KR20010103921A - Process for separating and recovering protein and isoflavones from a plant material - Google Patents

Abstract

The present invention relates to an improved method for separating and recovering protein and isoflavones from plant material containing proteins and isoflavones. In this method, purified protein extracts of plant materials are prepared and contacted with a polar ion exchange resin to allow the isoflavones in the extract to bind with the ion exchange resin and deplete the extract of the isoflavones. Isoflavone depleted protein extracts are separated from the ion exchange resin and isoflavone depleted protein material is recovered from the isoflavone depleted extract. After the isoflavone depleted extract is removed from the resin, the isoflavones are separated and recovered from the ion exchange resin. The recovered isoflavone glycosides and isoflavone glycoside conjugates can be converted to their corresponding nonsaccharide isoflavone forms.

Description

PROCESS FOR SEPARATING AND RECOVERING PROTEIN AND ISOFLAVONES FROM A PLANT MATERIAL}

The present invention relates to a method for separating and recovering protein and isoflavones from plant material containing protein and isoflavones, more specifically, to separating and recovering protein and isoflavones from plant material using ion exchange. It is about.

Plant proteins provide important nutrients worldwide. Soybeans, for example, are excellent sources of nutrition for humans and animals. Soy protein is commercially extracted from soybeans to provide an inexpensive and nutritious protein source. Isolated soy protein can be used in many food fields with its nutritional benefits as well as the functional properties that make it suitable for food or beverage. Some conventional foods using soy protein include minced meat, emulsified meat and pickled meat; Beverages such as nutritional drinks, sports drinks, protein enriched drinks, juices, milk, milk substitutes, and weight loss drinks; Cheeses such as hard cheeses, soft cheeses, cream cheeses and cottage cheeses; Frozen desserts such as ice cream, cold milk, low fat frozen desserts and non-dairy frozen desserts; yogurt; Soup; Pudding; Confectionery; Salad dressing; And dips and spreads such as mayonnaise and chip dips.

Certain plants, such as soybeans, peas, green beans and other legumes, contain isoflavones as well as proteins. Isoflavones are phytoestrogens compounds that have been found to provide humans with a variety of health benefits. For example, the isoflavones present in soybean are genistein, daidzein, glycidin, formmononetin, and their natural glycosides and glycoside conjugates shown in formula (1). As used herein, "Mal" means "malonyl" and "Ac" means "acetyl". Another biologically active isoflavone found in plants other than soybean is Biocanin A, shown in Formula 1.

compound R ₁ R ₂ R ₃ R ₄ Genistein OH H OH OH Diyzein OH H H OH Glycinein OH OCH ₃ H OH Biocanine A OH H OH OCH ₃ Formononetine OH H H OCH ₃

compound R ₁ R ₂ R ₃ R ₄ Genistin H H OH OH 6'-OMal Genesti COCH ₂ CO ₂ H H OH OH 6'-OAc Genistin COCH ₃ H OH OH Dijin H H H OH 6'-OMal Dijin COCH ₂ CO ₂ H H H OH 6'-OAc Diazine COCH ₃ H H OH Glycidine H OCH ₃ H OH 6'-OMal glycidine COCH ₃ OCH ₃ H OH

The health benefits associated with isoflavones are numerous and can still be found. For example, some of these isoflavones have been shown to inhibit the development of breast and prostate cancer and to induce apoptosis in breast and prostate cancer cells. Isoflavones extracted from soybeans also inhibit the development of atherosclerosis, lower the blood serum concentrations of total cholesterol and low density lipoprotein cholesterol, alleviate or prevent menopausal symptoms, inhibit the development of Alzheimer's disease, It has also been shown to inhibit bone loss.

Isoflavones are associated with the bitter and fishy taste of soybeans containing significant amounts of this compound. Therefore, it is desirable to isolate and recover the delicious protein material depleted of isoflavones and the health benefits of isoflavones from the plant material containing isoflavones and proteins.

