[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.12925/jkocs.2015.32.1.7

Chemical Composition of Thermal Treatment Yam (Dioscorea batatas DECNE.)

Kim, Han-Soo (Department of Food Science and Technology, Pusan National University)
Duan, Yishan (Department of Food Science and Technology, Pusan National University)
Ryu, Jae-Young (Department of Urban Enviromental Engineering, Kyungnam University)
Kim, Sang-Woo (East Sea Fisheries Research Institute, NFRDI)
Jang, Seong-Ho (Department of Bioenviromental Energy, Pusan National University)

Publication Information

Journal of the Korean Applied Science and Technology / v.32, no.1, 2015 , pp. 7-15 More about this Journal

Abstract

In this study, the thermal treatment yam (Dioscorea batatas DECNE.) was analyzed for its proximate and nutritional compositions including mineral, vitamin, amino acids and fatty acids. Thermal treatment yam is mainly consisted of carbohydrate (70.3%) with small amounts of crude protein (15.8%), crude ash (5.1%) and crude fat (1.6%). It was found to be a good source of essential minerals such as K (1100.2 mg/100 g), Mg (99.4 mg/100 g), Ca (54.8 mg/100 g) and Na (44.9 mg/100 g) but Zn (4.8 mg/100 g) and Fe (0.2 mg/100g) content was low. Little amounts of vitamin E (8.3 mg/100g), vitamin C (3.5 mg/100g) and vitamin B1 (2.1 mg/100g) could be found. The amino acid analysis revealed that the yam was superior with respect to serine (1454.2 mg%), lysine (684.6 mg%) and histidine (684.6 mg%). Essential amino acids were calculated to be 2849.3 mg%. The amino acid profiles showed that thermal treatment yam is limiting in isoleucine and phenylaline. Linoleic acid was the most predominant fatty acids with the value of 47.3% followed by palmitic acid (24.7%) and oleic acid (12.7%). And the unsaturated fatty acids including oleic acid and linoleic acid were present in big quantities in thermal treatment yam.

Keywords

yam (Dioscorea batatas DECNE.); thermal treatment; color values; total phenol; antioxidant activities;

Citations & Related Records

Times Cited By KSCI : 2 (Citation Analysis)

