Production of Xylanase from Local Coastal soil Isolate of Trichoderma spp. And study Effect of Xylanase on Arabic Bread Characteristics

References  AACC.(2000) International Methods. AACC International Approved Methods of Analysis;11th edition .USA:American Association of Cereal Chemists, International Press: International,St.Paul,Minnesota,1200.  Abdel-Star.M.A&A.H.M.El-Said.(2001).Xylan-decomposing fungi and xylanolytic activity in agricultural and industrial wastes. Inter. Biodeter.Biod,47,15-21.  Adiguzel.G,O.Faiz,M.Sisecioglu,B.Sari,O.Baltaci,S.Akbulut,B.Genc, A.Adiguzel.(2019).A novel endo-β-1,4-xylanase from Pediococcus acidilactici GC25; purification, characterization and application in clarification of fruit juices. Int J Biol Macromol,15(129),571-578.  Ahmad.Z,M.S.Butt,A.Ahmed,M.Riaz,S.M.Sabir,U.Farooq,F.U.Rehman. (2014). Effect of Aspergillus niger xylanase on dough characteristics and bread quality attributes. J Food Sci Technol,51(10),2445–2453.  Ahmed.S,Imdad.S.S,Jamel.A.(2012).COMparative study for the kinetics of extracellular xylanase from Trichoderma harzianum and its Chaetomium thermophilum,Electron journal Biotechnol,15(3),1-8.  Ajijolakewu.K.A,L.Cheupeng,W.A.Nadiah,L.Cheekeong.(2016). Assessment of the effect of easily- metabolized carbon supplements on Xylanase production by newly isolated Trichoderma asperellum USM SD4 cultivated on oil palm empty fruit bunches.Bio Resources,11(4),9611-9627.  Ajila.C.M,K.Leelavathi,U.J.S.Prasada Rao.(2008).Improvement of dietary fiber content and antioxidant properties in soft dough biscuits with the incorporation of mango peel powder. J. Cereal Sci,48,319–326.  Akinyele.H.A,R.A.O.Gabriel-Ajobiewe,O.M.Ukhureigbe,A.A.Adebesin, T.L.Omotayo.(2019).Xylanase-production potential of Trichoderma Asperellum NG-T161 and NG-T163 isolated from banana farm soils in South Western Nigeria.Journal of Fungal Biology,9(1),301-312.  Aleid.S.M,A.A.AL-Hulaibi,M.Abu Ghoush,A. A.Al-Shathri. (2015). Enhancing arabic bread quality and shelf life stability using bread improvers. J Food Sci Technol,52(8),4761–4772.  Alfin.F,Ü.Çakmakli.(2000). A comparative study on the milling and flour characteristics of bread and durum wheats from syria and turkey PH.D in Food Engineering,172.  Al-hebeil.S.A.(2013).Quantification of bread crust crispness including the effects of selected additives.Doctor of Philosophy thises, School ofAgriculture,Food and Rural Development Newcastle University Newcastle Upon Tyne,United Kingdom.  Almeida.E.L,Y.K.Chang,C.J.Steel.(2013).Dietary fiber source in bread: influence on technological quality.LWT –Food science and technology,50(2)545-553.  Alomari.W,A.K.Alsaed,M.Hadadin.(2012).Utilization of labneh whey lactose hydrolyzed syrup in baking and confectionery.Pakistan Journal of Nutrition,11(8),688-695.  Altinel.B&S.S.Unal.(2017).Effects of certain enzymes on the rheology of dough and the quality characteristics of bread prepared from wheat meal. Journal of Food Science & Technology,54(6),1628–1637.  Ambehabati.K.K,S.Z.Hanapi,A.F.El Baz,R.Z.Sayyed, D.J.Dailin,H.A.El Enshasy.(2020). Isolation and Identification Studies on Potential Xylanase Producing Strain Trichoderma sp. WICC F46 Isolated from Tropical Soil. Journal of Scientific & Industrial Research, 79,153-159.  Ambehabati1.K.K,S.Z.Hanapi1,A.F.El Baz,R.Z.Sayyed,D.J.Dailin,H. A.El Enshasy.(2020). Isolation and Identification Studies on Potential Xylanase Producing Strain Trichoderma sp. WICC F46 Isolated from Tropical Soil. Journal of Scientific & Industrial Research,79,153-159.  Anand.G,M.Leibman-Markus,D.Elkabetz,M.Bar.(2021).Method for the Production and purification of plant Immuno-Active xylanase from Trichoderma. International journal of Molecular science,22,4214-4224.  Anwar.Z,M.Gulfraz,M.Irashad.(2014).Agro industrial lignocellulosic biomass a key to unlock the future bio- energy:A brief review. Journal of Radiation Research and Applied Science,7 (2),163–173.  AOAC.(2005) Association of Official Analytical Chemistry. Official methods of analysis (18th ed.). USA: Washington, DC, In K. Herlich (Ed.) 2500.  Aprodu.I,I.Banu,G.Stoenescu,V.Ionescu.(2010).Effect of the industrial milling process on the rheological behavior of different types of wheat flour. Chemistry and Chemical Engineering.Biotechnology Food Industry,11(4), 429 – 437.  Arapita.M&A.K.Datta.(2008).Bread baking-a review.J.Food.Eng,86,465-472.  Azin.M,R.Moravej,D.Zare.(2007).Production of xylanase by Trichoderma longibrachiatum on on a mixture of wheatbran and wheat strawoptimization of culture condition by taguchi method. Enzyme and Microbial Technology,40(4),801-805.  Azizi.M.H,S.M.Sayeddin,S.H.Payghambardoost.(2006).Effect of Flour Extraction Rate on Flour Composition,Dough Rheological Characteristics and Quality of Flat Bread.J.Agric.Sci. Technol,8,323-330.  Azzouz.Z,A.Bettache,N.Boucherba,Z.Amghar,S.Benallaou.(2020).Optimization of xylanase production by newly isolated strain Trichoderma afroharzianum isolate AZ 12 in solid state fermentation using response surface methodology.Cellulose Chemistry and Technology,54(5),451-462.  Banu.I,G.Stoenescu, V.Ionescu,I.Aprodu.( 2011).Estimation of the baking quality of wheat flours based on rheological parameters of the mixolab curve. Czech J. Food Sci, 29,35–44.  