Methods for separating isoflavones from plant materials containing proteins and isoflavones are known in the art. For example, US Pat. No. 5,679,806 discloses a method for extracting, isolating and purifying isoflavones from plant materials, which method extracts isoflavones from plant materials by extracting the plant material with an alcohol solvent; Alcohol extracts containing isoflavones are adsorbed onto the reversed phase matrix and then specifically desorbed isoflavones from the matrix by stepwise elution (isoflavones crystallized from the recovered eluate). Japanese Patent No. 1-258669 discloses soybean soaked in warm water to convert isoflavones into its aglycone type; Reflux extraction of the non-saccharide isoflavones from the soybean material with an aqueous alcohol; Condensation and drying of the extracted liquid; The dried material is dissolved in alcohol and attached to the reverse phase resin; A method of eluting isoflavones from an resin with an aqueous alcohol is presented.

While these methods are sufficient to separate and purify isoflavones from plant material, they do not provide a method for recovering purified protein material and isoflavones from plant material including both isoflavones and proteins. Both methods use an alcohol solvent to extract isoflavones from plant materials. Plant proteins, such as soy protein, remain substantially insoluble in alcoholic solutions and remain as residual by-products from alcohol extraction along with other plant materials that are insoluble in alcohol, such as plant fiber materials.

US Pat. No. 4,428,876 discloses a method for separating plant proteins and flavonoids including isoflavones from plant materials containing flavonoids and proteins. The plant material is extracted with an aqueous alkaline solution to form an extract containing flavonoids and proteins, and the extract is extracted from non-extractable and insoluble plant materials. The extract is applied as such or after acidification onto a nonpolar or weakly polar adsorbent resin to adsorb the flavonoids on the resin. Acidification causes protein to precipitate from the extract. Once acidified, the precipitated protein is separated from the extract before applying the extract on the resin. After applying the extract on the resin, the resin is eluted with water, the eluate is collected to obtain an eluate containing carbohydrates, and unless acidified, a protein is obtained. If the protein is not precipitated and separated from the extract prior to application on the resin, the water eluate is acidified to precipitate and separate the protein. The resin is then eluted with a polar solvent such as methanol or ethanol and the eluate is concentrated to separate the flavonoids from the resin.

Using the method of US Pat. No. 4,428,876, the isoflavones and carbohydrates / proteins are not cleanly separated due to the nature of the resins and eluates and isoflavones used in the method. As shown in formulas (1) and (2), isoflavones are relatively polar compounds, especially their natural glycosides or glycoside conjugate forms. Due to its polarity, isoflavones are weakly adsorbed to resins of nonpolar or weak polarity. In aqueous environments, proteins and carbohydrates are also relatively polar solvents that do not bind particularly strongly to resins. Therefore, the adsorption of isoflavones, carbohydrates, and proteins to the resins causes the compounds to dissolve upon resin elution with a solvent, since the compounds are easily substituted from the resins and are not particularly differentiated from each other by interaction with the resins. It is not effective enough to separate well.

The method of US Pat. No. 4,428,876 describes a method for separating a portion of isoflavones from proteins and carbohydrates due to the relative solubility of isoflavones in the eluate. For example, if the eluate initially used is water, and the extract is an extract of soybeans (especially containing isoflavone genistein and dizin), then the genistein is only slightly soluble in water, so it is less likely to be consumed by proteins and carbohydrates. Although eluted, diazine is eluted by proteins and carbohydrates because it is water soluble.

Therefore, there is a need for an effective and commercially available method for cleanly separating and recovering protein and isoflavones from plant materials containing protein and isoflavones.

The present invention provides an improved method of separating and collecting isoflavones and proteins from plant materials, which can be efficient and economical on a commercial scale. The method comprises contacting a purified plant protein extract containing isoflavones and protein with a polar ion exchange resin; Coupling isoflavones with a polar ion exchange resin; Separating and recovering the protein extract depleted of isoflavone from the ion exchange resin; And isolating and collecting isoflavones and plant proteins by separating and recovering isoflavones from the ion exchange resin. In a preferred embodiment, the isolated and recovered isoflavones are converted to their non-saccharide form.

An important feature of the present invention is that the isoflavones are separated from the plant protein by contacting the purified plant protein extract with a polar ion exchange resin rather than a nonpolar or weakly polar resin. The use of polar ion exchange resins greatly promotes the clean separation and collection of proteins and isoflavones because isoflavones are strongly adsorbed to polar resins due to their polarity, and are well classified from proteins upon elution of the extract through the resin.

