JP4957470B2 - Method for separating hydrophobic substance using polyvalent anionic cyclodextrin compound, and selective adsorbent for hydrophobic substance - Google Patents

Description

  The present invention relates to a method for separating a hydrophobic substance using the inclusion action of cyclodextrin, and more specifically, a cyclodextrin compound having a plurality of anionic groups and an insoluble polymer molded article having a plurality of cationic groups. The present invention relates to a method for separating hydrophobic substances which do not require complicated operations, and a selective adsorbent for hydrophobic substances used for removing contaminants in water and isolating useful substances.

Cyclodextrin is a cyclic oligosaccharide in which glucose is linked cyclically by α1,4-bonds. Those having 6, 7, and 8 glucose units are called α-, β-, and γ-cyclodextrin, and are industrially manufactured and used.
The cyclodextrin molecule has a characteristic of causing an association phenomenon called “inclusion” that has a hydrophobic cavity in the central portion and traps a hydrophobic substance matching the size of the cavity in the cavity.
The nature of this cyclodextrin is the object of various industrial uses in the fields of food, medicine, cosmetics and the like.
In addition, the inclusion phenomenon of cyclodextrin can be expected to be applied to the removal of pollutants in waste water and river water, separation and purification of useful substances, and optical resolution of optically active substances. However, since cyclodextrin itself is water-soluble, it has been studied to convert it by some means so as to be insoluble in water in order to be used in applications where it is used as an adsorbent in water.

As a conventional technique for converting cyclodextrin to insolubility, for example, a method of obtaining an insoluble epoxy-crosslinked cyclodextrin polymer by crosslinking the hydroxyl group of cyclodextrin with an epihalohydrin which is an epoxy compound or the like is known. As epihalohydrins, epichlorohydrin has been most often used (see, for example, Non-Patent Document 1 and references cited therein).
As described in Non-Patent Document 1 and the cited references, the epoxy-crosslinked cyclodextrin polymer obtained by the above method is a phthalate ester, alkylphenol, or natural environment whose action as an environmental hormone substance has been pointed out. Since it has the property of adsorbing nonionic surfactants such as alkylphenol ethoxylates which are converted into alkylphenols by organisms, these substances can be removed from water.

However, as pointed out in the review of Non-Patent Document 1, the epoxy-crosslinked cyclodextrin polymer obtained by the above method has adsorption selectivity for cyclodextrin because adsorption of a hydrophobic substance to the crosslinked portion occurs. There is one side that can be damaged.
In general, when an insoluble material is used in water, it is easy to handle if the shape of the material is particulate. In the above method, the cyclodextrin polymer is obtained as a lump. However, there is a problem that it is necessary to perform the cross-linking process under special conditions in which a cyclodextrin aqueous solution is dispersed in a solvent such as liquid paraffin to cause a reaction. However, when cyclodextrin is cross-linked with epihalohydrin, by adding a water-soluble silica compound during the reaction, it is possible to easily obtain a granular material without using a solvent that is difficult to wash such as liquid paraffin as described above. It is reported that we can do it, and we are looking at a solution.

  On the other hand, as another technique for converting cyclodextrin to insolubility, a method of fixing cyclodextrin to water-insoluble particles by a chemical reaction has been studied. As the water-insoluble particles, polystyrene resin (for example, see Patent Document 1), silica gel (for example, see Non-Patent Document 2), and crosslinked chitosan beads (for example, see Patent Document 2 and Non-Patent Document 3) can be used. It is reported. A problem in this method is that cyclodextrin immobilization reaction becomes a heterogeneous reaction, and it is difficult to efficiently immobilize cyclodextrin to particles efficiently and in large quantities.

In order to prevent adsorption at sites other than cyclodextrin in the adsorbing material, it is considered promising to immobilize cyclodextrin on a material having high hydrophilicity instead of a hydrophobic material. In this respect, chitosan is considered to be suitable as a material having high hydrophilicity and a functional group for fixing, and many studies are reported as summarized in Non-Patent Document 4. Has reached.
However, the chitosan complex compound obtained by simply chemically bonding cyclodextrin to chitosan and the chitosan complex compound obtained by reacting carboxymethylated cyclodextrin with low molecular weight chitosan in neutral aqueous solution are both water-soluble. (See Non-Patent Documents 5 and 6), Patent Document 2 describes a method of bonding a cyclodextrin compound after cross-linking and insolubilizing chitosan formed into a fibrous shape. Non-Patent Document 3 is a research paper published by the inventor of Patent Document 2 regarding crosslinked chitosan beads.

Therefore, the present inventors converted cyclodextrin into an insoluble form by reacting a cyclodextrin compound having a plurality of carboxyl groups per molecule without previously crosslinking the formed chitosan. A method of simultaneously performing immobilization and crosslinking reaction was invented (see Patent Document 4).
However, in this invention as well, since the reaction between the cyclodextrin compound and chitosan is necessary, the operation becomes complicated, the cost of chemicals necessary for the reaction step is required, and a more inexpensive method has been desired.

