JP2003190975A - Treatment method for chemical substance contained in water and having pharmacological activity - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a treatment method in which a compound contained in water and having pharmacological activity, particularly a cyclic compound having a cyclic structure such as a benzene ring or, a pyrimidine ring is easily decomposed and made inactive. <P>SOLUTION: The cyclic compound contained in water and having pharmacological activity is oxidized by an oxidation method using an oxidizing agent. The cyclic structure of the cyclic compound is cleaved and the pharmacological activity thereof is made inactive. The oxidation method using the oxidizing agent is exemplified by the oxidation method using ozone or a hydroxy radical. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a method for treating water containing a chemical substance having a pharmacological activity to inactivate the pharmacologically active action of the chemical substance.

[0002]

2. Description of the Related Art As chemical substances having pharmacological activity, there are some which are mainly used in the medical field as anticancer agents. Cancer is a disease that occurs in humans and animals, and anticancer agents are used for the purpose of suppressing growth of tumor cells. However, most of the anti-cancer agents currently used are cytotoxic and may have side effects even on healthy cells.

When producing or using a chemical substance having a pharmacological activity, it is considered that the chemical substance having a pharmacological activity is mixed in water. Conventionally, in such a case, a chemical substance having a pharmacological activity contained in water has been treated by adsorption treatment with activated carbon or the like.

[0004]

However, the adsorption treatment with activated carbon or the like is not a decomposition treatment of a chemical substance having a pharmacological activity but a removal treatment by adsorption from water, so that a chemical substance having a pharmacological activity is decomposed. In order to inactivate it, it is necessary to carry out another treatment by a combustion method or the like after that, and the decomposition treatment of the above chemical substances is troublesome.

The present invention has been made in view of the above-mentioned circumstances, and an object thereof is to provide a treatment method capable of easily decomposing and inactivating a chemical substance having a pharmacological activity contained in water. To do.

[0006]

Means for Solving the Problems First of all, the present inventors have found that a chemical substance having a pharmacological activity used as an anticancer agent is an organic compound having a cyclic structure in the molecule, that is, a cyclic compound. Focused on many. Then, as a result of various studies on a method for decomposing a cyclic compound having such pharmacological activity, when the cyclic compound was oxidized using an oxidizing agent, particularly ozone or a hydroxy radical was used as an oxidizing agent. In this case, it was found that the cyclic structure of the cyclic compound is specifically cleaved and the pharmacological activity of the cyclic compound having pharmacological activity is inactivated.
The mechanism is that an oxidant such as ozone or a hydroxy radical selectively attacks the double bond site in the cyclic structure to cleave the double bond site, changing the cyclic compound having pharmacological activity to another compound. It is presumed that its pharmacological activity is inactivated.

The present invention has been made on the basis of the above-mentioned findings, and is characterized in that a cyclic compound having pharmacological activity contained in water is treated by an oxidation method using an oxidizing agent. A method for treating an active chemical substance is provided.

The present invention will be described in more detail below. In the present invention, the cyclic compound having pharmacological activity contained in water is oxidized by an oxidation method using an oxidizing agent. In this case, examples of the oxidizing method using an oxidizing agent include an oxidizing method using ozone, hydroxy radical, hydrogen peroxide, potassium permanganate, etc. as the oxidizing agent. Particularly preferred is the oxidation method using ozone or hydroxyl radicals, since the cyclic structure of the cyclic compound can be effectively cleaved.