Another important feature of the present invention is that both isoflavone depleted protein material and isoflavones are collected, not just one of each. The present invention uses purified protein extracts as substrates to contact polar ion exchange resins. Purified protein extracts contain significant amounts of protein and isoflavones, unlike isoflavones and alcoholic extracts of plant material containing proteins. Since two preferred materials in the plant material are separated and recovered at the same time, the use of the method of the present invention provides a significant economic effect.

Purified plant protein extracts for use in the methods of the present invention can be prepared by extracting plant material containing protein and isoflavones with an aqueous extractant having a pH above the isoelectric point of the protein for dissolving the protein and isoflavones in the extractant. Can be. Liquid extractants containing dissolved isoflavones and proteins are separated from plant materials, such as lignans, cellulose, plant fibers and insoluble hemicellulose, which do not dissolve in the extractant to form a clarified extract. The clarified extract is preferably separated from the insoluble plant material by filtration or centrifugation and decantation of the extract which is the supernatant from the insoluble material. The resulting purified protein extract is selected from soluble proteins derived from plant materials, and isoflavone compounds selected from genistein, dizein, glycidine, biocanin A, formoninetin and its natural glycosides and glycoside conjugates. One or more, and substantially no insoluble protein material. Isoflavone glycoside herein refers to a compound comprising a glucose moiety covalently bonded to the non-saccharide isoflavone moiety, and isoflavone glycoside conjugate refers to isoflavone glycoside ester, compound 6 "-O-Mal Geni Stine, 6 "-O-Ac Genistin, 6" -O-Mal Dizin, 6 "-O-Ac Dizin and 6" -O-Mal Glycithin.

Plant materials containing proteins and isoflavones that can be used to form clarified extracts include flowering plant materials such as soybeans, chick peas, peanuts, marama beans and sword beans. ), Jack bean, beach bean, caraobean, cluster bean, hyacinth bean, grass pea, pea pea, djenko bean, Goa beans, yam beans, broad beans, earth peas, lentils, jumping beans, velvet beans, African grasshopper beans, other beans and derivatives of these plant materials For example, but not limited to, one or more materials of skim soy flakes, soy flour and coarse soy flour. The plant material is most preferred soybean material or soybean derivatives, most preferably commercially skimmed soybean flakes, due to the high protein and isoflavone content present in soybeans.

In a most preferred embodiment, clarified soy protein extracts are prepared for use in the methods of the present invention. Commercially available soy flour, coarse soy flour, fine soy flour, or skim soy flakes are used as starting materials. Soybean materials are preferably treated with sulfides such as sodium sulfite for improved flow characteristics and improved microbial control. The soybean material is extracted with an aqueous solution having a pH of about 6 to about 12, preferably with an aqueous sodium hydroxide solution having a pH of about 8 to about 11. The weight ratio of extractant to soybean material is from about 3: 1 to about 20: 1, with about 8: 1 to about 16: 1 being preferred. The clarified soy protein extract is preferably separated from the insoluble soybean material by filtration or centrifugation and decantation of the extract from the insoluble material.

According to the method of the present invention, the purified protein extraction solution is contacted with a polar ion exchange resin to allow isoflavones in the extract to bind with the resin. The resin is preferably filled in a column having an inlet and an outlet, where the extract is contacted with the resin by loading the extract onto the resin through the inlet of the column, and the eluted extract is collected from the resin at the outlet of the column.

It is preferred to use an anion exchange resin in the process, although weak base anion exchange resins can be used, but type II macropore base anion exchange resins are most preferred. Type II strong base anion exchange resin as used herein is defined as a tetravalent ammonium type resin wherein four substituents of the nitrogen atom are one ethanol group, two methyl groups and one polymer benzyl group. Commercially available Type II strong base anion exchange resins include IRA 910 available from Rohm and Haas, Independence Mall West, Philadelphia, 19105; Dow 22, commercially available from Dow Chemical U.S.A., Willard H. 2040, Midland Dow Center, 48674, Michigan; And Ionak A651, available from Sibronn, 08011 Birmingham, Birmingham, Road Cibron Chemical Division, NJ. A commercially available weak base anion exchange resin that can be used in the process of the invention is Duolite A-7 from Rohm and Haas.

