The present invention relates to a growth inhibitor of bacteria of the genus Legionella, and a bath agent and a cleaning agent containing the growth inhibitor.
Bacteria of the genus Legionella are aerobic Gram-negative bacilli. It has been discovered that the bacteria are likely to grow in, for example, a bathing facility and a cooling tower. A Legionella infection is caused by inhalation of an aerosol containing bacteria of the genus Legionella. The Legionella infection includes Legionella pneumonia and Pontiac fever. Legionella pneumonia is known to be an infection with high mortality. Patent Document 1 discloses that an ingredient extracted from bamboo grass inhibits the growth of bacteria of the genus Legionella.
At the same time, as described in Patent Document 2, it is known that an extract of Macaranga tanarius (Oobagi), which belongs to the genus Macaranga of the family Euphorbiaceae, has an antimicrobial action. However, the action of the Macaranga tanarius extract on bacteria of the genus Legionella has not been clarified yet, and also Patent Document 2 does not describe it at all.
Patent Document 1: Japanese Laid-Open Patent Publication No. 2006-45077
Patent Document 2: Japanese Laid-Open Patent Publication No. 2007-45754
The present invention is based on the fact that the inventors have found, as a result of their intensive studies, that an extract of Macaranga tanarius has an inhibitory action on the growth of bacteria of the genus Legionella, and an objective thereof is to provide a novel growth inhibitor of bacteria of the genus Legionella, and a bath agent and a cleaning agent containing the growth inhibitor.
In order to achieve the above-mentioned objective, a first aspect of the present invention provides a growth inhibitor of bacteria of the genus Legionella containing as an active ingredient a Macaranga tanarius extract extracted from Macaranga tanarius with an extraction solvent including at least an organic solvent.
A second aspect of the present invention provides a growth inhibitor of bacteria of the genus Legionella containing as an active ingredient at least one selected from nymphaeol-A, nymphaeol-B, and nymphaeol-C.
A third aspect of the present invention provides a bath agent containing the growth inhibitor of bacteria of the genus Legionella according to the above first or second aspect of the present invention.
A fourth aspect of the present invention provides a cleaning agent containing the growth inhibitor of bacteria of the genus Legionella according to the above first or second aspect of the present invention.
An embodiment of the present invention will be described in detail below.
A growth inhibitor of bacteria of the genus Legionella according to the present embodiment contains as an active ingredient an Oobagi extract extracted from Oobagi with an extraction solvent including at least an organic solvent. Oobagi is also called Macaranga tanarius and is a dioecious broad-leaved evergreen tree belonging to the genus Macaranga of the family Euphorbiaceae. Macaranga tanarius grows, for example, in Southeast Asia, such as Okinawa (southern Japan), Taiwan, southern China, the Malay Peninsula, the Philippines, Malaysia, Indonesia, and Thailand, and in northern Australia. Macaranga tanarius grows significantly fast compared to other trees and can grow on degraded lands.
All the organs of Macaranga tanarius and constituents of each organ can be used as raw material to be subjected to extraction with the extraction solvent. The raw material for extraction may be a single organ of Macaranga tanarius or its constituents or may be a mixture of two or more organs of Macaranga tanarius or their constituents. In order to enhance the growth-inhibitory action of the resulting Macaranga tanarius extract on bacteria of the genus Legionella, it is preferred to use the raw material for extraction which includes fruit, seeds, flowers, roots, a trunk, the tip of a stem, a leaf blade, or an exudate (such as wax) of Macaranga tanarius. Since the tip of the stem includes a growth point of the stem and a leaf bud and is softer than the leaf blade, an efficient extraction procedure thereof is easy. Furthermore, the occupation ratios of the trunk, the roots, and the leaves to the entire Macaranga tanarius are high compared to those of other organs. Therefore, the use of leaf blade of Macaranga tanarius as a raw material for extraction is industrially advantageous from the standpoint of easiness of obtaining the raw material.
The raw material for extraction is subjected to an extraction procedure in the state when it is harvested, in the state that it is pulverized, crushed, or ground after the harvest, in the state that it is pulverized, crushed, or ground after the harvest and drying, or in the state that it is crushed, pulverized, or ground after the harvest and then is dried. In order to efficiently perform the extraction, the raw material for extraction is preferably crushed. The crushing of the raw material for extraction can be performed, for example, using a cutter, a shredder, or a crusher. The raw material for extraction can be pulverized using, for example, a mill, a crusher, or a grinder. The raw material for extraction can be ground using, for example, a kneader or a mortar.
