Browse > Article
http://dx.doi.org/10.5010/JPB.2019.46.1.056

Ginsenoside composition of Panax ginseng flower extracts obtained using different high hydrostatic pressure extraction conditions  

Kim, Hyun Soo (Amorepacific R&D Center)
Kim, Gyu Ri (Department of Beauty and Cosmetic Science, Eulji University)
Kim, Donghyun (Amorepacific R&D Center)
Zhang, Cheng-Yi (Amorepacific R&D Center)
Lee, Eun-Soo (Amorepacific R&D Center)
Park, Nok Hyun (Amorepacific R&D Center)
Park, Junseong (Department of Engineering Chemistry, Chungbuk National University)
Lee, Chang Seok (Department of Beauty and Cosmetic Science, Eulji University)
Shin, Moon Sam (Department of Beauty and Cosmetic Science, Eulji University)
Publication Information
Journal of Plant Biotechnology / v.46, no.1, 2019 , pp. 56-60 More about this Journal
Abstract
Ginsenosides are active constituents of ginseng (Panax ginseng) that have possible anti-aging, physiological and pharmacological activities, such as anti-cancer and anti-inflammatory effects. Although the ginseng root is generally used more often than the aerial parts for medicinal purposes, the flowers also contain numerous ginsenosides, including Rb2, Rc, Rd, Re and Rg1. Therefore, an extract from the flowers of the P. ginseng could have the pharmacological efficacy of bioactive compounds including ginsenosides. The high hydrostatic pressure extraction (HHPE) is a method that is used for the efficient extraction of bioactive compounds from plant materials. In this study, we compared the yield of ginsenosides from ginseng flowers under different conditions of extraction pressure and time of HHPE. The results indicate that the total yield of the ginsenosides improved as the pressure increased from 0.1 to 80 MPa and treatment duration increased to 24 hours. In addition, the ginsenoside extracts from HHPE at 80 MPa, which possessed a higher total ginsenoside concentration, decreased the viability of the primary human epidermal keratinocytes (HEKs) significantly than the ginsenoside extracts from HHPE at 0.1 MPa. Collectively, we found that the method of HHPE that was performed for 24 hours at 80 MPa showed the highest yield of ginsenosides from the flowers of P. ginseng. In addition, our study provides a foundation for the efficient extraction of ginsenosides, which had a potent bioactivity, from flowers of P. ginseng through HHPE.
Keywords
Ginsenoside; Panax ginseng; High hydrostatic Pressure extraction (HHPE); Cell viability;
Citations & Related Records
Times Cited By KSCI : 1  (Citation Analysis)
연도 인용수 순위
1 Ali MB, Singh N, Shohael AM, Hahn EJ, Paek K-Y (2006). Phenolics metabolism and lignin synthesis in root suspension cultures of Panax ginseng in response to copper stress. Plant Sci 171:147-154   DOI
2 Chen R, Meng F, Zhang S, Liu Z (2009). Effects of ultrahigh pressure extraction conditions on yields and antioxidant activity of ginsenoside from ginseng. Sep Purif Technol 66:340-346   DOI
3 Chen Y, Liu ZH, Xia J, Li XP, Li KQ, Xiong W, Li J, Chen DL (2016). 20(S)-ginsenoside Rh2 inhibits the proliferation and induces the apoptosis of KG-1a cells through the Wnt/${\beta}$-catenin signaling pathway. Oncol Rep 36:137-46   DOI
4 Jia L, Zhao Y, Liang XJ (2009). Current evaluation of the millennium phytomedicine-ginseng (II): Collected chemical entities, modern pharmacology, and clinical applications emanated from traditional Chinese medicine. Curr Med Chem 16:2924-2942   DOI
5 Kazuhiro H, Makoto M, Kaoru N, Yukinobu I, Hiroshi M (1991). Polyacetylenes from the roots of Panax ginseng. Phytochemistry 30:3327-3333   DOI
6 Kim JH, Yi YS, Kim MY, Cho JY (2017). Role of ginsenosides, the main active components of Panax ginseng, in inflammatory responses and diseases. J Ginseng Res 41:435-443   DOI
7 Oh Y, Lim HW, Kim K, Lim CJ (2016). Ginsenoside Re improves skin barrier function in HaCaT keratinocytes under normal growth conditions. Biosci Biotechnol Biochem 13:1-3   DOI
8 Lee HS, Lee HJ, Yu HJ, Ju do W, Kim Y, Kim CT, Kim CJ, Cho YJ, Kim N, Choi SY, Suh HJ (2011). A comparison between high hydrostatic pressure extraction and heat extraction of ginsenosides from ginseng (Panax ginseng CA Meyer). J Sci Food Agric 91:1466-1473   DOI
9 Lee KW, Jung SY, Choi SM, Yang EJ (2012). Effects of ginsenoside Re on LPS-induced inflammatory mediators in BV2 microglial cells. BMC Complement Altern Med 12:196   DOI
10 Lim HW, Kim K, Lim CJ (2016). Contribution of ginsenoside Re to cellular redox homeostasis via upregulating glutathione and superoxide dismutase in HaCaT keratinocytes under normal conditions. Pharmazie 71:413-419   DOI
11 Oh Y, Lim HW, Park KH, Huang YH, Yoon JY, Kim K, Lim CJ 2017). Ginsenoside Rc protects against UVBinduced photooxidative damage in epidermal keratinocytes. Mol Med Rep 16:2907-2914   DOI
12 Park JD (1996). Recent studies on the chemical constituents of Korean ginseng (Panax ginseng CA Meyer). Korean J Ginseng Sci 20:389-415
13 Yahara S., Kaji K., Tanaka O (1979). Further Study on Darnmarane-Type Saponins of Roots, Leaves Flower-Buds, and Fruits of Panax ginseng CA Meyer. Chem Pharm Bull 27:88-92   DOI
14 Popovich DG, Kitts DD (2004). Generation of ginsenosides Rg3 and Rh2 from North American ginseng. Phytochemistry 65:337-44   DOI
15 Shin D, Moon HW, Oh Y, Kim K, Kim DD, Lim CJ (2018). Defensive Properties of Ginsenoside Re against UV-B-Induced Oxidative Stress through Up-Regulating Glutathione and Superoxide Dismutase in HaCaT Keratinocytes. Iran J Pharm Res 17:249-260
16 Shouqin Z, Jun X, Changzheng W (2005). High hydrostatic pressure extraction of flavonoids from propolis. J Chem Technol Biotechnol 80:50-54   DOI
17 Tung NH, Song, GY, Nhiem NX, Ding Y, Tai BH, Jin LG, Lim, CM, Hyun, JW, Park CJ, Kang HK, Kim YH (2010). Dammarane-type saponins from the flower buds of Panax ginseng and their intracellular radical scavenging capacity. J Agric Food Chem 58:868-874   DOI
18 Tung NH, Song GY, Woo S, Hyun JW, Koh YS, Kang HK, Shoyama Y, Kim YH (2012). Ginsenosides from the leaves and flower buds of panax ginseng and their pharmacological effects. Curr Bioact Comp 8:159-166   DOI