Browse > Article
http://dx.doi.org/10.9724/kfcs.2017.33.3.307

Granular Morphology and Thermal Properties of Acid-Hydrolyzed Rice Starches with Different Amylose Contents  

No, Junhee (Department of Food and Nutrition Chonnam National University)
Lee, Chae Eun (Department of Food and Nutrition Chonnam National University)
Shin, Malshick (Department of Food and Nutrition Chonnam National University)
Publication Information
Korean journal of food and cookery science / v.33, no.3, 2017 , pp. 307-315 More about this Journal
Abstract
Purpose: To develop nano-sized starch particles for application as dietary fiber sources in liquid food system, the morphology and thermal properties of acid hydrolyzed rice starches with different amylose contents were evaluated. Methods: Rice starches purified from three Korean cultivars, including Goami, Hopyeong, and Hwaseonchal, were hydrolyzed with 2.2 N HCl solution in a $35^{\circ}C$ shaking water bath (100 rpm) for 7, 10 and 15 days. Results: Acid hydrolysis rates of rice starches increased with increasing hydrolysis duration, and rates for Goami, Hopyeong, and Hwaseonchal were 28.74-38.50%, 38.96-49.53%, and 40.24-48.88%, respectively. The granular size of acid hydrolyzed starches decreased to 122.4-479.9 nm, whereas granular aggregation increased with increasing hydrolysis duration. In particular, waxy rice starch of Hwaseonchal was composed of many tiny granules without aggregates. Gelatinization temperature and temperature range increased with increasing hydrolysis duration. All starches showed A type crystallinity using an x-ray diffractometer, regardless of acid hydrolysis. Conclusion: It is suggested that nanoparticles could be prepared by acid hydrolysis of rice starches, and waxy rice starch is the most preferred source for application.
Keywords
rice starch; acid hydrolysis; nano particle; amylose content; crystallinity;
Citations & Related Records
Times Cited By KSCI : 5  (Citation Analysis)
연도 인용수 순위
1 Atichokudomchai N, Shobsngob S, Varavinit S. 2000. Morphological properties of acid-modified tapioca starch. Starch-Starke 52(8-9):283-289.   DOI
2 Buleon A, Colonna P, Planchot V, Ball S. 1998. Starch granules: Structure and biosynthesis. Int J Biol Macromol 23(2):85-112.   DOI
3 Choi ID. 2010. Physicochemical properties of rice cultivars with different amylose contents. J Korean Soc Food Sci Nutr 39(9):1313-1319.   DOI
4 Han JA. 2009. Digestive, physical and sensory properties of cookies made of dry-heated OSA-high amylose rice starch. Korean J Food Sci Technol 41(6):668-672.
5 Huh CK, Lee JW, Kim YD. 2012. Fermentation and quality characteristics of Yakju according to different rice varieties. Korean J Food Preserv 19(6):925-932.   DOI
6 Jiping P, Shujun W, Jinglin Y, Hongyan L, Jiugao Y, Wenyuan G. 2007. Comparative studies on morphological and crystalline properties of B-type and C-type starches by acid hydrolysis. Food Chem 105(3):989-995.   DOI
7 Kang KJ, Kim K, Lee SK, Kim SK. 1997. Relationship between molecular structure of acid-hydrolyzed rice starch and retrogradation. Korean J Food Sci Technol 29(5):876-881.
8 Lee MK, Kim JO, Shin MS. 2004. Properties of nonwaxy rice flours with different soaking time and particle sizes. Korean J Food Sci Technol 36(2):268-275.
9 Kim HY, Lee JH, Kim JY, Lim WJ, Lim ST. 2012. Characterization of nanoparticles prepared by acid hydrolysis of various starches. Starch-Starke 64(5):367-373.   DOI
10 Koksel H, Masatcioglu T, Kahraman K, Ozturk S, Basman A. 2008. Improving effect of lyophilization on functional properties of resistant starch preparations formed by acid hydrolysis and heat treatment. J Cereal Sci 47(2):275-282.   DOI
11 Lee SK, Mun SH, Shin MS. 1997. Enzyme-resistant starch formation from mild acid-treated maize starches. Korean J Food Sci Technol 29(6):1309-1315.
12 Lee SK, Shin MS. 1997. Morphological properties of lintnerized maize starches with different amylose content. J Korean Soc Food Sci Nutr 26(6):1086-1090.
13 Medcalf DG, Gilles KA. 1965. Wheat starches. I. Comparison of physicochemical properties. Cereal Chem 42(6):558-568.
14 Nakazawa Y, Wang YJ. 2003. Acid hydrolysis of native and annealed starches and branch-structure of their Naegeli dextrins. Carbohyd Res 338(24):2871-2882.   DOI
15 Oh SM, No JH, Shin M. 2014. Gelatinization properties and molecular structure of waxy rice starches isolated from Korean japonica and indica cultivars. J Food Cook Sci 30(6):716-725.   DOI
16 Robin JP. 1974. Lint-nerized starches. Gel filtration and enzymatic studies of insoluble residues from prolonged acid treatment of potato starch. Cereal Chem 51:389-406.
17 Kaur M, Oberoi DPS, Sogi DS, Gill BS. 2011. Physicochemical, morphological and pasting properties of acid treated starches from different botanical sources. J Food Sci Technol 48(4):460-465.   DOI
18 Oh SM, Shin M. 2015. Physicochemical properties and molecular structures of Korean waxy rice starches. Food Sci Biotechnol 24(3):791-798.   DOI
19 Park YK, Kim SK, Kim K. 1991. Properties of lintnerized rice starches. Korean J Food Sci Technol 23(1):62-67.
20 Putaux JL, Molina-Boisseau S, Momaur T, Dufresne A. 2003. Platelet nanocrystals resulting from the disruption of waxy maize starch granules by acid hydrolysis. Biomacromol 4(5):1198-1202.   DOI
21 Sandhu KS, Singh N, Lim ST. 2007. A comparison of native and acid thinned normal and waxy corn starches: Physicochemical, thermal, morphological and pasting properties. LWT-Food Sci Technol 40(9):1527-1536.   DOI
22 Shujun W, Jinglin Y, Jiugao Y, Haixia C, Jiping P. 2007. The effect of acid hydrolysis on morphological and crystalline properties of Rhizoma dioscorea starch. Food Hydrocoll 21(7):1217-1222.   DOI
23 Singh J, Kaur L, McCarthy OJ. 2007. Factors influencing the physico-chemical, morphological, thermal and rheological properties of some chemically modified starches for food applications-A review. Food Hydrocoll 21(1):1-22.   DOI
24 Wang L, Wang YJ. 2001. Structures and physicochemical properties of acid-thinned corn, potato and rice starches. Starch-Starke 53(11):570-576.   DOI
25 Wang S, Copeland L. 2015. Effect of acid hydrolysis on starch structure and functionality: A review. Crit Rev Food Sci Nutr 55(8):1081-1097.   DOI