Bread-Making Potential and Yielding of Hybrid Wheat Under Varied Agronomic and Environmental Factors

1. AACC International (2009). American Association of Cereal Chemists (AACC) International Approved Methods of Analysis. No. 46-11.02, No. 54-21, 11th ed. AACC: Saint Paul, USA. Search in Google Scholar

2. Belcar J., Sobczyk A., Sekutowski T. R., Stankowski S., Gorzelany J. 2021. Evaluation of flours from ancient varieties of wheat (einkorn, emmer, spelt) used in production of bread. Acta Universitatis Cibiniensis Series E: Food Technology. 25 (1); 53-66 https://doi.org/10.2478/aucft-2021-000510.2478/aucft-2021-0005 Search in Google Scholar

3. Bojňanská T. & Frančáková H. 2002. The use of spelt wheat (Triticum spelta L.) for baking applications. Rostlinná Výroba, 48(4): 141-147.10.17221/4212-PSE Search in Google Scholar

4. Buczek, J., Migut, D. & Jańczak-Pieniązek, M. (2021). Effect of soil tillage practice on photosynthesis, grain yield and quality of hybrid winter wheat. Agriculture. 11, 479. doi: 10.3390/agriculture11060479 Apri DOISearch in Google Scholar

5. CCA (2020). Common catalogue of varieties of agri-cultural plant species. Official Journal of EU/C4.https://ec.europa.eu/food/sites/food/files/plant/docs/plant-variety-cataloguesagricultural-plant-species.pdf (accessed on 12 November 2022). Search in Google Scholar

6. Dąbkowska E. 2009. Wpływ odmiany ziarna orkiszu uzyskanego w warunkach produkcji ekologicznej na jakość mąki. Praca doktorska przygotowana na Wydziale Nauki o Żywności Uniwersytetu Warmińsko – Mazurskiego w Olsztynie. Search in Google Scholar

7. De Vita, P., Di Paolo, E., Fecondo, G., Di Fonzo, N. & Pisante, M. (2007). No-tillage and conventional tillage effects on durum wheat yield, grain quality and soil moisture content in southern Italy. Soil Till. Res. 92, 69–78. doi: 10.1016/j.still.2006.01.012 Apri DOISearch in Google Scholar

8. García-Molina, D.M. & Barro, F. (2017). Characterization of changes in gluten proteins in low-gliadin transgenic wheat lines in response to application of different nitrogen regimes. Front. Plant Sci. 8, 257. doi: 10.3389/fpls.2017.00257532678128289425 Apri DOISearch in Google Scholar

9. Godfrey, D., Hawkesford, M.J., Powers, S.J., Millar, S. & Shewry, P.R. (2010). Effects of crop nutrition on wheat grain composition and end use quality. J. Agr. Food Chem. 58, 3012–3021. doi: 10.1021/jf904064520131902 Apri DOISearch in Google Scholar

10. Growth Stages of Mono- and Dicotyledonous Plants (2001). BBCH Monograph (2nd Ed.), Federal Biological Research Centre for Agriculture and Forestry. Braunschweig, Germany, 1–204. Search in Google Scholar

11. Hadnadev, M., Dapčević-Hadnadev, T., Šimurina, O. & Filipčev, B. (2013). Empirical and fundamental rheological properties of wheat flour dough as affected by different climatic conditions. J. Agric. Sci. Technol. 15, 1381–1391. Search in Google Scholar

12. Haliniarz, M., Gawęda, D., Bujak, K., Frant, M. & Kwiatkowski, C. (2013). Yield of winter wheat depending on the tillage system and level of mineral fertilization. Acta Sci. Pol. Agricultura. 12, 59–72. Search in Google Scholar

13. Hausherr Lüder, M.R., Qin, R., Richner, W., Stamp, P., Streit, B. & Noulas, Ch. (2019). Effect of tillage systems on spatial variation in soil chemical properties and winter wheat (Triticum aestivum L.) performance in small fields. Agronomy. 9, 182; doi:10.3390/agronomy9040182 Apri DOISearch in Google Scholar

