KR980009275A - New saponin components and their separation method - Google Patents

Abstract

The present invention relates to novel saponins, 6-O-? -D-glucopyranyl dimalea-20 (22), 24-diene-3 ?, 6 ?, 12? -Triol. This saponin was named ginsenoside Rh ₄ . The present invention also relates to a method for separating ginsenoside Rh ₄ from silica extract of ethanol extract of Korean red ginseng by silica gel column chromatography.

Description

New saponin components and their separation method

1 is a diagram showing the ginsenoside Rh ₄ hydrogen nuclear magnetic resonance spectrum (400 mega helcheu, deuterated pyridine) of.

Figure 2 is a diagram showing a binary hydrogen nuclear magnetic resonance spectrum (100 mega helcheu, deuterated pyridine) of ginsenoside Rh _4.

Figure 3 is showing a ginsenoside Rh ₄ hydrogen nuclear magnetic resonance spectrum (400 mega helcheu, deuterated pyridine) in a non-assignment of the diagram.

Figure 4 is showing the ginsenoside Rh ₄ hydrogen nuclear magnetic resonance spectrum (100 mega helcheu, deuterated pyridine) in a non-assignment of the diagram.

[TECHNICAL FIELD OF THE INVENTION AND RELATED ART OF THE SAME]

The present invention relates to a novel saponin represented by the following structural formula (1): 6-O-? -D-glucopyranosyldamma-20 (22), 24-diene-3 ?, 6 ?, 12? Side Rh ₄ ").

As the above-mentioned ginsenoside Rh ₄ new substance, it is separated from ginseng.

Panax ginseng C.A. Meyer is a perennial herb that belongs to the Araliaceae family. Most of the ginseng roots that are commercially distributed are processed into roots of Korean ginseng, and are distinguished by white ginseng and red ginseng. White ginseng is dried as it is, and red ginseng is processed through numerical processes. In other words, red ginseng is a dried ginseng which is heat treated during processing, so it is considered that ginseng components are chemically changed. Especially, the main question of this numerical process in red ginseng is thought to be to increase the efficacy, widen the working capacity of the drug, and to clean and store the drug.

Studies on the structure of ginseng saponin have been conducted by Sabata and Tanaka Group in Japan since the early 1960s. Namely, the structure of various saponins of about 30 types has been revealed since the name of ginsenosides Ro, Ra, Rb, Rd, Re, Rf, Rg and Rh in the order of increasing Rf value by thin layer chromatography of ginseng saponin. , The pharmacological actions of individual saponins began to be examined in connection with the medicinal effects of ginseng. Especially, the major saponins contained in ginseng (ginseng, white ginseng, and red ginseng) have been studied pharmacologically. Among them, saponin mainly contained in red ginseng, . The red ginseng saponin has been found to be mostly white ginseng. However, the red ginseng Rs, Rs ₂ and 20 (R) -ginsenoside Rh ₁ , 20 (S) -ginsenoside Rg ₃ and 20 R) -ginsenoside Rg _{2 and the like} . Particularly, the above-mentioned saponin components are regarded as prosapogenin glycosides in which the terminal sugar of carbon 20 is separated from the main saponin of ginseng by thermal decomposition during the red ginseng manufacturing process or the terminal sugar of carbon 6 is separated. In addition, a specific saponin component, which is presumed to be a saponin compound in which one molecule of water is dewatered and a double bond is formed, is also known as the sugar of carbon 20 is released according to chemical change. Thus, the saponin compound having a double bond at carbon 20 was isolated from the side of ginseng and identified as ginsenoside Rh ₃ , but no ginsenoside Rh ₃ was isolated and identified in the roots of ginseng.

[Technical Problem]

It is an object of the present invention to provide a new ginseng saponin.

The present inventors have found that there is a new saponin having a double bond introduced into carbon 20 at the chewing gum that tracks a new active ingredient of Korean red ginseng. Compared to the compound and ginsenoside Rh ₁ binary, but the carbon nuclear magnetic resonance spectrum and the position of each pig of ginsenosides Rh ₁ is almost the same it is possible to find some difference in ambient carbon 20 times, in the case of a new saponin A molecular weight of 620 was obtained. One molecule of water dropped at residue No. 20 of ginsenoside Rh ₁ , and a double bond was observed. Also, the stereochemistry of the double bond between carbon 20 and 22 was reported as Entgegen because NOE is observed between 21 methyl hydrogen and 23 methylene hydrogen from nuclear magnetic resonance spectrum (NOESY).

[Structure and operation of the invention]

The present invention consists of the ginsenoside Rh ₄ of the above-mentioned structural formula (1).

The ginsenoside Rh ₄ of the present invention showed steric differences with ginsenoside Rh ₃ . It can be inferred that ginsenoside Rh ₄ , a novel saponin glycoside of the present invention, was produced by dehydration of one molecule of water from ginsenosides Rh ₁ in the red ginseng production process from fresh ginseng. The physicochemical properties of the new saponin were as follows and this material was named ginsenoside Rh ₄ of the general formula (1).

