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http://dx.doi.org/10.3746/jkfn.2016.45.8.1221

Effect of Cooking Methods on S-Allyl-L-Cysteine Content of Garlic  

Lee, Sang Hoon (Department of Agrofood Resources, National Academy of Agricultural Sciences, Rural Development Administration)
Jeong, Yun Sook (Department of Agrofood Resources, National Academy of Agricultural Sciences, Rural Development Administration)
Hwang, Kyung-A (Department of Agrofood Resources, National Academy of Agricultural Sciences, Rural Development Administration)
Song, Jin (Department of Agrofood Resources, National Academy of Agricultural Sciences, Rural Development Administration)
Noh, Geon Min (Department of Agrofood Resources, National Academy of Agricultural Sciences, Rural Development Administration)
Hwang, In Guk (Department of Agrofood Resources, National Academy of Agricultural Sciences, Rural Development Administration)
Publication Information
Journal of the Korean Society of Food Science and Nutrition / v.45, no.8, 2016 , pp. 1221-1226 More about this Journal
Abstract
This study investigated changes in the S-allyl-L-cysteine (SAC) content of garlic using different cooking methods. Methods for determining SAC were validated by determining specificity, linearity, limit of detection (LOD), limit of quantification (LOQ), precision, and accuracy using an high-performance liquid chromatography-fluorescence detection system. Results showed high linearity in the calibration curve with a coefficient of correlation ($R^2$) of 0.9999. The LOD and LOQ values for SAC were 0.15 and $0.47{\mu}g/mL$, respectively. The relative standard deviations for intra- and inter-day precision of SAC were less than 5%. The recovery rate of SAC was in the range from 97.35% to 97.47%. The SAC content of raw garlic was 2.77 mg/g, and there was no significant difference in SAC content according to blanching and microwave treatment. However, SAC content upon boiling and autoclaving at $110^{\circ}C$ and $121^{\circ}C$ increased from 3.50~9.16 mg/g, 6.52~16.21 mg/g, and 14.15~50.24 mg/g with increasing cooking temperature and time, respectively.
Keywords
garlic; S-allyl-L-cysteine; cooking methods; method validation;
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Times Cited By KSCI : 8  (Citation Analysis)
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1 Chae SK. 2007. Studies on the changes in the alliinase activity during the drying of garlic. Korean J Sanitation 22: 57-66.
2 Oh TY, Kyung KH. 2011. Isolation and purification of garlic specific organic compounds. Korean J Food Sci Technol 43: 553-557.   DOI
3 Whitaker JR. 1976. Development of flavor, odor, and pungency in onion and garlic. Adv Food Res 22: 73-133.   DOI
4 Colin-Gonzalez AL, Santana RA, Silva-Islas CA, Chanez-Cardenas ME, Santamaria A, Maldonado PD. 2012. The antioxidant mechanisms underlying the aged garlic extract- and S-allylcysteine-induced protection. Oxid Med Cell Longevity 2012: 1-16.