On the other hand, in Non-Patent Document 7, ions are introduced into a cyclodextrin compound in which one amino group per molecule is selectively introduced into a cyclodextrin primary hydroxyl group and CM-Sephadex C-25, which is an anionic polymer compound. A method is described for removing bisphenol A from an aqueous bisphenol A solution by forming a bond. This method realizes adsorption removal of bisphenol A without forming a covalent bond between the cyclodextrin compound and the polymer compound, compared to the above-mentioned research and invention related to the conventional cyclodextrin immobilization, It has become a promising technology.
However, when the present inventors examined the technical contents in detail, the method requires a cyclodextrin compound and an expensive anionic polymer compound that require complicated operations for its production, and costs are low for practical use. It is less effective for aqueous solutions containing salts that are expected to inhibit the formation of ionic bonds between cyclodextrin compounds and anionic polymer compounds. There was a problem of concern.
JP 54-61291 A JP 2002-327338 A JP 2003-64103 A JP 2005-281372 A Murai Shoji, PETROTECH, Vol. 26, No. 3, pp. 191-194, 2003 T.A. N. T.A. Phan, M.C. Bacquet, and M.M. Morcellet, Reactive & Functional Polymers, Vol. 52, 117-125, 2002 M.M. Nishiki, T .; Tojima, N .; Nishi, and M.C. Sakairi, Carbohydrate Letters, Vol. 4, No. 1, pp. 61-67, 2000 M.M. Prabaharan and J.M. F. Mano, Chitosan derivatives bearing cyclodextrins cavitesas novel adsorbents matrix Carbohydrate Polymers, 63, 2, 153-166 (2006). Y. Kurauchi, H .; Ono, B.M. Wang, N .; Egashira, and K.K. Ohga, Analytical Sciences, Vol. 13, pp. 47-52, 1997 Etsuko Furusaki, Yoshiharu Ueno, Nobuo Sakairi, Norio Nishi and Seichi Tokyo, Carbohydrate Polymers, Vol. 29, No. 1, pages 29-34. Y. Fukazawa, W .; Bluesab, N.M. Sakairi and T.K. Furike, Chem. Lett. 34, 12, 1652-1653 (2005).

  In view of the above-mentioned problems in the prior art, an object of the present invention is to use a cyclodextrin compound having a plurality of anionic groups (hereinafter sometimes simply referred to as “multivalent anionic cyclodextrin compound”) as an insoluble material. A method of efficiently separating and selectively separating hydrophobic substances such as phenols, and the inclusion of cyclodextrin by the above-described method sufficiently to remove contaminants from a solution such as sewage Another object of the present invention is to provide a substance separation method effective for isolating a useful substance from an aqueous solution of a useful substance, and a selective adsorbent for a hydrophobic substance used in the method.

The present inventors have repeatedly studied to solve the above-mentioned problems, and in the process, focused on the chemical structure of a material molecule having an anionic cyclodextrin compound and a cationic group which is a binding partner thereof.
As a result, when a compound having a plurality of carboxyl groups introduced into the cyclodextrin molecule and an insoluble polymer molded product having a plurality of cationic groups such as amino groups are mixed in water, It has been found that the cationic group of the molecular molded body forms an ionic bond without using an expensive reaction reagent, and the hydrophobic substance in water can be adsorbed and removed by using the obtained ionic bond. For an aqueous solution containing salts such as sodium chloride, the number of carboxyl groups in one molecule of the cyclodextrin compound to be used is 2 to 3 or more. It has been found that the ionic bond with the molecular compact can be strengthened and the adverse effects of salts on the adsorption efficiency can be reduced. Further, the adsorbed hydrophobic substance can be separated again by washing with ethanol or an aqueous solution thereof, and only the hydrophobic substance can be taken out. It has been found that cyclodextrin having a group is bound and can be reused as an adsorbent. Based on these findings, the present invention has been completed.

That is, the present invention
(1) A cyclodextrin compound having a plurality of anionic groups in a molecule and an insoluble polymer molded product having a plurality of cationic groups are bonded via an ionic bond between the anionic group and the cationic group. A method for separating a hydrophobic substance in a solution by the inclusion action of the cyclodextrin compound, which comprises the step of:
(2) Selectively adsorbing a hydrophobic substance after the cyclodextrin compound having a plurality of anionic groups and the insoluble polymer molded body having a plurality of cationic groups are bonded through the ionic bond. The method for separating a hydrophobic substance according to (1), wherein the method is used for separating the hydrophobic substance in a solution as an agent,
(3) The separation method according to (1) or (2), wherein the cyclodextrin compound having a plurality of anionic groups is a compound represented by the following general formula 1:

