JPWO2003090770A1 - Method for producing proanthocyanidin-containing material - Google Patents

Abstract

By extracting proanthocyanidins from a plant body, bringing the obtained extract into contact with chitin, chitosan, or a derivative thereof, and recovering non-adsorbed products, a proanthocyanidin-containing product rich in physiologically active OPC is obtained. It can be manufactured efficiently. Furthermore, a proanthocyanidin-containing product having a higher OPC content can be produced by treating proanthocyanidins with a synthetic resin adsorbent.

Description

なお、表１中のアニスアルデヒド硫酸および硫酸の欄は、プロアントシアニジンの検出結果を示し、＋の数が多いほど、含量が多いことを示す。この検出は、ＡからＦ各粉末の各５ｍｇを１ｍＬのメタノールに溶解し、上記条件でシリカゲルＴＬＣを用いて展開し、アニスアルデヒド硫酸および硫酸で発色させ、移動率（Ｒ_ｆ）が０．７〜１．０の範囲のスポットを検出した。
ＯＰＣ含有率を、以下のように算出した。まず、精製粉末ＥがＯＰＣを８０重量％以上含むことから、精製粉末Ｅ中の全ＯＰＣ重量を固形分重量（１．６ｇ）の８０重量％と仮定した（１．２８ｇ）。精製プロセスにおいて、アニスアルデヒド硫酸によって発色した各固形分中に全ＯＰＣが含まれていると仮定して、ＯＰＣ含有率を算出した。発色しない固形分については、０．０％とした。
表１の結果より、キチン処理によってキチンに吸着しないプロアントシアニジン含有物が得られ、この含有物を合成樹脂系吸着剤で処理してプロアントシアニジンを吸着させることにより、夾雑物が除去された高純度のプロアントシアニジン含有物が得られることがわかる。さらに、キチン類に吸着されない画分に含まれるプロアントシアニジン含有物の固形分中には、４０％以上のＯＰＣを含有することがわかる。
（実施例２）
松樹皮１００ｇに１Ｌの精製水を加え、破砕し、１００℃で１０分間加熱処理した。その後、濾過し、１．２Ｌの抽出液Ｇを得た。次いで、この抽出液Ｇを２５℃まで放冷し、キチン樹脂１５ｇを抽出液Ｇに加え、３時間攪拌を行った。さらに攪拌後、ろ過し、１．２Ｌの処理液Ｈを得た。さらに、この処理液Ｈを減圧濃縮し、３．３６ｇの処理粉末Ｈを得た。さらに、この処理粉末Ｈと処理粉末Ｂとをそれぞれ実施例１と同様にＴＬＣで測定したところ、処理粉末Ｂと同様に発色を示し、約４０％以上のＯＰＣを含有していた。さらに、３．３１ｇの処理粉末Ｈを２Ｌのメタノールに溶解し、実施例１と同様に５０ｇのダイアイオン ＨＰ２０を充填したカラムへ通液し、吸着させ、精製水で洗浄した。次いでカラムに２０〜１００％（Ｖ／Ｖ）エタノール−水混合溶媒でグラジエントをかけて、通液した。通液量は１．６Ｌであった。２０〜４０％（Ｖ／Ｖ）エタノール−水混合溶媒による溶出画分を併せ、減圧濃縮し、２．１５ｇの精製粉末Ｉを得た。精製粉末Ｉと精製粉末Ｅとをそれぞれ、実施例１と同様にＴＬＣで検出したところ、精製粉末Ｅと同様の発色を示し、８０％以上のＯＰＣを含有していた。
（実施例３）
実施例２において、接触処理後のキチン樹脂を減圧濃縮し１７ｇの粉末Ｊを得た。この得られた粉末Ｊを用いて、シェークフラスコ法による抗菌活性を測定した。比較として、接触処理を行っていないキチン樹脂の粉末Ｋも同様に抗菌活性を測定した。測定方法は下記の通りである。
最初に、リン酸一カリウム（３４ｇ）を精製水（５００ｍＬ）に溶かし、これに４％（Ｗ／Ｖ）水酸化ナトリウム水溶液（約１７５ｍＬ）を加えてｐＨ７．２に調整後、全量を１０００ｍＬとし、さらに精製水で８００倍に希釈して振盪培養液を調製した。
試験菌として、黄色ブドウ状球菌Ｓｔａｐｈｙｌｏｃｏｃｃｕｓ ａｕｒｅｕｓを使用した。この試験菌株をブレイン・ハート・インフュジョン寒天斜面培地に移植後、３７℃、２４時間培養した。この培養菌を白金耳を用いて普通ブイヨン培地に植菌し、３７℃、６〜１０時間培養した後、普通ブイヨン培地を用いて菌数を１．５〜３×１０^８個／ｍＬに調整した。さらにこの菌液をリン酸緩衝液の保存液で１０００倍に希釈し、接種菌液とした。
以上のようにして調製した振盪培養液および接種菌液を用いて、抗菌試験を行った。２００ｍＬ容ネジ口キャップ付き三角フラスコを６本用意し、それぞれに振盪培養液（７０ｍＬ）を入れ、キャップを緩く閉めた後オートクレーブで滅菌した。冷却後、接種菌液（５ｍＬ）を加えてよく撹拌した。最終的に三角フラスコ中の菌数は、１〜２×１０^４個／ｍＬとした。各三角フラスコのうち、任意の３本から菌液（１ｍＬ）を採取し、試験液で１０倍希釈系列を作り、標準寒天培地を用いて混釈寒天平板を作成した。この平板を３７℃、２４〜４８時間培養した。生育したコロニー数をそれぞれ計測し、その希釈倍率を乗じて生菌数（初発菌数）を算出した。この生菌数の平均値をＡとした。
次いで、３５０ｍｇの粉末Ｊおよび粉末Ｋを、試験接種菌液を入れた三角フラスコ３本ずつにそれぞれ加え、合計６検体を同時にリストアクション振盪機（回転数３２０〜３４０ｒｐｍ）で１時間振盪培養した。振盪培養後、各三角フラスコより菌液（１ｍＬ）を採取し、上記と同様にして混釈寒天平板を作成し、生菌数を測定した。この生菌数の平均値をＢとした。
得られた値ＡおよびＢから減菌率を｛（Ａ−Ｂ）／Ａ｝×１００として算出したところ、粉末Ｋの滅菌率は９３％であったのに対して、粉末Ｊの滅菌率は２９％であった。以上のことから、接触処理後のキチン樹脂には、高い抗菌活性を有することがわかる。
産業上の利用可能性
本発明の方法により、生理活性の高いＯＰＣを高い割合で含有するプロアントシアニジン含有物を効果的に得ることができる。特に、合成樹脂系吸着剤で処理する工程を含む方法を採用することによって、よりＯＰＣ含量の高いプロアントシアニジン含有物を提供できる。このＯＰＣ含量の高いプロアントシアニジンは、血管増強、高血圧、冷え性などの改善に効果があり、食品、化粧品、医薬品の製造原料として用いられる。Technical field
The present invention relates to a method for efficiently producing proanthocyanidins useful for improving blood vessel enhancement, hypertension, coldness, etc., as a raw material for producing foods, cosmetics, pharmaceuticals and the like.
Background art
Proanthocyanidin is a polymerized or condensed tannin present in various plants, and is a compound bonded by condensation or polymerization (hereinafter referred to as polycondensation) using flavan-3-ol or flavan-3,4-diol as a constituent unit. A group. These are given their names because they produce anthocyanidins such as cyanidin, delphinidin and pelargonidin by acid treatment.
