Cereals processing technology

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72 Cereals processing technology Royal Australian Chemical Institute Cereal Chemistry Division. Melbourne. The Institute of Brewing. London. International Society for Plant Molecular Biology. Athens, Georgia. Association of Applied Biologists. Wellesbourne, UK. Plant and Animal Genome conferences – San Diego, California. 4.11 References ALAM M F, DATTA K, ABRIGO E, VASQUEZ A, SENADHIRA D and DATTA S K, Production of transgenic deepwater indica rice plants expressing a synthetic Bacillus thuringiensis cryIA(b) gene with enhanced resistance to yellow stem borer, Plant Sci (1998) 135 25–30. ALTPETER F, VASIL V, SRIVASTAVA V and VASIL I K, Integration and expression of the high-molecular-weight glutenin subunit 1Ax1 gene into wheat. Nature Biotechnology (1996) 14(9) 1155–9. ANDERSON O, Molecular approaches to cereal quality improvement in Cereal Grain Quality, Chapman and Hall, London (1996) pp 371–404. BARRO F, ROOKE L, BÉKÉS F, GRAS P, TATHAM A S, FIDO R, LAZZERI P A, SHEWRY P R and BARCELO P, Transformation of wheat with high molecular weight subunit genes results in improved functional properties. Nature Biotechnology (1997) 15(11) 1295–9. BERGELSON J, WINTENER J and PURRINGTON C B, Ecological impacts of transgenic crops in Applied Plant Biotechnology Chopra V C, Malik V S and Bhat S R (eds). Science Publishers Inc, USA (1999) pp 325–43. BLECHL A E and ANDERSON O D, Expression of a novel high-molecular-weight glutenin subunit in transgenic wheat. Nature Biotechnology (1996) 14(7) 875–9. BOWLES D J, Defence-related proteins in higher plants. Ann. Rev. Biochem (1990) 59 873–907. BRETTSCHNEIDER R, BECKER D and LÖRZ H, Efficient transformation of scutellar tissue of immature maize embryos, Theor Appl Genet (1997) 94 737–48. BRINCH-PEDERSEN H, GALILI G, KNUDSEN S and HOLM P B, Engineering of the aspartate family biosenthetic pathway in barley (Hordeum vulgare L.) by transformation with heterologous genes encoding feedback-sensitive aspartate kinase and dihydrodipicolinate synthase. Plant Molecular Biology (1996) 32(4) 611–20. BUCK K W, Virus resistant plants in Plant Genetic Engineering Grierson D (ed.) Blackie, USA (1991) pp 131–78. BURKHARDT P K, BEYER P, WÜNN J, KLÖTI A, ARMSTRONG G A, SCHLEDZ M, LINTIG JV and POTRYKUS I, Transgenic rice (Oryza sativa) endosperm expressing daffodil (Narcissus pseudonarcissus) phytoene synthase accumulates phytoene, a key intermediate of provitamin A biosynthesis, Plant J (1997) 11 1071–8. CHEN L, MARMEY P, TAYLOR N J, BRIZARD J-P, ESPINOSA C, D’CRUZ P, HUET H,
Biotechnology, cereal and cereal products quality 73 ZHANG S, DE KOCHKO A, BEACHY R N and FAUQUET C M, Expression and inheritance of multiple transgenes in rice plants, Nature Biotechnol (1998) 16 1060–4. CHENG X, SARDANA R, KAPLAN H and ALTOSAAR I, Agrobacterium-transformed rice plants expressing synthetic cryIA(b) and cryIA(c) genes are highly toxic to striped stem borer and yellow stem borer, Proc Natl Acad Sci USA (1998) 95 2767–72. DALE P J and IRWIN J A, Environmental impact of transgenic plants in Transgenic Plant Research Harwood Academic Publishers, Amsterdam (1998) pp 227– 85. DATTA K, VASQUEZ A, TU J, TORRIZO L, ALAM M F, OLIVA N, ABRIGO E, KHUSH G S and DATTA S K, Constitutive and tissue-specific differential expression of the cryIA(b) gene in transgenic rice plants conferring resistance to rice insect pest, Theor Appl Genet (1998) 97 20–30. EDNEY M, Barley in Cereal Grain Quality Henry R J and Kettlewell P S (eds) Chapman and Hall, London (1996) pp 113–51. FEARING P L, BROWN D, VLACHOS D, MEGHJI M and PRIVALLE L, Quantitative analysis of CryIA(b) expression in Bt maize plants, tissues, and silage and stability of expression over successive generations, Mol Breed (1997) 3 169– 76. FINCHER G B, Potential for the improvement of malting quality of barley by genetic engineering in Improvement of Cereal Quality by Genetic Engineering Henry R J and Ronalds J A (eds) Plenum Press, New York (1994) pp 135–8. GHAREYAZIE B, ALINIA F, CORAZON A, MENGUITO C A, RUBIA L G, DE PALMA J M, LIWANAG E A, COHEN M B, KHUSH G S and BENNETT J, Enhanced resistance to two stem borers in an aromatic rice containing a synthetic cryIA(b) gene, Mol Breed (1997) 3 401–14. HAMMONDKOSACK K E and JONES J D G, Plant disease resistance genes. Ann. Rev. of Plant Physiology and Plant Molecular Biology (1997) 48 575–607. HAN F, ROMAGOSA I, ULLRICH S E, JONES B L, HAYES P M and WESENBERG D M, Molecular marker-assisted selection formulating quality traits in barley. Molecular Breeding (1997) 3 427–57. HENRY R J, Barley quality: an Australian perspective. Aspects of Applied Biology (1990) 25 5–14. HENRY R J, Biotechnology applications in the cereal industry: Procedures and prospects. Cereal Foods World (1995) 40 370–3. HENRY R J, Improvement of the quality of barley for beer production in Agri-food Quality – an interdisciplinary approach Fenwick G R, Hedley C, Richard R L and Khokhar S (eds). The Royal Society of Chemistry, London (1996) pp 15– 18. HENRY R J, Practical applications of plant molecular biology. Chapman and Hall, London (1997). HENRY R J and KETTLEWELL P S (eds), Cereal Grain Quality. Chapman and Hall, London (1996). HENRY R J, KO H L and WEINING S, Identification of cereals using DNA-based
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Cereals processing technology Edite
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Related titles from Woodhead’s fo
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vi Contents 3.4 Recent developments
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viii Contents 9.11 References . . .