(In the above general formula, n represents an integer of 6 to 8. Also, R ¹ , R ² and R ³ each represent a hydroxyl group or an anionic group, and each may be the same or different. Good and at least two of the anionic groups in the cyclodextrin compound.)
(4) The separation method according to any one of (1) to (3), wherein the anionic group is a substituent having a carboxyl group.
(5) The separation method according to any one of (1) to (4), wherein the insoluble polymer molded body having a plurality of cationic groups is a molded body made of a chitosan compound.
(6) The separation method according to any one of (1) to (4), wherein the insoluble polymer molded body having a plurality of cationic groups is a molded body made of an ion exchange resin having a polystyrene compound as a skeleton. ,
(7) After adsorbing the hydrophobic substance, which is a substance to be separated, washed with an alcohol represented by the general formula CH ₃ (CH ₂ ) _m OH (m is an integer from 0 to 4) or an aqueous solution of the alcohol. (1) including a step of repeatedly using the insoluble polymer molded body holding the cyclodextrin compound having a plurality of anionic groups via an ionic bond as a selective adsorbent for a hydrophobic substance. The separation method according to any one of to (6),
(8) After adsorbing the hydrophobic substance, which is a substance to be separated, to the insoluble polymer molded body holding the cyclodextrin compound having a plurality of anionic groups via ionic bonds, ethanol or an aqueous solution of ethanol The separation method according to any one of (1) to (6), including a step of recovering the separation target substance by washing with
(9) Binding a cyclodextrin compound having a plurality of anionic groups in the molecule and an insoluble polymer molded product having a plurality of cationic groups via an ionic bond between the anionic group and the cationic group A hydrophobic material selective adsorbent,
(10) The selective adsorbent according to (9), wherein the hydrophobic substance is an endocrine disrupting substance or a hydrophobic component in food, and (11) after adsorbing the hydrophobic substance that is a substance to be separated (9) or (10), which can be reused repeatedly by washing with an alcohol represented by the general formula CH ₃ (CH ₂ ) _m OH (where m is an integer from 0 to 4) or an aqueous solution of the alcohol. The selective adsorbent is provided.

The method for separating a hydrophobic substance of the present invention comprises a cyclodextrin compound having a plurality of anionic groups such as carboxyl groups in the molecule and an insoluble polymer molded body having a plurality of cationic groups such as amino groups. By binding through an ionic bond between the functional group and the cationic group, no complicated and costly production process of an adsorbent that requires a reaction accelerator for forming a covalent bond is required. A water-soluble cyclodextrin can be bound and insolubilized to an insoluble polymer former, and a hydrophobic substance that can be included by the cyclodextrin can be selectively separated from the solution. That is, it is possible to realize an adsorptive separation technique that directly uses the inclusion action of cyclodextrin.
The selective adsorbent of the hydrophobic substance of the present invention exhibits the inclusion action of cyclodextrin and can selectively adsorb pollutants efficiently in a short time, so that pollutants from wastewater and river water It is useful for removal. In addition, application to separation and purification of useful substances from aqueous solutions such as food extracts and optical resolution of optically active substances can be expected.

First, a selective adsorption agent for a hydrophobic substance (hereinafter simply referred to as “selective adsorbent for a hydrophobic substance of the present invention”) used in the method for separating a hydrophobic substance of the present invention will be described.
The hydrophobic material selective adsorbent of the present invention comprises a cyclodextrin compound having a plurality of anionic groups such as carboxyl groups in the molecule, and an insoluble polymer molded article having a plurality of cationic groups such as amino groups, The plurality of anionic groups and the cationic group are bonded through an ionic bond. As the anionic group, a carboxyl group is preferable.
In the present invention, a cyclodextrin compound having the anionic group and an insoluble polymer molded article having the cationic group by containing a plurality of anionic groups such as carboxyl groups that are easily used as reactive functional groups in the molecule, The ionic bond between can be made stronger.
In the cyclodextrin compound having an anionic group such as a plurality of carboxyl groups, the number of anionic groups such as the carboxyl group may be plural, that is, two or more, but preferably three or more. When the number of anionic groups such as carboxyl groups is less than 2, there is no problem with the cyclodextrin compound binding to the insoluble polymer molded product having the cationic group, but salts such as sodium chloride are included. In the case of treatment with an aqueous solution, the cyclodextrin compound tends to dissociate from the insoluble polymer molded product having the cationic group, which is not preferable. In addition, there is no restriction | limiting in particular about the upper limit of anionic groups, such as the said carboxyl group.

Here, as described above, the cyclodextrin serving as the skeleton of the cyclodextrin compound refers to a cyclic oligosaccharide in which glucose is linked cyclically by α1,4-bonds. Those having 6, 7, and 8 glucose units are called α-, β-, and γ-cyclodextrin, respectively. In the present invention, any of α-, β-, and γ-cyclodextrin may be used, and derivatives such as hydroxypropyl derivatives and sugar-branched cyclodextrins may be used.
In the present invention, examples of the cyclodextrin compound having an anionic group such as a plurality of carboxyl groups include those in which at least two of the hydroxyl groups of cyclodextrin are substituted with a substituent having a carboxyl group. A compound represented by Formula 1 is preferred.

In the general formula 1, n represents an integer of 6 to 8. R ¹ , R ² , and R ³ each represent a hydroxyl group or an anionic group, each of which may be the same or different, and at least two of the anionic groups in the cyclodextrin compound. It is. All of R ¹ , R ² and R ³ in the above general formula may be a substituent having a carboxyl group.
In the said General formula 1, it is preferable that the said anionic group is a substituent which has a carboxyl group.
In the case R ^{1, R 2,} R ³ is other than a substituent having a carboxyl group is not particularly limited as long as it does not inhibit the ionic binding of the insoluble polymer mold having a cationic group. Accordingly, cationic groups such as amino groups are not preferred. When no other cyclodextrin modification reaction is performed, it is usually a hydroxyl group.
As a substituent which has a carboxyl group represented by R < ¹ >, R < ² >, R < ³ > in the said General formula 1, it is preferable that it is a substituent represented by either of the following general formulas 2-4, for example.