Of the proanthocyanidins, proanthocyanidins having a low degree of polymerization are preferably used. The degree of polymerization is preferably a 2-30 condensation polymer (2-30 mer), more preferably a condensation polymer having a polymerization degree of 2-10 (2-10 mer), and a polymerization degree of 2-4 condensation. A polymer (2 to 4 mer) is more preferably used.
In the present specification, among the condensed polymers of proanthocyanidins, a condensed polymer having a polymerization degree of 2 to 4 having flavan-3-ol and / or flavan-3,4-diol as a structural unit is referred to as OPC (oligomeric). -Proanthocyanidins; called oligomeric proanthocyanidins).
OPC is a kind of polyphenols and is a powerful antioxidant produced by plants, and is mainly contained in plant leaves, bark, fruit peels and seed parts. Specifically, it is contained in grape seeds, pine bark, peanut skin, ginkgo, false acacia fruit, cowberry and the like. It is also known that cola nuts in West Africa, Latania roots in Peru, and Japanese green tea contain OPC. OPC is a substance that cannot be produced in the human body.
Furthermore, in addition to antioxidant action, OPC has the effect of suppressing bacterial growth in the oral cavity and reducing plaque (dentals); the effect of restoring the elasticity of blood vessels; and lipoproteins in the blood are damaged by active oxygen The effect of preventing ingestion and preventing damaged fat from aggregating on the inner wall of blood vessels and adhering cholesterol; the effect of regenerating vitamin E decomposed by active oxygen; the effect of vitamin E as an enhancer, etc. It is known to have
Tannin, which is a polymer of flavan-3-ol and / or flavan-3,4-diol, and chitin, chitosan, and derivatives thereof have antibacterial activity against Staphylococcus aureus, Salmonella, Salmonella typhi, Vibrio cholerae, etc. Bactericidal action is remarkable. In particular, it has been reported that MRSA (methicillin-resistant staphylococci), which has become a topic because most antibiotics do not work, is also effective.
Proanthocyanidins are generally obtained by extraction from plant bodies. Examples of the solvent used for extraction include water; organic solvents such as methanol, ethanol, acetone, hexane, and ethyl acetate; or a mixture thereof (Japanese Patent Laid-Open No. 11-80148). However, simply by extraction with a solvent, the recovered amount of proanthocyanidins is low and the purity is low. Therefore, in order to use as a raw material for health foods, cosmetics and pharmaceuticals, further steps such as concentration and purification are required to increase the purity, which is costly and time consuming.
Japanese Patent Laid-Open No. 5-279264 describes a method for recovering polyphenols containing proanthocyanidins. In this method, polyphenols are adsorbed to chitin, and chitin adsorbed with polyphenols is used as a polyphenol product. However, the adsorbed polyphenols are polyphenols having a high degree of polymerization, and the content of OPC in the above-described 2- to 4-mer having high physiological activity is extremely low, so that the physiological activity such as antioxidant action is low.
