Series "Food and Biotechnologies"

The urgent task of the food industry is to introduce balanced food products that meet modern
quality and safety requirements into the diet of Russians. It can be done by grain sprouting in order
to obtain a new raw ingredient with a well-balanced amino acid composition, an increased amount
of vitamins and minerals, as well as dietary fibers, the use of which in food production will contribute
to the population health strengthening. The article describes an innovative method of intensification
of the sprouting process based on ultrasonic effect, which accelerates the process and makes
it safer. The process of wheat grain sprouting has a positive effect on the amount of protein mass
fraction of wheat grain and the amount of gluten. At the same time, the quality of gluten practically
does not change (there is its relaxation within 3–4 units, FDM. Since the process of sprouting takes
16–20 hours, the enzyme protein disulfide reductase has minimal effect on the disulfide bonds of
protein molecules and baking properties of flour (relative to its protein composition) practically do
not deteriorate. The authors note that the process of sprouting makes the raw ingredient the of the
most balanced amino acid composition. The increase in the number of both essential and nonessential
amino acids is observed. In the process of sprouting the number of essential amino acids
such as isoleucine, leucine, lysine, threonine increases. The bioavailability of sprouted grain increases
by an average of 6%, which makes it possible to recommend this type of grain ingredient as
an enriching additive in the production of bread and bakery products.

Калинина, И.В. Применение эффектов ультразвукового кавитационного воздействия как фактора интенсификации извлечения функциональных ингредиентов / И.В. Калинина, Р.И. Фаткуллин // Вестник ЮУрГУ. Серия «Пищевые и биотехнологии». – 2016. – Т. 4, № 1. – С. 64–70. DOI: 10.14529/ food160108

Казаков, Е.Д. Биохимия зерна и хлебопродуктов / Е.Д. Казаков, Г.П. Карпиленко. – 3-е изд., перераб. и доп. – СПб.: ГИОРД, 2005. – 512 с.

Мелешкина, Е.П. Современные требования, предъявляемые к качеству зерна пшеницы и пшеничной муки / Е.П. Мелешкина // Хлебопродукты. – 2018. – № 10. – С. 14–15.

Науменко, Н.В. Возможности использования биотехнологий при производстве пищевых продуктов / Н.В. Науменко // Актуальная биотехнология. – 2013. – № 2 (5). – С. 14–17.

Потороко, И.Ю. К вопросу обеспечения качества и безопасности воды, используемой в пищевых производствах / И.Ю. Потороко, Р.И. Фаткуллин, И.В. Калинина // Вестник ЮУрГУ. Серия «Экономика и менеджмент». – 2013. – Т. 7, № 1. – С. 165–169.

Потороко, И.Ю. Системный подход в технологии водоподготовки для пищевых производств / Потороко И.Ю., Фаткуллин Р.И., Цирульниченко Л.А. // Вестник ЮУрГУ. Серия «Экономика и менеджмент». – 2013. – Т. 7, № 3. – С. 153–158.

Технология и оборудование для обработки пищевых сред с использованием кавитационной дезинтеграции / С.Д. Шестаков, О.Н. Красуля, В.И. Богуш, И.Ю. Потороко. – М.: Изд-во «ГИОРД», 2013. – С. 98–102.

Хмелев, В.Н. Многофункциональные ультразвуковые аппараты и их применение в условиях малых производств, сельском и домашнем хозяйстве: монография / В.Н. Хмелев, О.В. Попова. – Барнаул: Изд. АлтГТУ, 1997. – С. 112–126.

Ding, J. Enhancing contents of γ-aminobutyric acid (GABA) and other micronutrients in dehulled rice during germination under normoxic and hypoxic conditions / J. Ding, T. Yang, H. Feng, M. Dong, M. Slavin, et al.// J. Agric. Food. Chem. – 2016. – Vol. 64 (5). – P. 1094–1102.

Fardet, A. New hypotheses for the healthprotective mechanisms of wholegrain cereals: what is beyond fibre? / A. Fardet // Nutrition Research Reviews. – 2010. – Vol. 23. – P. 65–134.

Giacco, R. Whole grain intake in relation to body weight: from epidemiological evidence to clinical trials / R. Giacco, G. Della Pepa, D. Luongo, G. Riccardi // Nutrition Metabolism and Cardiovascular Diseases. – 2011. – Vol. 21. – P. 901–908.

Hübner, F. The influence of germination conditions on beta-glucan, dietary fibre and phytate during the germination of oats and barley / F. Hübner, T. O’Neil, K.D. Cashman, E.K. Arendt // Eur. Food Res. Technol. – 2010. – Vol. 231 (1). – P. 27–35.

Hung, P.V. Phenolic acid composition of sprouted wheats by ultra-performance liq-uid chromatography (UPLC) and their antiox-idant activities / P.V. Hung, D.W. Hatcher, W. Barker // Food. Chem. – 2011. – Vol. 126 (4). – P. 1896–1901.

Jacobs, D.R. Wholegrain intake and cancer: an expanded review and meta-analysis / D.R. Jacobs, L. Marquart, J. Slavin, L.H. Kushi // Nutrition and Canceran International Journal. – 1998. – Vol. 30. – P. 85–96.

Mellen, P.B. Whole grain intake and cardiovascular disease: a meta-analysis / P.B. Mellen, T.F. Walsh, D.M. Herrington // Nutrition Metabolism and Cardiovascular Diseases. – 2008, – Vol. 18. – P. 283–290.

Nelson, K. Germinated grains: a superior whole grain functional food? / K. Nelson, L. Stojanovska, T. Vasiljevic, M. Mathai // Can. J. Physiol. Pharmacol. – 2013. – Vol. 91 (6). – P. 429–441.

Singh, А.В. Enhancement of attributes of cereals by germination and fermentation: a review / А.В. Singh, A.K. Singh, J. Rehal, A. Kaur, G. Jyot // Crit. Rev. Food. Sci. Nutr. – 2015. – Vol. 55 (11). – P. 1575–1589.

Tian, B. Physicochemical changes of oat seeds during germination / B. Tian, B. Xie, J. Shi, J. Wu, Y. Cai, et al.// Food. Chem. – 2010. – Vol. 119 (3). – P. 1195–1200.

Whole Grains Council, 2008. Definition of Sprouted Grains. – https://wholegrainscouncil.org/wholegrains-101/whats-whole-grain/sprouted-whole-grains/definitions-sprouted-grains.

Ye, E.Q. Greater wholegrain intake is associated with lower risk of type 2 diabetes, cardiovascular disease, and weight gain / E.Q. Ye, S.A. Chacko, E.L. Chou, M. Kugizaki, S. Liu // Journal of Nutrition. – 2012. – Vol. 142. – P. 1304–1313.