The extraction solvent used for extracting a Macaranga tanarius extract from the raw material for extraction may be a solvent mixture of water and an organic solvent or may be an organic solvent such as lower alcohol, dimethyl sulfoxide, acetonitrile, acetone, ethyl acetate, hexane, glycerin, or propylene glycol. Examples of the lower alcohol that can be used include methanol, ethanol, propanol, isopropanol, and butanol. As the organic solvent, only one type of solvent may be used, or a mixture of a plurality of types of solvents may be used. When a solvent mixture of water and an organic solvent is used as the extraction solvent, the content of the organic solvent in the solvent mixture is preferably 50% by volume or more and more preferably 80% by volume or more. When the content of the organic solvent in a solvent mixture is 50% by volume or more, the active ingredient contained in Macaranga tanarius can be particularly efficiently extracted. The organic solvent is preferably lower alcohol and more preferably ethanol.
In the extraction solvent, for example, an organic salt, an inorganic salt, a buffer, an emulsifier, and dextrin may be dissolved.
The extraction is performed by immersing the raw material for extraction in the above extraction solvent for a predetermined time. In the extraction, according to need, for example, either stirring or heating or the both of them may be conducted for increasing the extraction efficiency. Furthermore, in order to minimize extraction of unnecessary impurities into the extraction solvent, prior to the extraction with the extraction solvent, the raw material for extraction may be prepared by being subjected to extraction with water or hot water and removing the extraction water in advance. The ingredient that is contained in Macaranga tanarius and presumably has an inhibitory action on the growth of bacteria of the genus Legionella is nymphaeols. The nymphaeols are water-insoluble. Impurities other than the nymphaeols are efficiently transferred to extraction water by boiling Macaranga tanarius with, for example, hot water and are thereby removed.
A Macaranga tanarius extract extracted from the raw material for extraction is subjected to solid liquid separation to separate and remove the residue of the raw material for extraction. The solid liquid separation is performed, for example, by a known method such as filtration or centrifugation. The Macaranga tanarius extract in a liquid form after the solid liquid separation may be concentrated according to need.
A Macaranga tanarius extract in a solid form can be obtained by removing the extraction solvent contained in the Macaranga tanarius extract in the liquid form, according to need. The removal of the extraction solvent from the Macaranga tanarius extract in the liquid form may be performed, for example, by heating under reduced pressure or by lyophilization.
The Macaranga tanarius extract extracted from Macaranga tanarius with an extraction solvent including at least an organic solvent contains at least one selected from nymphaeol-A (also known as 5,7,3′,4′-tetrahydroxy-6-geranylflavanone), nymphaeol-B (also known as 5,7,3′,4′-tetrahydroxy-2′-geranylflavanone), and nymphaeol-C (also known as 5,7,3′,4′-tetrahydroxy-6-(3″′,3″′-dimethylallyl)-2′-geranylflavanone). A main ingredient of the Macaranga tanarius extract is at least one selected from nymphaeol-A, nymphaeol-B, and nymphaeol-C, that is, nymphaeols, and the nymphaeols presumably have an inhibitory action on the growth of bacteria of the genus Legionella.
The Macaranga tanarius extract further contains propolin A (also known as 5,7,3′,4′-tetrahydroxy-2′-(7″-hydroxy-3″,7″-dimethyl-2″-octenyl)-flavanone). Furthermore, the Macaranga tanarius extract contains as minor ingredients, for example, 5,7,3′,4′-tetrahydroxy-5′-geranylflavanone (also known as isonymphaeol-B), 5,7,3′,4′-tetrahydroxy-5′-(7″-hydroxy-3″,7″-dimethyl-2″-octenyl)-flavanone, 5,7,3′,4′-tetrahydroxy-6-(7″-hydroxy-3″,7″-dimethyl-2″-octenyl)-flavanone, 5,7,4′-trihydroxy-3′-(7″-hydroxy-3″,7″-dimethyl-2″-octenyl)-flavanone, and 5,7,4′-trihydroxy-3′-geranylflavanone.
Among extract solutions each extracted from portions of Macaranga tanarius, an extract solution extracted from flowers, seeds, and fruit (containing wax) particularly contains high concentrations of nymphaeol-A, B, and C and isonymphaeol-B.