Chitin, chitosan, and derivatives thereof are known to have antibacterial action.
Under such circumstances, an efficient method for producing proanthocyanidins having useful physiological activity is desired.
Disclosure of the invention
The present inventors diligently studied about a method for efficiently obtaining proanthocyanidins. As a result, proanthocyanidins were extracted from plants, and the obtained extract was brought into contact with chitin, chitosan, or derivatives thereof, and non-adsorbed. It was found that a proanthocyanidin-containing material containing a large amount of highly bioactive OPC can be efficiently obtained by recovering the product. The present invention was completed by finding that a proanthocyanidin-containing material having a higher OPC content can be obtained by further treating this proanthocyanidin-containing material with a synthetic resin-based adsorbent.
The present invention provides a method for producing a proanthocyanidin-containing product, the method comprising (a) obtaining an extract or juice from a plant by extraction or pressing; and (b) obtaining the extract or juice from the plant, The step of contacting with chitin, chitosan, or a derivative thereof to recover non-adsorbed material is included.
In a preferred embodiment, the extraction is hot water extraction.
In a further preferred embodiment, the method further includes (c) a step of bringing the non-adsorbed product obtained in the step (b) into contact with a synthetic resin-based adsorbent.
The present invention provides a proanthocyanidin-containing product obtained by the above production method.
In a preferred embodiment, oligomeric proanthocyanidins are contained in a solid content of the proanthocyanidin-containing material in a proportion of 40% by weight or more.
The present invention is obtained by bringing an extract or juice obtained from a plant into contact with chitin, chitosan, or a derivative thereof, and then recovering an insoluble component containing the chitin, chitosan, or a derivative thereof. Providing antibacterial agents.
BEST MODE FOR CARRYING OUT THE INVENTION
The plant used in the present invention is a plant containing proanthocyanidins, and there is no particular limitation on the type thereof. Bark of trees such as cedar, straw and pine rich in proanthocyanidins; grape seeds, peels and fruits; peanut skin; ginkgo, cacao; tea leaves and tea extract; sorghum millet; apple fruit; kumazasa; fucoidan; Elderberry; Black Acacia fruit; Cowberry; Cola nut (eg, West African Cola nut); Latania (eg, Peruvian Latania) root; Among these, pine bark, grape seeds and pericarp, peanut thin skin, and the like are particularly preferably used.
Hereinafter, the manufacturing method of the proanthocyanidin containing material of this invention is demonstrated. First, proanthocyanidins are extracted from the plant body, or juice is obtained from the plant body. When performing extraction, from the viewpoint of extraction efficiency, the plant body is preferably crushed to an appropriate size to increase the surface area per volume. The crushing method is not particularly limited. For example, the crushed material processed with a cutter, a slicer, etc .; The pulverized material processed with the mixer, the juicer, the blender, the mass collider, etc. may be sufficient. The size of the crushed product or crushed product is 0.1 to 10 cm, preferably 0.1 to 5 cm. In order to increase crushing efficiency, an organic solvent such as water, ethanol, methanol, or ethyl acetate may be added during crushing.
As the extraction solvent, water or an organic solvent is used. Examples of the organic solvent include methanol, ethanol, 1-propanol, 2-propanol, 1-butanol, 2-butanol, butane, acetone, hexane, cyclohexane, propylene glycol, hydrous ethanol, hydrous propylene glycol, ethyl methyl ketone, and glycerin. , Methyl acetate, ethyl acetate, diethyl ether, dichloromethane, edible oils and fats, 1,1,1,2-tetrafluoroethane, 1,1,2-trichloroethene and the like. Furthermore, a mixed solvent of water-organic solvent is also preferably used. These may be used alone or in combination of two or more solvents. Water is preferably used from the viewpoint of waste liquid treatment during production.
The amount of the extraction solvent added to the plant body is set in consideration of the target proanthocyanidin concentration and extraction efficiency. For example, when water is used as an extraction solvent, the ratio of plant body: water is 1: 5 to 1:50 by weight, preferably 1:10 to 1:20. In the case of crushing by adding water and / or an organic solvent, the amount of extraction solvent to be added may be adjusted in consideration of the amount used for crushing.
A higher extraction temperature is preferable in order to increase extraction efficiency. When water is used, extraction is performed with hot water at 50 to 120 ° C, preferably 70 to 100 ° C. Hot water may be added to the plant body, and water may be added to the plant body and then heated. The extraction is generally performed for 10 minutes to 24 hours, but is determined by the extraction temperature.
As an extraction method using an organic solvent, extraction by warm extraction or supercritical fluid extraction may be performed. As a warming extraction method using an organic solvent, a method of adding a warmed solvent to a plant body or adding a solvent to a plant body and heating the plant body is used. For example, with respect to the pulverized plant body, using a 5-fold amount of a water-ethanol mixed solvent having a water: ethanol ratio of 1: 1 by weight as an extraction solvent, while refluxing at 70 to 75 ° C., The method of stirring for 3 hours is mentioned. In addition, when using an organic solvent, it is necessary to set the extraction temperature below the boiling point of the organic solvent.