Suitable methods for conditioning polar anion exchange resins are set forth in US Pat. No. 5,248,804, which is incorporated herein by reference. Preferred techniques for controlling anion exchange resins include exposing the resin to a formulation that strips the residue of the resin and converts the resin to hydroxide form, and then exposes the resin to a formulation that converts the resin to a chloride or sulfate form, Converting at least a portion to the carbonate form and exposing the weak base to the free base form. Suitable formulations which strip the surface of the resin of the residue and convert the resin into the hydroxide form are sodium hydroxide solutions. Suitable formulations for converting the resin into the chloride form are hydrochloric acid, preferably one solution of hydrochloric acid, and suitable formulations for converting the resin into the sulfate form are sulfuric acid, preferably monosulfuric acid. Examples of suitable agents for converting at least a portion of the strong base into the carbonate form and the weak base into the free base form are sodium carbonate, sodium bicarbonate and ammonium hydroxide.

The purified protein extract was contacted with an ion exchange resin to allow the isoflavones to bind with the resin, and then the isoflavone was depleted from the ion exchange resin, preferably by eluting the resin into an aqueous solution adjusted to the pH of the extract and collecting the eluate. Protein extracts are isolated and collected. In a preferred embodiment, at least most of the protein material of the clarified extract is collected in the eluate as isoflavone depleted protein extract. More preferably, substantially all of the material of the protein material in the clarified extract is collected in the eluate as an isoflavone depleted protein extract, wherein the term "substantially all" means 80 or more, more preferably It means over 90. If desired, isoflavone depleted protein material may be recovered from the extract by spray drying the extract.

In a preferred embodiment, the isoflavone depleted protein material can be precipitated from isoflavone depleted protein separated and collected from the ion exchange resin. The pH of the extract is adjusted near the isoelectric point of the protein, which precipitates the protein. If the protein in the extract is soy protein, the extract may be adjusted to a pH of about 4 to about 5 to precipitate the protein. Precipitated protein can be neutralized by adjusting the pH of the extract containing it to about 7. The precipitated protein, whether neutralized or not, is separated from the liquid portion of the extract by conventional means, preferably by filtration or centrifugation and decantation of the liquid portion of the extract from the protein precipitate. The isolated isoflavone depleted protein material is dried by conventional means, preferably by spray drying.

After separation of the isoflavone depleted protein containing the extract from the ion exchange resin, the resin is preferably methanol, ethanol, propanol, isopropyl alcohol, isobutyl alcohol, butanol, ethyl acetate, acetonitrile, acetone, Isoflavones are separated and collected from the resin by eluting with a solvent selected from an aqueous mixture, methylene chloride, chloroform, carbon tetrachloride or any mixture of these solvents, and collecting the eluate containing isoflavones. In a preferred embodiment, at least most of the isoflavones in the clarified protein extract are recovered from the ion exchange resin in the isoflavone containing eluate and substantially all of the isoflavones in the purified protein extract are recovered in the isoflavone containing eluate, Here, "substantially all" means 80 or more, more preferably 90 or more.

Isoflavones can be recovered from the isoflavone-containing eluate separated from the resin by concentrating the isoflavone-containing eluate. In one aspect, the isoflavone containing eluate is concentrated under vacuum, heating or both conditions to remove solvent to provide a residue of concentrated isoflavones. In another embodiment, the eluate is concentrated to about 10-25 of its original volume under vacuum, heating or both conditions. At least an equal volume of water, preferably cooled to a temperature of about 2 ° C. to about 15 ° C., is added to the concentrated eluate to precipitate the isoflavones. Precipitated isoflavones can be recovered from the eluate / water mixture by filtration or centrifugation.

In the most preferred embodiment, the isoflavones in the collected isoflavone containing eluate are treated so that substantially all isoflavones in the eluate are non-saccharide isoflavones. Non-saccharide isoflavones have been found to be biologically significantly more active in the field of health use than natural glycoside or glycoside conjugate forms, and it is therefore desirable to recover isoflavones in their non-saccharide form. Non-saccharide isoflavones are also less soluble in water than their glycoside or glycoside conjugate forms, and thus the non-saccharide isoflavones can be more easily separated from the isoflavone containing eluate.

