Evaluation of the Triticale Flour Blend Dough in the Mixing and Fermentation Processes
The research was accomplished on triticale flour blend, which was made from whole grain triticale, rye, hull-less barley flour and rice, maize flour. The aim of this research was to evaluate physico-chemical and sensory properties of triticale flour blend dough in the mixing and fermentation processes. For dough making was used triticale flour blend, yeast, sugar, salt, and water. In the mixing process ware evaluated moisture, acidity, pH, and dough sensory properties (softness, viscosity, and stickiness), but in the fermentation process ware evaluated volume, moisture, acidity, and pH. During present research was established that increasing fermentation temperature and time, increase dough temperature, volume, moisture, and acidity. The mixing time and fermentation time and temperature have significant effect (p<0.05) on triticale flour blend dough physico-chemical and sensory properties.
[1] N. L. Darvey and H. Naeem, J. P. Gustafson, “Triticale: production and
utilization,” in Handbook of Cereal Science and Technology, 2nd ed., K.
Kulp, J. Ponte, Eds. New York: Marcel Dekker, 2000, pp. 257–274.
[2] G. Varughese, W. H. Pfeiffer, and R. J. Pena, “Triticale: A Successful
alternative crop (Part 1),” J. Cereal Foods World, vol. 41, no. 6,
pp. 474–482, 1996.
[3] G. Oettler, “The fortune of a botanical curiosity – Triticale: past, present
and future,” J. Agric. Sci., vol. 143, is. 5, pp. 329–346, 2005.
[4] N.L. Kent, A.D. Evers, Kent’s Technology of Cereals, 4th edn. Oxford:
Elsevier, 1994.
[5] M. Mergoum, W. H. Pfeiffer, R. J. Peña, K. Ammar, and S. Rajaram,
“Triticale crop improvement: the CIMMYT programme,” in Triticale
Improvement and Production, M. Mergoum, H. Gómez-Macpherson,
Eds. FAO Plant Production and Protection Paper 179, 2004, pp. 11–22.
[6] N. C. Popa, R. Tamba-Berhoiu, S. Popescu, M. Varga, and G. G.
Codina, “Predictive model of the alveografic parameters in flours
obtained from Romanian grains,” Rom. Biotech. Lett., vol. 14, no. 2, pp.
4234–4242, 2009.
[7] P. W. Gras, H. C. Carpenter, and R. S. Andersen, “Modelling the
developmental rheology of wheat flour dough using extension tests,” J.
Cereal Sci. vol. 31, is. 1, pp. 1–13, 2000.
[8] H. Zheng, M.P. Morgenstern, O.H. Campanella, and N.G. Larsen,
“Rheological properties of dough during mechanical dough
development,” J. Cereal Sci., vol. 32, is. 3, pp. 293–306, 2000.
[9] A.J. Wilson, M.P. Morgenstern, and S. Kavale, “Mixing response of a
variable speed 125 g laboratory scale mechanical dough development
mixer,” J. Cereal Sci., vol. 34, is. 2, pp. 151–158, 2001.
[10] H. A. Naeem, N.L. Darvey, P.W. Gras, and F. MacRitchie, “Mixing
properties, baking potential, and functionality changes in storage
proteins during dough development of triticale wheat flour blends,”
Cereal Chem., vol. 79, no. 3, pp. 332–339, 2002.
[11] B. J. Dobraszczyk, and M.P. Morgenstern, “Rheology and the bread
making process,” J. Cereal Sci.,vol. 38, no. 2, pp. 229–245, 2003.
[12] A. Angioloni, S. Romani, G. G. Pinnavaia, M. D. Rosa, “Characteristics
of Bread Making Doughs: Influence of Sourdough Fermentation on the
Fundamental Rheological Properties,” Eur. Food Res. Technol., vol.
222, is. 1-2, pp. 54–57, 2006.
[13] C. I. Clarke, T. J. Schober, and E. K. Arendt, “Effect of single strain and
traditional mixed strain starter cultures on rheological properties of
wheat dough and on bread quality,” Cereal Chem., vol. 79, no. 5, pp.
640–647, 2002.
[14] H. M. Elmehdi, J. H. Page, and M. G. Scanlon, “Monitoring Dough
Fermentation Using Acoustic Waves,” Food Bioprod. Process., vol. 81,
is. 3, pp. 217–223, 2003.
[15] H. Weiser, “The use of redox agents,” in Bread making: Improving
quality, S. P. Cauvain, Ed. England, Cambrige: Woodhead Publishing
Limited, 2003, pp. 438–460.
[16] R. C. Hoseney, D. E. Rogers, “The formation and properties of wheat
flour doughs,” Crit. Rev. Food Sci. Nutr., vol. 29, no. 2, pp. 74–93,
1990.
[17] S. P. Cauvain, “Breadmaking: an overview,” in Bread making:
Improving quality, S. P. Cauvain, Ed. England, Cambrige: Woodhead
Publishing Limited, 2003, pp. 25–45.