(In the above general formulas, R ′ represents a linear or branched alkylene group having 1 to 20 carbon atoms or an arylene group having 7 to 30 carbon atoms.)
Specific examples of the substituent having such a carboxyl group include a carboxymethyl ether group; a monoester group of an aliphatic dicarboxylic acid (such as a carboxyethyl monoester group); a monoester group of an aromatic dicarboxylic acid (phthalic acid monoester) Groups, isophthalic acid monoester groups, terephthalic acid monoester groups, etc.); carboxyl group-containing thiol thioether groups (carboxymethyl thioether group, carboxyethyl thioether group, 2-carboxyethyl thioether group, carboxyphenyl thioether group, etc.) Can be mentioned. Examples of the anionic group include a sulfate group and a sulfoalkyl ether group (general formula —O— (CH ₂ ) ₁ —SO ₃ H, where 1 represents 1 to 6) in addition to a carboxyl group. . For example, a β-cyclodextrin compound having a sulfobutyl ether group in which l is 4 is commercially available and can be used in the present invention. Of these substituents having an anionic group, a carboxymethyl ether group is most preferred from the viewpoint of being able to be produced industrially at low cost.

In producing the cyclodextrin compound having a plurality of carboxyl groups, there are no particular restrictions on materials, conditions, procedures, and the like.
Examples of the production of the cyclodextrin compound having a plurality of carboxyl groups include organic acid compounds obtained by halogenating organic acids such as acetic acid and propionic acid, succinic acid, adipic acid, phthalic acid, isophthalic acid, terephthalic acid Substituents containing dicarboxylic acids such as monochloroacetic acid, monobromoacetic acid, or monoiodoacetic acid with cyclodextrin under neutral to alkaline conditions and containing a carboxyl group at the hydroxyl group of cyclodextrin It can be obtained by introducing a group. As a method using monochloroacetic acid, S. Satomura, K .; Omichi, T .; Ikenaka's research paper (Carbohydrate Research, Vol. 180, pages 137-146, 1988) and Makoto Hattori, Yoko Okada, and Koji Takahashi, Vol. Year).

In the above production example, since the hydroxyl group of cyclodextrin is subjected to the reaction, the type of cyclodextrin used as a material is not limited, α-, β-, γ-cyclodextrin and hydroxypropyl derivatives thereof, Any sugar-branched cyclodextrin can be used.
Other production examples include thioglycolic acid, 2-mercaptopropionic acid, thiomalic acid, thiosalicylic acid, 4-mercaptobenzoic acid and other carboxyl group-containing thiols, and halogenated or tosylated cyclodextrin compounds. It can also be obtained by reacting. Also in this case, the kind of cyclodextrin used as a material is not limited.
In the present invention, the cyclodextrin compound having a plurality of carboxyl groups may be a single type or a mixture of two or more types.
In addition, when a carboxyl group is introduced into cyclodextrin by the production method exemplified above, a mixture of cyclodextrin compounds in which substituents having a carboxyl group are introduced into hydroxyl groups at various sites in cyclodextrin can be obtained. In the invention, such a mixture can be used as it is.
In addition, this mixture only needs to contain at least a cyclodextrin compound having a plurality of carboxyl groups in the molecule, and the other is mono-substituted (that is, has only one carboxyl group in the molecule). Even if a carboxyl group-introduced cyclodextrin compound or a cyclodextrin in which no carboxyl group is introduced into the molecule is present, there is no particular problem with using the mixture.

Next, an insoluble polymer molded product having a plurality of groups (cationic groups) that exhibit cationic properties in water such as amino groups will be described.
In the present invention, “insoluble” means that the solubility in water is 5 mass% or less, preferably 1 mass% or less.
Examples of the insoluble polymer molded product having a cationic group such as amino group include, for example, chitosan, anion exchange resins, or one or a mixture of two or more of various polymer compounds commercially available as derivatives thereof. Can be mentioned. Examples of the form of the molded body include various forms such as powder, particles, and fibers, and are not particularly limited.

As such an insoluble polymer molding having an amino group, a molding made of a chitosan compound is preferable. The chitosan compound molded body includes various chitosan particles (for example, chitopearl AL-10 (trade name)) commercially available from Fuji Boseki Co., Ltd. (Published, 1995) Chitosan particles which can be prepared by various methods described in pages 506 to 508 can be used. The molecular weight of the chitosan compound contained in the chitosan particles is not particularly limited, but is preferably 5,000 to 1,000,000.
In the present invention, the term “chitosan” means a product obtained by deacetylating the acetylamino group of chitin, but there is no particular restriction on the degree of acetylation. Chitosan with a degree of acetylation is included.
The molded body of the chitosan compound may be in various forms such as powder, particles, fibers, and films. Moreover, there is no problem even if it is a molded product of a mixture obtained by adding chitosan and other polymer compounds and additives.
In the present invention, among various ion exchange resins commercially available from Organo Corporation, an anion resin can be used. In the present invention, since a cyclodextrin compound into which an anionic group such as a carboxyl group is introduced is used, it is particularly preferable to use a weakly basic ion exchange resin.

