JP4868323B2 - Deodorant composition, deodorant containing deodorant composition, and deodorant tool comprising fiber structure carrying deodorant composition - Google Patents

Description

The present invention relates to a deodorant composition extracted from a plant belonging to the genus Button, a deodorant containing the deodorant composition, and a deodorizer equipped with a fiber structure carrying the deodorant composition.

In recent years, there has been an increasing demand for deodorization of various odorous substances. Examples of the deodorization method include a deodorization method using a chemical reaction such as neutralization, a deodorization method in which an odorous substance is adsorbed and removed with activated carbon, a method in which a fragrance is gradually released, and a malodor is suppressed by aroma. Here, when using the deodorant composition on the fiber structure and directly contacting the skin, such as diapers, it is preferable to use natural ingredients gentle to the skin, for example, Patent Document 1 discloses a technique for causing a fiber to contain catechins contained in a tea leaf extract or the like.
JP 2000-303250 A

However, the above-described technology has a problem in that it does not have a great deodorizing effect on odorous substances derived from living bodies, for example, inorganic nitrogen compounds such as ammonia and organic nitrogen compounds such as amines which are odorous substances such as human odor and body odor there were.

Therefore, the present invention carries a deodorant composition having a high deodorizing effect on various odorous substances, particularly a odorous substance derived from a living body, a deodorant containing the deodorant composition, and a deodorant composition. An object of the present invention is to realize a deodorant tool provided with a fiber structure.

In order to achieve the above object, according to the present invention, the deodorizer is extracted from petal and / or leaf of peony, and at least one of gallic acid, galloylglucose and astragalin. The technical means of containing only a deodorizing composition containing a seed and having a deodorizing action on nitrogen compounds as a deodorizing component is used.

By the invention described in claim 1 lever, it is possible to extract a deodorant composition having a deodorant effect from peony petals and / or leaves. Deodorant composition extracted from peony petals and / or leaves, because it contains a large amount of deodorant components having a yet higher deodorizing effect can be used to good suitable.

In addition, since the peony petals and leaves contain more deodorant components than other parts such as roots and stems, the deodorant composition can be efficiently extracted.

As a result of intensive studies by the applicant, it has been found that gallic acid, galloylglucose and astragalin have a good deodorizing action among the extracts extracted from peony. Gallic acid has a strong deodorizing action, and particularly shows a remarkable deodorizing action on nitrogen compounds. Pentagalloyl glucose has a strong deodorizing effect, particularly a remarkable deodorizing effect on nitrogen compounds, and also has antibacterial properties, so it can suppress the generation of malodor associated with the growth of microorganisms. . Astragalin also has a good deodorizing effect and also exhibits a deodorizing effect on nitrogen compounds. Thus, death Shokuko acid, galloylated glucose, to indicate the deodorant composition is excellent deodorizing effect containing at least one of astragalin, can be suitably used.

Biological odors such as human odor and body odor are often due to inorganic nitrogen compounds such as ammonia and organic nitrogen compounds such as amines . Since the deodorizing composition has a deodorizing action on the nitrogen compound, it can be suitably used for the deodorizing application of the odor produced by the biological nitrogen compound.

The deodorant composition as described above can be suitably used as a deodorant having a strong deodorizing action by being contained in the deodorant.

In the invention according to claim 2 , the deodorizer is extracted from the petals and / or leaves of peony and contains at least one of gallic acid, galloylglucose and astragalin, and is effective for eliminating nitrogen compounds. The technical means of providing a fiber structure carrying only a deodorant composition having an odor function as a deodorant component is used.

Since the deodorant composition of this invention has the outstanding deodorizing effect, it can carry | support to a fiber structure and can be used suitably as a deodorizing tool like the invention of Claim 2 . In addition, since the deodorant composition of the present invention is a plant-derived natural component, there is little irritation to the skin, and the fiber structure is used in contact with the skin as in the invention of claim 3. And when it has a deodorizing action with respect to nitrogen compounds derived from living organisms, it can be used particularly preferably. In addition, when the deodorant composition is configured to contain at least one of galloylglucose or astragalin as in the invention described in claim 4 , the detergent is once supported on the fiber structure. Since it is difficult to remove from a fiber even by a substance having a high cleaning effect, a suitable deodorant composition can be obtained.

