Difference between revisions of "Team:Bordeaux/Description"
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<p align="justify" style="text-indent: 3vw;"> Curdlan, the linear (1→3)-β-glucan from Agrobacterium, has unique rheo-logical and thermal gelling properties. It is neutral and insoluble in water and if it is heated in an aqueous suspension, it adopts simple helical conformations (55-80°C) or a triple helical connected conformation (80-130°C). [1] It then acts as a gelling agent and form two types of gels (low-set gel or high-set gel which have been documented by Zhang et al [3]). Apart from being tasteless, colourless and odourless, its advantages are that, in contrast to cold-set gels (e.g. gelatin, gellan, carrageenan) and heat-set gels (e.g. konjac glucomannan, methylcellulose), the heating process alone produces different forms of curdlan gels with different textural qualities, physical stabilities and water-holding capacities. Curdlan gels are widely used in the food industry as a food additive ( E424 ) and to develop new food products (e.g. freezable tofu noodles) and calorie-reduced food, since there are no digestive enzymes for curdlan in the upper alimentary tract, and curdlan can be used as a fat substitute [4]. The safety of curdlan has been assessed in animal studies and in vitro tests [4,5] and it is approved for food use in Korea, Taiwan and Japan as an inert dietary fibre. It is registered in the United States as a food additive [7] </p> | <p align="justify" style="text-indent: 3vw;"> Curdlan, the linear (1→3)-β-glucan from Agrobacterium, has unique rheo-logical and thermal gelling properties. It is neutral and insoluble in water and if it is heated in an aqueous suspension, it adopts simple helical conformations (55-80°C) or a triple helical connected conformation (80-130°C). [1] It then acts as a gelling agent and form two types of gels (low-set gel or high-set gel which have been documented by Zhang et al [3]). Apart from being tasteless, colourless and odourless, its advantages are that, in contrast to cold-set gels (e.g. gelatin, gellan, carrageenan) and heat-set gels (e.g. konjac glucomannan, methylcellulose), the heating process alone produces different forms of curdlan gels with different textural qualities, physical stabilities and water-holding capacities. Curdlan gels are widely used in the food industry as a food additive ( E424 ) and to develop new food products (e.g. freezable tofu noodles) and calorie-reduced food, since there are no digestive enzymes for curdlan in the upper alimentary tract, and curdlan can be used as a fat substitute [4]. The safety of curdlan has been assessed in animal studies and in vitro tests [4,5] and it is approved for food use in Korea, Taiwan and Japan as an inert dietary fibre. It is registered in the United States as a food additive [7] </p> | ||
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Revision as of 08:16, 15 August 2015