Banu.I,S.Stoenescu,V.S.Ionescu,I.Aprodu.(2012).Effect of the addition of wheat bran stream on dough rheology and bread quality.Food Technology, 36(1),39-52.  Baran.B&S.Yurdugül.(2020).The Role of Thermostable Xylanase Enzymes in Bread Making. International Journal of Innovative Approaches in Science Research,4(4):130-140.  Baratto.C.M,N.B.Becker,J.M.Gelinski,S.M.Silveira.(2015).Influence of enzymes and ascorbic acid on dough rheology and wheat bread quality.African Journal of Biotechnology,14(46),3124-3130.  Battallion.M,A.P.Nunes,A.P.Cardinali,N.Castillon,F.Duchiron.(2000). Purification and characterization of a moderately thermostable xylanase from Bacillus sp. strain SPS -0. Enz Microbiol Technol ,26,187-192.  Battan.B,J.K.Sharma,S.SDhiman.(2006).High level xylanase production by alkalophilic B. pumilus ASH under solid state fermentation. World Journal of Microbiology & Biotechnology,22,1281-1287.  Beg.Q.K,M.Kapoor,L.Mahajan,G.S.Hoondal.(2001).Microbial xylanases and their industrial applications: a review. Applied microbiology and biotechnology,56, 326-338.  BeMiller.J.N.(2011).Pasting, paste, and gel properties of starchhydrocolloid combinations.Carbohydrate Polymers,86(2),386–423.  Berrin,J.G&Juge,N.(2008).Factors affecting xylanase functionality in the degradation of arabinoxylans. Biotechnology letters,30,1139‐1150.  Bettge.A.D,C.F.Morris,V.L.Demoacin,K.K.Kidwell.(2002).Adaptation of AACC method 56-11, solvent retention capacity, for use as an early generation selection tool for cultivar development.Cereal Chem,79, 670-674 Bhardwaj.N,B.Kumar,P.Verma.(2019).A detailed overview of xylanases: An emerging biomolecule for current and future prospective. Bioresour. Bioprocess,6, 1–36.  Bice.C.W&W.F.Geddes..(1949).Studies on bread staling IV. Evaluation of methods, for the measurement of changes which occurduring bread staling. Cereal Chenm,26,440-465.  Bilgiçli.N,S.Ibanoğlu,E.N.Herken.(2007).Effect of dietary fiber addition on the selected nutritional properties of cookies.Journal of Food Engineering,78,86–89.  Blanchar.C.(2014).On the study of the different factors influencing the structure and the texture of semi-humid baked aerated cereal products : sensory and instrumental dimensions of texture. Ph.D.Thesis. UniversitédeBourgogne.1-287.  Butt.M.S,M.Tahir-Nadeem,Z.Ahmad,M.T.Sultan.(2008).Xylanases and Their Applications in Baking Industry. Food Technol. Biotechnol,46(1),22–31.  Caballero.P.A.(2006).Improvement of dough rheology, bread quality and bread shelf-life by enzymes combination.Journal of food engineering,81,42-53.  Carmona.E.C,M.B.Fialho,E.B.Buchgnani.(2005).Production, purification & characterization of a minor form of xylanase from A. versicolor.Process- Biochemistry,40,359-364.  Chakdar.H,M.Kumar,K. Pandiyan,A. Singh,K.Nanjappan,P.L. Kashyap ,A.K.Srivastava.(2016). Bacterial xylanases: biology to biotechnology. Biotech. 6,1-15.  Chivero.E.T,A.N.Mutukumira,R.Zvauya.(2001).Partial purification and characterization of a xylanase enzyme produced by a microorganism isolated from selected indigenous fruits of Zimbabwe. Food Chem,72,179-185.  Collar.C,C.Bollaín,C.M.Rosell.(2007).Rheological Behaviour of Formulated Bread Doughs During Mixing and Heating.Food Sci Technol Int,13(2),99–107.  Conn.E.E,P.K.Stumpf.(1976).Outlines of biochemistry ,4th.ed. John wiley and Sons , New York.  Covino.C,A.Sorrentino,P.D.Pierro,P.Masi.(2023).Study of Physico-Chemical Properties of Dough and Wood Oven-Baked Pizza Base: The Effect of Leavening Time.Foods,12,1407-1427.  Craeyveld.V.V,E.Dornez,U.Holopainen,E.Selinheimo,K.Poutanen,J.A. Delcour,C. M.Courtin.(2010).Wheat Bran AX Properties and Choice ofXylanase Affect Enzymic Production of Wheat Bran-Derived Arabinoxylan-Oligosaccharides.Cereal chemistry,87(4),283-291.  Cunha.C.C.Q.B,A.R.Gama.,L.C.Cintra.,L.A.M.Bataus,C.J.Ulhoa.(2018). Improvement of bread making quality by supplementation with a recombinant xylanase produced by Pichia pastoris. Plos One, 26,1-14.  Dahiya.S,B.Singh.(2019).Enhanced endoxylanase production by Myceliophthora thermophile with applicability in saccharification of agricultural substrates.Biotech,3(9),214-224.  Davis.J.(1964).Disc electrophoresis, II. Method & application to human serum proteins.J. Am. N. Y. Acad. Sci,121,404-427  Deutschmann.R&R.F.H.Dekker.(2012).From plant biomass to bio-based chemicals: Latest developments in xylan research.Biotechnol Adv,30,1627–1640.  Dhaka.v,N.Gulia,B.S.Khatkar.(2012).Application of Mixolab to Assess the Bread Making Quality of Wheat Varieties.Open Access Scientific Reports,1(3),183-191.  Dhaver.P,B.Brett Pletschke, B.Sithole,R.Govinden.(2022).Optimization, purification, and characterization of xylanase production by a newly isolated Trichoderma harzianum strain by a two-step statistical experimental design strategy.Scientific reports,12,177-191.  Dhaver.P,B.Brett Pletschke,B.Sithole,R.Govinden.(2022).Optimization, purification, and characterization of xylanase production by a newly isolated Trichoderma harzianum strain by a two-step statistical experimental design strategy.Scientific reports,12,177-191.  Dhiman,S.S,J.Sharma,B.Battan.(2008).Industrial applications and future prospects of microbial xylanases. Bio Resources,3(4),1377-1402.  Dubois.M,A.Dubat,B.Launay.