Structure, properties, and potential applications of waxy tapioca starches – A review

• Published in: Trends in food science & technology Vol. 83; pp. 225 - 234
• Main Authors: Hsieh, Chao-Feng, Liu, Weichang, Whaley, Judith K., Shi, Yong-Cheng
• Format: Journal Article
• Language: English
• Published: Cambridge Elsevier Ltd 01.01.2019; Elsevier BV
• Subjects: Amylopectin; Cassava; Chain branching; Chain-length distribution; Clean-label; Cold storage; Corn; Crop yield; Food industry; Freeze-thaw durability; Freeze-thaw stability; Freeze-thawing; Frozen food; Frozen foods; Genetic modification; Organic chemistry; Pastes; Potatoes; Retrogradation; Reviews; Shelf life; Starch; Starches; Tapioca; Temperature; Waxy starch; Wheat; Chain-length distribution; Freeze-thaw stability; Waxy starch; Tapioca; Retrogradation; Cassava; Clean-label
• ISSN: 0924-2244; 1879-3053
• DOI: 10.1016/j.tifs.2018.11.022

Waxy tapioca starches, successfully developed less than two decades ago, have unique functionalities. In Africa, cassava is principally used as a staple food, whereas in Asia, cassava is mostly processed into starch. Tapioca starches, which are isolated from cassava, are heavily traded comparable to maize, potato and wheat starches. This review aims to highlight the properties of waxy tapioca starches compared to normal taopica starch and to waxy starches from other botanical sources and draw attention to food industries that can benefit from the unique functionalities of waxy tapioca starches. Pastes of native waxy tapioca starches perform well in refrigerated and frozen foods as opposed to waxy starches and non-waxy starches from maize, wheat, and potato. Unmodified waxy tapioca starch yields thick, clear pastes with good shelf life. The cold-temperature stability of waxy tapioca is correlated to its amylopectin structure with a relatively high proportion of short branch chains of DP 6–12. The high stability of waxy tapioca starch under freeze-thaw conditions and refrigerated storage indicates that the starch is resistant to retrogradation. With a rising demand for clean-label foods by consumers and markets, the cold-temperature stability of waxy tapioca starch offers an attractive alternative to the use of chemically or genetically modified starch in frozen/refrigerated foods. In this review, we undertake to gain insight on waxy tapioca starches and other starches in order to identify approaches to further develop solutions to make products with desired functionality. •Development of waxy tapioca starch (WTS) was reviewed.•Properties of WTS were compared to the normal genotype and other waxy starches.•WTS had a low proportion of chains with DP 13–24 that associated with retrogradation.•WTS paste was stable to freeze-thaw and cold storage conditions.•WTS could serve as a clean-label thickener in frozen foods.