The growth inhibitor of bacteria of the genus Legionella may contain a component other than the Macaranga tanarius extract as long as the inhibitory action on the growth of bacteria of the genus Legionella is not impaired. Examples of the component that can be contained in the growth inhibitor of bacteria of the genus Legionella, in addition to the Macaranga tanarius extract, include an excipient, a base, an emulsifier, a stabilizer, and a flavoring.
The growth inhibitor of bacteria of the genus Legionella may be in a liquid form or in a solid form. The dosage form of the growth inhibitor of bacteria of the genus Legionella is not particularly limited and may be, for example, a powder, a dust, a granule, a tablet, a capsule, a pill, or a liquid. The growth inhibitor of bacteria of the genus Legionella prepared in a solid form is used, for example, by being supported on a filter that is set in a pipe for drainage or water circulation and a bacteria removal facility.
For example, a surfactant, a chelating agent, an emulsifier, or ethanol can be added to the growth inhibitor of bacteria of the genus Legionella to improve the water dispersibility and water solubility of the Macaranga tanarius extract.
Inhibition of the growth of bacteria of the genus Legionella is extremely important in order to prevent a Legionella infection such as Legionella pneumonia and Pontiac fever caused by inhalation of an aerosol containing bacteria of the genus Legionella. The growth inhibitor of bacteria of the genus Legionella is useful in preventing human infection with bacteria of the genus Legionella through inhibition of the growth of bacterial of the genus Legionella.
While Legionella pneumophila is known as a representative bacterium of the genus Legionella, several tens of species of bacteria of the genus Legionella have been identified at present, and all of them are considered to possibly cause a Legionella infection.
The growth inhibitor of bacteria of the genus Legionella can be applied to a site where the growth of bacterial of the genus Legionella is expected without any particular limitation. Specifically, the growth inhibitor of bacteria of the genus Legionella is added, for example, to water used in a bathing facility, a water and hot-water supply facility, a cooling tower, a humidifier, a waterscape facility, and a thermal storage tank. Infections caused by bacterial of the genus Legionella is likely to occur particularly in the elderly, neonates, and infants and young children, who have low resistance. Since the active ingredient of the growth inhibitor of bacteria of the genus Legionella of the present embodiment is the Macaranga tanarius extract, which is originated from a natural substance, the growth inhibitor can be safely used in a medical facility and a welfare facility for the elderly.
The growth inhibitor of bacteria of the genus Legionella can be used as, for example, a bath agent, a cleaning agent, a deodorant, and a fragrance. Since the growth inhibitor is easily applicable to such a site that could be a source of generation of the bacteria as described above, it is preferably used as a bath agent or a cleaning agent. It is desirably used in such a way that the total concentration of nymphaeol-A, nymphaeol-B, and nymphaeol-C, that is, the concentration of nymphaeols, in a site that could be a source of generation of the bacteria of the genus Legionella is preferably 15 ppm or more, and more preferably 20 ppm or more. When the concentration of nymphaeols is 15 ppm or more, an inhibitory action on the growth of bacteria of the genus Legionella is particularly well exerted.
The bath agent of the present embodiment contains the above-mentioned growth inhibitor of bacteria of the genus Legionella. The agent form of the bath agent can be, for example, a solid, a liquid, and a powder. The bath agent contains at least one selected from, for example, a water-soluble inorganic salt, a colorant, a fragrance, a humectant, a pH regulator, a vitamin, a herbal medicine, an organic salt, and an enzyme, in addition to the above-mentioned growth inhibitor of bacteria of the genus Legionella. Examples of the water-soluble inorganic salt include a carbonate such as sodium carbonate and sodium bicarbonate, a silicate such as sodium metasilicate, a phosphate such as sodium orthophosphate, a sulfate such as sodium sulfate and magnesium sulfate, and a chloride such as sodium chloride, calcium chloride, and ammonium chloride.
By using such a bath agent by mixing it into a bath liquid in a bathing facility, the growth of bacteria of the genus Legionella can be inhibited in a bathtub, a pipe circulating the bath liquid into the bathtub, a filter connected to the pipe, and a heat exchanger while the bathing facility is in operation. Therefore, the bath agent of the present embodiment is suitable for preventing human infection by bacteria of the genus Legionella in various bathing facilities. The content of the Macaranga tanarius extract in the bath agent can be appropriately set according to the amount of the bath agent to be mixed in a bath liquid. The bath agent is desirably used in such a way that the total concentration of nymphaeol-A, nymphaeol-B, and nymphaeol-C, that is, the concentration of nymphaeols, in a bath liquid is preferably 15 ppm or more, and more preferably 20 ppm or more. When the concentration of nymphaeols in a bath liquid is 15 ppm or more, an inhibitory action on the growth of bacteria of the genus Legionella is particularly well exerted.
