Background : This study was carried out to investigate the antioxidative activity and active ingredients of Glehenia littoralis through purification process.
Methods and Results : Above-ground and below-ground parts of Glehenia littoralis, dried in Gangneung, were purchased, crushed, sonicated for 2 hours in 100% ethanol, filtered and concentrated. Above-ground part of G.littoralis which is more effective higher antioxidant effect than below-ground part in 2,2-diphenyl-1-picrylhydrazyl (DPPH) assays. Was used to extract the above-ground part of the solvent fraction according to polarity (hexane, ethyl acetate, water) and HP20 column separation (0, 30, 60, 100% EtOH). Using the fraction was the DPPH assay with high-performance liquid chromatography (HPLC) analysis. Comparing the antioxidant efficacy with that of fraction isolated from Glehenia littoralis extract. Hexane, water layer and 100% EtOH fraction showed lower efficacy than Glehenia littoralis extract. 60% EtOH fraction showed more than 8 times higher efficacy. In order to compare the components according to their efficacy, HPLC analysis was carried out. The fraction (hexane, water layer, 100% EtOH fraction) which showed low antioxidative activity confirmed imperatoin and nonpolar compound, the fraction (ethyl acetate, 60% EtOH fraction) showed a higher antioxidant activity was confirmed 2 flavonoid and scopoletin.
Conclusion : Glehenia littoralis extract showed low antioxidant activity of 893 ㎍/㎖ with IC50 of DPPH assay. However, it showed an increase of antioxidant activity by IC50 of 115㎍ /㎖ of DPPH assay of 60% EtOH fraction by fractionation and separation. Through HPLC analysis, the active ingredient, scopoletin and two flavonoids were identified.
Background : Korean mountain ginseng (Panax ginseng C.A. Meyer) are difficult to industrially apply because of its scarcity and high cost. Advances in plant biotechnology have made it possible to produce mountain ginseng on a large scale using adventitious root cultures in bio-reactors. This study was conducted to develop a cosmetic emulsion using ginsenoside and physiological activity - enhanced raw materials by fermentation process. Methods and Results : Wild ginseng adventitious roots were fermented with Pediococcus pentosaceus HLJG 0702 (KACC 81017BP). ginsenoside contents was analysed by using HPLC. Antioxidant activity was measured by DPPH and ABTS radical scavenging activity and whitening effect was measured by tyrosinase inhibitory activity. After microfluidizer processing was performed to prepare emulsions with homogenized particles, particle size and distribution were measured through a transmission electron microscop e(TEM). Particle stability compares pH, viscosity, light and zeta potential. When fermented with Pediococcus pentosaceus HLJG 0702, the highest change rates of Rg3, Rk1 and Rg5 were shown and the antioxidant activity was increased. The whitening effect was 73.2 ± 0.9% when treated at 100 ㎍/㎖, 1.5 times higher than the control. The optimum particle size and distribution were shown to be 418.0 ± 14.9 ㎚ for 6 times treatment with 0 - 10 times microfluidizer treatment. Stability was about 3% in pH, viscosity and light test. the zeta potential was found to be homogeneous at –33.33 mV. Conclusion : Pediococcus pentosaceus HLJG 0702 Fermented Wild ginseng adventitious roots were found to have effective ingredients and improved physiological activity. We have also developed emulsions that exhibit optimal particle size and distribution
Background : The study about cultured wild ginseng root (Panax ginseng C. A. Meyer) have been reported mainly ginsenosides in saponins family. However metabolites of fermented wild ginseng roots by microorganisms was not reported yet. Methods and Results : Cultured wild ginseng roots were used for fermentation of ginseng roots using Pediococcus pentosaceus and other bacterial strains. We analyzed different types of ginsenoside contents, metabolite and enzyme contents, and gene expression by using microorganisms. Results showed considerable differences in ginseonoside contents specially Rk1 and Rg5. The highest enzyme activity level was by Glutathione reductase (GR) and Glutathione S transferase (GST) in fermented ginseng roots than control (non-fermented), whereas Glutathione peroxidase (GPX) and Peroxidase (POD) contents were reduced. Score plots and loading plots of principal components 1 of the PCA result obtained from the data on 43 metabolites in fermented wild ginseng root of five conditions. The concentration of metabolite such as β-alanin and 4-aminobutyric acid (GABA), which is used to improve memory were increased in fermented ginseng roots than control. We found functional gene in wild ginseng root related with metabolic process. The APX gene expression gradually increased in fermented ginseng root with respect to fermentation times. Conclusion : In this study, accumulation of functional metabolite in cultured ginseng r
Background : The minor saponins produced by the hydrolysis of a major saponins sugar. The minor saponins has high absorption and efficacy compared to major saponin. The acid treatment, heat treatment and fermentation with minor saponin research has been actively conducted. This study was performed in order to investigate the bioconversion of ginsenoside Rg5 of fermented wild ginseng adventitious roots by using lactic acid bacteria. Methods and Results : 20g adventitious roots of ginseng was added to water (10-fold v/w). 10% (v/v) of lactic acid bacteria (Pediococcus pentosaceus HLJG0702[KACC 81017BP]) were inoculated with wild ginseng adventitious roots. For the fermentation process the inoculated samples were transferred to culture room for 1, 3 and 5 days. The fermented samples were dried at room temperature and extracted with 70% ethanol. Extract was concentrated completely at 50 ℃ and Rg5 was analysed by using HPLC. Results showed no significant difference the dry weight of non-fermented and fermented wild ginseng adventitious roots. During the fermentation process, the pH changed from 5.7 to 4.2. HPLC analysis showed higher ginsenoside Rg5 (39.588 mg/g) at 3 days. Conclusion : The fermentation of ginseng root can increase the Rg5 contents and minor saponin composition. This process may be used to enhance the minor saponin thereby increasing in fermented property of wild ginseng adventitious roots.