The supercritical fluid extraction method is a method in which a target component is extracted using a supercritical fluid that is a fluid that exceeds a critical point (critical temperature, critical pressure) of a gas-liquid substance. As the supercritical fluid, carbon dioxide, ethylene, propane, nitrous oxide (laughing gas) or the like is used, and carbon dioxide is preferably used. The supercritical fluid extraction method includes an extraction step of extracting a target component with a supercritical fluid and a separation step of separating the target component and the supercritical fluid. Examples of the separation step include a separation step due to a pressure change, a separation step due to a temperature change, or a separation step using an adsorbent / absorbent. These may be used alone or in combination.
Moreover, you may perform supercritical fluid extraction by the entrainer addition method. In this method, for example, ethanol, propanol, n-hexane, acetone, toluene, other aliphatic lower alcohols; aliphatic hydrocarbons; aromatic hydrocarbons; By adding about volume% and performing supercritical fluid extraction using this as an extraction solvent, the solubility of proanthocyanidins in the extraction solvent is dramatically increased, and efficient extraction of proanthocyanidins becomes possible.
For the extraction, for example, any extraction device such as a batch type, a semi-continuous type, or a continuous type may be used.
When obtaining squeezed juice from a plant body, the plant body is squeezed directly, or squeezed after being appropriately cut or crushed. This method is preferably employed when a plant having a high water content is used. For example, in the case of grape fruits, squeezed juice containing proanthocyanidins is obtained by pressing. A plant crushed material containing solid matter derived from the plant body obtained by crushing the plant body (for example, the above-mentioned grape fruit crushed material) is also used in the same manner as squeezed juice. The crushed plant containing solid content is also included in the juice.
Next, the obtained extract or juice (hereinafter referred to as extract) and chitin, chitosan, or derivatives thereof (hereinafter, chitin, chitosan, and at least one of these derivatives are referred to as chitins). And contact. Hereinafter, this process is referred to as a contact process. The chitins used in the contacting step may be used as a powder, or may be used in the form formed into fibers, fibrils, films, porous bodies, microbeads, resins and the like. In the contacting step, any method may be used as long as the extract or the like and chitin come into contact with each other. For example, as a simple method, as an example of a chitin derivative, a column method in which a synthetic resin is used as a carrier and a chitin resin in which chitin is bound to the column is packed in a column and the extract is passed through, and chitins are extracted, etc. In addition, a batch method in which chitins are removed after a certain time can be used. In addition, when an organic solvent is contained in an extract etc., it is necessary to dilute an extract etc. to such an extent that chitin does not melt | dissolve in an organic solvent, or to remove an organic solvent.
In the column method, it is preferable to remove insoluble matters contained in the extract or the like in advance in consideration of clogging of the column. Examples of removal of insolubles include methods usually used by those skilled in the art, such as filtration and centrifugation. From the viewpoint of processing time, filtration is preferably used. Filtration can be performed at 50-100 degreeC, and more proanthocyanidins can be collect | recovered under high temperature. Preferably it is performed at 50 ° C. or higher, more preferably at 70 ° C. or higher. A larger amount of proanthocyanidins can be recovered by washing the filtered insoluble matter with hot water or a warming solvent at 70 ° C. or higher.
After removing the insoluble matter, it is preferable to cool the extract obtained from the aspect of adsorption efficiency to chitins. Preferably it cools until it becomes 4-30 degreeC. Examples of the cooling include natural cooling by cooling; forced cooling using water or ice, or a cooling device such as a freezer and a refrigerator.
After cooling, the extract is passed through a column packed with chitins (eg, chitin resin). The amount of chitin (for example, chitin resin) may be appropriately determined according to the nature, shape, and plant of the raw material. For example, when a proanthocyanidin-containing material is obtained from pine bark using chitin resin, the chitin resin is preferably used in an amount of 5 to 100 g, more preferably 10 to 80 g, based on 100 g of pine bark. After passing the extract through a column filled with chitins, the extract is washed with 100 mL of water, and the liquid and washing liquid that have passed through the column are collected to obtain a proanthocyanidin-containing material. Here, the proanthocyanidin-containing material includes a concentrate, a powder, and the like obtained by a method usually used by those skilled in the art.
The treatment with chitins in the batch method is performed, for example, by adding 5 to 100 g, more preferably 10 to 80 g of chitins to an extract obtained from 100 g of pine bark, and 1 to 3 with stirring. It is preferable to perform for hours.
After the treatment, chitins are removed by filtration or centrifugation, whereby a proanthocyanidin-containing product can be obtained.
By passing through the contact step, a proanthocyanidin-containing material is obtained, and 40 to 90% by weight of OPC (oligomeric proanthocyanidin) is contained in the solid content of the proanthocyanidin-containing material.
By treating the obtained proanthocyanidin-containing product with a synthetic resin adsorbent, impurities such as saccharides and organic acids are further removed and purified. That is, a proanthocyanidin-containing material having an increased OPC content is obtained by bringing a proanthocyanidin-containing material into contact with a synthetic resin-based adsorbent, adsorbing the proanthocyanidin to the synthetic resin-based adsorbent, and eluting with a predetermined solvent. be able to. Examples of the synthetic resin-based adsorbent used for purification include organic resins, ion exchange resins, silica gel, reverse phase silica gel, and the like.