Next, the method for separating a hydrophobic substance of the present invention will be described.
In the method for separating a hydrophobic substance of the present invention, the cyclodextrin compound having an anionic group such as a plurality of carboxyl groups and the insoluble polymer molded body having a cationic group such as an amino group are combined with the plurality of anionic groups. It is a method for separating a hydrophobic substance in a solution by the inclusion action of cyclodextrin, which comprises a step of bonding via an ionic bond between a group and the cationic group.
Here, as a solution containing a hydrophobic substance, arbitrary aqueous liquids, for example, aqueous solution (a waste water, river water, a drink etc. are included) etc. are mentioned.
The mixing ratio of the cyclodextrin compound and the cationic polymer molded product can be appropriately determined according to the type and concentration of the substance to be separated.
In this ionic bonding step, if a substance that inhibits ionic bonding between the cyclodextrin compound and the polymer molding is present in the mixed system, the cyclodextrin compound reacts sufficiently with the polymer molding. Even if the cyclodextrin compound forms an inclusion complex with the substance to be separated, the generated inclusion complex remains in the aqueous solution, and the separation efficiency may be reduced. In addition, even when a salt is contained in an aqueous solution containing the substance to be separated, interference of ionic bond formation by the salt may occur. As a countermeasure against these ionic bond formation inhibitions, it is effective to increase the number of carboxyl groups contained in the cyclodextrin compound, as described in detail in Examples below. Regarding the method for producing a cyclodextrin compound having a large number of carboxyl groups, for example, in the production of carboxylmethylated cyclodextrin, it is effective to increase the amount of monochloroacetic acid used as a reaction reagent. There are no particular restrictions on the reaction conditions such as the number of equivalents of the reaction reagent, the type and volume of the solvent, and the reaction temperature for the method of increasing the number of carboxyl groups in the reaction.

  In addition, in the production process of a cyclodextrin compound into which an anionic group such as a carboxyl group is introduced, the target cyclodextrin compound is often obtained by conducting a basic reaction and neutralizing the reaction solution. However, in that case, the anionic group such as a carboxyl group in the obtained cyclodextrin compound is, for example, a sodium salt. This sodium salt dissociates in an aqueous solution to generate sodium ions, which may inhibit ionic bond formation between the cyclodextrin compound and the polymer molded body. Therefore, when the cyclodextrin compound having a carboxyl group is a salt, before carrying out the separation method of the present invention, the cyclodextrin compound is made into an aqueous solution in advance and this aqueous solution is treated with an acidic ion exchange resin. It is preferable to convert the carboxylic acid salt in the cyclodextrin compound to a carboxylic acid group as much as possible by such a process. This conversion method is not particularly limited in the present invention.

In the method for separating a hydrophobic substance of the present invention, the cyclodextrin compound having a plurality of anionic groups and the insoluble polymer molded article having a cationic group are bonded via the ionic bond and washed with water. After that, it is preferably used in the separation treatment as a selective adsorbent for hydrophobic substances. Here, the water used for washing includes any water such as distilled water and ion exchange water.
That is, in the method for separating a hydrophobic substance of the present invention, the chemical equilibrium relating to the ionic bond between the cyclodextrin compound and the insoluble polymer molded body, and the inclusion association formation of the cyclodextrin compound and the substance to be separated This is realized by controlling two equilibria of the chemical equilibria. The latter chemical equilibrium is affected by the hydrophobicity and molecular size of the substance to be separated, and at the same time, if the cyclodextrin compound remains dissolved in the treated water by the chemical equilibrium related to the ionic bond, This leads to a decrease in separation efficiency. Therefore, regarding the chemical equilibrium related to the ionic bond, the cyclodextrin compound and the insoluble polymer molded body are mixed in advance to achieve the chemical equilibrium state related to the ionic bond, and then the water does not form an ionic bond. After the cyclodextrin compound remaining in the column is removed by washing with distilled water, etc., high separation efficiency is achieved by using the insoluble polymer molded body ion-bonded with the cyclodextrin compound as an adsorbent. Can do.

In the separation method of the present invention, after the substance to be separated is adsorbed, it is washed with an alcohol represented by the general formula CH ₃ (CH ₂ ) _m OH (m is an integer from 0 to 4) or an aqueous solution of the alcohol. As a result, the insoluble polymer molded article holding the cyclodextrin compound having a plurality of anionic groups via ionic bonds can be repeatedly used as a selective adsorbent for a hydrophobic substance.
In the present invention, examples of substances to be separated include hydrophobic environmental pollutants mixed in wastewater such as industrial wastewater and household wastewater and river water. For example, substances that have been shown to act as environmental hormones (endocrine disrupting substances) such as bisphenol A, phthalates, alkylphenols such as 4-nonylphenol and nonylphenol ethoxylate, and nonionic interfaces such as alkylphenol ethoxylates Preferred examples include activators, organochlorine compounds such as estrogens, trichlene, and parklene.
The method for separating a hydrophobic substance of the present invention can also be used for separating active ingredients in foods that have been reported to promote health. In such a case, the substances to be separated in the present invention include hydrophobic components in foods such as catechins contained in tea, etc., vitamin E, lycopene contained in tomatoes, and isoflavones contained in soybeans.
In the separation method of the present invention, in the case of recovering the separation target substance in this way, after the separation target substance is adsorbed, the separation is performed by using the inclusion action of cyclodextrin and washing with ethanol or an aqueous solution of ethanol. The target substance can be recovered.