The oxidation method using ozone or hydroxyl radicals is not necessarily limited, but (a) a method of adding ozone to the water to be treated, (b) a method of adding ozone to the water to be treated under alkaline conditions, (C) A method of adding ozone to the water to be treated and irradiating the water to be treated to which the ozone has been irradiated with ultraviolet rays, (d) a method of adding ozone and hydrogen peroxide to the water to be treated, or (e) a substance to be treated A method of adding hydrogen peroxide to water and irradiating with ultraviolet rays can be suitably adopted. In the oxidation method (a), a cyclic compound having a pharmacological activity is brought into contact with ozone to be oxidized. In the oxidation method (b), a cyclic compound having a pharmacological activity is brought into contact with a hydroxy radical generated by a reaction between ozone and an alkali (see the following reaction formula B) to be oxidized. The oxidation method (c) is a method in which a cyclic compound having a pharmacological activity is brought into contact with a hydroxy radical generated by a reaction between ozone and ultraviolet rays to oxidize the cyclic compound. Oxidation method (d)
Is a compound in which a cyclic compound having a pharmacological activity is brought into contact with a hydroxy radical generated by the reaction between ozone and hydrogen peroxide (see the following reaction formula D) to be oxidized. In the oxidation method (e), a cyclic compound having a pharmacological activity is brought into contact with a hydroxy radical generated by the reaction between hydrogen peroxide and ultraviolet rays to oxidize the cyclic compound.

2O ₃ + OH ⁻ → OH · + O ₂ · − + 2O ₂ (B) 2O ₃ + H ₂ O ₂ → 2OH · + 3O ₂ (D)

In the oxidation method (b), p of the water to be treated is
It is suitable that H has a lower limit of 7, particularly 8, and an upper limit of 12, particularly 11, and for example, the pH of the water to be treated can be 7 to 12, preferably 8 to 11. In the oxidation method (b), ozone may be added to the water to be treated after adjusting the pH of the water to be treated, or the pH of the water to be treated may be adjusted after adding ozone to the water to be treated. The pH of the water to be treated and the addition of ozone to the water to be treated may be simultaneously performed.

In the oxidation method (c), the ultraviolet irradiation mechanism for irradiating the water to be treated to which ozone has been added with ultraviolet rays is not particularly limited, and is equipped with a high-pressure ultraviolet lamp.
Any of those equipped with a low-pressure ultraviolet lamp can be used, but it is more suitable to use one equipped with a high-pressure ultraviolet lamp that mainly emits ultraviolet light having a wavelength near 365 nm.

In the oxidation method (d), the amount of hydrogen peroxide added to the water to be treated is preferably 0.5 to 10 mg / L. In the oxidation method (d), ozone may be added after adding hydrogen peroxide to the water to be treated, or hydrogen peroxide may be added after adding ozone to the water to be treated. Alternatively, ozone and hydrogen peroxide may be simultaneously added to the water to be treated.

In the oxidation method (e), it is preferable to add 0.5 to 100 mg / L of hydrogen peroxide to the water to be treated and irradiate it with ultraviolet rays at pH neutrality. The ultraviolet irradiation mechanism for irradiating the water to be treated with ultraviolet rays is the same as described above.

In the present invention, the lower limit of the amount of ozone consumed in the water to be treated is 1 mg / L when performing the above-mentioned treatment by the oxidation method using ozone or hydroxy radicals.
Especially 50 mg / L, upper limit 200 mg / L, especially 150
It is suitable that the amount of ozone is 1 to 200 mg / L, preferably 50 in the water to be treated.
It can be controlled to ˜150 mg / L. Even if the ozone consumption is 200 mg / L or more, inactivation of the pharmacologically active action of the chemical substance may not proceed any further.
The ozone consumption can be obtained by subtracting the unreacted ozone amount (mg / L) from the generated ozone amount (mg / L).

The present invention is a cyclic compound having pharmacological activity,
For example, it is effectively used for inactivating azatyrosine, mitomycin, clemastine and the like. In particular, the present invention is effectively used for inactivating a cyclic compound having a benzene ring structure and / or a pyrimidine ring structure represented by the following formula (1). Examples of the cyclic compound having a benzene ring structure and / or a pyrimidine ring structure include fluorouracil represented by the following formula (2), uracil, thymine, and cytosine.