As the organic resin, for example, an aromatic resin, an acrylic acid-based methacrylic resin, an acrylonitrile aliphatic resin, and the like can be used, and an aromatic resin is preferable. Examples of the aromatic resin include an aromatic resin having a hydrophobic substituent, an unsubstituted aromatic resin, and an aromatic resin obtained by subjecting the unsubstituted group to a special treatment. An aromatic resin subjected to special treatment is more preferable. Examples of general-purpose aromatic resins include styrene-divinylbenzene resins. These resins are preferably porous. Such synthetic resins are commercially available, for example, HP-10, HP-20, HP-21, HP-30, HP-40, HP-50 (above, unsubstituted groups) as Diaion (registered trademark) series Types of aromatic resins, all trade names, manufactured by Mitsubishi Chemical Corporation); SP-825, SP-800, SP-850, SP-875 (above, aromatic type obtained by subjecting an unsubstituted group to special treatment) Resin, both trade names, manufactured by Mitsubishi Chemical Corporation); SP-900 (aromatic resins, trade names, manufactured by Mitsubishi Chemical Corporation); Amberlite (registered trademark) systems, XAD-2, XAD-4, XAD-16, XAD-2000 (above, aromatic resins, both trade names, manufactured by Organo Corporation); Diaion (registered trademark), SP-205, SP-206, SP-207 (above, hydrophobic Has a functional substituent Aromatic resins, both trade names, manufactured by Mitsubishi Chemical Corporation); HP-2MG, EX-0021 (above, aromatic resins having a hydrophobic substituent, both trade names, manufactured by Mitsubishi Chemical Corporation) ; Amberlite (registered trademark) system, XAD-7, XAD-8 (above, aromatic resin having a hydrophobic substituent, both trade names, manufactured by Organo Corporation); Diaion (registered trademark) system , HP1MG, HP2MG (above, acrylic acid-based methacrylic resin, both trade names, manufactured by Mitsubishi Chemical Corporation); Sephadex (registered trademark) LH20, LH60 (above, cross-linked dextran derivatives, trade names, Pharmacia) Biotech Co., Ltd.). Among these, Diaion HP-20 or Sephadex LH20 is preferable.
As the ion exchange resin, any of a cation exchange resin and an anion exchange resin can be used. Examples of commercially available ion exchange resins include Amberlite (registered trademark) cation exchange resin, CG-4000, CG-5000, CG-6000, CG-8000 (above, sulfonate group as a functional group. Resin, all trade names, manufactured by Organo Co., Ltd .; IR-116, IR-118, IR-120B, IR-122, IR-124 (above, resins having sulfonate groups as functional groups, all trade names XT-1007, XT-1009, XT-1002 (above, a resin having a sulfonate group as a functional group, both trade names, manufactured by Organo Corporation); a weakly basic anion exchange resin , OPTIPORE-XUS40285.00, OPTIPORE-XUS40390.00 And resins having quaternary amines, all of which are trade names, manufactured by Dow Chemical Co., Ltd.). The elution solvent when using the ion exchange resin is preferably water, the column temperature is preferably 50 to 120 ° C., and the inside of the column is preferably in a normal pressure or pressurized state.
What is necessary is just to set the quantity of a synthetic resin type adsorbent suitably according to the kind of solvent, the kind of synthetic resin type adsorbent, etc. For example, it is preferable to use a synthetic resin-based adsorbent in an amount of 0.01 to 5 times the weight of the solid content in the proanthocyanidin-containing material.
In order to purify using a synthetic resin-based adsorbent, for example, a synthetic resin-based adsorbent is packed into a column, a proanthocyanidin-containing material is passed through the column, and then 5 wt. Pass water of double to 10 times weight. Thereby, the saccharide | sugar and organic acid which are impurities are removed. Thereafter, proanthocyanidins are eluted with a predetermined solvent. Examples of the solvent include water, methanol, ethanol, ethyl acetate, chloroform, and a mixed solvent thereof. Preferably, a mixed solvent of water and ethanol is used. For example, the mixing ratio of water and ethanol varies depending on the synthetic resin adsorbent used, but in the case of Diaion HP-20, the ratio of water: ethanol is 1: 1 to 4: 1 by volume. In this way, a proanthocyanidin-containing product with an increased OPC content is obtained.
The OPC contained in the solid content of the proanthocyanidin-containing product obtained through the above steps is 80% by weight or more, preferably 95% by weight or more.
The proanthocyanidin-containing product produced by the above method can be concentrated to obtain a food material. For the concentration, various methods such as membrane concentration, heat concentration, vacuum (reduced pressure) concentration, freeze concentration and the like are used.
Further, if necessary, these proanthocyanidin-containing materials are sterilized and stored. Sterilization is performed by methods used by those skilled in the art, such as air sterilization, high-pressure sterilization, and heat sterilization.
Further, these proanthocyanidin-containing materials may be concentrated, dried and powdered after sterilization. Drying is performed by a method commonly used by those skilled in the art. Among these, freeze drying, vacuum drying, and spray drying are preferably used.