Isoflavone glycoside conjugates in isoflavone containing eluates can be converted to isoflavone glycosides by treating the isoflavone containing eluate for a period of time under temperature and pH conditions effective to effect the conversion. The pH range for converting isoflavone glycoside conjugates to isoflavone glycosides in isoflavone containing eluates is from about 6 to about 13.5. The pH of the isoflavone containing eluate should be adjusted to the desired pH with a suitable basic or acidic reagent as needed. The conversion of isoflavone glycoside conjugates to isoflavone glycosides has been found to be catalyzed by a base, and therefore high pH is most preferred to achieve rapid conversion. The most preferred pH for the conversion of isoflavone glycoside conjugates to isoflavone glycosides is from about 9 to about 11.

The temperature range for the conversion of isoflavone glycoside conjugates to isoflavone glycosides in the isoflavone containing eluate is from about 2 ° C to about 121 ° C. The temperature range over which conversion occurs easily depends on the pH of the isoflavone containing eluate. The conversion occurs more easily at lower temperatures when the pH is relatively high. For example, at pH about 11, the conversion occurs quickly and efficiently in the temperature range of about 5 ° C to about 50 ° C. At pH about 9 the conversion takes place efficiently in the temperature range of about 45 ° C to about 75 ° C. If the pH of the isoflavone containing eluate is relatively low, the conversion takes place at higher temperatures. For example, at pH about 6, the conversion takes place in the temperature range of about 80 ° C to about 121 ° C. In the most preferred embodiment, the conversion is carried out at a pH of about 11 and a temperature of about 35 ° C.

The time required for conversion of isoflavone glycoside conjugates to isoflavone glycosides depends primarily on the pH and temperature range used to effect the conversion. Such conversion time is about 15 minutes to several hours or more. Conversion occurs more rapidly at higher pH and temperature. In the most preferred embodiment, substantially all isoflavone glycoside conjugates are converted to isoflavone glycosides in about 30 minutes to about 1 hour at pH about 11 and temperature about 35 ° C.

The isoflavone glycosides in the isoflavone containing eluate are preferably converted to isoflavone glycoside conjugates to isoflavone glycosides, and then the isoflavone glycosides in the isoflavone containing eluate for a certain time By contacting the β-glucosidase enzyme, which is effective for cleavage of 1,4-glucoside bonds, to its corresponding non-saccharide isoflavones. Such enzymes may be derived, for example, from Aspergillus niger , Aspergillus oryzae, Kluyveromyces lactis and Kluyveromyces fragilis . . Particularly preferred commercial enzymes that are effective in converting isoflavone glycosides to non-saccharide isoflavones are 100L of biofectinase (preferably at about pH 3 to about 6), 300L of biopeptinase (optimum pH about 3 to about) 6), biopectase OK 70L (optimum pH about 3 to about 6), biolactase 30,000 (optimum pH about 3 to about 6) and neutral lactase 30,000 (optimal pH about 6 to about 8) All are available from 342 International Sarasota Post Office Box 3917 57th Street, 1833, Quest International, Florida. Lactase F (preferably in the pH range of about 4 to about 6) and lactase 50,000 (optimum pH range of about 4 to about 6) are also particularly preferred, both of which are Amano International, 22974 Troy Post Office Box 1000, Virginia. Commercially available from Enzyme Company. Other particularly preferred enzymes include lactozyme 3000L (preferably in the pH range of about 6 to about 8) and alpha-gal available from Novo Nordisk Bioindustry, Inc. 06813 Danbury Turner Road 33, Connecticut. 600L (preferably in the pH range of about 4 to about 6.5); MaxiLact L2000 (preferably in the pH range of about 4 to about 6), available from Gist Brocade Foods Inc., 19406 King of Prussia, Pennsylvania; Neutral Lactase (preferably in the pH range of about 6 to about 8), commercially available from the Fudge Food Science Group, East 42nd Street, 205, New York, NY 10017; And Enzeco Fungal Lactase Concentrate (preferably in the pH range of about 4 to about 6) commercially available from Enzyme Development Corporation, 1039 New York Suite 2439 Penn Plaza 2, New York. Certain gluco-amylase enzymes may be used in place of or in combination with the enzymes described above. The commercial gluco-amylase enzyme that performs the conversion is G-zyme G990, which is commercially available from Enzyme Development Corporation (preferably in the pH range of about 4 to about 6). In order to carry out the conversion, it is preferred to add about 0.1% to about 10% of the enzyme material to the isoflavone containing eluate.