14. Hofmeijer, J.A.M.; Krauss, M., Berner, A., Peigné, J., Mäder, P. & Armengot, L. (2019). Effects of reduced tillage on weed pressure, nitrogen availability and winter wheat yields under organic management. Agronomy. 9, 180. doi: 10.3390/agronomy9040180 Apri DOISearch in Google Scholar

15. Horvat, D., Drezner, G., Sudar, R., Šimic, G., Dvojkovic, K., Španic, V. & Magdic, D. (2015). Distribution of wheat protein components under different genetic backgrounds and environments. Turk. J. Field Crops. 20, 150–154. doi: 10.17557/tjfc.12437 Apri DOISearch in Google Scholar

16. https://www.ior.poznan.pl, Institute of Plant Protection-National Research Institute, Poznań, Poland (accessed on 15 November 2022). Search in Google Scholar

17. ICC Method No 107/1. (1994). Determination of the Falling Number according to Hagberg-As a measure of the degree of alpha-amylase activity in grain and flour. Available online: https://icc.or.at/publications/icc-standards/standards-overview/107-1-standard-method (accessed on 22 November 2022). Search in Google Scholar

18. ICC Method No 116/1 (1994). Determination of the Sedimentation Value (according to Zeleny) as an approximate measure of baking quality. Available online: http://old.icc.or.at/standard_methods/116.1 (accessed on 22 November 2022). Search in Google Scholar

19. ICC Standard No 155 (1994). Determination of wet gluten quantity and quality (Gluten Index ac. To Perten) Of whole wheat meal and wheat flour. Available online: http://old.icc.or.at/standard_methods/155 (accessed on 15 November 2022). Search in Google Scholar

20. ISO (2015). International Organization for Standardization (ISO). ISO 27971:2015. Cereals and cereal products. Common wheat (Triticum aestivum L.). Determination of alveograph properties of dough at constant hydration from commercial or test flours and test milling methodology. ISO: Geneva, Switzerland. Search in Google Scholar

21. ISO (2015). International Organization for Standardization (ISO). ISO 5530-1:2015. Physical characteristics of doughs. Part 1. Determination of water absorption and rheological properties using a farinograph. ISO: Geneva, Switzerland. Search in Google Scholar

22. Jaskulska, I., Jaskulski, D., Gałęzewski, L., Knapowski, T., Kozera, W. & Wacławowicz, R. (2018). Mineral composition and baking value of the winter wheat grain under varied environmental and agronomic conditions. J Chem. 1–7. doi: 10.1155/2018/5013825 Apri DOISearch in Google Scholar

23. Keres, I., Alaru, M., Talgre, L., Luik, A., Eremeev, V., Sats, A., Jõudu, I., Riisalu, A. & Loit, E. (2020). Impact of weather conditions and farming systems on size distribution of starch granules and flour yield of winter wheat. Agriculture. 10, 22. doi: 10.3390/agriculture11121232 Apri DOISearch in Google Scholar

24. Keres, I., Alaru, M., Koppel, R., Altosaar, I., Tosens, T. & Loit, E. (2021). The combined effect of nitrogen treatment and weather conditions on wheat protein-starch interaction and dough quality. Agriculture. 11, 1232. doi: 10.3390/agriculture11121232 Apri DOISearch in Google Scholar

25. Konopka, I., Tańska, M., Pszczółkowska, A., Fordoński, G., Kozirok, W. & Olszewski, J. (2007). The effect of water stress on wheat kernel size, color and protein composition. Pol. J. Nat. Sci. 2, 157–171. doi: 10.2478/v10020-007-0016-5 Apri DOISearch in Google Scholar

26. Krejčířová, L., Capouchová, I., Petr, J., Bicanová, E. & Faměra, O. (2007). The effect of organic and conventional growing systems on quality and storage protein composition of winter wheat. Plant Soil Environ. 53, 499–505.10.17221/2304-PSE Search in Google Scholar

27. Lacko-Bartošová, M., Lacko-Bartošová, L. & Konvalina P. (2021). Wheat rheological and Mixolab quality in relation to cropping systems and plant nutrition sources. Czech J. Food Sci. 39, 265–272. doi: 10.17221/189/2020-CJFS). Apri DOISearch in Google Scholar

