تاثیر فرایند حرارت دهی مرطوب( هیدروترمال) و خشک در اندازه ذرات مختلف آرد برنج واکسی بر رئولوژی خمیرآبه و بیاتی نان عاری از گلوتن

نوع مقاله : مقاله پژوهشی

نویسندگان

گروه علوم وصنایع غذایی، دانشگاه علوم کشاورزی و منابع طبیعی ساری

چکیده

بیاتی نان بدون گلوتن از جمله عوامل مهم در امر ضایعات این محصول می باشد. تحقیقات بیشماری جهت اصلاح و بهبود در فرآیند آماده سازی و افزایش زمان ماندگاری نان ارائه شده است. هدف از این پژوهش بررسی میزان آسیب دیدگی نشاسته، خواص رئولوژیکی خمیرآبه و بیاتی نان بدون گلوتن حاصل از اندازه ذرات مختلف (180، 150و 125 میکرون) آرد برنج واکسی تحت تاثیر تیمار حرارتی خشک به مدت 2 ساعت و تیمار حرارتی مرطوب (رطوبت، 25%) به مدت 5 ساعت در دمای 110 درجه سانتیگراد بود. نتایح نشان داد کاهش اندازه ذرات و تیمار جرارتی به ترتیب منجر به افزایش و کاهش میزان آسیب دیدگی نشاسته شدند. مدل ویسکوز و الاستیک خمیرآبه برنج با کاهش اندازه ذرات افزایش یافت و بالاترین مدول ویسکوز و الاستیک مربوط به خمیر‌آبه حاصل از آرد تیمار حرارتی خشک با اندازه ذرات کمتر از 125 میکرون بود. تاثیر اندازه ذرات و تیمار حرارتی خشک بر فعالیت آبی مغز و پوسته معنی دار نبود، درحالیکه تیمار حرارتی مرطوب بطور معنی داری از رطوبت و فعالیت آبی مغز بیشتری برخوردار بود، اما تاثیری بر فعالیت آبی پوسته نداشت. طبق نتایج بدست آمده تغییر اندازه ذرات و تیمار حرارت خشک تاثیری بر بافت نان ها نداشت، در حالیکه بکار گیری آرد حاصل از تیمار حرارتی مرطوب با کاهش میزان سفتی و قابلیت جویدن نمونه ها در طول مدت زمان نگهداری منجر به بهبود ویژگی بافت نان حاصل گردید. نتایج حاصل از آنالیز حرارتی نشان داد نمونه حاصل از اندازه ذرات 125 میکرون کمترین آنتالپی را به خود اختصاص داد ولی بطور کلی نمونه های حاصل از تیمار حرارتی مرطوب با کمترین میزان آنتالپی در این پژوهش بهترین نمونه بودند. بطور کلی استفاده از آرد با اندازه ذرات کمتر از 125 میکرون و تیمار حرارتی مرطوب با بهبود خواص رئولوژیکی و بیاتی نان بهترین نمونه بودند.

کلیدواژه‌ها

موضوعات

عنوان مقاله [English]

Effect of moist (Hydrothermal) and dry heating process on different particle size of waxy rice flour on the rheology of batter and staling of gluten-free bread

نویسندگان [English]

  • ali hashemi shaktai
  • Jafar Milani
  • Ali Motamedzadegan
  • sepideh haghighat
Sari Agricultural Sciences and Natural Resources University
چکیده [English]