The cleaning agent of the present embodiment contains the above-mentioned growth inhibitor of bacteria of the genus Legionella. The agent form of the cleaning agent can be, for example, a solid, a liquid, and a powder. The cleaning agent contains at least one selected from, for example, a surfactant, a chelating agent, and a pH regulator, in addition to the above-mentioned growth inhibitor of bacteria of the genus Legionella. The cleaning agent may further contain a chlorine-based or an oxygen-based disinfectant according to need.
The cleaning agent is used, for example, by being periodically contacted with a site that could be a source of generation of bacterial of the genus Legionella for a predetermined time. In more detail, a site that could be a source of generation of bacterial of the genus Legionella may be immersed in a diluted liquid of the cleaning agent, which is obtained by appropriately diluting the cleaning agent. Alternatively, the cleaning agent may be directly sprayed to a site that could be a source of generation of bacterial of the genus Legionella. The content of the Macaranga tanarius extract in the cleaning agent can be appropriately set according to the application form of the cleaning agent. The cleaning agent is desirably used in such a way that the total concentration of nymphaeols in a site that could be a source of generation of bacterial of the genus Legionella is preferably 15 ppm or more, and more preferably 20 ppm or more. When the concentration of nymphaeols is 15 ppm or more, an inhibitory action on the growth of bacteria of the genus Legionella is particularly well exerted.
According to the present embodiment, the following advantageous effects are achieved.
The growth inhibitor of bacteria of the genus Legionella of the present embodiment is a novel growth inhibitor of bacteria of the genus Legionella containing the Macaranga tanarius extract as an active ingredient. The growth inhibitor is useful in preventing infection by bacteria of the genus Legionella through inhibition of the growth of bacterial of the genus Legionella.
In addition, since Macaranga tanarius grows significantly fast compared to other trees and can grow on degraded lands, the cultivation does not take much effort. Furthermore, since the Macaranga tanarius extract is originated from a plant, it is highly safe. Therefore, the growth inhibitor of bacteria of the genus Legionella of the present embodiment is also excellent in stable supply of raw material, productivity, and safety.
Since the bath agent and the cleaning agent of the present embodiment contain the above-mentioned growth inhibitor of bacteria of the genus Legionella, they have an inhibitory action on the growth of bacteria of the genus Legionella.
The above-described embodiment may be modified as follows.
The growth inhibitor of bacteria of the genus Legionella of the above embodiment may contain at least one selected from nymphaeol-A, nymphaeol-B, and nymphaeol-C that are not originated from Macaranga tanarius extracts, as an active ingredient, instead of the Macaranga tanarius extract or in addition to the Macaranga tanarius extract. Nymphaeol-A, nymphaeol-B, and nymphaeol-C that are not originated from Macaranga tanarius extracts can be obtained by, for example, chemical synthesis.
Bacteria of the genus Legionella exist in a natural environment such as soil. Therefore, there is a risk that bacteria of the genus Legionella might grow in soil or fertilizer for gardening that is kept in a sealed bag made of resin. In view of the above, with the aim of preventing human infection by bacteria of the genus Legionella via soil or fertilizer for gardening, the growth inhibitor of bacteria of the genus Legionella of the above-mentioned embodiment may be used by being added to soil or fertilizer for gardening. Since the active ingredient of the growth inhibitor of bacteria of the genus Legionella is the Macaranga tanarius extract, which is originated from a natural substance, when the soil or the fertilizer containing the growth inhibitor of bacteria of the genus Legionella is used to cultivate a garden plant, the growth of the plant is hardly inhibited.
Next, the present invention will be further specifically described with reference to examples.