Hereinafter, as one embodiment of the method for separating a hydrophobic substance of the present invention, a case where a contaminant is separated using a selective adsorbent for the hydrophobic substance is shown.
Into an aqueous solution that can contain the substance to be separated, a cyclodextrin compound having an anionic group such as a carboxyl group and an insoluble polymer molded body having a cationic group such as an amino group are added, and stirred as necessary. The material to be separated can be removed by 80% or more by dipping for a predetermined time (preferably about 1 hour to 3 days, although it varies depending on the type of contaminant). The mixing ratio of the cyclodextrin compound and the cationic polymer molded body to the aqueous solution can be appropriately determined according to the type and concentration of the substance to be separated. In addition, when an aqueous solution of the substance to be separated contains an ionic substance such as a salt, the aqueous solution is preferably desalted in advance with a cation exchange resin and an anion exchange resin.

Production Example 1 (Production of carboxymethylated cyclodextrin)
In Production Example 1, carboxymethyl for use in the following Examples with reference to the literature (S. Satomura, K. Omichi, T. Ikenaka, Carbohydrate Research, Vol. 180, pages 137 to 146, 1988). A cyclodextrin (hereinafter sometimes simply referred to as “CM-β-CD”) was synthesized. Monochloroacetic acid 52.6g was dissolved in distilled water 270mL. Separately, 93.0 g of sodium hydroxide was dissolved in 370 mL of distilled water, and 100.0 g of β-CD was further dissolved. The obtained β-CD aqueous solution was mixed with the previous monochloroacetic acid aqueous solution in a 1-liter eggplant flask and reacted in an oil bath at 73 ° C. for 1.5 hours. After completion of the reaction, the reaction solution was concentrated under reduced pressure while warming with a rotary evaporator. After cooling to room temperature, the concentrate was added dropwise to about 3 L of vigorously stirred methanol, and a white precipitate immediately formed. After stirring for about 2 hours, a white powder was obtained by filtration. This white powder was dissolved in a small amount of distilled water and neutralized with 1M hydrochloric acid. This solution was reprecipitated again with about 1.3 L of methanol, filtered, and vacuum-dried to obtain 119.4 g of CM-β-CD as a white powder.

In the above literature by Satomura et al., There is no detailed description of the number of carboxyl groups per molecule of cyclodextrin, but the reaction product obtained in this production example was analyzed by a time-of-flight mass spectrometer. The product was confirmed to be a mixture of CM-β-CD with different numbers of carboxymethyl groups per molecule.
Moreover, when the number of carboxymethyl groups per molecule of CM-β-CD obtained in this Production Example was examined by proton NMR analysis, it was estimated to be about 3.2.
Furthermore, quantitative analysis of sodium by ion chromatography revealed that the obtained CM-β-CD contained 4.45% sodium. When this CM-β-CD was treated with a strongly acidic ion exchange resin, the sodium content was 2.02%. This decrease in sodium is due to the conversion of the carboxyl group from -COONa, which is a sodium salt, to -COOH.

Example 1 [Adsorption of Bisphenol A in Aqueous Solution by Carboxymethylated β-Cyclodextrin and Chitosan]
0.041 g (dry weight) of CM-β-CD treated with the strongly acidic ion exchange resin obtained in Production Example 1 and chitosan (chitosan beads marketed by Fuji Spinning Co., Ltd., trade name Chitopearl AL-10, average particle diameter) 0.048 g) (about 1 mm, water content 90%) was put into a 1 × 10 ⁻⁴ mol / l bisphenol A aqueous solution in a glass bottle, and the temperature was kept at 25 ° C. and shaken 90 times per minute. After 4 hours, the shaking was stopped, and 3 ml of the supernatant other than the precipitated beads was collected, and the absorbance was measured with an ultraviolet-visible absorptiometer to calculate the relative concentration of bisphenol A. Table 1 shows the results of measuring bisphenol A in the aqueous solution after 4 hours with an ultraviolet-visible spectrophotometer.

  The concentration of bisphenol A decreased with the lapse of the treatment time and became 21.6% after 4 hours. As a result of performing the same experiment using only CM-β-CD without adding CM-β-CD and using only chitosan or without adding chitosan, the concentration of bisphenol A hardly decreased. From this, it is clear that the decrease in the concentration of bisphenol A in Example 1 requires adsorption based on the interaction between the anionic cyclodextrin compound and chitosan.

Example 2 [Order of mixing cyclodextrin, chitosan and aqueous solution to be treated]
According to the procedure of Example 1, 0.04 g of CM-β-CD obtained in Production Example 1 and 0.48 g of chitosan particles were mixed in 30 ml of water, kept at a temperature of 25 ° C., and shaken 90 times per minute. did. After 24 hours, filtration with filter paper was performed to remove water, and then the chitosan particles on the filter paper were washed with distilled water. The chitosan particles were added to 30 mL of a 1 × 10 ⁻⁴ mol / l bisphenol A aqueous solution, and the results of measuring bisphenol A in the aqueous solution after 4 hours with an ultraviolet-visible spectrophotometer in the same manner as in Example 1 are shown in Table 1 above. Show. As a result, it was found that the concentration of bisphenol A decreased with time, and the degree of the decrease was larger than that in Example 1. That is, it can be said that the method shown in Example 2 in which CM-β-CD is bonded to chitosan particles in advance is an efficient method for carrying out the method for separating a hydrophobic substance of the present invention.