The proanthocyanidin-containing product obtained by the above production method can be used as a raw material for foods, cosmetics, and pharmaceuticals.
The obtained proanthocyanidin-containing product can be used as a drink or gelled food or drink. Furthermore, the proanthocyanidin-containing product is not only used for food and drink as it is, but also mixed with excipients, extenders, binders, thickeners, emulsifiers, fragrances, food additives, seasonings, etc. It can also be formed in the form of granules, tablets and the like. For example, it is mixed with royal jelly, vitamins, protein, calcium, chitosan, lecithin, caffeine, and the like, and the taste is adjusted with a sugar solution and a seasoning. Furthermore, these are made into capsules such as hard capsules and soft capsules, pills, or tea bags. These may be eaten as they are, depending on their shape or preference, or may be taken by dissolving in water, hot water, milk or the like. In the case of a tea bag or the like, the ingredient may be leached before drinking.
Chitins after contact with extracts, etc. contain tannins derived from plant materials, which are raw materials, and have antibacterial effects as well as deodorizing effects, so they are used as deodorants or antibacterial materials can do. On the other hand, since chitins also have antibacterial action, for example, antibacterial action against O-157, Staphylococcus aureus, etc., chitins after contact treatment synergistically exerts an antibacterial action and has an effective antibacterial action. .
The chitins after this contact treatment are used for drinking and water supply, pet water, bath water, cooking water, washing water, water for appreciation fish, water for washing dishes and ingredients, face washing Water purification material for purifying water, toilet water, toilet sink, pool water, flower arrangement and horticultural water; filter materials (filters for air conditioners, air cleaners, vacuum cleaners, clean rooms) , Water filters, etc .; Fans and moldings around the fans; Refrigerator inner wall panels; Clothing (clothes, interlining, lining, apron, socks, socks, etc.); Footwear (shoes, slippers, insoles, etc.); Goods (towels, scarves, mufflers, belts, hats, gloves, tablecloths, umbrellas, bags, bags, wallets, etc.); daily necessities and kitchen utensils (toothbrushes, clothes brushes, hairbrushes, scrubbing brushes, dishwashers, rags, hooks, scrapes Na ); Medical supplies / Welfare-related products / Sanitary products / Hygiene materials (Surgery clothes, lab coats, bed mats, masks, bandages, gauze, sutures, absorbent materials, wound protection materials, diapers, various sanitary products); Materials (puffs, makeup brushes, etc.); interior products / interior products / furniture (hot carpets, carpets, curtains, chair upholstery, screen doors, bath mats, etc.); interior materials (wall sheets, flooring, etc.); bedding (Futonwata, sheets, futon covers, blankets, mats, pillow covers, cushions, etc.), sporting goods (sports, etc.); car interiors (car cover sheets, seat cloths, ceiling materials, flooring, etc.); bathrooms Toiletries, pets, packaging materials (food packaging films, sheets, bottles, trays, household appliance packaging films, compost bags, etc.); Gushing materials; Shopping bags; Garbage bags; Wrapping paper; Other industrial and consumer use (tents, conveyor belts, hoses, ropes, hoods, canvas, curing sheets, vegetation nets, mats, non-woven fabrics, construction nets, fishing nets) , Longline, seaweed net, fishing line, bird net, insect net, animal net, filter cloth, dry canvas for paper machine, sweat remover for helmet, attachment brush for vacuum cleaner, mop, plush toy, polishing brush, sewing thread, mosquito net, towel , Cards, disposable tableware, stationery, daily miscellaneous goods, etc.).
Furthermore, the chitins after contact treatment are antibacterial for materials such as agricultural films, agricultural simple covering materials, cold chills, binding tapes, herbicidal bags, grass nets, plant nets, root-proof sheets, nursery beds and pots. It can be used as a raw material for imparting properties.
The chitins after the contact treatment are also used as food materials. For example, it can be used as a raw material for snacks, jellies, gums, candy, tablets, hard and soft capsules, etc., and effects such as intestinal regulation effect due to antibacterial action, infection prevention and bad breath removal can be obtained.
(Example)
EXAMPLES Hereinafter, although this invention is demonstrated based on an Example, this Example does not restrict | limit this invention. In the examples, the unit (V / V) indicates (capacity / capacity), and (W / W) indicates (weight / weight). In addition, the solid content weight of the extraction liquid and the treatment liquid in the examples is determined by concentrating and drying the total amount of each liquid under reduced pressure, or measuring the total amount accurately and then measuring a certain amount of the extraction liquid and the treatment liquid (usually 5 mL) was concentrated under reduced pressure, weighed, and then converted to the total liquid amount.
(Example 1)
1 L of purified water was added to 100 g of pine bark, crushed with a blender (Waring Blender), and then heat-treated at 100 ° C. for 10 minutes. Next, the mixture was immediately filtered, and the insoluble matter after filtration was washed with 200 mL of purified water to obtain 1.2 L of Extract A.
