gut microbiota and immune responses, Clinical & Experimental Allergy, 2009;39(12):1842-1851.
  • Mir NA, Riar CS and Singh S. Nutritional constituents of pseudo cereals and their potential use in food systems: A review, Trends in Food Science & Technology, 2018;75:170–180.
  • Hitache Z, Al-Dalali S, Pei H, Cao X. Review of the health benefits of cereals and pseudocereals on human gut microbiota, Food and Bioprocess Technology, 2023;16(11):2382-2399.
  • Suárez-Estrella D, Bresciani A, Lametti S, Marengo M, Pagani AM, Marti A. Effect of sprouting on proteins and starch in quinoa (Chenopodium quinoa Willd.), Plant Foods for Human Nutrition, 2020;75(4):635-641.
  • Kraevska S, Stetsenko N and Korol O. Comparing between the amino acid composition of flax seeds before and after germination, Agrobiodiversity for Improving Nutrition, Health and Life Quality, 2017;1:253-257.
  • Wu F, Yang N, Touré A, Jin Z, Xu X. Germinated brown rice and its role in human health, Critical Reviews in Food Science and Nutrition, 2013;53(5):451-463.
  • Benincasa P, Falcinelli B, Lutts S, Stagnari F, Galieni A. Sprouted grains: A comprehensive review, Nutrients, 2019;11(2):421.
  • Le L, Gong X, An Q, Xiang D, Zou L, Peng L, Wu X, Tan M, Nie Z, Wu Q, Zhao G, Wan Y. Quinoa sprouts as potential vegetable source: Nutrient composition and functional contents of different quinoa sprout varieties, Food Chemistry, 2021;357:129752.
  • Atudorei D and Codina GG. Perspectives on the use of germinated legumes in the bread making process, a review, Applied Sciences, 2020;10(18):6244.
  • Dhillon B, Choudhary G and Sodhi NS. A study on physicochemical, antioxidant and microbial properties of germinated wheat flour and its utilization in breads, Journal of Food Science Technology, 2020;57(8):2800-2808.
  • Liu S, Wang W, Lu H, Shu Q, Zhang Y, Chen Q. New perspectives on physiological, biochemical and bioactive components during germination of edible seeds: A review, Trends in Food Science and Technology, 2022;123:187-197.
  • Lan Y, Zhang W, Liu F, Wang L, Yang X, Ma S, Wang Y, Liu X. Recent advances in physiochemical changes, nutritional value, bioactivities, and food applications of germinated quinoa: A comprehensive review, Food Chemistry, 2023;426:136390.
  • Suárez-Estrella D, Bresciani A, Iametti S, Marengo M, Pagani MA, Marti A. Effect of sprouting on proteins and starch in quinoa (Chenopodium quinoa Willd.), Plant Foods for Human Nutrition, 2020;75(4):635-641.
  • Hernández-García Y, Melgar-Lalanne G, Tellez-Medina DI, Ruiz-May E, Salgado-Cruz AP, Andrade-Velásquez A, Dorantes-Alvarez L, Lopez-Hernandez D and Gomez MPS. Scavenging peptides, antioxidant activity, and hypoglycemic activity of a germinated amaranth (Amaranthus hypochondriacus L.) beverage fermented by Lactiplantibacillus plantarum, Journal of Food Biochemistry, 2022;46(7):14139.
  • Devrajan N, Prakash P and Jindal N. Some physico-chemical properties of germinated and ungerminated buck wheat (Fagopyrum esculentum Dur), International Journal of Science, Environment and Technology, 2017;6(2):1491-1501.
  • Thakur P, Kumar K, Ahmed N, Chauhan D, Rizvi KUEH, Ocak S, Singh TP, Dhaliwal HS. Effect of soaking and germination treatments on nutritional, anti-nutritional and bioactive properties of amaranth (Amaranthus hypochondriacus L.), quinoa (Chenopodium quinoa L.) and buckwheat (Fagopyrum esculentum L.), Current Research in Food Science, 2021;4:917-925.
  • Beltrán-Orozco MC, Martínez-Olguín A and Robles-Ramírez MC. Changes in the nutritional composition and antioxidant capacity of chia seeds (Salvia hispanica L.) during germination process, Food Science Biotechnology, 2020;29(6):751.
  • Demir B and Bilgiçli N. Changes in chemical and anti-nutritional properties of pasta enriched with raw and germinated quinoa (Chenopodium quinoa Willd.) flours, Journal of Food Science and Technology, 2020;57(10):3884-3892.
  • Gómez-Favela MA, Gutierrez-Dorado R, Cuevas-Rodriguez EO, Canizalez-Roman VA, Leon-Sicairos CR, Milan-Carrillo J, Reyes-Moreno C. Improvement of chia seeds with antioxidant activity, GABA, essential amino acids and dietary fiber by controlled germination bioprocess, Plant Foods for Human Nutrition, 2017;72(4):345-352.
  • Poutanen KS, Karlund AO, Gomez-Gallego C, Johansson DP, Scheers NM, Marklinder IM, Eriksen AK, Silventoinen PC, Nordlund E, Sozer N, Hanhineva KJ, Kolehmainen RL. Grains – a major source of sustainable protein for health, Nutrition Reviews, 2022;80(6):1648-1663.
  • Khare B, Sangwan V and Rani V. Influence of sprouting on proximate composition, dietary fiber, nutrient availability, antinutrient, and antioxidant activity of flaxseed varieties, Journal of Food Processing Preservation, 2021;45(4):15344.
  • Hung PV, Trinh LND, Thuy NTX, Morita N. Changes in nutritional composition, enzyme activities and bioactive compounds of germinated buckwheat (Fagopyrum esculantum M.) under unchanged air and humidity conditions, International Journal of Food Science and Technology, 2021;56(7):3209-3217.
