November
1999
Volume
76
Number
6
Pages
837
—
842
Authors
John T.
Chien
,
1
,
2
Ya-Yi
Lien
,
1
and
C. F.
Shoemaker
3
Affiliations
Dept. of Nutrition and Food Sciences, Fu-Jen University, Taipei, Taiwan, R.O.C.
Corresponding author. E-mail: nutr1000@mails.fju.edu.tw Phone: 886-229-031-111 ext. 3627.
Department of Food Science and Technology, University of California, Davis, CA 95616.
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RelatedArticle
Accepted June 15, 1999.
Abstract
ABSTRACT
The ability of rice starch to complex with ligands of various polarities was studied to examine the mechanism of complex formation in an aqueous solution. Differential scanning calorimetry (DSC) showed that TNuS19 rice starch (27.9% amylose) formed inclusion complexes with all 12-C complexing agents. The onset melting temperatures (To) of the complexes were ≈93–96°C. The saturation concentrations of added ligands with high polarity, lauric acid (LA), and lauryl alcohol (LOH), had a range of 2–4% (w/w) of the starch, and both of the corresponding melting enthalpies (ΔH) were ≈3.0 J/g. In contrast, the saturation concentrations of ligands with low polarity, methyl laurate (ML) and dodecane (DO), were ≈1–2% (w/w), and the ΔH were 1.87 and 1.80 J/g, respectively. This implied that solubility of ligands had a significant effect on the extent of complexation. The To and ΔH increased with an increase of annealing time at 85°C, and the optima for the partially reversible complex formation were 2 hr of annealing in all cases. When measured by a dynamic rheometer, the TNuS19 rice starch gel with added LA or LOH showed a higher storage modulus (G′) than that with no complexing agent added during heating. The G′ and tan δ of the complexed gel were further increased during 12 hr of storage. The increase of G′ indicated that the elastic structure of the concentrated rice starch gels could be improved by complex formation and annealing, whereas the increase of tan δ suggested incompatibility of starch components during storage.
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© 1999 American Association of Cereal Chemists, Inc.