[0017]

[Chemical 1]

[0018]

[Chemical 2]

[0019]

BEST MODE FOR CARRYING OUT THE INVENTION Next, an embodiment of the present invention will be described. FIG. 1 is a flow chart showing an example of a treatment apparatus used for carrying out the treatment method of the present invention. This apparatus uses a method (b) of adding ozone to water to be treated under alkaline conditions as an oxidation method. . In this apparatus, 2 is a raw water tank, 4 is an acid / alkali tank, 6 is a reaction tank, 8 is an ozone generator, 10 ozone decomposer, and 12 is a treated water tank.

When water containing a chemical substance having a pharmacological activity is treated with this apparatus, the acid or alkali 14 is added from the acid / alkali tank 4 to the water to be treated in the raw water tank 2 and the treated water is treated. pH 7-12, more preferably 8
Adjust to ~ 11. That is, when the pH of the water to be treated is lower than the above range, an alkali is added to the water to be treated, and when the pH is higher than the above range, an acid is added to the water to be treated. If the pH of the water to be treated is originally within the above range, it is not necessary to add an acid or alkali to the water to be treated. Next, the water to be treated is introduced into the reaction tank 6 through the pipe 16, and the ozone 18 generated by the ozone generator 8 is added to the water to be treated in the reaction tank 6. At this time, the ozone consumption in the water to be treated is 1
~ 200 mg / L, more preferably 50-150 mg / L
Control to L. The ozone consumption amount is controlled by controlling the ozone generation amount in the ozone generator 8, for example. As a result, the cyclic compound having pharmacological activity in the reaction tank 6 is oxidized and inactivated by the hydroxy radical produced by the reaction between ozone and alkali. The residence time of the water to be treated in the reaction tank 6 is usually 1 to 60.
It is suitable that the time is about 5 minutes, especially about 5 to 30 minutes.
The treated water 20 after the reaction is stored in the treated water tank 12 and then discharged or provided for other treatment. Further, the unreacted ozone gas 22 discharged from the reaction tank 6 is processed by the ozone decomposer 10.

[0021]

Example An experiment was conducted in which a cyclic compound having a pharmacological activity contained in water was oxidized by an oxidation method using an oxidizing agent. In this case, as the cyclic compound having pharmacological activity, fluorouracil of the above formula (2) (concentration 100 mg /
L) was used. As the oxidation method, the method (a) of adding ozone to the water to be treated and the method (b) of adding ozone to the water to be treated under alkaline conditions were used. The pH of the water to be treated (raw water) was 7, the pH of the water to be treated was not adjusted in the treatment method (a), and the pH of the water to be treated was adjusted to 11 by the addition of an alkali in the treatment method (b).

The experiment was carried out using an ozo generated from an ozone generator.
The fluorouracil aqueous solution in the reaction tank,
The degradability of fluorouracil was investigated. In this case, the processing method
Each of the methods (a) and (b) requires decomposition
The amount of ozone was calculated and the decomposition treatment performance of both was evaluated.
It was Fluorouracil can be quantified by high performance liquid chromatography.
It was done by graphy. According to the processing method (a) in FIG.
As a result, the processing method (b) in FIG. 3 and the processing in FIG.
IR spectra of water before and after treatment by method (b)
A torchart is shown. 2 and 3, the x-axis is ozone
Consumption (mgO ₃/ L), y-axis is fluorouracil and
And TOC concentration (mg / L). Also processing
After fluorouracil decomposition by methods (a) and (b)
Each of the toxicity tests of the treated water of
Fluorouracil has no residual pharmacological activity in water.
Was confirmed.

From this experiment, it was confirmed that according to the present invention, a cyclic compound having pharmacological activity contained in water can be decomposed and inactivated.