5 Saravanan G, Ponmurugan P. 2010. Beneficial effect of Sallylcysteine (SAC) on blood glucose and pancreatic antioxidant system in streptozotocin diabetic rats. Plant Foods Hum Nutr 65: 374-378.   DOI
6 Saravanan G, Ponmurugan P. 2012. Antidiabetic effect of S-allylcysteine: Effect on thyroid hormone and circulatory antioxidant system in experimental diabetic rats. J Diabetes Complications 26: 280-285.   DOI
7 Shouk R, Abdou A, Shetty K, Sarkar D, Eid AH. 2014. Mechanisms underlying the antihypertensive effects of garlic bioactives. Nutr Res 34: 106-115.   DOI
8 Ried K, Frank OR, Stocks NP. 2010. Aged garlic extract lowers blood pressure in patients with treated but uncontrolled hypertension: A randomised controlled trial. Maturitas 67: 144-150.   DOI
9 Saravanan G, Ponmurugan P. 2012. Ameliorative potential of S-allylcysteine: Effect on lipid profile and changes in tissue fatty acid composition in experimental diabetes. Exp Toxicol Pathol 64: 639-644.   DOI
10 Sohn CW, Kim H, You BR, Kim MJ, Kim HJ, Lee JY, Sok DE, Kim JH, Lee KJ, Kim MR. 2012. High temperature- and high pressure-processed garlic improves lipid profiles in rats fed high cholesterol diets. J Med Food 15: 435-440.   DOI
11 Ray B, Chauhan NB, Lahiri DK. 2011. The "aged garlic extract" (AGE) and one of its active ingredients S-allyl-L-cysteine (SAC) as potential preventive and therapeutic agents for Alzheimer's disease (AD). Curr Med Chem 18: 3306-3313.   DOI
12 Ashafaq M, Khan MM, Shadab Raza S, Ahmad A, Khuwaja G, Javed H, Khan A, Islam F, Siddiqui MS, Safhi MM, Islam F. 2012. S-Allyl cysteine mitigates oxidative damage and improves neurologic deficit in a rat model of focal cerebral ischemia. Nutr Res 32: 133-143.   DOI
13 Rojas P, Serrano-Garcia N, Medina-Campos ON, Pedraza-Chaverri J, Maldonado PD, Ruiz-Sanchez E. 2011. S-Allylcysteine, a garlic compound, protects against oxidative stress in 1-methyl-4-phenylpyridinium-induced parkinsonism in mice. J Nutr Biochem 22: 937-944.   DOI
14 Hong GH, Jang HS, Kim YB. 1999. Effect of processing treatments on change in quantity of the functional components in garlic, Allium sativum L. Korean J Hort Sci Technol 40: 23-25.
15 Bae HJ, Chun HJ. 2002. Changes in volatile sulfur compounds of garlic under various cooking conditions. Korean J Soc Food Cook Sci 18: 365-371.
16 Bae HJ, Chun HJ. 2003. Changes in volatile sulfur compounds of garlic under short-term storage conditions. Korean J Soc Food Cook Sci 19: 17-23.
17 Chung JY, Kim CS. 2009. Antioxidant activities of domestic garlic (Allium sativum L.) stems and garlic bulbs according to cooking methods. J Korean Soc Food Sci Nutr 38: 188-194.   DOI
18 KFDA. 2004. Analytical method guideline about validation of drugs and etc. Korea Food and Drug Administration, Seoul, Korea. p 1-18.
19 Jeong YS, Hwang KA, Kim GR, Song J, Noh GM, Hwang IG. 2015. Effects of the aging conditions on the quality characteristics of garlic. Korean J Food Nutr 28: 745-751.   DOI
20 Bae SE, Cho SY, Won YD, Lee SH, Park HJ. 2012. A comparative study of the different analytical methods for analysis of S-allyl cysteine in black garlic by HPLC. LWT-Food Sci Techonol 46: 532-535.   DOI
21 Lee S, Yoo M, Kim S, Shin D. 2014. Identification and quantification of S-allyl-L-cysteine in heated garlic juice by HPLC with ultraviolet and mass spectrometry detection. LWT-Food Sci Technol 57: 516-521.   DOI
22 Yoo M, Lee S, Lee S, Seog H, Shin D. 2010. Validation of high performance liquid chromatography methods for determination of bioactive sulfur compounds in garlic bulbs. Food Sci Technol 19: 1619-1626.
23 Chihara T, Shimpo K, Kaneko T, Tomatsu A, Beppu H, Higashiguchi T, Sonoda S. 2013. The effect of preparatory conditions of high temperature- and pressure-treated garlic on 5-hydroxymethyl-2-furfural and S-allylcysteine formation. J Anal Bio-Sci 36: 186-192.
24 Bae SE, Cho SY, Won YD, Lee SH, Park HJ. 2014. Changes in S-allyl cysteine contents and physicochemical properties of black garlic during heat treatment. LWT-Food Sci Technol 55: 397-402.   DOI
25 Hanum T, Sinha NK, Cash JN. 1995. Characteristics of $\gamma$-glutamyl transpeptidase and alliinase of onion and their effects on the enhancement of pyruvate formation in onion macerates. J Food Biochem 19: 51-65.   DOI
26 dos Anjos F, Machado A, Ferro C, Otto F, Bogin E. 1998. $\gamma$-Glutamyltransferase as a marker for the pasteurization of raw milk. J Food Prot 61: 1057-1059.   DOI