A method for extracting a deodorant composition from a plant belonging to the genus Button will be described. Here, peony was used as a plant belonging to the genus Button. Peonies petals and leaves can be suitably used because they contain a large amount of deodorizing components described later among plants belonging to the genus Button.

  The deodorant composition is extracted from the peonies petals. The peony petals are preferably powdered after drying in order to improve extraction efficiency. In addition to petals, peony can be used for leaves, stems, stems, bark, roots, seeds, etc., but since petals and leaves have a high content of deodorant components described later, they are deodorant. The composition can be efficiently extracted, which is preferable.

The extraction method of the deodorant composition is not particularly limited, and a vapor extraction method such as a solid-liquid extraction method or a percolation method can be used. In addition, a steam distillation method in which extraction is performed using water vapor, a method of extraction into a supercritical fluid, or the like can be employed.

For example, in the solid-liquid extraction method, a container containing a predetermined amount of peony petal powder together with a solvent such as water is placed in an autoclave and heated under conditions of 2 atm and 121 ° C., thereby deodorizing. The composition can be extracted. In addition, a solvent, extraction conditions, etc. can be set suitably.

  Furthermore, solvent extraction can also be performed using an organic solvent such as ethyl acetate. At this time, in order to enhance extraction efficiently, it is preferable to remove fat-soluble components and the like using n-hexane or the like.

The form of the deodorant composition extracted by the above extraction method is not particularly limited, and an extract is prepared by concentrating the extract using an evaporator or a spray drying method, or a solvent is used. It can be in the form of a solid such as an evaporated powder.

The extracted deodorant composition contains gallic acid (garlic acid), galloyl glucose, astragalin and the like as a deodorant component. Here, gallic acid and galloylglucose have a strong deodorizing action, and particularly show a remarkable deodorizing effect on nitrogen compounds. Biological odors such as human odor and body odor are mostly due to inorganic nitrogen compounds such as ammonia and organic nitrogen compounds such as amines, and therefore can be suitably used for deodorizing the odor produced by biological nitrogen compounds. . Since galloylglucose such as pentagalloylglucose and astragalin are once supported on the fiber structure, it is difficult to remove them from the fiber even with a substance having a high cleaning effect such as a detergent. Furthermore, since galloylglucose also has antibacterial properties, the generation of malodor associated with the growth of microorganisms can be suppressed. Astragalin also has a good deodorizing action and exhibits a deodorizing effect on nitrogen compounds.

From the above, a deodorant composition containing at least one of gallic acid, galloylglucose, and astragalin exhibits a good deodorizing effect and can be suitably used.

The deodorant composition can be used as a deodorant having a high deodorizing effect by adding to a solvent, for example. Such a deodorant can be used by spraying on the object to deodorize, for example by spraying.

As a solvent to which the deodorant composition is added, various solvents such as water and alcohol can be used as long as the deodorant effect of the deodorant composition is not inhibited.

  Moreover, this deodorizer can contain the arbitrary component which does not inhibit the deodorizing effect by a deodorant composition as needed. For example, preservatives, surfactants, antioxidants, stabilizers, fragrances, pigments and the like can be included.

A liquid deodorant can be used, for example, by impregnating a sponge-like porous material and releasing the deodorant component gradually. Also, it can be used in various forms such as powder-molded tablets and microcapsules. Such a deodorant can be suitably used for deodorization of toilets, kitchens, refrigerators, living rooms, automobiles, and the like.

The deodorant composition can be supported on a fiber structure and used as a deodorant tool. Here, as deodorants, underwear such as pants and shirts, absorbent members such as diapers, napkins and pads, toiletries such as seat covers and toilet covers, pet supplies, general medical materials such as masks and lab coats, sheets, etc. Examples thereof include bedding and care products, and can be widely used for deodorizing applications, particularly for deodorizing nitrogen compounds derived from living organisms. Since the deodorant composition of this invention is a plant-derived natural component, there is little irritation | stimulation with respect to skin and it can use it especially suitably for the fiber structure which contacts skin directly.

The fiber structure provided in the deodorant tool corresponds to, for example, a gauze portion of a mask, and is a cloth, a nonwoven fabric, a fiber lump of natural fibers or synthetic fibers that can carry a deodorant composition.