The pH range for the conversion of isoflavone glycosides to non-saccharide isoflavones in isoflavone containing eluate is about 3-9. The pH used depends primarily on the type of enzyme used and should be selected accordingly. Typically the enzyme is active at neutral pH about 6-8 or at acidic pH about 3-6. The pH of the isoflavone containing eluate can be adjusted to a suitable pH range with conventional acidic and basic reagents.

The temperature range for the conversion of isoflavone glycosides to non-saccharide isoflavones is from about 5 ° C to about 75 ° C. The temperature has a significant effect on the activity of the enzyme and therefore also on the conversion if higher temperatures increase the conversion. The enzyme may be active above 70 ° C., for example Alpha-Gal 600L is active at 75 ° C., but undergoes conversion at slightly lower temperatures, preferably from about 50 ° C. to about 65 ° C. It is desirable to avoid.

The time required to effect the conversion of isoflavone glycosides to non-saccharide isoflavones depends on the enzyme related factors, in particular the enzyme activity and concentration, as well as the temperature and pH of the system. The conversion of substantially all isoflavone glycosides to non-saccharide isoflavones is preferably carried out within 5 hours, more preferably within about 1 to 2 hours.

The resulting non-saccharide isoflavones can be separated from the isoflavone containing eluate as described above. Since non-saccharide isoflavones have lower solubility in water than their corresponding isoflavone glycoside conjugates or isoflavone glycosides, non-saccharide isoflavones are more readily separated from the concentrated isoflavone containing eluate with cooling water. do.

It will be apparent to those skilled in the art that various modifications to the preferred embodiments of the invention can be made without departing from the spirit or scope of the invention as defined by the appended claims.

The method of the present invention separates the isoflavones from the plant protein by contacting the purified plant protein extract with a polar ion exchange resin that is not a nonpolar or weakly polar resin. The use of polar ion exchange resins greatly promotes the clean separation and collection of proteins and isoflavones because isoflavones are strongly adsorbed to polar resins due to their polarity, and are well classified from proteins upon elution of the extract through the resin.

According to the method of the present invention, both the protein material depleted of isoflavones and the isoflavones are collected, not just one of each. Since two preferred materials in the plant material are separated and recovered at the same time, the use of the method of the present invention provides a significant economic effect.

Claims (38)