Frozen raw leaves of Macaranga tanarius harvested in Okinawa were thawed, and the leaves were cut into small pieces with scissors. Thirty grams of the cut raw leaves were immersed in 100 mL of a solvent mixture consisting of 90 parts by volume of ethanol and 10 parts by volume of water and left standing at room temperature for two weeks, followed by filtration to yield the filtrate as a Macaranga tanarius extract solution. The Macaranga tanarius extract solution was lyophilized to prepare a Macaranga tanarius extract that was a powder of the solid content contained in the Macaranga tanarius extract solution. The total concentration of nymphaeol-A, nymphaeol-B, and nymphaeol-C, that is, the concentration of nymphaeols, in the Macaranga tanarius extract in the powder form was 50% by mass when calculated from the chromatogram shown in
System: PDA-HPLC system (Shimadzu Corp.), LC10ADvp series, UV:
SPD-10Avp, PDA: SPD-M10Avp,
Solvent: A: water (5% acetic acid), B: acetonitrile (5% acetic acid)
0 to 20 minutes
(gradient dissolution: A:B=80:20→A:B=30:70)
20 to 50 minutes
(gradient dissolution: A:B=30:70→A:B=0:100)
50 to 60 minutes (A:B=0:100)
60 to 75 minutes (A:B=80:20)
Flow rate: 0.2 mL/min
PDA detection: UV from 190 to 370 nm
UV detection: UV 287 nm
Injection amount: 20 μL
A strain of bacteria of the genus Legionella, Legionella pneumophila (GIFU9134), was cultured at 37° C. for four days using a buffered charcoal yeast extract (BCYE) medium supplemented with L-cysteine. Then, the bacteria thus obtained were suspended in a phosphate buffer to prepare a bacterial liquid for inoculation having a bacterial count of 106 to 107 CFU/mL.
The above-mentioned Macaranga tanarius extract in a powder form was mixed in 99.5 V/V % ethanol to prepare a sample liquid having a concentration of the Macaranga tanarius extract of 100×103 ppm. Further, by diluting the sample liquid with 99.5 V/V % ethanol, sample liquids in doubling-dilution series, that is, sample liquids having respective concentrations of the Macaranga tanarius extract of 50×103 ppm, 25×103 ppm, 12.5×103 ppm, 6.25×103 ppm, 3.13×103 ppm, and 1.56×103 ppm, were also prepared.
To 99% by mass of B-SYEα media, which had been kept warm at 50 to 60° C. after sterilization, 1% by mass of each sample liquid was added and thoroughly mixed. The mixtures were dispensed into petri dishes and solidified. Accordingly, plate media for sensitivity measurement having respective concentrations of the Macaranga tanarius extract of 1,000 ppm, 500 ppm, 250 ppm, 125 ppm, 62.5 ppm, 31.3 ppm, and 15.6 ppm were prepared. The plate media thus prepared were dried in a clean bench. B-SYEα media is composed of 1.5 g of starch, 1.0 g of yeast extract, 1.3 g of agar, 1 vial of Legionella BSYEα Growth Supplement (OXOID), and 100 mL of purified water.
The bacterial liquid for inoculation was streaked on the plate media for sensitivity measurement using a loop having an inner diameter of 1 mm. Subsequently, the bacterial strain on each plate medium was cultured at 37° C. for three days.
Observation of the plate media after culturing showed that the growth of bacteria of the genus Legionella was inhibited in the plate media having a concentration of the Macaranga tanarius extract of 31.3 ppm or more. In other words, the minimum inhibitory concentration (MIC) of the Macaranga tanarius extract of Example 1 against bacteria of the genus Legionella was 31.3 ppm. As described above, since the Macaranga tanarius extract of Example 1 contains 50% by mass of nymphaeols, it is speculated from the above results that the concentration of nymphaeols in practical application is preferably 15.6 ppm or more.
Thirty grams of cut raw leaves of Macaranga tanarius were immersed in 95° C. water for 30 minutes. The water was removed by filtration, and the remaining leaves were immersed in 100% ethanol for 3 days, followed by filtration to yield the filtrate as a Macaranga tanarius extract solution. The Macaranga tanarius extract solution was lyophilized to prepare a Macaranga tanarius extract that was a powder of the solid content contained in the Macaranga tanarius extract solution. The total concentration of nymphaeol-A, nymphaeol-B, and nymphaeol-C, that is, the concentration of nymphaeols, in the Macaranga tanarius extract in the powder form was 40% by mass when calculated from the chromatogram shown in
An antimicrobial activity test was performed as in Example 1. Regarding the Macaranga tanarius extract prepared in Example 2, similar results as those of the Macaranga tanarius extract prepared in Example 1 were obtained to show that the antimicrobial activities of the Macaranga tanarius extract prepared in Example 1 and the Macaranga tanarius extract prepared in Example 2 were similar to each other.
Number | Date | Country | Kind |
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2008-059780 | Mar 2008 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2009/053607 | 2/26/2009 | WO | 00 | 9/8/2010 |