A known method can be used as a method for supporting the deodorant composition on the fiber structure. For example, it is possible to use a method in which a fiber structure is impregnated with a solution containing a deodorant composition, dried and supported. In addition, a method using a binder resin, a method of fixing a microcapsule to a fiber surface, and the like can be given. Moreover, when using an extract, you may carry | support in an extraction process.

EXAMPLES Hereinafter, although an Example demonstrates this invention in detail, this invention is not limited to these Examples.

Example 1
The deodorizing effect of the deodorant composition solid-liquid extracted from the peonies petals with hot water was confirmed.

The method for extracting the deodorant composition and the method for preparing the test cloth carrying the deodorant composition are shown below. 10 g of peony petal powder and gauze (20 g, 25 cm x 200 cm) are immersed in 500 ml of pure water and extracted simultaneously with solid-liquid extraction of peony components in an autoclave at 2 atm and 121 ° C for 20 minutes. The components were adsorbed on gauze. The temperature inside the autoclave was returned to room temperature by allowing it to stand overnight, and after thoroughly washing the gauze with running water, the gauze was further washed and dehydrated five times or more to remove the adsorbed components. The gauze was naturally dried, and a test cloth cut into 25 cm × 20 cm was used. Moreover, the gauze which performed the same process without putting the peony petal powder in the pure water as a control test cloth was used.

The odor solution was prepared by the following method. Ammonia and dimethylamine were used as odor solutions. As the ammonia odor solution, 25% ammonia diluted 10 times by volume with ultrapure water was used, and 200 μl was added to the test cloth. As the dimethylamine odor solution, 50% dimethylamine was diluted 10 times by volume with ultrapure water, and 100 μl was added to the test cloth.

The test of the deodorizing effect of the deodorant composition on each odorous substance was performed as follows. Put the test cloth soaked in odor solution into the Tedlar bag, close the inlet with a sealer, and then inject 1 liter of air from the Tedlar bag's gas sample inlet / outlet using a syringe. 100 ml) was taken out with a syringe while passing through a gas detection tube, and the concentration of odorous substances contained in 100 ml of air in the Tedlar bag was measured over time.

FIG. 1 shows changes over time in the concentration of each odorous substance. FIG. 1A shows the change over time in the ammonia concentration, and FIG. 1B shows the change over time in the dimethylamine concentration. Each was compared with the change over time in the case of using a control test cloth (denoted as control in the figure). As shown in FIG. 1A, the initial concentration of ammonia was several thousand ppm, but the concentration became 2 ppm or less 10 minutes after the start of the test, and it was confirmed that there was a strong deodorizing action against ammonia. . In addition, as shown in FIG. 1B, the initial concentration of dimethylamine was about 50 ppm, but the concentration became 2 ppm or less 10 minutes after the start of the test, and there was a strong deodorizing action against dimethylamine. Was confirmed. Furthermore, although an olfactory test was conducted, ammonia odor and amine odor were hardly felt, and a deodorizing effect on ammonia and dimethylamine, which are nitrogen compounds, was confirmed.

(Example 2)
The deodorizing effect of the deodorant composition extracted from the peonies petals with ethyl acetate was confirmed.

The extraction method of a deodorant composition is shown below. 1500 mL of ultrapure water was added to 50 g of peony petal powder, and solid-liquid extraction was performed using an autoclave (121 ° C., 10 minutes). Thereafter, the obtained extract was centrifuged with a centrifuge (6000 rpm, 15 minutes, 4 ° C.), and the supernatant was filtered through paper to separate the solvent extract. Next, 1260 mL of the solvent extract and an equivalent amount of n-hexane were placed in the separatory funnel, and after stirring about 100 times, 1246 mL of the aqueous layer containing the antimicrobial component in the lower layer was separated to remove the fat-soluble component and the like. Thereafter, an equal amount of chloroform was added to the obtained aqueous layer, and after stirring about 100 times, 1124 mL of an aqueous layer containing an antimicrobial component on the upper layer side was separated. Next, an equal amount of ethyl acetate was added to the obtained aqueous layer and stirred for about 100 times, and then the upper ethyl acetate layer was extracted and dried and solidified with an evaporator. Then, after re-dissolving with 7.2 mL of ultrapure water, 3.8 g of ethyl acetate extract powder was obtained by freeze-drying.