Background : This study, the fraction for testing the efficacy of the Astragalus extract was concentrated active ingredient. The concentrated fraction was applied to a cosmetic material that Astragalus testing results confirmed that the improved efficacy. Methods and Results : The fractions were performed using an n-butanol solvent for increasing the efficacy of the Astragalus extract, by using the material fractions collected to compare and ultimately an increase in whitening and wrinkle efficacy. The solvent to be used in the fractions was used for the n-butanol good dissolution to the effective substance(Astragaloside, Isoflavonoid). It increased approximately 6.5 times the sample extract and the n-butanol fraction of the Astragalus as a result Astragaloside 15 ppm, 97 ppm respectively analyzed by HPLC equipment, isoflavonoid content was confirmed by an increase in the content of the fractions increased 4.5 times to 280 ppm, 1,260 ppm. Tyrosinase inhibitory effect, respectively IC50 5.70 mg/mL, IC50 1.02 mg/mL to, Collagenase producing ability is IC50 4.88 mg/mL, IC50 0.93 mg/mL with n-butanol fraction was good whitening, anti-wrinkle efficacy than the extract. Sensory evaluation was conducted in the same amount of sample, using a purified Astragalus cosmetics received high marks. Stability evaluation(MTT assay) was checked for more than 100% cell viability at the concentration 2,000 ppm. Conclusion : n-butanol fraction of Astragalus was subjected to a component analysis and In vitro test, it was confirmed an increase active ingredient content. The results of sensory evaluation and stability evaluation, it was confirmed been made to improve qualities as a cosmetic materials.
Background : Perilla frutescens L. is a bisexual, annual plant belonging to the Labiatae. Dormancy period of Perilla seed usually ranged from 85-200 days. The germination enhancing effects in a reduced seed vigor during the GA3 treatment has been reported. Objectives of the present study was to evaluate the effect of GA3 on germination rate and the expression of germination-related genes expression by using perilla seeds. Methods and Results : Three different cultivars (Saeyeopsil, Okdong) and accession (line 141) of perilla were used in the experiment and treated with GA3 at different concentration (50, 100, 300, 500 μM) for one day at dark condition. Germination test for perilla seed was carried out by using 100 perilla seeds treated with GA3 at 25℃. Rate of germination were evaluated after 10 days and the experiments were repeated three times in similar condition. Samples were collected from each cultivar and accessions for RNA extraction. After cDNA synthesis quantification, templates were subjected to RT-PCR using actin primers. EST blast performed for sequencing the RT-PCR products. Conclusion : Result showed that 100μM GA3 treated seeds of three perilla cultivars and accessions showed the highest germination rate. However, concentration of GA3 over 100 μM and lower than 100 μM resulted into reduced germination rate. Furthermore, expression of germination-related genes from 100 μM treated GA3 was higher compared to untreated sample by using 100 μM GA3 treated sample by using pC12, pJ14 primers.
Background : Ginsenosides, the main ingredient of ginseng roots can be confirmed various physiological activity such as anticancer, antioxidant, a natural ginsenosides is there a structure to be absorbed into the body does not work well absorbed through this process biologically active thus a high conversion ginsenosides. β-glucosidase enzyme is observed in several of the microorganism with an enzyme that serves to convert a ginsenoside prosper that is absorbed into the body. Methods and Results : To view a primary β-glucosidase activity, the bacteria were innoculated in esculin agar medium and the color change of the media were measured by the time and degree of changing color. In the other method, 5 mM of p-nitrophenyl-β-D-glucopyranoside (pNPG) containing 25 mM phosphate buffer solution (pH 7.0) was added to 50 ul enzyme solution. Then the solution was added to 50 ul reaction for 5 min at 30°C. The amount of p-nitrophenol liberated measured at 405 nm absorbance. The experimental results showed higher β-glucosidase activity in Pediococcus pentosaceus, Leuconostoc mesenteroide, Leuconostoc mesenteroides subsp. cremoris, and Paenibacillus polymyxa by using esculin agar medium method. Similarly in second method, β-glucosidase activity was higher in P. pentosaceus 402.32±11.43 unit/l, L. mesenteroide 353.73±14.64 unit/l, Lactobacillus sakei 198.4±15.47 unit/l Lactobacillus plantarum subsp. plantarum 164.1±8.12 unit/l. Conclusion : The result that the β-glucosidase activity was higher in P. pentosaceus, L. mesenteroide, and L. plantarum subsp. plantarum as compared to tested microbes. Therefore selected bacteria can be used in the industry of functioned foods and beverage to improve human healths.