(2008).The Alveo Consistograph Handbook. Wiley-VCH,Inc.Third Avenue,(2nd edition).New York, 580.  Duyvejonck.A,B.Lagrain,B.Pareyt,C.Courtin,J.Delcour.(2011).Relative contribution of wheat flour constituents to solvent retention capacity profiles of European wheats. J. Cereal Sci,53,312-318.  Elegbede.J.A&A.Lateef.(2019).Optimization of the production of xylanases in corncob-based media by Aspergillus niger and Trichoderma longibrachiatum using Taguchi approach. Acta Biologica Szegediensis, 63(1),51-58.  Ezeilo.U.R,C. T.Lee,F.Huyop,I.I.Zakaria,R.A.Wahab.(2019).Raw oil palm frond leaves as cost-effective substrate for cellulase and xylanaseproductions by Trichoderma asperellum UC1 under solid-state fermentation. The Journal of Environmental Management,243(1),206-217.  Ezeilo.U.R,R.A.Wahab,F.Huyop,E. E.David,L.C.Tin.(2021).Solid-state valorization of raw oil palm leaves by novel fungi Trichoderma asperellum UC1 and Rhizopus oryzae UC2 for sustainable production of cellulase and xylanase. Journal of chemical technology and Biotechnology,97(2),520-533.  Fadel.H.M,M.G.Mahmoud,M.M.S.Asker,S.N.Lotfy.(2015).Characterization and evaluation of coconut aroma produced by Trichoderma viride EMCC-107 in solid state fermentation on sugarcane bagasse. Electronic journal of Biotechnology,18(1),5-9.  Faergestad.E.M,E.L.Molteberg,E.M.Magnus.(2000).Interrelationships of protein composition, protein level, baking process and the characteristics of hearth bread and pan bread. J Cereal Sci ,31,309-320.  Fialho.M.B&E.C.Carmona.(2004).Purification and characterization of xylanases from Aspergillus giganteus. Folia Microbiol(Praha),49(1),13–18.  Fortkamp.D&A.Konb.(2014).High xylanase production by Trichoderma viride using pineapple peel as substrate and its application in pulp biobleaching. African Journal of Biotechnology,13(22),2248-2259.  Fu.L,N.Jiang,C.Li,X.Lou,S.Zhao,J.Feng.(2019).purification and characterization of an endo –xylanase from Trichoderma sp with xylobiose as the main product from xylan hydrolysis.world .J.Microbial Biotechnol,35(11),171-180. doi: 10.1007/s11274-019-2747-1.  Furigay.M.H,M.M.Boucher,N.A.Mizgier,C.S.Brindle.(2018).Separation of Aldehydes and Reactive Ketones from Mixtures Using a Bisulfite Extraction Protocol. Journal Visualized Experiments,134,1-10.  Ghoshal.G,U.S.Shivhare,U.C.Banerjee.(2017).Rheological properties and microstructure of xylanase containing whole wheat bread dough. Journal of Food Science & Technology,54(7),1928–1937.  Goesaert.H,K.Brijs,W.S.Veraverbeke,C.M.Courtin,K.Gebruers,J.A.Delcour.(2005).Wheat flour constituents: how they impact bread quality, and how to impact their functionality. Trends Food Sci Technol,16(1),12-30.  Gomes-Garcia.M.R,A.Miguel,M.Medina,R.Rodriguez,B. Farruggia,G. Pico,C. Aguilar.(2018).Production of a xylanase by Trichoderma harzianum(Hypocrea Lixii) in solid-state fermentation and its recovery by an aqueous two- phase system. Canadian journal of Biotechnology,2(2),108-115.  Goyal.M,K.L. Kalra,V.K.Sareen,G.Soni.(2008). Xylanase Production With Xylan Rich Lignocellulosic Wastes By a Local Soil Isolate Of Trichoderma Viride.Brazilian Journal of Microbiology, 39,535-541 Gray.J&J.Bemiller.(2003).Bread staling: molecular basis and control. Comprehensive reviews.food science and food safety,2,1-21.  Gupta.R,P.Gigras,H.Mohapatra,V.K.Goswami,B.Chauhan.(2003).Microbial α-amylase: a biotechnological perspective. Process Biochem,38(11),1599-1616.  Hadnadeva.T,A.Torbica,M.Hadnadev.(2011).Rheological properties of wheat flour substitutes/alternative crops assessed by Mixolab. Procedia Food Science,1,328 – 334.  Hakulinen.N,O.Turunen,J.Janis,M.Leisola,J.Rouvinen.(2003). Threedimensional structures of thermophilic beta‐1,4‐xylanases from Chaetomium thermophilum and Nonomuraea flexuosa Comparison of twelve xylanases in relation to their thermal stability. European journal of biochemistry,270(7),1399‐1412.  Hande.D,G.Nihan,T.Canan,H.Doreen,L.Marcelo.(2012). Optimization of the process parameters for the utilization of orange peel to produce polygalacturonase by solid-state fermentation from an Aspergillus sojae mutant strain.Turk J Biol,36,394-404.  Hawraa.H.A.(2011). Production and Characterization of Chitinase and β 1-3 Glucanase from Trichoderma fertile Local Isolate. Degree of Master of Science in Biology.Kerbala university.1-188.  Heck.JX,L.H.de Barros Soares,P.F.Hertz,M.A.Z.Ayub.(2006).Purification and properties of a xylanase produced by Bacillus circulans BL53 on solid-state cultivation. Biochem Eng J,32,179-184.  Hoda .M.S, A.S.Abdel-Dayem,B.E.L.T. Arafat.(2012).Production of Xylanase by Aspergillus niger andTrichodermaviride using Some Agriculture Residues. International Journal of Agricultural Research,7,46–57.  Holker,U&A.Jurgen.(2005).Solid-state fermentation are there any biotechnological advantages. Current Opinion in Microbiology,8,301-306.  Hou.C,Zhao. X,Tian.M,Zhou.Y,Yang.R,Gu.Z,Wang.P.(2020).Impact of water extractable arabinoxylan with different molecular weight on the gelatinization and retrogradation behavior of wheat starch. Food Chemistry, 15,318:126477. https://doi:10.1016j.food chem.2020.126477.  Hruskova.M&O.Femera.(2003). Prediction of Wheat and Flour Zeleny Sedimentation Value Using NIR Technique.Czech J.Food Sci,21(3),91-96. https://doi.org/10.1155/2022/2910821. Huang.X,J.Ge,J.Fan,X.Chen,X.Xu,J.Li,Y.Zhang,D.Zhou.