A method for preparing a test paper carrying a deodorant composition is shown below. 10 mg of ethyl acetate extract powder was dissolved in 10 ml of special grade methanol to prepare a 0.1% solution. Paper (No. 1, φ110 mm) was divided into 16 sectors (0.05 to 0.06 g per sheet), and 0.1 ml of ethyl acetate extract solution was divided into 2 portions of 50 μl and 1 ml soaked on the entire surface of the paper. Let And it air-dried in the clean bench for 15 minutes, and left and produced for 18 hours in the dark. The amount of the deodorant composition adsorbed per unit area is 1 mg (168 μg / cm ² ). Controlro paper was prepared by impregnating 1 ml of methanol and performing the same treatment.

The odor solution was prepared by the following method. Ammonia and dimethylamine were used as odor solutions. The ammonia-smelling solution was prepared by weighing 0.71 g of 25% ammonia diluted 10-fold by weight with ultrapure water and adding ultrapure water to a total weight of 7.48 g. Further, this solution was diluted 10 times by volume with ultrapure water and the concentration was 2.37%, and 10 to 100 μl was added to the test paper. As the dimethylamine odor solution, 50% dimethylamine was diluted 10 times by weight with ultrapure water, and 10 to 100 μl was added to the test paper.

The deodorization test method is the same as in Example 1.

FIG. 2 shows changes over time in the concentration of each odorous substance. FIG. 2A shows the change over time in the ammonia concentration, and FIG. 2B shows the change over time in the dimethylamine concentration. As the density in FIG. 2B, a value obtained by multiplying the measured value by a correction coefficient of 0.9 was used. Each was compared with the change over time in the case of using control paper. As shown in FIG. 2 (A) and FIG. 2 (B), both the ammonia concentration and the dimethylamine concentration are less than half that of the control paper, and the deodorant composition extracted with ethyl acetate is also ammonia. And it was confirmed that it has a deodorizing effect on dimethylamine.

(Example 3)
The deodorizing effects of gallic acid, pentagalloylglucose and astragalin, which are the main components of the deodorant composition extracted from the petals of peony, were confirmed.

A method for preparing a test paper carrying gallic acid, pentagalloylglucose and astragalin is shown below. First, each refined form powder was dissolved in special grade methanol, and 500 ml of each solution was divided into 2 times in the same shape as in the paper used in Example 2, and 1 ml was soaked on the entire surface of the paper. And it air-dried in the clean bench for 15 minutes, and left and produced for 18 hours in the dark. Controlro paper was prepared by impregnating 1 ml of methanol and performing the same treatment. The amount of each vote article test filter paper is supported ^{is, 1mg (168μg / cm 2)} , 0.3mg (50.0μg / cm 2), and the three levels of 0.1mg (16.8μg / cm ^2).

The preparation of the odor solution and the deodorization test method are the same as in Example 2.

FIG. 3 shows the change over time in the concentration of each odorous substance due to gallic acid. FIG. 3A shows the change over time in the ammonia concentration, and FIG. 3B shows the change over time in the dimethylamine concentration. As the density in FIG. 3B, a value obtained by multiplying the measured value by a correction coefficient of 0.9 was used. Each was compared with the change over time in the case of using control paper. As shown in FIGS. 3A and 3B, both the ammonia concentration and the dimethylamine concentration greatly decreased as the amount of gallic acid carried increased. Thereby, it was confirmed that gallic acid has a strong deodorizing effect on ammonia and dimethylamine.

FIG. 4 shows the change over time of the concentration of each odorous substance due to pentagalloyl glucose. FIG. 4A shows the change over time in the ammonia concentration, and FIG. 4B shows the change over time in the dimethylamine concentration. For the density in FIG. 4B, a value obtained by multiplying the measured value by a correction coefficient of 0.9 was used. Each was compared with the change over time in the case of using control paper. As shown in FIGS. 4 (A) and 4 (B), both the ammonia concentration and the dimethylamine concentration decreased as the amount of the supported pentagalloyl glucose increased. Thereby, it was confirmed that pentagalloyl glucose has a strong deodorizing effect on ammonia and dimethylamine.