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x Contributors Chapter 6 Dr Jim Dex
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2 Cereals processing technology The
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Part I Cereal and flour production
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8 Cereals processing technology Fig
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10 Cereals processing technology Fi
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Total UK area = 792,000 ha Total UK
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14 Cereals processing technology 80
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Page 86 and 87: 5 Rice production B. S. Luh, Univer
Page 88 and 89: Rice production 81 evaluating quali
Page 90 and 91: Rice production 83 Table 5.1 Range
Page 92 and 93: Table 5.2 Physicochemical (quality)
Page 94 and 95: Table 5.3 Physicochemical (quality)
Page 96 and 97: Table 5.4 Milled rice grades and re
Page 98 and 99: Rice production 91 caused by the va
Page 100 and 101: Rice production 93 Based on water r
Page 102 and 103: Rice production 95 Rice disease res
Page 104 and 105: Rice production 97 Fig. 5.1 Flow ch
Page 106 and 107: Rice production 99 The milling yiel
Page 108 and 109: 5.7.1 Frozen rice Frozen cooked ric
Page 110 and 111: Rice Chex Õ and Crispix Õ are mad
Page 112 and 113: cake puffing machine that has been
Page 114 and 115: 5.16 References Rice production 107
Page 116 and 117: 6 Pasta production B. A. Marchylo a
Page 118 and 119: Pasta production 111 dumpling-like
Page 120 and 121: Fig. 6.1 A simple schematic of a lo
Page 122 and 123: Pasta production 115 from the sprea
Page 124 and 125: environment with a final moisture c
Page 126 and 127: Pasta production 119 cooking qualit
Page 128 and 129: 6.5 Raw material selection Pasta pr
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Pasta production 123 is directly re
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Pasta production 125 because of sup
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more difficult for farmers to grow
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Pasta production 129 Cereal Chem, (
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7 Asian noodle processing D. W. Hat
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Asian noodle processing 133 Most mi
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Fig. 7.1 Stages in different noodle
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Asian noodle processing 137 number
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Asian noodle processing 139 White s
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Asian noodle processing 141 Fig. 7.
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the final product. A two-stage proc
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Asian noodle processing 145 Table 7
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Asian noodle processing 147 Fig. 7.
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Asian noodle processing 149 with th
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7.7 Future of the industry Asian no
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percent, thus allowing the core to
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Asian noodle processing 155 PreHarv
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Asian noodle processing 157 43. KIM
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form as a breakfast food. He called
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Breakfast cereals 161 words. Jobber
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8.3 Recent trends and technology de
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Breakfast cereals 165 In continuous
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Breakfast cereals 167 were parallel
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Breakfast cereals 169 with quiet fa
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With the addition of personal compu
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9 Malting G. Gibson, Consultant, Co
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3. Muntons Malt This company operat
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Malting 177 of a barley corn. Signi
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Fig. 9.3 Diagrammatic layout of cir
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stored in relatively small hoppered
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allow gentle drying without subject
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Malting 185 situated externally, on
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Fig. 9.6 Capacity of circular flat
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convenient to convert their reinfor
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Malting 191 free filling of steeps
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Malting 193 Fig. 9.7 Fixed floor ge
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Malting 195 Fig. 9.8 Fixed floor ki
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Malting 197 with greater flexibilit
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Malting 199 machines, and an ideal
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storage to malt storage. Any additi
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9.10 Further reading BRIGGS D E (19
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The discovery that dough left for l
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Breadmaking 207 The development of
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the processes are similar to those
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ead to be ‘fresh’. When we coll
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such as unwanted holes or dense pat
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main function of yeast is to produc
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• Enzyme active materials have be
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Breadmaking 219 application of a mi
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Breadmaking 221 mixing, namely that
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Breadmaking 223 devices which roll
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Breadmaking 225 that a point which
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Breadmaking 227 10.9.2 Mixing and p
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Breadmaking 229 UK, pp. 1-17. CAUVA
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Index acid flavours 211 acidified l
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disease control 23-4 grain quality
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asic process 175-81 future of the i
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special and numerical grades 90 US
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