(2013).Characterization and optimization of Xylanase and endoglucanase production by Trichoderma viride HG 623 using response surface methodology (RSM). African journal of Microbiology Research,7(36),4521-4532.  Hug-Iten.S,B.Conde-Petit ,F.Echer.(2001).Structural properties of starch in bread and bread model systems: influence of an antistaling α -amylase. Cereal Chemistry,78(4),421–428.  Ifran.M&Q.Syed.(2012).Partial purification and characterization of Xylanase from Trichoderma viride produced under SSF. International Journal of Applied Research in Natural Products,5(1),7-11.  Ikram.H&A.Sikander.(2007).Kinetics Of Invertase Production By Saccharomyces Cerevisiae In Batch Culture. Pak. J. Bot,39(3),907-912.  Irfan.M,M.Nadeem,Q.Syed.(2014).One-factor-at-a-time(OFAT) optimization of xylanase production from Trichoderma viride-IR05 in solid-state fermentation.Journal of Radiation Research and Applied Sciences, 7,317-326.  Izydorczyk.M.S,T.L.Chornick,F.G.Paulley,N.M.Edwards,J.E.Dexter.(2008).Physicochemical properties of hull-less barley fiber-rich fractions varying in particle size and their potential as functional ingredients in two-layer flat bread.Food Chem,108,561–570.  Jaekel.L.Z,C.B.da.Silva,C.J.Steel,Y.K.Chang.(2012).Influence of xylanase addition on the characteristics of loaf bread prepared with white flour or whole grain wheat flour. Ciênc. Tecnol. Aliment., Campinas,32(4),844-849.  Jampala.P,S.Tadikamalla,M.Preethi,S.Ramanujam,K.B.Uppuluri.(2017). Concurrent production of cellulose and exylanase from Trichoderma reesei NCIM 1186:enhancement of production by desirability-based multi-objective method. Biotech,7,1-14.  Jayalakshmi.S.K,S.Raju,R.S.Usha,V.I.Benagi,K.Sreeramulu.(2009). Trichoderma harzianum L1 as a potential source for lytic enzymes and elicitor of defense responses in chickpea (Cicer arietinum L.) against wilt disease caused by Fusarium oxysporum f.sp. Ciceri . Australian Journal of Crop Science, 3(1),44-52.  Jegannathan,K.R&P.H,Nielsen.(2013).Environmental assessment of enzyme use in industrial production. Journal of cleaner production, 42,228-240.  Jia.C,W.Huang,M.A.Abdel-Samie,G.Huang.(2011).Dough rheological, Mixolab mixing, and nutritional characteristics of almond cookies with and without xylanase.Journal of Food Engineering,105(2),227-232. Jun.H,T.Kieselbach,L.J.Jonsson.(2011). Enzyme production by filamentous fungi: analysis of the secretome of Trichoderma reesei grown on unconventional carbon source. Microbial Cell Factorm ,10(1),1-10.  Jun.H,Y.Bing,Z.Keying,D.Xuemei,C.Daiwen.(2009).Expression of endo -1,4beta—Xylanase from Trichoderma reesei in Pichia pastoris and functional characterization of the produced enzyme. BMC Biotechnology,9(56),4-10  Juturu,V&J.C.Wu.(2012).Microbial xylanases:Engineering ,production and industrial applications.Biotechnol Adv,30,1219-1227.  Kachlishvili.E,M.J.Penninckx,N.Tsiklauri,V.Elisashvili.(2006).Effect of nitrogen source on lignocellulolytic enzyme production by white-rot basidiomycetes under solid-state cultivation. World Journal Microbiol Biotechnol,22(4),391–397.  Kahraman.K,O.Sakyyan,S.Ozturk,H.Koksel,G.Sumnu,A.Dubat.(2008). Utilization of mixolab to predict the suitability of flours in terms of cake quality.European Food Research Technology,227,565–570.  Kamble.R.D&A.R.Jadhav.(2012).Isolation,Purification,and Characterization of Xylanase Produced by a New Species of Bacillus in Solid State Fermentation. International Journal of Microbiology,8,1-8. doi:10.1155/2012/683193.  Kanaga.K,A.Pandey,S.Kumar.(2016).Multi-objective optimization of media nutrients for enhanced production of algae biomass and fatty acid biosynthesis from Chlorella pyrenoidosa NCIM 2738.Bioresour Technol ,200,940–950.  Kapich.A,B.Prior,A.Botha,S.Galkin,T.Lundell,A.Hatakka.(2004).Effect of lignocellulose-containing substrates on production of ligninolytic peroxidases in submerged cultures of Phanerochaete chrysosporium ME-446. Enzyme microb technol,34(2),187-195.  Kathirvel.P&P.Kumudha.(2011).Chemical composition of Prosopis Juliflora (SW.) D.C (MOSQUITO BEAN). International journal of Applied Biology and Pharmaceutical Technology,2(4),199-209.  Katina.K,M.Salmenkallio-Marttila,R.Partanen,P.Forssell,K.Autio.(2006). Effects of sourdough and enzymes on staling of high fiber wheat bread. Technol,39,479-491.  Khandeparkar.R&N.B.Bhosle.(2006).Purification and characterization of thermoalkalophilic xylanase isolated from the Enterobacter sp.MTCC 5112. Res. Microbiol,157,315‐325. Kim.H.J&S.H.Yoo.(2020).Effects of Combined α-Amylase and Endo-Xylanase Treatments on the Properties of Fresh and Frozen Doughs and Final Breads. Polymers,12(6),1349-1359.  Kim.K,R.Tsao,R.Yang,S.W.Andcui.(2006).Phenolic acid profiles and antioxidant activities of wheat bran extracts and the effect of hydrolysis conditions. Food Chem,95(3),466-473.  Kiszonas.A.M,E.P.Fuerst,D.Luthria,C.F.Morris.(2015).Arabinoxylan content and characterisation throughout the bread‐baking process. International journal of food science & technology, 50(8),1911-1921.  Kocadagli.T&V.Gokmen.(2016).Multiresponse kinetic modelling of Maillard reaction and caramelisation in a heated glucose/wheat flour system. Food Chemistry,211,892-902.  Konopka.I,L.Fornal,D.Abramczyk,J.Rothkaehl,D.Rotkiewicz.