[18] O. O. Oladunmoye, R. Akinoso, A. A. Olapade, “Evaluation of some
physical-chemical properties of wheat, cassaca, maize and cowpea flours
for bread making,” J. Food Quality, vol. 33, is. 6, pp. 693–708, 2010.
[19] P. W. Gras, H. C. Carpenter, and R. S. Andersen, “Modelling the
developmental rheology of wheat flour dough using extension tests,” J.
Cereal Sci., vol. 31, is. 1, pp. 1–13, 2000.
[20] R. Haraszi, O. R. Larroque, B. J. Butow, K. R. Gale, and F.
Bekes,”Differential mixing action effects on functional properties and
polymeric protein size distribution of wheat dough,” J. Cereal Sci., vol.
47, is. 1, pp. 41–51, 2008.
[21] S. Millar, “Controlling dough development,” in Bread making:
Improving quality, S. P. Cauvain, Ed. England, Cambrige: Woodhead
Publishing Limited, 2003, pp. 415–437.
[22] A. Aamodt, E. M. Magnus, and E. M. Faergestad, “Effect of flour
quality, ascorbic acid, and DATEM on dough Rheological parameters
and hearth loves characteristics,” J. Food Sci., vol. 68, is. 7, pp. 2201–
2210, 2003.
[23] A. H. Bloksma, “Dough structure, dough rheology, and baking quality,”
Cereal Food World, vol. 35, is.2, pp. 238–244, 1993.
[24] D. Weipert, “The Benefits of Basic Rheometry in Studying Dough
Rheology,” Cereal Chem., vol. 67, no. 4, pp. 311–317, 1990.
[25] P. Catterall, S. P. Cauvain “Flour Milling,” in Technology of
Breadmaking, 2nd ed., S. P. Cauvain, L. S. Young, Eds., New York,
Springer, 2007, pp. 333–369.
[26] S. Lee, L. J. Pyrak-Nolte, and O. Campanella, “Determination of
ultrasonic-based rheological properties of dough during fermentation,” J.
Texture Stud., vol. 35, no. 1, pp. 33–51, 2004.
[27] C. E. Stauffer, “Principles of Dough Formation,” in Technology of
Breadmaking, 2nd Ed., S. P. Cauvain, L. S. Young, Eds., New York,
Springer, 2007, pp. 299–332.
[1] N. L. Darvey and H. Naeem, J. P. Gustafson, “Triticale: production and
utilization,” in Handbook of Cereal Science and Technology, 2nd ed., K.
Kulp, J. Ponte, Eds. New York: Marcel Dekker, 2000, pp. 257–274.
[2] G. Varughese, W. H. Pfeiffer, and R. J. Pena, “Triticale: A Successful
alternative crop (Part 1),” J. Cereal Foods World, vol. 41, no. 6,
pp. 474–482, 1996.
[3] G. Oettler, “The fortune of a botanical curiosity – Triticale: past, present
and future,” J. Agric. Sci., vol. 143, is. 5, pp. 329–346, 2005.
[4] N.L. Kent, A.D. Evers, Kent’s Technology of Cereals, 4th edn. Oxford:
Elsevier, 1994.
[5] M. Mergoum, W. H. Pfeiffer, R. J. Peña, K. Ammar, and S. Rajaram,
“Triticale crop improvement: the CIMMYT programme,” in Triticale
Improvement and Production, M. Mergoum, H. Gómez-Macpherson,
Eds. FAO Plant Production and Protection Paper 179, 2004, pp. 11–22.
[6] N. C. Popa, R. Tamba-Berhoiu, S. Popescu, M. Varga, and G. G.
Codina, “Predictive model of the alveografic parameters in flours
obtained from Romanian grains,” Rom. Biotech. Lett., vol. 14, no. 2, pp.
4234–4242, 2009.
[7] P. W. Gras, H. C. Carpenter, and R. S. Andersen, “Modelling the
developmental rheology of wheat flour dough using extension tests,” J.
Cereal Sci. vol. 31, is. 1, pp. 1–13, 2000.
[8] H. Zheng, M.P. Morgenstern, O.H. Campanella, and N.G. Larsen,
“Rheological properties of dough during mechanical dough
development,” J. Cereal Sci., vol. 32, is. 3, pp. 293–306, 2000.
[9] A.J. Wilson, M.P. Morgenstern, and S. Kavale, “Mixing response of a
variable speed 125 g laboratory scale mechanical dough development
mixer,” J. Cereal Sci., vol. 34, is. 2, pp. 151–158, 2001.
[10] H. A. Naeem, N.L. Darvey, P.W. Gras, and F. MacRitchie, “Mixing
properties, baking potential, and functionality changes in storage
proteins during dough development of triticale wheat flour blends,”
Cereal Chem., vol. 79, no. 3, pp. 332–339, 2002.
