References
- Agence Française de Normalisation (AFNOR). 1970. Dosage de l'azote avec minéralisation selon la méthode de Kjeldahl. Standard NF.V03-050.
- Agu RC, Palmer GH. Effect of mashing procedures on some sorghum varieties germinated at different temperatures. Process Biochem 1997; 32(2)147–158
- Ahmed SB, Mahgoub SA, Babiker BE. Changes in tannin and cyanides contents and diastic activity during germination and the effect of traditional processing on cyanide content of sorghum cultivars. Food Chem 1996; 56(2)159–162
- Aniche GN. Studies on the effects of germination and drying conditions on the cyanide content of sorghum sprouts. J Food Technol 1990; 27(4)202–204
- Brown KH, Sanchez-Grinan M, Perez F, Peerson JM, Ganoza L, Stern JS. Effects of dietary energy density and feeding frequency on total daily energy intakes of recovering malnourished children. Am J Clin Nutr 1995; 62(1)13–18
- Dada, LO, Dendy, DAV. 1988. La teneur en cyanures des céréales germées et l'effet des techniques de conditionnement. In: D Alnwick, Moses, S, Schmidt, OG, editors. Pour améliorer l'alimentation des jeunes enfants en Afrique Orientale et Australe: une technologie à la portée des ménages, compte rendu d'un atelier tenu à Nairobi, Kenya, 12–16 octobre 1987, IDRC-265 f. pp. 407–414. Ottawa: CRDI.
- Darling JC, Kitundu JA, Kingamkono RR, Msengi AE, Mduma B, Sullivan KR. Improved energy intakes using amylase-digested weaning foods in Tanzanian children with acute diarrhea. J Pediatr Gastroenterol Nutr 1995; 21(1)73–81
- Den Besten L, Glatthaar II, Ijsselmuiden CB. Adding alpha-amylase to weaning food to increase dietary intake in children. A randomized controlled trial. J Trop Pediatr 1998; 44(1)4–9
- Dewar J, Taylor JRN, Berjak P. Determination of improved steeping conditions for sorghum malting. J Cereal Sci 1997; 26: 129–136
- Duhan A, Khetarpaul N, Bishnoi S. Content of phytic acid and HCl-extractability of calcium, phosphorus and iron as affected by various domestic processing and cooking methods. Food Chem 2002; 78(1)9–14
- Elmaki HB, Babiker EE, El Tinay AH. Changes in chemical composition, grain malting, starch and tannin contents and protein digestibility during germination of sorghum cultivars. Food Chem 1999; 64: 331–336
- Ikediobi CO, Olugboji O. Cyanide profile of component parts of sorghum (Sorghum bicolor L. Moench) sprouts. Food Chem 1988; 27: 167–175
- Lestienne I, Icard-Vernière C, Mouquet C, Picq C, Trèche S. Effect of soaking whole cereal and legume seeds on iron, zinc and phytate contents. Food Chem 2005; 89: 421–425
- Mahgoub SEO, Elhag SA. Effect of milling, soaking, malting, heat-treatment and fermentation on phytate level of four Sudanese sorghum cultivars. Food Chem 1998; 61: 77–80
- Malleshi NG, Daodu MA, Chandrasekhar A. Development of weaning food formulations based on malting and roller drying of sorghum and cowpea. Int J Food Sci Technol 1989; 24: 511–519
- Moursi M, Mbemba M, Trèche S. Does the consumption of amylase-containing gruels impact on energy intake and growth of Congolese infants?. Public Health Nutr 2003; 6(3)249–257
- Nirmala M, Subba Rao MVSST, Muralikrishna G. Carbohydrates and their degrading enzymes from native and malted finger millet (Ragi, Eleusine coracana, Indaf-15). Food Chem 2000; 69: 175–180
- Okoh PN, Ikediobi CO, Olugboji O. The fate in the rat of ingested dhurrin present in sprouted sorghum grain. Food Chem 1988; 29: 299–307
- Onyeka U, Dibia I. Malted weaning food made from maize, soybean, groundnut and banana. J Sci Food Agric 2002; 82: 513–516
- Opuku AR, Ohenhen SO, Ejiofor N. Nutrient composition of millet (Pennisetum thyphoides) grains and malts. J Agric Food Chem 1981; 29: 1247–1248
- Panasiuk O, Bills DD. Cyanide content of sorghum sprouts. J Food Sci 1984; 49: 791–793
- Prosky L, Asp NG, Schweizer TF, Devries JW, Furda I. Determination of insoluble, soluble, and total dietary fiber in foods and food products: interlaboratory study. J AOAC Int 1988; 71(5)1017–1023
- Saharan K, Khetarpaul N, Bishnoi S. HCl-extractability of minerals from ricebean and Fababean: influence of domestic processing methods. Innov Food Sci Emerg Technol 2001; 2(4)323–325
- Sandberg AS, Svanberg U. Phytate hydrolysis by phytase in cereal; effects on in vitro estimation of iron availability. J Food Sci 1991; 56(5)1330–1333
- Svanberg U, Lorri W, Sandberg AS. Lactic fermentation of non-tannin and high tannin cereals: effects on in vitro estimation of iron availability and phytate hydrolysis. J Food Sci 1993; 58: 408–412
- Talamond P, Gallon G, Trèche S. Rapid and sensitive liquid chromatographic method using a conductivity detector for the determination of phytic acid in food. J Chromatogr A 1998; 805: 143–147
- Taylor JRN, Dewar J. Development in sorghum food technologies. Adv Food Nutr Res 2001; 43: 217–264
- Traoré T, Mouquet C, Icard-Vernière C, Traoré AS, Trèche S. Changes in nutrient composition, phytate and cyanide contents and α-amylase activity during cereal malting in small production units in Ouagadougou (Burkina Faso). Food Chem 2004; 88(1)105–114
- Trèche S. Techniques for increasing the energy density of gruel. Complementary feeding of young children in Africa and the Middle-East, MC Dop, D Benbouzid, S Trèche, B de Benoist, A Verster, F Delpeuch. World Health Organization, Geneva 1999; 101–119
- Vieu MC, Traoré T, Trèche S. Effects of energy density and sweetness of gruels on Burkinabe infant energy intakes in free living conditions. Int J Food Sci Nutr 2001; 52: 213–218
- Wahed MA, Mahalanabis D, Begum M, Rahman M, Islam MS. Energy-dense weaning foods liquefied by germinated-wheat amylase: effect on viscosity, osmolality, macronutrients, and bacterial growth. Food Nutr Bull 1994; 15(3)257–261