(2004). Statistical evaluation of different technological and rheological tests of Polish wheat varieties for bread volume prediction. International Journal of Food Science and Technology, 39,11–20.  Koryachkina.S,N.Berezina,E.Khmeleva.(2010).Quality research methods for Bakery products. Russia, Oryol: Orel State Technical University,86–88 (in Russian).  Kostyuchenko.M,V.Martirosyan,M.Nosova,G.Dremucheva, E.Nevskaya, O.Savkina.(2021).Effects of α-amylase, endo-xylanase and exoprotease combination on dough properties and bread quality.Agronomy Research. ,19(3),1234–1248.  Kredics.L,Z.Antal,L.Manczinger,A..Szekeres,F.Kevei,E.Nagy.(2003). Influence of environmental parameters on Trichoderma strains with biocontrol potential. Food Technol.Biotechnol,41(1),37-42.  Kumar.D,S.S.Kumar,J.Kumar,O.Kumar,S.V.Mishra,R.Kumar,S.K.Malyan.=.(2017).Xylanase and their industrial applications :A review. Biochemical and Cellular Archives,17(1),353-360.  Kunzel.M.O&M.Ali.(2008).A Comparative study of some wheat varieties. in the most important physical properties and chemical and rheology. Yemeni Journal of Agricultural Research,27,111-125.  Kweon.M,L.Slade,H.Levine.(2011).Solvent Retention Capacity (SRC) Testing of Wheat Flour: Principles and Value in Predicting Flour Functionality in Different Wheat-Based Food Processes and in Wheat Breeding-A Review.Cereal Chem,88(6),537–552.  Laemmli.U.K.(1970).Cleavage of structural proteins during the assembly of the head of bacteriophage T4. Nature,227,680‐685. Lagaert.S,T.Belien,G.Volckaert.(2009).Plant cell walls: protection the Barrier from degradation by microbial enzymes.Semin Cell Dev Bio. 20(9).1064-1073.  Lakshmi.G.S,P.L.Bhargavi,R.S.Prakasham.(2011).Sustainable Bioprocess Evaluation for Xylanase Production by Isolated Aspergillus terreus and Aspergillus fumigatus Under Solid -State Fermentation Using Oil Palm Empty Fruit Bunch Fiber Current Trends in.Biotechnology and Pharmacy, 5(4),1434–1444.  Latif.F,M.Asgher,R.Saleem,A.Akram,R.Legge.(2006).Purification and characterization of xylanase produced by C.thermophile NIBGE. World Journal of Microbiology & Biotechnology,22,45-50.  Launay.B&C.Michon.(2008).Biaxial extension of wheat flour doughs: lubricated squeezing flow and stress relaxation properties. J. Texture Stud, 39,496-529.  Lazaridou.A,D.Duta,M.Papageorgiou,N.Belc,C.G.Biliaderis.(2007).Effects of hydrocolloids on dough rheology and bread quality parameters in gluten-free formulations. J Food Eng,79,1033–1047.  Lee.M.R&W.Lee.(2012).Wheat Quality and Its Effect on Bread Staling.Journal of Agriculture and Life Science,46(1),153-161.  Lin.H,M.Sun,J.Li,Q.Xu,B.Yang,Q.Wang,W.Xie,S.Sun,K.Hu,L.Zhang.(2018).Purification and characterization of xylanase from spent mushroom compost and its application in saccharification of biomass wastes. Bio Res,13(1),220-230.  Lindgren.A.L.(2016).Solvent Retention Capacity And Quality Parameters Of Whole Wheat Flour from Hard Red Spring Wheat. Master Of Science.North Dakota State University of Agriculture and Applied Science. Fargo,North Dakota.140(21).  Liu.L,M.Y. Xu,Y.L. Cao,H. Wang,J. Shao,M.Q. Xu,Y.C. Zhang,Y.H. Wang,W.X. Zhang,X.F. Meng,W.F.Liu.(2020).Biochemical Characterization of Xylanases from Streptomyces sp. B6 and Their Application in the Xylooligosaccharide Production from Viscose Fiber Production Waste. Journal Of Agricultural And Food Chemistry, 68, 3184-3194.  Liu.T,G.G.Hou,M.Cardin,L.Marquart,A.Dubat.(2017).Quality attributes of whole-wheat flour tortillas with sprouted whole-wheat flour substitution. LWT-Food Science and Technology,77,1-7.  Lowry.O.H,N.J.Rosebrough,A.L. Farr,R.J.Randall.(1951).Protein measurement with the Folin phenol reagent.J biolchem,193,265-275. Majzoobi.M,A.Farahnaky,Z.Nematolahi,M.Mohamadi Hashemi,M.Taghipour.(2013).Effect of different levels and particle sizes of wheat bran on the quality of flat bread.Journal of Agricultural Science and Technology,15(1),115-123.  Mamo.G,R.Hatti‐Kaul,B.Mattiasson.(2006).A thermostable alkaline active endo‐β‐1‐4‐ xylanase from Bacillus halodurans S7: Purification and characterization. Enzy. Microb.Technol,39,1492‐1498.  Mandal.A.(2015).Review on microbial xylanases and their applications. International journal of life science,4(3),178-187.  Manivannan.A&R.Narendhirakannan.(2014).Response surface optimization for co-production of cellulase and xylanase enzymes by Trichoderma reesei NRRL–3652. International Journal Chem Tech Research,6(7),3883-3888.  Mardawati.E,Y.Sinurat.,T.Yuliana.(2020). Production of Crude Xylanase From Trichoderma sp. Using Reutealis trisperma Exocarp substrate in solid state fermentation. International Conference of Sustainability Agriculture and Biosystem:Earth and Environmental Science,515,1-10.  Martins.Z.E,O.Pinho,I.M.Ferreira.(2017).Food industry by-products used as functional ingredients of bakery products.Trends in Food Science and Technology,67,105-128.  Masood.S.B,T.N.Muhammad,A.Zulfiqar,T.S.Muhammad.(2008). Xylanases and their applications in baking industry.Food technol Biotechnol,46(1),22-31.  Massri.M.A&A.bd Alhameed.(2017).The Use of Wheat, Corn Bran and Apples, Carrots Pomace as a Source of Dietary Fibers and Its Impact on the Wheat Specifications and Rheological Properties of Dough. Jordanian Journal of Agricultural Sciences,2(13),539-553.  