[11] B. J. Dobraszczyk, and M.P. Morgenstern, “Rheology and the bread
making process,” J. Cereal Sci.,vol. 38, no. 2, pp. 229–245, 2003.
[12] A. Angioloni, S. Romani, G. G. Pinnavaia, M. D. Rosa, “Characteristics
of Bread Making Doughs: Influence of Sourdough Fermentation on the
Fundamental Rheological Properties,” Eur. Food Res. Technol., vol.
222, is. 1-2, pp. 54–57, 2006.
[13] C. I. Clarke, T. J. Schober, and E. K. Arendt, “Effect of single strain and
traditional mixed strain starter cultures on rheological properties of
wheat dough and on bread quality,” Cereal Chem., vol. 79, no. 5, pp.
640–647, 2002.
[14] H. M. Elmehdi, J. H. Page, and M. G. Scanlon, “Monitoring Dough
Fermentation Using Acoustic Waves,” Food Bioprod. Process., vol. 81,
is. 3, pp. 217–223, 2003.
[15] H. Weiser, “The use of redox agents,” in Bread making: Improving
quality, S. P. Cauvain, Ed. England, Cambrige: Woodhead Publishing
Limited, 2003, pp. 438–460.
[16] R. C. Hoseney, D. E. Rogers, “The formation and properties of wheat
flour doughs,” Crit. Rev. Food Sci. Nutr., vol. 29, no. 2, pp. 74–93,
1990.
[17] S. P. Cauvain, “Breadmaking: an overview,” in Bread making:
Improving quality, S. P. Cauvain, Ed. England, Cambrige: Woodhead
Publishing Limited, 2003, pp. 25–45.
[18] O. O. Oladunmoye, R. Akinoso, A. A. Olapade, “Evaluation of some
physical-chemical properties of wheat, cassaca, maize and cowpea flours
for bread making,” J. Food Quality, vol. 33, is. 6, pp. 693–708, 2010.
[19] P. W. Gras, H. C. Carpenter, and R. S. Andersen, “Modelling the
developmental rheology of wheat flour dough using extension tests,” J.
Cereal Sci., vol. 31, is. 1, pp. 1–13, 2000.
[20] R. Haraszi, O. R. Larroque, B. J. Butow, K. R. Gale, and F.
Bekes,”Differential mixing action effects on functional properties and
polymeric protein size distribution of wheat dough,” J. Cereal Sci., vol.
47, is. 1, pp. 41–51, 2008.
[21] S. Millar, “Controlling dough development,” in Bread making:
Improving quality, S. P. Cauvain, Ed. England, Cambrige: Woodhead
Publishing Limited, 2003, pp. 415–437.
[22] A. Aamodt, E. M. Magnus, and E. M. Faergestad, “Effect of flour
quality, ascorbic acid, and DATEM on dough Rheological parameters
and hearth loves characteristics,” J. Food Sci., vol. 68, is. 7, pp. 2201–
2210, 2003.
[23] A. H. Bloksma, “Dough structure, dough rheology, and baking quality,”
Cereal Food World, vol. 35, is.2, pp. 238–244, 1993.
[24] D. Weipert, “The Benefits of Basic Rheometry in Studying Dough
Rheology,” Cereal Chem., vol. 67, no. 4, pp. 311–317, 1990.
[25] P. Catterall, S. P. Cauvain “Flour Milling,” in Technology of
Breadmaking, 2nd ed., S. P. Cauvain, L. S. Young, Eds., New York,
Springer, 2007, pp. 333–369.
[26] S. Lee, L. J. Pyrak-Nolte, and O. Campanella, “Determination of
ultrasonic-based rheological properties of dough during fermentation,” J.
Texture Stud., vol. 35, no. 1, pp. 33–51, 2004.
[27] C. E. Stauffer, “Principles of Dough Formation,” in Technology of
Breadmaking, 2nd Ed., S. P. Cauvain, L. S. Young, Eds., New York,
Springer, 2007, pp. 299–332.
@article{"International Journal of Biological, Life and Agricultural Sciences:65195", author = "Martins Sabovics and Karina Ruse and Evita Straumite and Ruta Galoburda", title = "Evaluation of the Triticale Flour Blend Dough in the Mixing and Fermentation Processes", abstract = "The research was accomplished on triticale flour blend, which was made from whole grain triticale, rye, hull-less barley flour and rice, maize flour. The aim of this research was to evaluate physico-chemical and sensory properties of triticale flour blend dough in the mixing and fermentation processes. For dough making was used triticale flour blend, yeast, sugar, salt, and water. In the mixing process ware evaluated moisture, acidity, pH, and dough sensory properties (softness, viscosity, and stickiness), but in the fermentation process ware evaluated volume, moisture, acidity, and pH. During present research was established that increasing fermentation temperature and time, increase dough temperature, volume, moisture, and acidity. The mixing time and fermentation time and temperature have significant effect (p", keywords = "Dough quality, dough fermentation, dough mixing, triticale flour blend.", volume = "7", number = "9", pages = "921-7", }