A part (5 mL) of this extract A was concentrated under reduced pressure, and the weight of the resulting extract powder A was measured. The weight of the extracted powder A was 26 mg, and the extract A contained 6.3 g of solid content. The extract A was allowed to cool to 25 ° C. and passed through a column packed with 15 g of chitin resin (manufactured by Nacalai Tesque). Next, this column was washed with 200 mL of purified water, and the passing solution and the washing solution were combined to obtain 1.4 L of a treatment solution B containing proanthocyanidins. Furthermore, a part of the treatment liquid B was concentrated under reduced pressure, and the weight of the obtained treatment powder B was measured. The weight of the processing powder B was 10.4 mg, and the processing liquid B contained 2.9 g of solid content.
Next, the component adsorbed on the chitin resin was eluted from the column using a 60-80% (V / V) water-ethanol mixed solvent to obtain 200 mL of eluate C. Next, the eluate C was concentrated under reduced pressure, and the weight of the obtained powder C was measured. The weight of the powder C was 2.2 g. The treatment liquid B containing proanthocyanidins was passed through a column packed with 50 g of an aromatic synthetic resin (Diaion HP-20: manufactured by Mitsubishi Chemical Corporation), and the proanthocyanidins were adsorbed on the column. The column was washed with 200 mL of purified water, and combined with the passing solution to obtain 1.6 L of a synthetic resin adsorbent passing solution D.
The column was eluted with a gradient of 20 to 100% (V / V) ethanol-water, and 10 mL fractions were collected. 2- to 4-mer OPC preparation (dimer: proanthocyanidin B-2, trimer: proanthocyanidin C-1, tetramer: cinnamtannin A ₂ ) Was used as an index, and OPC in each elution fraction was detected by silica gel thin layer chromatography (TLC).
TLC development conditions and detection methods are as follows.
TLC: Silica gel plate (Merck & CO., Inc.)
Developing solvent: benzene: ethyl formate: formic acid (1: 7: 1)
Detection reagent: sulfuric acid and anisaldehyde sulfuric acid
Sample volume: 10 μL each
It was found that OPC was contained in the fraction eluted with 20 to 40% (V / V) ethanol-water mixed solvent, and these fractions were combined to obtain 400 mL of purified liquid E. Subsequently, this purified liquid E was concentrated under reduced pressure. The weight of the purified OPC powder E obtained was 1.6 g. Using a part of the purified powder E, the OPC content in the purified powder E S. It was 80% (W / W) or more as measured by the method of Thompson et al. (J. Chem. Soc. Perkin Transl., 1387-1399, 1972). The synthetic resin adsorbent passage liquid D was concentrated under reduced pressure, and the weight of the obtained powder D was measured. The weight of the powder D was 0.25 mg, and the synthetic resin adsorbent passage liquid D contained 0.8 g of a solid content. Further, the fractions eluted with 40-100% (V / V) ethanol-water mixed solvent were combined and concentrated under reduced pressure to obtain powder F.
Table 1 shows the yield in each step of producing the proanthocyanidin-containing product.

In addition, the column of anisaldehyde sulfuric acid and sulfuric acid in Table 1 shows the detection result of proanthocyanidins, and the greater the number of +, the greater the content. In this detection, 5 mg of each powder of A to F was dissolved in 1 mL of methanol, developed using silica gel TLC under the above conditions, developed with anisaldehyde sulfuric acid and sulfuric acid, and the transfer rate (R _f ) Detected spots in the range of 0.7 to 1.0.
The OPC content was calculated as follows. First, since the purified powder E contains 80 wt% or more of OPC, the total OPC weight in the purified powder E was assumed to be 80 wt% of the solid content weight (1.6 g) (1.28 g). In the purification process, the OPC content was calculated on the assumption that all OPCs were contained in each solid colored by anisaldehyde sulfuric acid. The solid content that does not develop color was set to 0.0%.
From the results in Table 1, a proanthocyanidin-containing product that is not adsorbed to chitin is obtained by chitin treatment, and this content is treated with a synthetic resin-based adsorbent to adsorb proanthocyanidins, thereby removing impurities. It can be seen that a proanthocyanidin-containing product is obtained. Furthermore, it turns out that 40% or more of OPC is contained in the solid content of the proanthocyanidin-containing material contained in the fraction not adsorbed by chitins.
(Example 2)
1 L of purified water was added to 100 g of pine bark, crushed, and heat-treated at 100 ° C. for 10 minutes. Thereafter, filtration was performed to obtain 1.2 L of extract G. Next, the extract G was allowed to cool to 25 ° C., 15 g of chitin resin was added to the extract G, and the mixture was stirred for 3 hours. After further stirring, the mixture was filtered to obtain 1.2 L of treatment liquid H. Further, this treatment liquid H was concentrated under reduced pressure to obtain 3.36 g of treated powder H. Further, when the treated powder H and the treated powder B were measured by TLC in the same manner as in Example 1, they were colored similarly to the treated powder B and contained about 40% or more of OPC. Further, 3.31 g of the treated powder H was dissolved in 2 L of methanol, passed through a column packed with 50 g of Diaion HP20 in the same manner as in Example 1, adsorbed, and washed with purified water. Next, the column was passed with a gradient of 20 to 100% (V / V) ethanol-water mixed solvent. The flow rate was 1.6L. Fractions eluted with 20-40% (V / V) ethanol-water mixed solvent were combined and concentrated under reduced pressure to obtain 2.15 g of purified powder I. Purified powder I and purified powder E were each detected by TLC in the same manner as in Example 1. As a result, they showed the same color as purified powder E and contained 80% or more of OPC.