Matsushita.K,D.M.santiago,T.Noda,K.Tsuboi,S.KawaKaMi,H.YaMauchi. (2017).The Bread Making Qualities of Bread Dough Supplemented with Whole Wheat Flour and Treated with Enzyme. Food Science and Technology Research, 23(3),403-410.  McNeil.B&L.M.Harvey.(2008).The Design and Preparation of Media for Bioprocesses . in Practical Fermentation Technology .John Wiley and Sons , L td. ISBN: 978-0-470-01434-9.  Meenakshi.G,K.L.Kalra,V.K.Sareen,G.Soni.(2008).Xylanase production whith xylan rich lignocellulosic wastes by a local soil isolate of Trichoderma viride. Brazilian Journal of Microbiology,39,535-541.  Millar.G.L.(1959).Use of dinitrosalicylic and reagent for determination of reducing sugar.Analytical chemistry,31,426-428. Minz.P.S,C.Singh,I.K.Sawhney.(2013).Color measurement of food products. 25th National Training,CAFT, India. Dairy Processing.130- 133.  Mohamed.S.A,A.L.Al-Malki,J.A.Khan,S.A.Kabli,S.M.Al-Garni.(2013). Solid state production of polygalacturonase and xylanase by Trichoderma species using cantaloupe and watermelon rinds. Journa of Microbiology,51,605-611.  Mohammadi.M,A.Zoghi,M.H.Azizi.(2022).Effect of xylanase and pentosanase Enzymes on Dough Rheological properties and Quality of Baguette Bread. Journal of Food Quality,6,1-9.  Mohammadi.M,A.Zoghi,M.H.Azizi.(2022).Effect of xylanase and pentosanase Enzymes on Dough Rheological properties and Quality of Baguette Bread. Journal of Food Quality.1-9. https://doi.org/10.1155/2022/2910821.  Monte.E.(2001).Understanding Trichodera :between biotechnology and microbial ecology. Int Microbiol,4,1-4.  Moradi.V,A.M.Khaneghah,A.Fallah,H.Akbarirad.(2016).Rheological properties of wheat. Flour with different extraction rate. International Food Research Journal,23(3),1056-1061.  Myers.R.H&D.C.Montogomery.(2002).Response surface methodology : Process and product optimization using designed experiments.2nd.ed.Wiley. New York, 2100.  Nathan.V.K,M. E.Rani,G.Rathinasamy,K.N.Dhiraviam.(2017).Low Molecular Weight Xylanase from Trichoderma viride VKF3 for Bio-bleaching of Newspaper Pulp. BioResources,12(3),5264-5278.  Nionelli.L&C.Rizzello.(2016).Sourdough-Based Biotechnologies for the Production of Gluten-Free Foods. Foods, 5(3),65-79.  Nishitsuji.Y,K.Whitney,K.Nakamura,K.Hayakawa,S.Simsek.(2020). Changes in structure and solubility of wheat arabinoxylan during the breadmaking process.Food Hydrocolloids.109.2020.December:106129. https:// doi.org/10.1016/j.food hyd. 2020.106129.  Noort.M.W,D.Vanhaaster,Y.Hemery,H.A.Schols,R.J.Hamer.(2010).The effect of particle size of wheat bran fractions on bread quality: evidence for fibre-protein interactions.Journal of Cereal Science,52(1),59-64. http://dx.doi.org/10.1016/j.jcs.2010.03.003.  Oliveira.D.M,T.R.Mota,F.V.Salatta,R.Marchiosi,L.D.Gomez,S.J.McQueen-Mason,O.Ferrarese-Filho,W.D.dos Santos.(2019). Designing xylan for improved sustainable biofuel production. Plant Biotechnology Journal,17(12),2225-2237. Omar.A.W,M.H.Khataibeh,K.Abu-Alruz.(2008).The use of xylanases from different microbial origin in bread making and their effects on bread quality.J Appl Sci,8,672-676.  Pahwa.A,A.Kaur,R.Puri.(2015).Influence of Hydrocolloids on the Quality of Major Flat Breads: A Review. Journal of Food Processing,20(16),1-10.  Pandey.A.(2003).Solid-state fermentation.BioChemical Engineering Journal,13,81-84.  Pathak.P,N.K.Bhardwaj,A.K.Singh.(2014).Production of crude cellulase and xylanase from Trichoderma harzianum PPDDN10 NFCCI-2925 and its application in photocopier waste paper recycling. Appl Biochem Biotechnol,172(8),3776-3797.  Paucean.A,S.Man,S.A.Socaci.(2016).Wheat germ bread quality and dough rheology as influenced by added enzymes and ascorbic acid. Studia Universitatis Babes-Bolyai, Chemia,61(2),103-118.  Pico.J,J.Bernal,M.Gómez.(2015).Wheat bread aroma compounds in crumb and crust: A review. Food Research International ,75, 200–215. doi:10.1016/j.foodres.2015.05.051.  Pirota.R.D.P.B,P.S.Delabona,C.S.Farinas.(2014).Simplification of the biomass to ethanol conversation process by using the whole medium of filamentous fungi cultivated under solid-state fermentation.Bioenergy Res, 7,744-752.  Polizeli.M.L.T.M, A.C.S.Rizzatti,R. Monti,H.F.Terenzi,J.A. Jorge,D.S. Amorim.(2005). Xylanases from fungi: properties and industrial applications. Appl Microbiol Biotechnol,67, 577-591.  Poorna.C.A.(2011).Purification and Biochemical Characterization of Xylanases from Bacillus Pumilus and their Potential for Hydrolysis of Polysaccharides.FermentationTechnology,1(1),101-106.  Primo-Martín.C,M.Wang,W.J.Lichtendonk,J.J.Plijter,R.J.Hamer.(2005).An explanation for the combined effect of xylanase–glucose oxidase in dough systems.Journal of the Science of Food and Agriculture,85(7),1186-1196.  Raghavendra.S.N,N.K.Rastogi,K.S.M.S.Raghavarao,R.N.Tharanathan. (2004).Dietary fiber from coconut residue: effects of different treatments and particle size on the hydration properties. European Food Research and Technology, 218(6),563-567.  Ramasamy.S,H.S.Balakrishna,U.Selvaraj,K.B.Uppuluri.(2014).Production and statistical optimization of oxytetracycline from Streptomyces rimosus NCIM 2213 using a new cellulosic substrate Prosopis juliflora. BioResources,9(4),7209–7221. Raveendran.S,B.Parameswaran,S.B.Ummalyma,A.Abraham,A.K.Mathew. A.Madhavan,S.Rebello,A.Pandey.