Physicochemical properties of ginsenoside Rh ₄ are as follows.

Physicochemical Properties of Ginsenoside Rh ₄

1) Colorless off-white crystals (methanol-water)

2) Melting point: 160-161 DEG C

3) Nonlinearity. [[alpha]] _D : +28.2 [deg.] (c = 1.0, methanol)

4) Rf value: key selgel F ₆₀ by using a thin layer chromatography in chloroform-methanol-water -7: 3: 1, Rf; 0.64

5) Spray with 20% aqueous solution of persimmon in thin layer chromatography of 4) and show red violet upon heating and coloring.

6) Fast atom impact mass spectrum: M ⁺ + H = 621

7) Elemental analysis C ₃₆ H ₆₀ O ₈ Calculated: carbon 69.64%, hydrogen: 9.74%

Analytical value: carbon 69.58%, hydrogen: 9.80%

8) Hydrogen Nuclear Magnetic Resonance Spectrum: Same as the first.

9) Carbon Nuclear Magnetic Resonance Spectrum: Same as 2

The present inventors succeeded in confirming the structure of ginsenoside Rh ₄ by acid hydrolysis to obtain dimara-20 (22) 24-diene-3β, 6α, 12β-triol of the non- . As a result of the spectroscopic analysis of the non - sugar moiety, it was confirmed that the hydroxyl group of carbon 20 was dehydrated to form a double bond, and the stereochemistry of the double bond at carbon 20 of the tautopotaxanthol was also confirmed as the entegene type.

The physical and chemical properties of this material are as follows.

1) White powder (methanol-water)

2) Melting point: 131-132 DEG C

3) Specific rotation: [?] _D : + 40.0 (c = 0.2, methanol)

4) Electron impact mass spectrum: calculated value C ₃₀ H ₃₅ O ₃ : 458.3762

Anal. C ₃₀ H ₃₅ O ₃ : 458.3775

6) hydrogen nuclear magnetic resonance spectrum; Same as the third.

7) Carbon Nuclear Magnetic Resonance Spectrum: Same as 4th.

The present invention also relates to a method for separating ginsenoside Rh ₄ from ginseng.

A method of separating ginsenoside Rh ₄ of the present invention will be described as follows. Ethanol extract is obtained from Korean red ginseng and subjected to repeated silica gel column chromatography to separate ginsenoside Rh ₄ which is a colorless off-white crystalline form. In order to confirm the structure, acid hydrolysis of ginsenoside Rh ₄ obtained in a microcrystalline form is carried out and the non-sugar portion is subjected to column chromatography to purify it.

The present invention Jin silica gel chromatography to separate ginsenoside Rh ₄ is good best carried out repeatedly three times, for example once, the chloroform as eluent according to: methanol 5: using a first solution and twice, the chloroform: methanol: Use a 20: 3: 1 solution of water and 3 times of n-butane: ethyl acetate 1: 3 solution.

Hereinafter, the present invention will be described in detail with reference to the following examples.

[Example 1]

Isolation of ginsenoside Rh ₄ from red ginseng

One kilogram of Korean ginseng powder is sonicated by 2.5 times of ethane per 3 times at room temperature overnight to obtain 120 g of ethane extract. 100 g of the mixture is subjected to silica gel column chromatography (eluent = chloroform: methanol = 5: 1) to separate four fractions. The third fraction was purified by silica gel column chromatography (chloroform: methanol: water = 20: 3: 1) and repeatedly subjected to silica gel column chromatography (n-butanol ' 94.9 mg of senoside Rh ₄ was isolated and purified.

[Example 2]

200 mg of ginsenoside Rh ₄ is dissolved in 9% hydrochloric acid / methanol and refluxed for 2 hours. The reaction solution was neutralized with silver carbonate, filtered and concentrated under reduced pressure. D-Chloroquinone was identified by silica gel thin layer chromatography (chloroform-methanol-water = 6: 4: 1), and the remaining portion was subjected to silica gel column chromatography (hexane-ethyl acetate = 2: 1) 6.3 mg of dimale-20 (22), 24-diene-3 ?, 6 ?, 12? -Triol of structural formula (2) was isolated.

Claims (3)

20 (22), 24-diene 3?, 6 ?, 12? -Triol (hereinafter referred to as ginsenoside Rh ₄ ) represented by the structural formula (1) 6-O-? -D-glucopyranosyl dima-20 (22), 24-diene-3 ?, 6 ?, 12? -Triol of the structural formula (1), which was obtained from ethanol extract of Korean red ginseng by silica gel column chromatography, (Jin senenoside Rh ₄ ). The process according to claim 2, wherein the silica gel column chromatography for separating the ginsenoside Rh ₄ of the structural formula (1) is carried out using primary chloroform and methanol (5: 1) as eluent, methanol and water (20: 3: 1) as the eluent and tertiary silica gel column chromatography using n-butanol and ethyl acetate (1: 3) as the eluent. ※ Note: It is disclosed by the contents of the first application.