FIG. 5 shows the change over time of the concentration of each odorous substance by astragalin. FIG. 5A shows the change over time in the ammonia concentration, and FIG. 5B shows the change over time in the dimethylamine concentration. As the density in FIG. 5B, a value obtained by multiplying the measured value by a correction coefficient of 0.9 was used. Each was compared with the change over time in the case of using control paper. As shown in FIG. 5A, after 30 minutes from the start of the test, the ammonia concentration decreased compared to control paper. In addition, as shown in FIG. 5B, when the amount of astragalin carried was 1 mg, the dimethylamine concentration was reduced as compared to control paper. Thereby, it was confirmed that astragalin has a deodorizing effect on ammonia and dimethylamine.

[Effect of Best Embodiment]
(1) The deodorant composition of the present invention, particularly the deodorant composition extracted from the petals and / or leaves of peony has a high deodorizing action and should be suitably used for various deodorization applications. Can do. Of the extracts extracted from peony petals and / or leaves, gallic acid, pentagalloylglucose and astragalin were found to have a good deodorizing effect. Gallic acid has a strong deodorizing action, and particularly shows a remarkable deodorizing action on nitrogen compounds. Since pentagalloylglucose has not only a strong deodorizing action like gallic acid but also antibacterial properties, it can suppress the generation of malodor associated with the growth of microorganisms. Astragalin also has a good deodorizing effect and also exhibits a deodorizing effect on nitrogen compounds. Accordingly, a deodorant composition containing at least one of gallic acid, pentagalloylglucose, and astragalin exhibits a good deodorizing action and can be preferably used. Since galloylglucose such as pentagalloylglucose and astragalin are once supported on the fiber structure, it is difficult to remove them from the fiber even by a substance having a high cleaning effect such as a detergent.

(2) Since the peony petals and leaves contain more deodorant components than other parts such as roots and stems, the deodorant composition can be efficiently extracted.

(3) Biological odors such as human odor and body odor are mostly due to inorganic nitrogen compounds such as ammonia and organic nitrogen compounds such as amines. Since the deodorizing composition has a deodorizing action on the nitrogen compound, it can be suitably used for the deodorizing application of the odor produced by the biological nitrogen compound.

(4) The deodorant composition of the present invention can be suitably used as a deodorant having a strong deodorant action by being contained in the deodorant. Moreover, since the deodorizing composition of this invention has the outstanding deodorizing effect, it can carry | support to a fiber structure and can be used suitably as a deodorizing tool. Furthermore, since the deodorant composition of the present invention is a plant-derived natural component, it is less irritating to the skin and can be particularly suitably used for a fiber structure that is in direct contact with the skin.

[Other Embodiments]
The application of the deodorant composition of the present invention is not limited to the above, and can be used for various applications requiring a deodorizing action. For example, a liquid deodorant can be applied to an object to be deodorized and used.

The time-dependent change of the density | concentration of each odorous substance in Example 1 is shown. FIG. 1A shows the change over time in the ammonia concentration, and FIG. 1B shows the change over time in the dimethylamine concentration. The time-dependent change of the density | concentration of each odorous substance in Example 2 is shown. FIG. 2A shows the change over time in the ammonia concentration, and FIG. 2B shows the change over time in the dimethylamine concentration. The time-dependent change of the concentration of each odorous substance by gallic acid is shown. FIG. 3A shows the change over time in the ammonia concentration, and FIG. 3B shows the change over time in the dimethylamine concentration. The time-dependent change of the density | concentration of each odorous substance by a pentagalloyl glucose is shown. FIG. 4A shows the change over time in the ammonia concentration, and FIG. 4B shows the change over time in the dimethylamine concentration. The time-dependent change of the concentration of each odorous substance by astragalin is shown. FIG. 5A shows the change over time in the ammonia concentration, and FIG. 5B shows the change over time in the dimethylamine concentration.

Claims (4)

A deodorant composition containing only at least one of gallic acid, galloylglucose and astragalin and having a deodorizing action on nitrogen compounds is extracted from the petals and / or leaves of peony. Deodorant characterized by containing as follows. Extracted from peony petals and / or leaves, gallic acid, galloyl glucose and deodorant component only deodorant composition having a contains at least one, deodorizing effect on nitrogen compounds of astragalin deodorizing device which comprising the carrying fiber structure as. The deodorizing tool according to claim 2 , wherein the fiber structure is used in contact with the skin and has a deodorizing action on a biological nitrogen compound. The deodorant tool according to claim 2 or 3 , wherein the deodorant composition contains at least one of galloyl glucose and astragalin.

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