(Example 3)
In Example 2, the chitin resin after the contact treatment was concentrated under reduced pressure to obtain 17 g of powder J. Using the obtained powder J, antibacterial activity was measured by a shake flask method. For comparison, antibacterial activity was also measured for powder K of chitin resin not subjected to contact treatment. The measuring method is as follows.
First, monopotassium phosphate (34 g) was dissolved in purified water (500 mL), and 4% (W / V) aqueous sodium hydroxide solution (about 175 mL) was added thereto to adjust the pH to 7.2. Further, a shaking culture solution was prepared by diluting 800 times with purified water.
Staphylococcus aureus was used as a test bacterium. This test strain was transplanted to a brain heart infusion agar slant culture medium and cultured at 37 ° C. for 24 hours. This cultured bacterium is inoculated into a normal bouillon medium using a platinum loop, cultured at 37 ° C. for 6 to 10 hours, and then the number of bacteria is 1.5 to 3 × 10 6 using the normal bouillon medium. ⁸ Adjusted to pieces / mL. Furthermore, this bacterial solution was diluted 1000 times with a phosphate buffer stock solution to obtain an inoculated bacterial solution.
An antibacterial test was performed using the shaking culture solution and the inoculum solution prepared as described above. Six Erlenmeyer flasks with 200 mL screw caps were prepared, shake culture solution (70 mL) was added to each, and the caps were loosely closed, followed by sterilization with an autoclave. After cooling, inoculum (5 mL) was added and stirred well. Finally, the number of bacteria in the Erlenmeyer flask is 1-2 × 10 ⁴ The number per piece / mL. Bacterial liquid (1 mL) was collected from any three of the Erlenmeyer flasks, a 10-fold dilution series was prepared with the test liquid, and a pour agar plate was prepared using a standard agar medium. This plate was cultured at 37 ° C. for 24-48 hours. The number of grown colonies was counted, and the number of viable bacteria (number of initial bacteria) was calculated by multiplying the number of dilutions. The average value of the number of viable bacteria was A.
Next, 350 mg of powder J and powder K were respectively added to three Erlenmeyer flasks each containing the test inoculum, and a total of 6 specimens were simultaneously shake-cultured on a wrist action shaker (rotation speed: 320 to 340 rpm) for 1 hour. After shaking culture, a bacterial solution (1 mL) was collected from each Erlenmeyer flask, a pour agar plate was prepared in the same manner as described above, and the number of viable bacteria was measured. This average number of viable bacteria was defined as B.
When the sterilization rate was calculated from the obtained values A and B as {(AB) / A} × 100, the sterilization rate of powder K was 93%, whereas the sterilization rate of powder J was 29%. From the above, it can be seen that the chitin resin after the contact treatment has high antibacterial activity.
Industrial applicability
By the method of the present invention, a proanthocyanidin-containing product containing a high proportion of highly bioactive OPC can be effectively obtained. In particular, a proanthocyanidin-containing product having a higher OPC content can be provided by employing a method including a step of treating with a synthetic resin adsorbent. This proanthocyanidin having a high OPC content is effective in improving blood vessel enhancement, hypertension, coldness, etc., and is used as a raw material for producing foods, cosmetics and pharmaceuticals.

[Claims]
[Claim 1]
(a) obtaining a extract by extraction with hot water or organic solvent from pine bark; and (b) a said extract, chitin comma others in contact with the derivative of its, recovering the non-adsorbed product A method for producing a proanthocyanidin-containing product.
[Claim 2]
The method according to claim 1, further comprising the step of (c) bringing the non-adsorbed product obtained in the step (b) into contact with a synthetic resin-based adsorbent.

[Claims]
[Claim 1]
(a) obtaining an extract from pine bark by extraction with hot water or an organic solvent; and (b) contacting the extract with chitin or a chitin resin to recover non-adsorbed matter. A method for producing a proanthocyanidin-containing product having an oligomeric proanthocyanidin content higher than that of the extract .
[Claim 2]
The method according to claim 1, further comprising the step of (c) bringing the non-adsorbed product obtained in the step (b) into contact with a synthetic resin-based adsorbent.

Claims (6)

(A) a step of obtaining an extract or juice from a plant by extraction or pressing; and (b) a step of bringing the extract or juice into contact with chitin, chitosan, or a derivative thereof, and collecting a non-adsorbed product. A method for producing a proanthocyanidin-containing product. The method of claim 1, wherein the extraction is hot water extraction. Furthermore, (c) The method of Claim 1 or 2 including the process of making the non-adsorbent obtained by the said process (b) and a synthetic resin type adsorbent contact. A proanthocyanidin-containing product obtained by the method according to claim 1. The proanthocyanidin-containing product according to claim 4, wherein oligomeric proanthocyanidin is contained in a solid content of the proanthocyanidin-containing product in a proportion of 40% by weight or more. An antibacterial agent obtained by bringing an extract or juice obtained from a plant body into contact with chitin, chitosan, or a derivative thereof, and then recovering an insoluble component containing the chitin, chitosan, or a derivative thereof.