  • Correia I, Nunes A, Barros AS, Delgadillo I. Comparison of the effects induced by different processing methods on sorghum proteins, Journal of Cereal Science, 2010;51(1):146-151.
  • Agarwal A, Rizwana R, Tripathi AD, Kumar T, Sharma KP, Patel SKS. Nutritional and functional new perspectives and potential health benefits of quinoa and chia seeds, Antioxidant, 2023;12(7):1413.
  • Grancieri M, Martino HSD and Mejia EG. Chia seed (Salvia hispanica L.) as a source of proteins and bioactive peptides with health benefits: A review, Comprehensive Reviews in Food Science and Food Safety, 2019;18(2):480-499.
  • Paucar‐Menacho LM, Martínez‐Villaluenga C, Duenas M, Frias J, Penas E. Response surface optimisation of germination conditions to improve the accumulation of bioactive compounds and the antioxidant activity in quinoa, International Journal of Food Science and Technology, 2018;53(2):516-524.
  • Nemzer B and Al-Taher F. Analysis of fatty acid composition in sprouted grains, Foods, 2023;12(9):1853.
  • Omary MB, Fong C, Rothschild J, Finney P. Effects of germination on the nutritional profile of gluten‐free cereals and pseudocereals: a review, Cereal Chemistry, 2012;89(1):1-14.
  • Agregán R, Guzel N, Guzel M, Bangar SP, Zengin G, Kumar M, Lorenzo JM. The effects of processing technologies on nutritional and anti-nutritional properties of pseudocereals and minor cereal, Food and Bioprocess Technology, 2023;16(5):961-986.
  • Gamel TH, Linssen JP, Mesallam AS, Damir AA, Shekib LA. Effect of seed treatments on the chemical composition of two amaranth species: oil, sugars, fibres, minerals and vitamins, Journal of the Science of Food and Agriculture, 2006;86(1):82-89.
  • Pilco-Quesada S, Tian Y, Yang B, Repo-Carrasco-Valencia R, Suomela JP. Effects of germination and kilning on the phenolic compounds and nutritional properties of quinoa (Chenopodium quinoa) and kiwicha (Amaranthus caudatus), Journal of Cereal Science, 2020;94:102996.
  • Molska M, Reguła J, Rudzińska M, Świeca M. Fatty acids profile, atherogenic and thrombogenic health lipid indices of lyophilized buckwheat sprouts modified with the addition of Saccharomyces cerevisiae var. boulardii, Acta Scientiarum Polonorum Technologia Alimentaria, 2020;19(4):483-490.
  • Park SH and Morita N. Changes of bound lipids and composition of fatty acids in germination of quinoa seeds, Food Science and Technology Research, 2007;10(3):303-306.
  • Vrancheva R, Popova A, Mihaylova D, Krastanov A. Phytochemical analysis, in vitro antioxidant activity and germination capability of selected grains and seeds, Jordan Journal of Biological Sciences, 2020;13(3):337-342. Kaur H, Shams R, Dash KK, Dar AH. A comprehensive review of pseudo-cereals: Nutritional profile, phytochemicals constituents and potential health promoting benefits, Applied Food Research, 2023;3(2):100351.
  • Zhang G, Xu Z, Gao Y, Huang X, Zou Y, Yang T. Effects of germination on the nutritional properties, phenolic profiles, and antioxidant activities of buckwheat, Journal of Food Science, 2015;80(5):H1111-H1119.
  • Carciochi RA, Galván-D’Alessandro L, Vandendriessche P, Chollet S. Effect of germination and fermentation process on the antioxidant compounds of quinoa seeds, Plant Foods for Human Nutrition, 2016;71(4):361-367. Abdel-Aty AM, Elsayed AM, Salah HA, Bassuiny RI, Mohamed SA. Egyptian chia seeds (Salvia hispanica L.) during germination: Upgrading of phenolic profile, antioxidant, antibacterial properties and relevant enzymes activities, Food Science and Biotechnology, 2021;30:723-734.
  • Salgado VDSCN, Zago L, Fonseca END, Calderari MRDCM, Citelli M, Miyahira RF. Chemical composition, fatty acid profile, phenolic compound and antioxidant activity of raw, and germinated chia (Salvia hispanica L.) seeds, Plant Foods for Human Nutrition, 2023;78:735-741.
  • Ghafoor K, Juhaimi FA, Özcan MM, Uslu N, Ahmed IAM, Babiker EE. The effect of boiling, germination and roasting on bioactive properties, phenolic compounds, fatty acids and minerals of chia seed (Salvia hispanica L.) and oils, International Journal of Gastronomy and Food Science, 2022;27:100447.
  • De Ruiz ASC and Bressani R. Effect of germination on the chemical composition and nutritive value of amaranth grain, Cereal Chemistry, 1990;67(6):519-522.
  • Arslan A and Yalçın E. Pseudo-tahılların anti-besinsel bileşikleri ve azaltma yöntemleri, The Journal of Food, 2023;48(2):347-359.
  • Modgil R and Sood P. Effect of roasting and germination on carbohydrates and anti-nutritional constituents of indigenous and exotic cultivars of pseudo-cereal (Chenopodium), Journal of Life Sciences, 2017;9(1):64-70.
  • Ogbonna AC, Abuajah CI, Ide EO, Udofia US. Effect of malting conditions on the nutritional and anti-nutritional factors of sorghum grist, Food Technology, 2012;36(2):64–72.
There are 51 citations in total.