(2018).Applications of microbial enzymes in food industry. Food Technol Biotechnol,56,16-30.  Ribotta.P. D&A.L.Bail.(2007).Thermo-physical assessment of bread during staling. Food Science and Technology,40,879–884.  Rifai.M.A.(1969).A revision of the genus Trichoderma. Mycological papers, 116,1-52.  Sahnoun.M,M.Kriaa,S.Besbes,M.Jardak,S.Bejar,R.Kammoun.(2016).Optimization of Aspergillus oryzae S2 α-amylase, ascorbic acid, and glucose oxidase combination for improved French and composite Ukrainian wheat dough properties and bread quality using a mixture design approach. Food Science and Biotechnology,25(5),1291–1298.  Sakthiselvan.P,B.Naveena,N.Partha.(2012).Effect of medium composition and ultrasonication on xylanase production by Trichoderma harzianum MTCC 4358 on novel substrate. African Journal of Biotechnology,11(57),12067-12077.  Samuels.G,C.Suarez,C.Solis,K.A.Holmes,S.E.Thomas,A.Ismail,H.C.Evans. (2006).Trichoderma theobromicola and T. paucisporum: two new species isolated from cacao in South America. Mycological Research,110, 381-392.  Sanz-penella.J.M,M.Wronlowska,M.Soral-Smietana,M.Haros.(2013).Effect of whole amaranth flour on bread properties and nutritive value.LWT –Food science and technology,50(2),679-685.  Sa-Pereira.P,H.Paveia,M.Costa-Ferreira,M.R.Aires-Barros.(2003).A new look at xylanases: an overview of purification strategies.Mol Biotechnol. 24(3),257–281.  Sariah.M,C.W.Choo,H.Zakaria,M.S.Noriha.(2005).Quantifiction and characterization of Trichoderma spp. From different ecosystems. Mycopathologia,159(1),117-133.  Saulnier.L,P.E.Sado,G.Branlard,G.CHarmet,F.Guillon.(2007).Wheat arabinoxylans: exploiting variation in amount and composition to develop enhanced varieties.J.Cereal.Sci,46(3),261-281.  Sawal.R.K,R.Ratan,S.B.S.Yadav.(2004).Mesquite (Prosopis juliflora) Pods as a Feed Resource for Livestock. Asian-Australasian Journal of Animal Sciences,17(5),719-725.  Scheller.H.V&P.Ulvskov.(2010).Hemicelluloses.Annual Review of Plant Biology,61,263-289.  Schoenlechner.R,M.Szatmari,A.Bagdi,S.Tömösközi.(2013).Optimisation of bread quality produced from wheat and proso millet (Panicum miliaceum Lby adding emulsifiers, transglutaminase and xylanase. LWT - Food Science and Technology,51,361-366.  See.E.F,W.A.Wan Nadiah,A.A.Noor Aziah.(2007).Physico-Chemical and Sensory Evaluation of breads supplemented with pumpkin flour. Asean Food J ,14(2),123–30.  Selinheimo.E,K.Kruus,J.Buchert,A.Hopia,K.Autio.(2006).Effects of laccase, xylanase and their combination on the rheological properties of wheat doughs.J. Cereal Sci,43(2),152–159.  Seyis,I&N.Akzos.(2005). Xylanase production from Trichoderma harzianum 1073 D3 with alternative carbon and nitrogen sources.Food Technol Biotechnol,43(1), 37-40.  Shafisoltani.M,M.Salehifar,M.Hashem.(2014).Effects of enzematic treatment using Response surface methodology on the quality of bread flour.Food chemistry,148,176-183.  Shah.A.R&D.Madamwar.(2005).Xylanase production by a newly isolated Aspergillus foetidus strain and its characterization. Process Biochemistry,40,5,1763-1771.  Shah.A.R,R.K.Shah,D.Madamwar.(2006). Improvement of the quality of whole wheat bread by supplementation of xylanase from Aspergillus foetidus. Bioresource Technology,97(16),2047–2053.  Shalaby.M.T,M.A.Abou-Raya,R.E.EL-gammal,H.A.A.Al Janabi. (2014).Effect of storage on some physical and chemical properties of Iraky bread.J. Food and Dairy Sc,5(12),891-904.  Sharfuddin.C&R.Mohanka.(2012).In vitro antagonism of indigenous Trichoderma isolates against phyto pathogen causing wilt of lentil. Int J Life Sci Pharm Res,3,195-202.  Sharma.S,V.Sharma,P.Nargotra,B.K.Bajaj.(2018).Process desired functional attributes of an endoxylanase of GH 10 family from a new strain of Aspergillus terreus S9. Int J Biol Macromol,115,663-671.  Silva.L.A.O,C.R.F.Terrasanmc,E.C.Carmona.(2015). Purification and characterization of xylanases from Trichoderma inhamatum. Electronic journal of biotechnology,18,307-313.  Singleton.V.L,R.Orthofer,R.M.Lamuela-Raventós.(1999).Analysis of total phenols and other oxidation substrates and antioxidants by means of folin-ciocalteu reagent.Methods Enzymol,299,152–178.  Soliman.H.M,A.A.sherief,A.El-Tanash.(2012). Production of Xylanase by Aspergillus niger and Trichoderma viride using some agriculture residues.International Journal of Agriculture Research,7(1),46-57 Sridevi.A,G.Ramanjaniyulu,P.S.Devi.(2017).Biobleaching of paper pulp with xylanase produced by Trichoderma asperellum.Biotech,3,266-273.  Struyf.N,J.Verspreet,K.J.Verstrepen,C.M.Courtin.(2017).Investigating the impact of α-amylase,β-glucosidase and glucoamylase action on yeast-mediated bread dough fermentation and bread sugar levels. J. Cereal Sci,75, 35–44.  Subramaniyan,S&P.Prema.(2002).Biotechnology of microbial xylanases: enzymology, molecular biology, and application.Critical Reviews Biotechnol,22(1),33–64.  Sudan.R&B.K.Bajaj.(2007).Production and biochemical characterization of xylanase from an alkalitolerant novel species Aspergillus niveus RS.World J Microbiol Biotechnol,23(4),491–500.  Sun.J.Y,M.Q.Liu,X.Y.Weng,L.C.Qian,S.H.Gu.(2007).Expression of recombinant Thermomonospora fusca xylanase A in Pichia pastoris and xylooligosaccharides released from xylans by it.Food chemistry,104,1055-1064.  