Example 3 [Reuse of used chitosan beads]
The present inventors release the adsorbed substance by treating the chitosan particles to which cyclodextrin is covalently bonded with an alcohol such as ethanol or an aqueous solution of alcohol, so that the chitosan particles used are almost the same as before use. It is restored to the state and can be used again for adsorption, Transaction of Material Research Society of Japan, vol. 30. (4), 1143-1146 (2005).
Also in the present invention, it will be shown below that the chitosan particles used can be adsorbed with phenol again by treating them with alcohol.
The chitosan particles adsorbed with bisphenol A used in Example 1 were shaken 90 times per minute in 30 ml of 50% aqueous solution of ethanol at a temperature of 25 ° C., and the concentration of bisphenol A in the aqueous ethanol solution was measured with an ultraviolet-visible spectrophotometer. The measurement results are shown in Table 1. Almost the same amount of bisphenol A that had been adsorbed in Example 1 was eluted in the aqueous ethanol solution. Further, after the used chitosan particles treated with ethanol were washed with distilled water, 1 × 10 ⁻⁴ mol / l bisphenol A aqueous solution was adsorbed under the same conditions as in Example 1 without newly adding CM-β-CD. The results used are shown in Table 1 above. As a result, the chitosan beads regenerated with the aqueous ethanol solution decreased the concentration of the aqueous bisphenol A solution more than the result shown in Example 1, and the result was almost the same as in Example 2. This indicates that the used chitosan particles can be regenerated without the need to newly add CM-β-CD by treatment with an aqueous ethanol solution. In addition, by comparing Examples 1 to 3, the treatment liquid during the adsorption of phenols does not contain CM-β-CD that is not bound to chitosan. Shows that the adsorption of phenols occurs efficiently.

Example 4 [Use of synthetic ion exchange resin]
As shown below, the method for separating a hydrophobic substance of the present invention is effective not only for chitosan but also for commercially available anion exchange resins. CM-β-CD 0.04 g, anion-exchange resin IRA67 (trade name, manufactured by Rohm and Haas) instead of chitosan was used in the method shown in Example 1, and 1 × 10 Table 1 shows the results of experiments for treating 30 mL of a ^-4 mol / l aqueous bisphenol A solution. The decrease in the concentration of bisphenol A was almost the same as that when chitosan shown in Example 1 was used. It is apparent that the present invention can be effectively used not only for chitosan but also for ion exchange resins marketed for processes such as water treatment.

Example 5 [Adsorption of nonionic surfactant]
Similarly to Example 2, 0.04 g of CM-β-CD and 0.48 g of chitosan particles were mixed overnight in distilled water, filtered, and the resulting chitosan particles were washed with distilled water, and 1 × 10 ⁻ 30 mL of an aqueous solution of ⁴ mol / l 4-nonylphenol ethoxylate (the average number of ethylene oxide repeats is 10, hereinafter referred to as NPE) was treated, and the relative concentrations after 4 hours are shown in Table 1 above. Although the amount of adsorption was slightly lower than that of the aqueous solution of bisphenol A, it was found that NPE was also adsorbed. NPE exhibits a slightly lower amount of adsorption than BPA because the non-patent literature (Transaction of Material Research of Japan, vol.30. (4), 1143-1146) that the present inventors have published so far. (2005) and Journal of Inclusion Phenomena and Macrocyclic Chemistry, vol. 57, 237-241 (2007)), it is considered that NPE is less hydrophobic than BPA.

Example 6 [Adsorption of food ingredients]
The method for separating a hydrophobic substance of the present invention is effective not only for separating phenols in waste water but also for separating only a specific substance from a solution of a food extract. In the same manner as in Example 1 or Example 2, 0.1 g of CM-β-CD and 1 g of chitosan particles (wet state) were added to 30 ml of commercially available green tea beverage. In the case of treatment in the same manner as in Example 2, CM-β-CD and chitosan were mixed in distilled water for 16 hours, washed with distilled water, and then used in the experiment. In either case, the adsorption experiment was performed for 2 hours, and the liquid after 2 hours was filtered and analyzed by liquid chromatography. The chitosan beads were washed with distilled water, shaken in 30 mL of 50% ethanol aqueous solution for 2 hours, and subjected to liquid chromatographic analysis of the ethanol solution after 2 hours. Table 2 summarizes the amounts of adsorption and recovery of caffeine and epigallocatechin gallate in each treatment solution before treatment by liquid chromatography. Epigallocatechin gallate can adsorb around 80% of the amount originally contained in tea beverages, and the amount of epigallocatechin gallate released in 50% ethanol aqueous solution is almost the same as the adsorbed amount. I was able to. On the other hand, caffeine was hardly adsorbed and therefore released little. A similar adsorption method using a polymer in which cyclodextrin is crosslinked is shown in a patent document (Japanese Patent Laid-Open No. 2004-229). In the present invention, a complicated production operation is required as compared with the production of the polymer in the patent document. Instead, the same effect can be obtained by the production of the cyclodextrin compound.