Introduction: Celiac disease is a type of immune disorder of the small intestine caused by gluten, and other non-wheat grains such as corn, rice, millet, etc. can be used to prevent the occurrence of disease symptoms in susceptible people (Torobika et al 2021). Waxy rice flour is a suitable and widely used raw material as a starch module to compare the effect of different types of honey and heat treatment on the rheological properties of flour gels (Seow et al. 2019). Among gluten-free products, bread is considered the most widely consumed food, because it is easy to eat and convenient for mass production. Due to the removal of gluten, many gluten-free breads are prone to becoming stale. Gluten, as a protein that inhibits the staleness of bread, leads to a decrease in the rate of moisture transfer from the core of the bread to the crust (Haghighat‐Kharazi et al 2018). Therefore, research on delaying staleness and reducing bread waste is one of the concerns of researchers, and they try to delay staleness by adding additives, changing cooking and storage methods. Particle size distribution is the most widely used technique for classifying solid particles, which is effective in improving rheological properties by affecting the physicochemical properties of flour during hydration, such as water absorption, solvent retention, sedimentation, and adhesion properties. Heat treatments, depending on the intensity of temperature and storage time, by modifying starch granules, denaturing proteins, deactivating enzymes, reducing microbial load, and even modifying taste and aroma are suggested as a suitable method to change the performance of weak and gluten-free flour (Gomez and Martinez 2016). Due to the fact that the effect of rice flour particle size on the rheological properties of dough and gluten-free bread has not been studied so far, in this research, by dividing rice flour with different particle sizes (180, 150, 125 microns) and using heat treatment (moist and dry heat) were investigated to improve the functional characteristics of rice flour and improve the rheological characteristics of dough and gluten-free bread.
Material and methods: The content of moisture, pH, ash, protein of rice flour was measured using AACC standard method (2000) and the total amount of starch was measured by alkaline extraction method and the amount of starch damage was measured by non-enzymatic rapid method. In order to classify the size of the particles, waxy rice flour was divided by a shaker sieve with different sizes of 180, 150 and 125 microns, then under the influence of dry heat treatment for 2 hours and moist heat treatment with humidity, 25% for 5 hours at a temperature of 110 degrees. Celsius was placed. In order to produce gluten-free bread, the formulation used by Haghighat‐Kharazi in 2020 was used with a slight change. Ingredients for gluten-free bread formulation for 100 grams of rice flour included 125 ml of water, 4.5 grams of sugar, 2 grams of salt, 6 grams of vegetable oil, 3 grams of yeast and 2 grams of xanthan gum. The rheological parameters of the pastes included strain, frequency and temperature. In order to check the staleness of bread during the storage period, moisture tests of core and shell, blue activity of core to shell, analysis of bread texture and DSC were used. Finally, the factorial test was used to investigate the effects of particle size and heat treatment of rice flour, and Duncan's multiple range test was used to compare the means at the 5% probability level.
Results and discussion: The effect of particle size and heat treatment and their interaction showed a significant effect on the degree of starch damage (p<0.05). The samples of dry heat treatment and wet heat treatment had less starch damage than the control sample. Changing the particle size and dry and wet heat treatment led to a change in the rheological behavior of the samples. By reducing the size of particles, the viscous and elastic modulus of the samples increased. Wet heat treatment samples had the lowest G* modulus. The effect of particle size and dry heat treatment on tissue analysis was not significant (p>0.05). While the wet heat treatment significantly had the lowest hardness and Chewiness during the storage period (p<0.05). Although the amount of skin moisture and water activity increased during the storage time, the effect of particle size and heat treatment on the moisture level of the skin was not significant, while the wet heat treatment samples had more brain moisture and brain water activity during the storage time. were (p<0.05). Wet heat treatment samples compared to dry heat treatment and the change in particle size had the lowest enthalpy among the samples on the first day of cooking and during the storage period.
Conclusion: In general, the results of the present study showed that the degree of starch damage and the rheology of batters were affected by particle size and heat treatment. Changing the particle size and heat treatment led to an increase and decrease in starch damage, respectively. Rice flour with smaller particle size and wet heat treatment sample obtained with particle size less than 125 microns showed better rheological behavior. The results of the evaluations related to the staleness tests of bread in this research showed that during the storage time of the sample obtained with a particle size of less than 125 microns and samples of wet heat treatment due to the lower enthalpy of retrogradation and the high capacity of maintaining moisture, also The effect of wet heat treatment samples on the reduction of hardness and Chewiness led to the improvement of bread staleness. In total, the measured characteristics of using flour obtained from wet heat treatment compared to flour from dry heat treatment, as well as flour with a particle size of less than 125, led to the improvement of the rheological characteristics of gluten-free bread dough.

