Cellulosic Nano-Fibers Help Make Ice Cream Melt Less, Improves Texture

 
Adding tiny fibers extracted from banana plant to ice cream could lead to its slow melting, increase the shelf life, and potentially replace fats used to make the tasty treat, scientists said in a Sept. 5, 2018 report by News Nation (India). "Our findings suggest that cellulose nano-fibres extracted from banana waste could help improve ice cream in several ways," said Robin Zuluaga Gallego from the Universidad Pontificia Bolivariana in Colombia. 

"In particular, the fibers could lead to the development of a thicker and more palatable dessert, which would take longer to melt. "As a result, this would allow for a more relaxing and enjoyable experience with the food, especially in warm weather," said Gallego. Despite its popularity, ice cream does have some drawbacks that food scientists have struggled to overcome. Most obviously, it can melt when exposed to heat.

The researchers wanted to determine if they could slow down melting and extend the shelf life of ice cream using a fibrous extract from banana fruit stems, or rachis. Working in collaboration with researchers at the University of Guelph in Canada, the team extracted cellulose nanofibrils (CNFs), which are thousands of times smaller than the width of a human hair, from ground-up banana rachis.         

They mixed the CNFs into ice cream at varying concentrations, ranging from zero up to three-tenths of a gram per 100 grams of the dessert. Using a variety of analytical tools - including a rheometer, which measures how much force is needed to move a fluid, as well as a texturometer, which measures the hardness of ice cream - the researchers evaluated the effects that CNFs had on the popular frozen treat. They found that ice creams mixed with CNFs tended to melt much more slowly than traditional ice creams.         

They also determined that CNFs could increase shelf life of ice cream, or at least decrease its sensitivity to temperature changes that occur when moved to and from the freezer. In addition, CNFs increased the viscosity of low-fat ice cream, which improved the creaminess and texture of the product.
         
The study suggests that CNFs could help stabilize the fat structure in ice creams. As a result, CNFs could potentially replace some of the fats -and perhaps reduce calories - in these desserts. The research was presented at the National Meeting & Exposition of the American Chemical Society.

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