Details

Primary Language Turkish
Subjects Biochemistry and Cell Biology (Other)
Journal Section Review Article
Authors

Ayşe Nur Kunca This is me 0000-0002-8039-3646

Onur Güneşer 0000-0002-3927-4469

Publication Date June 30, 2024
Submission Date December 13, 2023
Acceptance Date January 25, 2024
Published in Issue Year 2024

Cite

APA Kunca, A. N., & Güneşer, O. (2024). Çimlendirilmiş Pseudo-tahılların Bazı Besinsel Özelliklerindeki Değişimler. Uşak Üniversitesi Fen Ve Doğa Bilimleri Dergisi, 8(1), 39-50. https://doi.org/10.47137/usufedbid.1404354
AMA Kunca AN, Güneşer O. Çimlendirilmiş Pseudo-tahılların Bazı Besinsel Özelliklerindeki Değişimler. Uşak Üniversitesi Fen ve Doğa Bilimleri Dergisi. June 2024;8(1):39-50. doi:10.47137/usufedbid.1404354
Chicago Kunca, Ayşe Nur, and Onur Güneşer. “Çimlendirilmiş Pseudo-tahılların Bazı Besinsel Özelliklerindeki Değişimler”. Uşak Üniversitesi Fen Ve Doğa Bilimleri Dergisi 8, no. 1 (June 2024): 39-50. https://doi.org/10.47137/usufedbid.1404354.
EndNote Kunca AN, Güneşer O (June 1, 2024) Çimlendirilmiş Pseudo-tahılların Bazı Besinsel Özelliklerindeki Değişimler. Uşak Üniversitesi Fen ve Doğa Bilimleri Dergisi 8 1 39–50.
IEEE A. N. Kunca and O. Güneşer, “Çimlendirilmiş Pseudo-tahılların Bazı Besinsel Özelliklerindeki Değişimler”, Uşak Üniversitesi Fen ve Doğa Bilimleri Dergisi, vol. 8, no. 1, pp. 39–50, 2024, doi: 10.47137/usufedbid.1404354.
ISNAD Kunca, Ayşe Nur - Güneşer, Onur. “Çimlendirilmiş Pseudo-tahılların Bazı Besinsel Özelliklerindeki Değişimler”. Uşak Üniversitesi Fen ve Doğa Bilimleri Dergisi 8/1 (June 2024), 39-50. https://doi.org/10.47137/usufedbid.1404354.
JAMA Kunca AN, Güneşer O. Çimlendirilmiş Pseudo-tahılların Bazı Besinsel Özelliklerindeki Değişimler. Uşak Üniversitesi Fen ve Doğa Bilimleri Dergisi. 2024;8:39–50.
MLA Kunca, Ayşe Nur and Onur Güneşer. “Çimlendirilmiş Pseudo-tahılların Bazı Besinsel Özelliklerindeki Değişimler”. Uşak Üniversitesi Fen Ve Doğa Bilimleri Dergisi, vol. 8, no. 1, 2024, pp. 39-50, doi:10.47137/usufedbid.1404354.
Vancouver Kunca AN, Güneşer O. Çimlendirilmiş Pseudo-tahılların Bazı Besinsel Özelliklerindeki Değişimler. Uşak Üniversitesi Fen ve Doğa Bilimleri Dergisi. 2024;8(1):39-50.