کلیدواژه‌ها [English]

  • moist heat treatment
  • dry heat
  • gluten-free bread staleness
  • dough rheology

مراجع

مهاجر خراسانی س، اعلمی م، کاشانی نژاد م و شهیری طبرستانی ه، ۱۳۹۸، مقایسه اثر تیمار حرارتی- رطوبتی دانه ارزن و افزودن صمغ زانتان بر ویژگی‌های خمیر و خصوصیات فیزیکوشیمیایی و حسی کیک بدون گلوتن.  مجله علوم و صنایع غذایی، 16 (90)، 229-243.
یزدانی ب، میلانی ج و حسینی 1، 1394، مقایسه کیفیت و بیاتی نان تهیه شده با استفاده از مایکروویو، سیستم جابجایی و ترکیبی، پژوهش‌های صنایع غذایی، 25(3)، 477-467.
AACC 2000. American Association of cereal chemists. Approved methods of the AACC, 10th ed. American Association of cereal chemists, St Paul, USA.
Azeem M, Mu TH & Zhang M, 2020. Influence of particle size distribution of orange-fleshed sweet potato flour on dough rheology and simulated gastrointestinal digestion of sweet potato-wheat bread. LWT 131:109690.
Bae IY & Lee HG, 2018. Effect of dry heat treatment on physical property and in vitro starch digestibility of high amylose rice starch. International Journal of Biological Macromolecules 108: 568-575.
Biliaderis CG, Izydorczyk MS & Rattan O, 1995. Effect of arabinoxylans on bread-making quality of wheat flours. Food Chemistry 53(2): 165-171.
Bourekoua H, Benatallah L, Zidoune MN & Rosell CM, 2016. Developing gluten free bakery improvers by hydrothermal treatment of rice and corn flours. LWT 73: 342-350.
Cham S & Suwannaporn P, 2010. Effect of hydrothermal treatment of rice flour on various rice noodles quality. Journal of Cereal Science 51(3): 284-291.
Dahle L & Sambucca N, 1987. Application of Devised Universal Testing Machine Procedures for Measuring the Texture of Bread and Jam Filled Cookies. American Association of Cereal Chemists 32(7): 466-470.
De La Hera E, Rosell CM & Gomez M, 2014. Effect of water content and flour particle size on gluten-free bread quality and digestibility. Food Chemistry 151: 526-531.
Ding XL, Wang LJ, Li TT, Wang F, Quan ZY, Zhou M & Qian JY, 2021. Pre-gelatinisation of rice flour and its effect on the properties of gluten free rice bread and its batter. Foods 10(11): 2648.
Fathi B, Aalami M, Kashaninejad M & Sadeghi Mahoonak A, 2016. Utilization of heat‐moisture treated proso millet flour in production of gluten‐free pound cake. Journal of Food Quality 39(6): 611-619.
Gomez M & Martinez MM, 2016. Changing flour functionality through physical treatments for the production of gluten-free baking goods. Journal of Cereal Science 67: 68-74.
Haghighat‐Kharazi S, Reza Kasaai M, Milani JM & Khajeh K, 2020. Antistaling properties of encapsulated maltogenic amylase in gluten‐free bread. Food Science & Nutrition 8(11): 5888-5897.
Haghighat-Kharazi S, Milani JM, Kasaai MR & Khajeh K, 2018. Microencapsulation of α-amylase in beeswax and its application in gluten-free bread as an anti-stalingagent. LWT 92: 73-79.
Hesso N, Loisel C, Chevallier S and Le-Bail A, 2014. Impact of pregelatinized starches on the texture and staling of conventional and degassed pound cake. Food and Bioprocess Technology 7: 2923-2930.
Hormdok R & Noomhorm A, 2007. Hydrothermal treatments of rice starch for improvement of rice noodle quality. LWT-Food science and Technology 40(10): 1723-1731.
Ji Y, Zhu K, Qian H & Zhou H, 2007. Staling of cake prepared from rice flour and sticky rice flour. Food Chemistry 104(1): 53-58‏.
Khwanchai, P & Fong-In S, 2022. Effect of Heat Treatment of Broken Rice Flour as Partial Substitution of Wheat Flour on the Qualities of Bread. Burapha Science Journal: 171-187.
Kim AN, Rahman MS, Lee KY & Choi SG, 2021. Superheated steam pretreatment of rice flours: Gelatinization behavior and functional properties during thermal treatment. Food Bioscience 41: 101013.