Further, even after the fluorouracil was decomposed and inactivated, the TOC concentration did not change so much. This indicates that fluorouracil was decomposed and changed to another substance to deactivate its pharmacological activity, but fluorouracil was not completely decomposed.
The ozone consumption (theoretical amount) required to completely decompose fluorouracil into carbon dioxide and water is 1700 mgO ₃ / L when the fluorouracil concentration is 100 mg / L.
It is a degree. On the other hand, the ozone consumption required to cleave the cyclic structure of fluorouracil and change it into another substance, that is, the ozone consumption required to lose the pharmacological activity of fluorouracil is 130 in the treatment method (a).
MgO ₃ / L, a processing method (b) in 90mgO ₃ / L. Therefore, according to the present invention, it was found that the pharmacological action of fluorouracil can be deactivated with an ozone amount significantly smaller than the amount of ozone required to completely decompose fluorouracil.

Further, according to the method (b) of adding ozone to the water to be treated under alkaline conditions, a cyclic compound having a pharmacological activity with a smaller amount of ozone than the method (a) of adding ozone to the water to be treated is used. It was found that the compound can be decomposed. In method (b), the pH of the treated water is treated by ozone treatment.
Therefore, when this method (b) is used, the initial pH of the water to be treated is 10 or more (preferably 11 or more).
In the case of the above, since the pH of the treated water can be made close to neutral as a result, the neutralization operation at the time of discharge can be omitted, which is advantageous in this respect.

[0026]

As described above, according to the present invention, a chemical substance having a pharmacological activity contained in water can be easily decomposed and inactivated. That is, according to the present invention,
Decomposition treatment of a chemical substance having a pharmacological activity contained in water, particularly a cyclic compound having a ring structure such as a benzene ring or a pyrimidine ring, can be easily carried out by an oxidation method using an oxidizing agent such as ozone or hydroxyl radical. . Therefore, the present invention is extremely effective in preventing the release of a chemical substance having a pharmacological activity into the environment and preventing the risk caused by the cytotoxicity of the chemical substance.

[Brief description of drawings]

FIG. 1 is a flow chart showing an example of a processing apparatus used for carrying out a processing method of the present invention.

FIG. 2 is a graph showing a fluorouracil decomposition treatment result by treatment method (a) in an experimental example.

FIG. 3 is a graph showing a fluorouracil decomposition treatment result by a treatment method (b) in an experimental example.

FIG. 4 is an IR spectrum chart of water before treatment and water after treatment according to the treatment method (b) in the experimental example.

[Explanation of symbols]

2 Raw water tank 4 Acid / alkali tank 6 reaction tanks 8 ozone generator 12 Treated water tank 18 ozone 20 treated water

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Claims (6)

[Claims] 1. A method for treating a chemical substance having a pharmacological activity contained in water, which comprises treating a cyclic compound having a pharmacological activity contained in water by an oxidation method using an oxidizing agent. 2. The method for treating a chemical substance having a pharmacological activity contained in water according to claim 1, wherein the oxidation method using an oxidizing agent is an oxidation method using ozone or a hydroxy radical. 3. An oxidation method using ozone or hydroxy radicals comprises (a) a method of adding ozone to water to be treated,
(B) a method of adding ozone to the treated water under alkaline conditions, (c) a method of adding ozone to the treated water and irradiating the treated water to which the ozone has been added with ultraviolet rays,
The method according to claim 2, which is (d) a method of adding ozone and hydrogen peroxide to the water to be treated, or (e) a method of adding hydrogen peroxide to the water to be treated and irradiating with ultraviolet rays. A method for treating a chemical substance having a pharmacological activity contained in water. 4. As the oxidation method using ozone or hydroxy radicals, (b) a method of adding ozone to the water to be treated under alkaline conditions is used, and the pH of the water to be treated is 7 to.
12. The method for treating a chemical substance having a pharmacological activity contained in water according to claim 3, which is 12. 5. The ozone consumption in the water to be treated is 1 to 20.
The method for treating a chemical substance having a pharmacological activity contained in water according to any one of claims 2 to 4, wherein the treatment amount is 0 mg / L. 6. The pharmacological activity contained in water according to claim 1, wherein the cyclic compound having pharmacological activity is a compound having a benzene ring structure and / or a pyrimidine ring structure. A method for treating an active chemical substance.