Contacting the purified plant protein extract containing isoflavones with a polar ion exchange resin; Contacting and binding the isoflavone with an ion exchange resin to deplete the isoflavone from the protein extract; Separating and collecting the protein-containing extract depleted of isoflavones from the ion exchange resin; And isolating and collecting said isoflavones from an ion exchange resin. Isolating and recovering isoflavones and plant proteins from plant material containing proteins and isoflavones. The method of claim 1, further comprising the step of precipitating the protein by adjusting the pH of the protein-containing extract depleted of isoflavones near the isoelectric point of the protein, isoflavones from the plant material containing the protein and isoflavones. And methods for isolating and recovering plant proteins. The method for separating and recovering isoflavones and plant proteins from plant material containing protein and isoflavones according to claim 2, wherein the protein is soy protein and the pH is adjusted to about 4 to about 5. Way. The method for separating and recovering isoflavones and plant proteins from plant material containing proteins and isoflavones according to claim 2, wherein the precipitated protein is separated from the liquid portion of the extract. The method for separating and recovering isoflavones and plant proteins from plant material containing proteins and isoflavones according to claim 4, characterized in that it neutralizes the precipitated protein separated from the liquid part of the extract. The method for separating and recovering isoflavones and plant proteins from plant material containing proteins and isoflavones according to claim 4, characterized in that the precipitated protein separated from the liquid part of the extract is dried. The method for separating and recovering isoflavones and plant proteins from plant material containing proteins and isoflavones according to claim 1, wherein the polar ion exchange resin is an anion exchange resin. 8. Isoflavones and plant proteins are separated from plant material containing proteins and isoflavones according to claim 7, characterized in that the anion exchange resin is a type II macroporous anion exchange resin selected from the group consisting of weak base and strong base anion exchange resin. And recovery. The method of claim 1, wherein prior to contacting the purified protein extract with the ion exchange resin, the resin is adjusted to an agent that converts the resin into hydroxide form to control the ion exchange resin, and the resin in hydroxide form is in the form of chloride or sulfate Iso-isolated from plant materials containing proteins and isoflavones characterized by treating the resin in hydroxide form with a preparation for conversion into a carbonate, and treating the resin in chloride or sulphate form with a preparation for converting at least a portion of the strong base of the resin into a carbonate form. Method for isolating and recovering flavones and plant proteins. The isoflavone according to claim 1, wherein the isoflavone comprises at least one of isoflavone compounds selected from genistein, diezein, glycinete, biocanin A, formonenetine and its natural glycosides and glycoside conjugates. A method for isolating and recovering isoflavones and plant proteins from plant material containing proteins and isoflavones characterized by the above-mentioned. The plant material containing protein and isoflavone according to claim 1, wherein the isoflavone is separated and collected from the ion exchange resin after the isoflavone depleted protein-containing extract is separated and collected from the ion exchange resin. Method for isolating and recovering isoflavones and plant proteins from. 12. The solvent of claim 11 wherein the solvent is selected from methanol, ethanol, propanol, isopropyl alcohol, isobutyl alcohol, butanol, ethyl acetate, acetonitrile, acetone, methylene chloride, chloroform, carbon tetrachloride or mixtures thereof. A method for separating and recovering isoflavones and plant proteins from plant material containing proteins and isoflavones, characterized in that the isoflavones are separated from the ion exchange resin by washing the isoflavones. The method of claim 1 wherein the isolated isoflavones are treated for a period of time at a temperature and pH effective to convert the isoflavone glycoside conjugates to isoflavone glycosides from plant material containing protein and isoflavones. Method for isolating and recovering isoflavones and plant proteins. The method of claim 1, further comprising contacting said isolated isoflavone with a β-glucosidase enzyme for a period of time at a temperature and pH effective to convert the isoflavone glycoside conjugate to a non-saccharide isoflavone. A method for isolating and recovering isoflavones and plant proteins from plant material containing proteins and isoflavones characterized by the above-mentioned. 2. The plant material of claim 1, wherein at least a majority of the protein in the purified plant protein extract is separated and recovered from the ion exchange resin in the isoflavone depleted protein containing extract from the plant material containing the protein and isoflavone. Method for isolating and recovering isoflavones and plant proteins. 16. The plant material of claim 15, wherein substantially all of said protein in said purified plant protein extract is separated and recovered from said ion exchange resin in said isoflavone depleted protein containing extract. Method for isolating and recovering isoflavones and plant proteins. 2. Isolation and recovery of isoflavones and plant proteins from plant material containing proteins and isoflavones according to claim 1, characterized in that at least a majority of said proteins in said purified plant protein extracts are separated and recovered from said ion exchange resin. How to. 18. The method of claim 17, wherein isoflavones and plant proteins are separated from plant material containing proteins and isoflavones, characterized in that substantially all of the isoflavones in the purified plant protein extract are separated and recovered from the ion exchange resin. How to recover. Preparing a purified protein containing dissolved plant protein and isoflavones and substantially free of insoluble protein material; Contacting the clarified protein extract with a polar ion exchange resin; Combining the isoflavones with the ion exchange resin to deplete the isoflavones in the protein extract; Separating and recovering the isoflavone depleted protein extract from the ion exchange resin; And separating and recovering the isoflavone from the ion exchange resin, wherein the isoflavone and plant protein are separated and recovered from the plant material containing the protein and isoflavone. 