Reference
Cited By KSCI

1	M. Alaiz, R. Zamora, and F. J. Hidalgo, Addition of oxidized lipid/amino acid reaction products delays the peroxidation initiated in a soybean oil, J. Agric. Food Chem., 43, 2698 (1995). DOI
2	M. Alaiz, R. Zamora, and F. J. Hidalgo, Antioxidative activity of pyrrole, imidazole, dihydropyridine, and pyridinium salt derivatives produced in oxidized lipid/amino acid browning reactions, J. Agric. Food Chem., 44, 686 (1996). DOI
3	M. Alaiz, F. J. Hidalgo, and R. Zamora, Antioxidative activity of nonenzymatically browned proteins produced in oxidized lipid/protein reactions, J. Agric. Food Chem., 45, 1365 (1997). DOI
4	AOAC. 1998. Official methods of analysis. 16th eds., Association of Official Analytical Chemists. Washington, D. C.
5	S. O. Agunbiade and O. G. Longe, African yam bean hull chemical composition and its effects on rat's mineral retention, serum biochemical components and enzymatic activities, Nahrung, 42, 89 (1998). DOI
6	E. O. Afoakwa and S. Sefa-Dedeh, Chemical composition and quality changes occurring in Dioscorea dumetorum pax tubers after harvest, Food Chem., 75, 85 (2001). DOI
7	Y. Alozie, M. I. Akpanabiatu, E. U. Eyong, I. B. Umoh and G. Alozie, Amino acid composition of Dioscorea dumetorum varieties, Pak. J. Nut., 8, 103 (2009). DOI
8	M. O. Aremu, I. Ogunlade and A. Olonisakin, Fatty acid and amino acid composition of protein concentrate from cashew nut (Anarcadium occidentale) grown in Nasarawa State, Nigeria, Pak. J. Nut., 6, 419 (2007). DOI
9	M. R. Bhandari and J. Kawabata, Organic acid, phenolic content and antioxidant activity of wild yam (Dioscorea spp.) tubers of Nepal, Food Chem., 88, 163 (2004). DOI
10	S. E. Bae, S. Y. Cho, Y. D. Won, S. H. Lee and H. J. Park, Changes in S-allyl cysteine contents and physicochemical properties of black garlic during heat treatment, LWT-Food Sci. Technol., 55, 397 (2014). DOI
11	E. Capuano and V. Fogliano, Acrylamide and 5-hydroxymethylfurfural (HMF): A review on metabolism, toxicity, occurrence in food and mitigation strategies, LWT-Food Sci. Technol., 44, 793 (2011). DOI
12	J. P. Eiserich and T. Shibamoto, Antioxidative activity of volatile heterocyclic compounds, J. Agric. Food Chem., 42, 1060 (1994). DOI
13	F. Fougere, D. L. Rudulier and G. J. Streeter, Effects of salt stress on amino acid, organic acid, and carbohydrate composition of roots, bacteroids, and cytosol of alfalfa (Medicago sativa L.), Plant Physiol., 96, 1228 (1991). DOI
14	E. O. Farombi, G. Britton and G. O. Emerole, Evaluation of the antioxidant activity and partial characterisation of extracts from browned yam flour diet, Food Res. Int., 33, 493 (2000). DOI
15	C. S. Hariprakash and B. Nambisan, Carbohydrate metabolism during dormancy and sprouting in yam (Dioscorea) tubers: changes in carbohydrate constituents in yam (Dioscorea) tubers during dormancy and sprouting, J. Agric. Food Chem., 44, 3066 (1996). DOI
16	S. Y. Kim, H. J. Jwa, Y. Yanagawa and T. S. Park, Extract from Dioscorea batatas ameliorates insulin resistance in mice fed a high-fat diet, J. Med. Food, 15, 527 (2012). DOI
17	C. L. Hsu, W. Chen, Y. M. Weng and C. Y. Tseng, Chemical composition, physical properties, and antioxidant activities of yam flours as affected by different drying methods, Food Chem., 83, 85 (2003). DOI
18	C. C. Huang, P. Y. Chiang, Y. Y. Chen and C. C. R. Wang, Chemical compositions and enzyme activity changes occurring in yam (Dioscorea alata L.) tubers during growth, LWT-Food Sci. Technol., 40, 1498 (2007).
19	C. Hernandez-Sebastia, F. Marsolais, C. Saravitz, D. Israel, R. E. Dewey and S. C. Huber, Free amino acid profiles suggest a possible role for asparagine in the control of storage-product accumulation in developing seeds of low- and high-protein soybean lines, J. Exp. Bot., 56, 1951 (2005). DOI
20	KFDA. 2010. Korea Food and Drug Association. Health Functional Food Standards Codex. Korean Foods Industry Association. Seoul. Korea. P 3.5.4-1.
21	KFDA. 2005. Korea Food and Drug Association. Food Standards Codex. Korean Foods Industry Association, Seoul, Korea, P 365-391.
22	J. Kubola, S. Siriamornpun and N. Meeso, Phytochemicals, vitamin C and sugar content of Thai wild fruits, Food Chem., 126, 972 (2011). DOI
23	H. S. Kim, Studies on the amino acid and fatty acid compositions in the seed and pulpy substance of feral peach (Prunus persica Batsch var. davidiana Max.), J. Life Sci., 17, 125 (2007). DOI
24	J. T. Lin and D. J. Yang, Determination of steroidal saponins in different organs of yam (Dioscorea pseudojaponica Yamamoto), Food Chem., 108, 1068 (2008). DOI
25	D. E. Oku and C.U. Ndu, Evaluation of the phytonutrients, mineral and vitamin contents of some varieties of yam (Dioscorea sp.), Int. J. Mol. Med. Adv. Sci., 2, 199 (2006).
26	F. A. Loewus, Improvement in anthrone method for determination of carbohydrates, Anal Chem., 24, 219 (1952).
27	P. R. Maria, A. Nicula, A. T. Nicula and C. Socaciu, The optimization of extraction and HPLC analysis of vitamins b from yeast products, Bull Univ. Agric. Sci. Veter. Med. Agric., 65, 323 (2008).
28	I. Novozamsky, V. J. G. Houba, E. C. K. Van and V. W. Van, Plant nitrogen and phosphorus in plant tissue, novel digestion technique for multi-element, Plant Anal. Comm. Soil Sci. plant anal., 14, 239 (1983). DOI
29	A. A. Oshodi, K. O. Ipinmoroti, E. I. Adeyeye and G. M. Hall, Amino and fatty acids composition of African yam bean (Sphenostylis stenocarpa) flour, Food Chem., 53, 1 (1995). DOI
30	J. P. D. Wanasundera and G. Ravindran, Nutritional assessment of yam (Dioscorea alata) tubers, Plant Foods Human Nut., 46, 33 (1994). DOI