Example 7 [Adsorption in an aqueous solution containing sodium chloride]
Since the present invention utilizes the ionic interaction between CM-β-CD, which exhibits anionic property in water, and the cationic polymer molded product, If salts that dissociate into ions are included, they are affected. The results of treatment in the same manner as in Example 2 using an aqueous solution containing 1 × 10 ⁻⁴ mol / l bisphenol A and 1 × 10 ⁻² mol / l (0.5844 g / l) sodium chloride are shown in Table 2. 3 shows.

  Compared to the case of not containing sodium chloride shown in Example 2, the decrease in the concentration of bisphenol A was small. This phenomenon is presumed to be due to the dissociation of CM-β-CD ionically bound to chitosan from chitosan due to the influence of sodium chloride in the aqueous solution. In order to confirm this, the following experiment was conducted. In order to analyze CM-β-CD bound to chitosan, the treated chitosan was shaken 90 times per minute for 2 hours at 25 ° C. with 10 ml of 0.1 molar hydrochloric acid. The hydrochloric acid was neutralized with an aqueous sodium hydroxide solution, and the residue obtained by freeze-drying was analyzed as residue A by time-of-flight mass spectrometry. In addition, the residue obtained by freeze-drying the treated aqueous bisphenol A solution was similarly analyzed as residue B by time-of-flight mass spectrometry. Residue A contains CM-β-CD that did not dissociate from chitosan by treatment with an aqueous solution containing sodium chloride, and residue B dissociated from chitosan and eluted during processing. A CD should be included. Comparing the analysis results of the residue A and the residue B, it can be seen that each residue contains CM-β-CD having a different number of carboxymethyl groups, but the distribution of the number of carboxymethyl groups. Is clearly shown to be different. That is, CM-β-CD having about 3 or more carboxymethyl groups retains the bond with chitosan even when treated with an aqueous sodium chloride solution, but CM-β-CD having about 2 or less carboxymethyl groups. Has been detached from chitosan. This is because CM-β-CD having a large number of anionic groups per molecule of cyclodextrin acts effectively in order to reduce the influence of salts such as sodium chloride on the adsorption efficiency in the method of the present invention. It can be said that this method is clearly superior to the case where only one anionic group per molecule of cyclodextrin is contained as in Non-Patent Document 7 described above.

Claims (10)

A step of bonding a cyclodextrin compound having a plurality of anionic groups in the molecule and an insoluble polymer molded article having a plurality of cationic groups via an ionic bond between the anionic group and the cationic group. a method of separating hydrophobic substances in the solution by the inclusion action of including pre Symbol cyclodextrin compound, the anionic group is a substituent having a carboxyl group, to separate the hydrophobic material in the solution Way .   After the cyclodextrin compound having a plurality of anionic groups and the insoluble polymer molded body having a plurality of cationic groups are bonded via the ionic bond, a solution as a selective adsorbent for a hydrophobic substance The method for separating a hydrophobic substance according to claim 1, wherein the method is used for separation treatment of the hydrophobic substance therein. The separation method according to claim 1 or 2, wherein the cyclodextrin compound having a plurality of anionic groups is a compound represented by the following general formula 1.

(In the above general formula, n represents an integer of 6 to 8. Also, R ¹ , R ² and R ³ each represent a hydroxyl group or an anionic group, and each may be the same or different. Good and at least two of the anionic groups in the cyclodextrin compound.) The separation method according to any one of claims 1 to 3 , wherein the insoluble polymer molded article having a plurality of cationic groups is a molded article comprising a chitosan compound. The separation method according to any one of claims 1 to 3 , wherein the insoluble polymer molded product having a plurality of cationic groups is a molded product made of an ion exchange resin having a polystyrene compound as a skeleton. After adsorbing the hydrophobic substance to be separated, it is washed with an alcohol represented by the general formula CH ₃ (CH ₂ ) _m OH (m is an integer from 0 to 4) or an aqueous solution of the alcohol. of claim 1-5 comprising the step of repeatedly available the insoluble polymer-extruded article of the cyclodextrin compound and held via an ionic bond having a plurality of anionic groups as selective adsorbents hydrophobes The separation method according to any one of the above. The hydrophobic substance, which is a substance to be separated, is adsorbed on the insoluble polymer molded article holding the cyclodextrin compound having a plurality of anionic groups via ionic bonds, and then washed with ethanol or an aqueous solution of ethanol. The separation method according to any one of claims 1 to 5 , further comprising a step of collecting the substance to be separated. A cyclodextrin compound having a plurality of anionic groups in the molecule and an insoluble polymer molded article having a plurality of cationic groups are bonded via an ionic bond between the anionic group and the cationic group. A selective adsorbent for a hydrophobic substance , wherein the anionic group is a substituent having a carboxyl group . The selective adsorbent according to claim 8 , wherein the hydrophobic substance is an endocrine disrupting substance or a hydrophobic component in food. After adsorbing the hydrophobic substance to be separated, it is washed with an alcohol represented by the general formula CH ₃ (CH ₂ ) _m OH (m is an integer from 0 to 4) or an aqueous solution of the alcohol. The selective adsorbent according to claim 8 or 9, which can be reused repeatedly.