The potential of individual glycolipid classes from lecithins (soybean, rapeseed, and sunflower) in breadmaking was determined in comparison to classical surfactants such as diacetyltartaric acid esters of mono- and diacylglycerides (DATEM), monoacylglycerides, sodium stearoyl-2-lactylate (SSL), and two synthetic glycolipids by means of rheological and baking tests on a microscale. A highly glycolipid-enriched sample containing the entire glycolipid moiety of the lecithin was obtained using an optimized batch procedure with silica gel. This sample was subsequently used to gain individual glycolipid classes through column chromatography on silica gel. The major glycolipid classes in the lecithins, digalactosyl diacylglycerides (1), sterol glucosides (2), acylated sterol glucosides (3), and cerebrosides (4), were identified and characterized. All isolated glycolipid classes displayed excellent baking performance. A better baking activity than that of the classical surfactants was displayed by 1, 3, and 4 and an equivalent baking activity by 2. The same glycolipid classes, except 3, of different lecithin origin showed only slight differences in their baking activities, due to different fatty acid compositions. Furthermore, the glycolipid classes influenced the crumb structure significantly by improving the crumb softness and grain. Interestingly, none of the glycolipid classes showed significant antistaling effect. A direct effect on the overall rheological behavior of the dough was only found for the commercial surfactants. However, the rheological effect seen on gluten isolated from surfactant-containing dough revealed that the surfactants could be divided into two main groups, one of them directly forming and stabilizing liquid film lamellae through adsorption to interfaces and the other indirectly increasing the surface activity of the endogenous lipids in the flour. The results suggest that in wheat dough, glycolipids seem to have an impact on the dough liquor rather than on the gluten-starch matrix.
To gain insight into structure-activity relationships of glycolipids in breadmaking monogalactosyl dilinoleylglycerol ( 8) and monogalactosyl monolinoleylglycerol ( 6) were synthesized. Then their functional properties in dough and breadmaking were compared to those of commercial surfactants such as lecithins (from soybean, rapeseed, and sunflower), diacetyltartaric acid esters of monoglycerides (DATEM), monoglycerides, and sodium stearoyl-2-lactylate. Chemical synthesis of the galactolipids consisted of a four-step reaction pathway, yielding amounts of 1-1.5 g suitable for the determination of the functional properties. Variation of the acylation time in the third step provided either the monoacyl ( 6) or the diacyl compound ( 8). The functional properties were determined by means of rheological and baking tests on a microscale (10 g of flour). The synthetic galactolipids both displayed an excellent baking performance, with 6 having by far the best baking activity of all examined surfactants. The baking activities of 8, DATEM, and the monoglycerides were in the same range, whereas sodium stearoyl-2-lactylate was less active. Although the lecithins gained similar maxima in bread volume increases as the synthetic surfactants did, considerably higher concentrations were required to do so. An antistaling effect was found for only 6 and not for 8. However, this effect was weaker than for sodium stearoyl-2-lactylate and the monoglycerides.
In wheat flour used for breadmaking, glycolipids are essential "endogenous surfactants" (1). Bread volume and crumb structure of wheat flour-based bakery products are influenced by glycolipids, without the decisive mode of action being conclusively known. Little information on how glycolipids from other plant sources perform as wheat flour improvers is available. In this paper we review our work done on revealing the baking performance of the four major glycolipid classes present in commercial lecithins (sterol glucosides (SG), acylated sterol glucosides (ASG), cerebrosides and digalactosyl diacylglycerides (DGDG). Our purpose is to better understand the role of these substances in the baking process. Our results suggest that there are two groups of glycolipids with excellent baking performance. Both groups were found to have an impact on the dough liquor rather than on the gluten-starch matrix. The cerebrosides and DGDG most likely influenced the overall baking result by directly stabilizing the dough liquor/gas cell interface, while ASG and SG did this indirectly through a synergistic effect with a dough liquor constituent, most probably the endogenous flour lipids.
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