Tabilo-Munizaga.G&G.V.Barbosa-Cà novas. (2005).Rheology for the food industry.J Food Eng, 67,147–156.  Taibi.Z,B.Saoudi,M.Boudelaa,H.Trigui,H.Belghith.A.Gargouri, A.Ladjama.(2012).Purification and biochemical characterizationof a highly thermostable xylanase from Actinomadura sp. Strain Cpt20 isolated from poultry compost. Appl Biochem Biotechnol,166(3),663–679.  Takata.K,H.Yamauchi,Z.Nishio,T.Kuwabara.(2001).Prediction of breadmaking quality by prolonged swelling SDS-sedimentation test. Breeding Sci,49,221-223.  Uday.U.S.P,Choudhury,P.T.K.Bandyopadhyay,B.Bhunia.(2016).Classification, mode of action and production strategy of xylanase and its application for biofuel production from water hyacinth.International journal of biological macromolecules,82,1041-1054.  Uhoraningoga.A,G.K.Kinsella,G.T.Henehan,B.J.Ryan.(2018).The goldilocks approach: A review of employing design of experiments in prokaryotic recombinant protein production. Bio engineering.5(4),89-116.  Uysal.H,N.Bilgicli,A.Elgun,S.Ibanoglu,E.N.Herken,M.K.Demir.(2007). Effect of dietary fiber and xylanase enzyme addition on the selected properties of wire-cut cookies. J. Food Eng,78(3),1074–1078.  Vanden Brink,J&R.P.Vries.(2011).Fungal enzyme sets for plant polysaccharide degradation.Appl Microbial Biotechnol,91(6),1477-1492 Venkatesh,M&D.Girija.(2009).Micrbial pectinase from tropical fruit Wastes. Journul of Tropical Agriculture,47(1),67-69.  Veraverbeke,W.S&J.A.Delcour.(2002).Wheat protein composition and properties of wheat glutenin in relation to breadmaking functionality. Critical Reviews in Food Science and Nutrition.42(3),179 - 208.  Vries.R.P&J.Visser.(2001).Aspergillus enzyme involved in degradation of plant cell wall polysaccharide. Microbial Mol Biol Rev,65(4),497-522.  Walia.A,P.Mehta,S.Guleria,A.Chauhan,C.K.Shirkot.(2015).Molecular cloning and sequencing of alkalophilic Cellulosimi-crobium cellulans CKMX1 xylanase gene and characterization of gene product. Braz Arch Biol Technol ,58(6),913–922.  Walia.A,S.Guleria,P.Mehta,A.ChauhanJ.Prakash.(2017).Microbial xylanases and their industrial application in pulp and paper biobleaching:a review.Biotech,7(11),1-12.  Walter.M,G.J.Jaklitsc,L.M.Sarah,S.L.Bing.(2006).Hypocrearufa/ Trichoderma viride: a reassessment and description of five closely related specieswith and without warted condidia.Stud Mycol USA,56(1),135-177.  Wang.P,C.Hou, X.Zhao,M.Tian,Z.Gu,R.Yang.(2019).Molecular characterization of water-extractable arabinoxylan from wheat bran and its effect on the heat-induced polymerization of gluten and steamed bread quality.Food Hydrocolloids,87,570–581. https://doi.org/10.1016/j.  Woldeamanuale.T.(2017).Isolation,screening and identification of cadmium tolerant fungi and their removal potential. Journal Forensic Sciences &Criminal Investigation,5(1),1-7.  Wuczowsky.M,I.Druzhinina,Y.Gherbawy,B.Klug,H.Prillinger,C.P..Kubicek. (2003).Species pattern and genetic diversity of Trichoderma in a mid-European, primeval floodplain-forest. Microbiol.Res,158,125-133.  Xhabiri.G,N.Durmishi,X.Idrizi,I.Ferati,I.Hoxha.(2016).Rheological qualities of dough from mixture of flour and wheat bran and possible correlation between bra bender and mixolab Chopin equipments.Food Processing & Technology,2(4),121-129.  Xhabiri.G,T.Acoski,M.Stanojeska,V.Sinani.(2013).The assessment of rheological qualities with the mixolab of different wheat flours enriched with their bran. European .Scientific Journal,9(24),1857-1881.  Xiao.F,X.Zhang,M.Niu,X.Xiang,Y.Chang,Z.Zhao,L.Xiong,S.Zhao,J.Rong, C.Tang,Y.Wu.(2021).Gluten development and water distribution in bread dough influenced by bran components and glucose oxidase. LWT - FoodScience and Technology, 137,110427. https://doi.org/10.1016/j.lwt.2020.110427.  Yadav.S,P.K.Yadav,D.Yadav,K.D.Yadav.(2009).Purification and characterization of pectin lyase produced by Aspergillus terricola and its application in retting of natural fibers. Appl Biochem Biotechnol,159 (1),270–283.  Yegin.S,B.Altinel,K.Tuluk.(2018).A novel extremophilic xylanase produced on wheat bran from Aureobasidium pullulans NRRL Y-2311-1: Effects on dough rheology and bread quality. Food Hydrocolloids,81,389–397.  Yousif.E.I.,A.A.Yaseen.,A.A.Abdel Fatah,AA.Shouk,M.G.Gadlla, A.A.Mohammad.(2019).Egyptian Balady Bread Quality as effected by functional Nano-Powders of some food industry by- product.Egypt.J.Food.Sci,47(2),213-226.  Zeleny.L.(1962).Wheat sedimentation test. Cereal Science Today,7,227.  Zhang.L,X.Wang,Z.Ruan,Y.Liu,X.Niu,Z.Yue,Z.Li,W.Liao,Y.Liu.(2014). Fungal cellulase/xylanase production and corresponding hydrolysis using pretreated corn stover as substrates. Appl Biochem Biotechnol ,172(2),1045–105.  Zhang.Y,L.Wang,H.Chen.(2017).Correlations of medium physical properties and process performance in solid-state fermentation.Chem Eng Sci,165,65-73.  Zhu.Z.Y,L.Zhao,X.R.Ge,Y.L.Tang,L.J.Chen,W.Pang,Y.Zhang.(2015). Prepration characterization and bioactivity of xylobiose and xylotriose from corncob xylan by xylanase.Eur food Res Technol,241,27-35.  Zhygunov.D,I.Toporash,Y.Barkovska,Y.Yehorshyn.(2020).Comparison Of Alveograph Characteristic Of Flour Obtained From Different Types Of Common Wheat And Spelt Wheat. Grain Products And Mixed Fodder’s,20(1),22-30.