28. Liniņa, A. & Ruža, A. (2015). Impact of agroecological conditions on the Hagberg falling number of winter wheat grain. Res Rural Dev. 1, 19–26. Search in Google Scholar

29. López-Bellido, L., Fuentes, M., Castillo, J.E. & López-Garrido, F.J. (1998). Effects of tillage, crop rotation and nitrogen fertilization on wheat-grain quality grown under rainfed Mediterranean conditions. Field Crops. Res. 1, 265–276. doi: 10.1016/S0378-4290(97)00137-8 Apri DOISearch in Google Scholar

30. López-Bellido, L., López-Bellido, J.R. Castillo, J.E. & López-Bellido, J.F. (2001). Effects of long-term tillage, crop rotation and nitrogen fertilization on bread-making quality of hard red spring wheat. Field Crops. Res. 72, 197-210. doi: 10.1016/S0378-4290(01)00177-0 Apri DOISearch in Google Scholar

31. Małecka, I., Blecharczyk, A., Sawińska, Z., Piechota, T. & Waniorek, B. (2012). Cereals yield response to tillage methods. Fragm. Agron. 29, 114–123. (In Polish) Search in Google Scholar

32. Miś, A. (2001). Determination of rheological properties of wet gluten by the creep test. Acta Agrophys. 46, 127–144. (In Polish) Search in Google Scholar

33. Pagnani, G., Galieni, A., D’Egidio, S., Visioli, D., Stagnari, F. & Pisante, P. (2019). Effect of soil tillage and crop sequence on grain yield and quality of durum wheat in Mediterranean areas. Agronomy. 9, 488. doi:10.3390/agronomy9090488. Apri DOISearch in Google Scholar

34. Peigné, J., Messmer, M., Aveline, A., Berner, A., Mäder, P., Carcea, M., Narducci, V., Samson, M.-F., Thomsen, I.K., Celette, F. & David, C. (2014). Wheat yield and quality as influenced by reduced tillage in organic farming. Org. Agr. 4, 1–13. doi: 10.1007/s13165-013-0055-x Apri DOISearch in Google Scholar

35. Podolska, G., Aleksandrowicz, E. & Szafrańska, A. (2020). Bread making potential of Triticum aestivum and Triticum spelta species. Open Life Sci. 15, 30–40. doi: 10.1515/biol-2020-0004 Apri DOISearch in Google Scholar

36. Rachoń, L., Szumiło, G., Brodowska, M. & Woźniak, A. (2015). Nutritional value and mineral composition of grain of selected wheat species depending on the intensity of a production technology. J. Elem. 3, 705–7015. doi: 10.5601/jelem.2014.19.4.640 Apri DOISearch in Google Scholar

37. Reference Base for Soil Resources (2015). Word Soil Resources Reports No. 106; FAO; Rome, Italy, 172–173. Search in Google Scholar

38. Różyło R. & Laskowski J. 2009. Porównanie cech jakościowych chleba pszennego wypieczonego z ciasta prowadzonego jednofazowo i dwufazowo. ŻYWNOŚĆ. Nauka. Technologia. Jakość. 5(66): 83-95. Search in Google Scholar

39. Silva, R.R., Zucareli, C., de Batista Fonseca, I.C., Gazola, D. & Riede, C.R. (2019). Influence of nitrogen, environment, and cultivars on the industrial quality of wheat. Semin Ciênc Agrár. 40, 6, 2571–2580. doi: 10.5433/1679-0359.2019v40n6p2571 Apri DOISearch in Google Scholar

40. Šip, V., Vavera, R., Chrpova, J. & Kusa, P. (2013). Winter wheat yield and quality related to tillage practice. input level and environmental condition. Soil Till. Res. 132, 77–85. doi: 10.1016/j.still.2013.05.002. Apri DOISearch in Google Scholar

41. Skowera, B. (2014). Changes of hydrothermal conditions in the Polish area (1971–2010). Fragm. Agron. 31, 74–87. (In Polish) Search in Google Scholar