Kim MJ, Oh SG & Chung HJ, 2017. Impact of heat-moisture treatment applied to brown rice flour on the quality and digestibility characteristics of Korean rice cake. Food Science and Biotechnology 26 (6): 1579-1586.
Kim JM & Shin M, 2014. Effects of particle size distributions of rice flour on the quality of gluten-free rice cupcakes. LWT-Food Science and Technology 59(1): 526-532.
Lapcikova B, Lapcik L, Valenta T, Majar P & Ondrouskova K, 2021. Effect of the rice flour particle size and variety type on water holding capacity and water diffusivity in aqueous dispersions. LWT 142: 111082.
Lawal OS, Lapasin R, Bellich B, Olayiwola TO, Cesàro A, Yoshimura M & Nishinari K, 2011. Rheology and functional properties of starches isolated from five improved rice varieties from West Africa. Food Hydrocolloids 25(7): 1785-1792.
 ‏Lazaridou A, Marinopoulou A & Biliaderis CG, 2019. Impact of flour particle size and hydrothermal treatment on dough rheology and quality of barley rusks. Food Hydrocolloids 87: 561-569.
Lazaridou A, Duta D, Papageorgiou M, Belc N and Biliaderis CG, 2007. Effects of hydrocolloids on dough rheology and bread quality parameters in gluten-free formulations. Journal of Food Engineering 79: 1033- 1047.
Liu C, Song M, Liu L, Hong J, Guan E, Bian K & Zheng X, 2020. Effect of heat-moisture treatment on the structure and physicochemical properties of ball mill damaged starches from different botanical sources. International Journal of Biological Macromolecules 156: 403-410‏.
Liu YF, Laohasongkram K & Chaiwanichsiri S, 2016. Effects of heat-moisture treatment on molecular interactions and physicochemical properties of tapioca starch.  Food Process Technology 3(3): 00072.
Lu X, Xu R, Zhan J, Chen L, Jin Z & Tian Y, 2020. Pasting, rheology, and fine structure of starch for waxy rice powder with high-temperature baking. International journal of biological macromolecules 146: 620-626.
McDermott EE, 1980. The rapid non‐enzymic determination of damaged starch in - flour. Journal of the Science of Food and Agriculture 31(4): 405-413.
Pérez-Quirce S, Ronda F, Lazaridou A and Biliaderis CG, 2017. Effect of microwave radiation pretreatment of rice flour on gluten-free breadmaking and molecular size of β-glucans in the fortified breads. Food and Bioprocess Technology 10: 1412-1421.
Purhagen JK, Sjoo ME and Eliasson AC, 2011. The use of normal and heat-treated barley flour and waxy barley starch as antistaling agents in laboratory and industrial baking processes. Journal of Food Engineering, 104: 414-421.
Qin W, Lin Z, Wang A, Chen Z, He Y, Wang L & Tong LT, 2021. Influence of particle size on the properties of rice flour and quality of gluten-free rice bread. LWT 151: 112236.
QinY, Liu C, Jiang S, Cao J, Xiong L & Sun Q, 2016. Functional properties of glutinous rice flour by dry-heat treatment. Plos One 11(8): 0160371‏
Raiola A, Romano A, Shanakhat H, Masi P & Cavella S, 2020. Impact of heat treatments on technological performance of re-milled semolina dough and bread. LWT 117: 108607. ‏
Ruiiz E, Srikaeo K & de la Revilla L S, 2018. Effects of heat moisture treatment on physicochemical properties and starch digestibility of rice flours differing in amylose content. Food and Applied Bioscience Journal 6(3): 140-153.
Seow EK, Gan CY, Tan TC, Lee LK & Easa AM, 2019. Influence of honey types and heating treatment on the rheological properties of glutinous rice flourgels. Journal of food science and technology 56(4): 2105-2114.
Torbica A, Belovic M, Popovic L & Cakarevic J, 2021. Heat and hydrothermal treatments of non-wheat flours. Food Chemistry 334: 127523.
پژوهش های صنایع غذایی
دوره 33، شماره 4
اسفند 1402
صفحه 95-111

فایل ها

هم رسانی

ارجاع به این مقاله

آمار