20. The method of claim 19, wherein the clarified plant protein extract comprises extracting a plant material containing protein and isoflavones with an aqueous extractant having a pH above the isoelectric point of the protein for dissolving the protein and isoflavones in the extractant; A method for isolating and recovering isoflavones and plant proteins from plant material containing proteins and isoflavones, which is then prepared by separating liquid extracts containing dissolved proteins and isoflavones from insoluble plant material. 21. The method of claim 20, wherein the plant material is selected from the group consisting of soy flakes, soy flour, coarse soy flour, fine soy flour, soybeans or mixtures thereof; The pH of the aqueous extractant is about 6 to about 12; A method for separating and recovering isoflavones and plant proteins from plant material containing proteins and isoflavones characterized in that the purified protein extract is soy protein extract. 20. The isoflavone of claim 19, further comprising the step of precipitating the protein by adjusting the pH of the protein-containing extract depleted of isoflavone to near the isoelectric point of the protein. And methods for isolating and recovering plant proteins. 23. The method for separating and recovering isoflavones and plant proteins from plant material containing proteins and isoflavones according to claim 22, wherein the plant protein is soy protein and the pH is adjusted to about 4 to about 5. Way. 23. The method for separating and recovering isoflavones and plant proteins from plant material containing proteins and isoflavones according to claim 22, characterized in that the precipitated protein is separated from the liquid portion of the isoflavone depleted protein containing extract. The method for separating and recovering isoflavones and plant proteins from plant material containing proteins and isoflavones according to claim 24, characterized in that it neutralizes the precipitated protein separated from the liquid part of the extract. The method for separating and recovering isoflavones and plant proteins from plant material containing proteins and isoflavones according to claim 24, characterized in that the precipitated protein separated from the liquid part of the extract is dried. The method of claim 19, wherein the polar ion exchange resin is an anion exchange resin. 20. The method for isolating and recovering isoflavones and plant proteins from plant materials containing proteins and isoflavones. 28. The isoflavone and plant protein of claim 27, wherein the anion exchange resin is a type II macroporous anion exchange resin selected from the group consisting of weak bases and strong base anion exchange resins. And recovery. 20. The method of claim 19, wherein prior to contacting the purified protein extract with an ion exchange resin, the resin is adjusted to an agent that converts the resin into hydroxide form to control the ion exchange resin, and the resin in hydroxide form is in the form of chloride or sulfate salts. Iso-isolated from plant materials containing proteins and isoflavones characterized by treating the resin in hydroxide form with a preparation for conversion into a carbonate, and treating the resin in chloride or sulphate form with a preparation for converting at least a portion of the strong base of the resin into a carbonate form. Method for isolating and recovering flavones and plant proteins. 20. The isoflavone of claim 19, wherein the isoflavone comprises at least one of isoflavone compounds selected from genistein, diezein, glycinete, biocanin A, formonenetine and its natural glycosides and glycoside conjugates. A method for isolating and recovering isoflavones and plant proteins from plant material containing proteins and isoflavones characterized by the above-mentioned. 20. The plant material containing protein and isoflavone according to claim 19, wherein the isoflavone is separated and collected from the ion exchange resin after the isoflavone depleted protein containing extract is separated and collected from the ion exchange resin. Method for isolating and recovering isoflavones and plant proteins from. 32. The solvent of claim 31 wherein the solvent is selected from methanol, ethanol, propanol, isopropyl alcohol, isobutyl alcohol, butanol, ethyl acetate, acetonitrile, acetone, methylene chloride, chloroform, carbon tetrachloride or mixtures thereof. A method for separating and recovering isoflavones and plant proteins from plant material containing proteins and isoflavones, characterized in that the isoflavones are separated from the ion exchange resin by washing the isoflavones. 20. The method of claim 19, wherein the isolated isoflavones are treated for a period of time at a temperature and pH effective to convert the isoflavone glycoside conjugates to isoflavone glycosides. Method for isolating and recovering isoflavones and plant proteins. 20. The method of claim 19, further comprising contacting said isolated isoflavone with a β-glucosidase enzyme for a period of time at a temperature and pH effective to convert the isoflavone glycoside conjugate to a non-saccharide isoflavone. A method for isolating and recovering isoflavones and plant proteins from plant material containing proteins and isoflavones characterized by the above-mentioned. 20. The plant material of claim 19, wherein at least a majority of said protein in said purified plant protein extract is separated and recovered from said ion exchange resin in said isoflavone depleted protein containing extract from said plant material containing protein and isoflavone. Method for isolating and recovering isoflavones and plant proteins. 36. The plant material of claim 35, wherein substantially all of said protein in said purified plant protein extract is separated and recovered from said ion exchange resin in said isoflavone depleted protein containing extract from said plant material containing protein and isoflavone. Method for isolating and recovering isoflavones and plant proteins. 20. The method of claim 19, wherein isoflavones and plant proteins are separated and recovered from plant material containing proteins and isoflavones, wherein at least a majority of the proteins in the purified plant protein extracts are separated and recovered from the ion exchange resin. How to. 38. The method of claim 37, wherein isoflavones and plant proteins are separated from plant material containing proteins and isoflavones, characterized in that substantially all of the isoflavones in the purified plant protein extract are separated and recovered from the ion exchange resin. How to recover.