42. Stępniewska, M.S. & Słowik, E. (2016). Assessment of technological value of selected winter and spring wheat varieties. Acta Agrophys. 23, 2, 275–286. (In Polish) Search in Google Scholar

43. Szafrańska, A. & Stępniewska, M.S. (2021). Changes in bread making quality of wheat during postharvest maturations. Int. Agrophys. 35, 179–185. doi: 10.31545/intagr/138841 Apri DOISearch in Google Scholar

44. Triboï, E., Martre, P. & Triboï-Blondel, A.M. (2003). Environmentally-induced changes in protein composition in developing grains of wheat are related to changes in total protein content. J. Exp. Bot. 54, 388, 1731–1742. doi: 10.1093/jxb/erg18312773520 Apri DOISearch in Google Scholar

45. Troccoli, A., Russo, M. & Farina, R. (2022). Is it sustainable to cultivate a monoculture of durum wheat with prolonged no-tillage management? Ann. Agric. Crop Sci. 7, 1105.10.26420/annagriccropsci.2022.1105 Search in Google Scholar

46. Vazquez, D., Berger, A., Prieto-Linde, M.L. & Johansson, E. (2019). Can nitrogen fertilization be used to modulate yield, protein content and bread-making quality in Uruguayan wheat? J. Cereal. Sci. 85, 153–161. doi: 10.1016/j.jcs.2018.12.001 Apri DOISearch in Google Scholar

47. Wieser, H. & Zimmerman, G. (2000). Importance of amounts and proportions of high molecular weight subunits of glutenin for wheat quality. Eur. Food Res. Technol. 210, 324-330. doi: 10.1007/s002170050558 Apri DOISearch in Google Scholar

48. Woźniak, A. & Rachoń, L. (2020). Effect of tillage systems on the yield and quality of winter wheat grain and soil properties. Agriculture. 10, 405. doi: 10.3390/agriculture10090405 Apri DOISearch in Google Scholar

49. Yousefian, M.; Shahbazi, F. & Hamidian, K. (2021). Crop yield and physicochemical properties of wheat grains as affected by tillage systems. Sustainability. 13, 4781. doi.org/10.3390/su1309478110.3390/su13094781 Search in Google Scholar

50. Žilić, S., Barać, M., Pešić, M., Dodig, D. & Ignjatović-Micić, D. (2021). Characterization of proteins from grain of different bread and durum wheat genotypes. Int. J. Mol. Sci. 12, 5878–5894; doi: 10.3390/ijms12095878318975822016634 Apri DOISearch in Google Scholar

• Thermal, Pasting, and Hydration Properties of Flour from Novel Cassava Cultivars for Potential Applications in the Food Industry
• Influence of Wheat-Mesquite (Prosopis L.) Composite Flour on Dough Rheology and Quality of Bread
• Effect of Maltodextrin, Arabic Gum, and Beetroot Juice Concentration on the Powder Properties of Spray-Dried Beetroot-Skim Milk Mixtures
• Microbial Diversity of Six Commercially Available Kefir Grains
• Chemical Characterization of Date Seeds (Phoenix dactylifera L.) Cultivated in Algeria for its Application as Functional Ingredients
• Production, Characterization, and Application of Biosurfactant From Lactobacillus plantarum OG8 Isolated From Fermenting Maize (Zea Mays) Slurry
• Development and Quality Assessment of Biscuits Made from Mixture of Wheat, Soybean, and Sorghum Flour
• Bread-Making Potential and Yielding of Hybrid Wheat Under Varied Agronomic and Environmental Factors
• Safety Assessment of Locusta migratoria Powder Enriched Peanut-Based Ready-to-Use Therapeutic Foods (RUTF)
• Effect of Ozone Treatment on Mechanical and Chemical Properties of Sea-Buckthorn (Hippophaë rhamnoides L.) Fruit
• Simple Method for Fatty Acids Determination in Food, Superfood and Spice Samples by GC-MS Technique
• Meat (Longissimus lumborum Muscle) Quality in Males of the Family Cervidae
• Effect of Substrate Composition on Yield and Antioxidative Activity of Exopolysaccharides From Lactobacillus fermentum B62