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JP2001178431A - Proliferation inhibitor against heat-resistant end spore- forming bacterium - Google Patents

Proliferation inhibitor against heat-resistant end spore- forming bacterium

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Publication number
JP2001178431A
JP2001178431A JP36798399A JP36798399A JP2001178431A JP 2001178431 A JP2001178431 A JP 2001178431A JP 36798399 A JP36798399 A JP 36798399A JP 36798399 A JP36798399 A JP 36798399A JP 2001178431 A JP2001178431 A JP 2001178431A
Authority
JP
Japan
Prior art keywords
spore
heat
coffee beans
green coffee
manufactured
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Pending
Application number
JP36798399A
Other languages
Japanese (ja)
Inventor
Toru Ogawa
徹 小川
Terutaka Mori
輝高 毛利
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Lion Corp
Original Assignee
Lion Corp
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Lion Corp filed Critical Lion Corp
Priority to JP36798399A priority Critical patent/JP2001178431A/en
Publication of JP2001178431A publication Critical patent/JP2001178431A/en
Pending legal-status Critical Current

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Abstract

PROBLEM TO BE SOLVED: To provide a proliferation inhibitor which is used against heat-resistant end spore-forming bacteria, has a high proliferation inhibiting action against the heat-resistant end spore-forming bacteria, has good biodegradability, and has excellent safety for human bodies. SOLUTION: This proliferation inhibitor against heat-resistant end spore- forming bacteria, characterized by containing as an active ingredient a fermentation liquid obtained by fermenting raw coffee beans.

Description

【発明の詳細な説明】DETAILED DESCRIPTION OF THE INVENTION

【0001】[0001]

【発明の属する技術分野】本発明は、一般に、レトルト
殺菌等で知られる高温・高圧条件下での加熱殺菌方法や
化学薬品処理等以外に有効的な手段がない耐熱性芽胞形
成細菌の増殖を抑制することができる耐熱性芽胞形成細
菌増殖抑制剤及びその製造方法に関する。
BACKGROUND OF THE INVENTION The present invention relates to the growth of heat-resistant spore-forming bacteria, which generally have no effective means other than heat sterilization methods under high temperature and high pressure conditions known as retort sterilization and chemical treatment. The present invention relates to a thermostable spore-forming bacterial growth inhibitor that can be suppressed and a method for producing the same.

【0002】[0002]

【従来の技術】従来より、天然原料・素材を用いる加工
食品の品質保持における最大の課題は、微生物の制御で
あり、微生物による腐敗や変質を極力抑えて安定的に流
通させることが当該製造業者に求められている。一般
に、自然界には、多数の微生物が存在し、人類と共存す
ることが常であるが、時と場合によりそれらの存在は有
害に作用することがある。耐熱性芽胞形成細菌は、薬剤
や熱に対する強固な耐性を持つことが知られており、通
常の加熱処理条件では死滅せず、製造場面では最終的な
製品にまで残存し品質に悪影響を及ぼすものである。
2. Description of the Related Art Conventionally, the biggest problem in maintaining the quality of processed foods using natural raw materials and materials is the control of microorganisms, and it is the manufacturer of the manufacturer that minimizes spoilage and deterioration caused by microorganisms and distributes them stably. Is required. In general, there are many microorganisms in nature and usually coexist with human beings, but their presence can sometimes be harmful. Thermostable spore-forming bacteria are known to have strong resistance to drugs and heat, and do not die under normal heat treatment conditions, but remain in the final product in the production stage and adversely affect quality. It is.

【0003】通常行われている加熱殺菌は、簡便且つ有
効な手段として古くから用いられ、現在も常用されてい
る。しかしながら、加熱殺菌方法は、加熱による食品素
材そのものへの負荷・影響を考慮した場合の風味、香味
や有用成分の安定性等に対する悪影響は著しく、また、
殺菌効果とのバランスから加熱温度と時間に限界がある
ため、常在菌であるバチルス属に代表される耐熱性芽胞
形成細菌には十分な効果が期待できない場合がある。
[0003] Heat sterilization, which is usually performed, has been used for a long time as a simple and effective means, and is still commonly used at present. However, the heat sterilization method has a remarkable adverse effect on the flavor, flavor, stability of useful components, and the like when the load and influence on the food material itself due to heating are considered,
Since there is a limit to the heating temperature and time from the balance with the bactericidal effect, a sufficient effect may not be expected for heat-resistant spore-forming bacteria represented by Bacillus, which is a resident bacterium.

【0004】従来、食品分野では、防腐・防黴を目的に
食品添加物である保存料や、日持ち向上剤が使用され、
加工食品や香粧品等の製品の保存流通期間中における品
質保持に大きく貢献してきている(「別冊フードケミカ
ル5 保存料総覧」,食品化学新聞社,平成5年5月2
5日発行)。
[0004] Conventionally, in the food field, preservatives as food additives and shelf life improvers have been used for the purpose of preservation and fungicide.
It has greatly contributed to quality preservation during the preservation and distribution period of products such as processed foods and cosmetics (“Food Chemical 5 Preservatives Overview”, Food Chemistry Newspaper, May 2, 1993)
5th).

【0005】このような事情から、従来以上に食品の保
存技術の重要性がますます増してきており、中でも耐熱
性芽胞形成細菌に対して顕著な効果を示す制御技術の開
発が望まれているのが現状である。特に、食品分野で
は、人体に摂取されることを考慮し安全であることが必
須要件であるが、このような観点からショ糖脂肪酸エス
テルやグリセリン脂肪酸エステルなどの食品添加物を主
剤とした保存料、日持ち向上剤が多く用いられている
(「食衛誌」第18巻、第3号、第217頁,日高 徹
著「食品用乳化剤 第2版」、244ページ、幸書房発
行)。
[0005] Under these circumstances, the importance of food preservation techniques has been increasing more and more than ever, and among them, the development of control techniques that have a remarkable effect on thermostable spore-forming bacteria has been desired. is the current situation. In particular, in the food field, it is essential to be safe in consideration of ingestion by the human body, but from such a viewpoint, preservatives mainly containing food additives such as sucrose fatty acid esters and glycerin fatty acid esters Many of the shelf life improvers are used ("Essential Emulsifiers, 2nd Edition", by Tohru Hidaka, ed., Eds., Published by Koshobo).

【0006】しかしながら、これらの食品添加物を主剤
とした保存料、日持ち向上剤では、耐熱性芽胞形成細菌
に対する殺菌効力等の面で未だ十分に満足しうるもので
はなかったものである。
However, these preservatives and preservatives containing food additives as main agents have not been sufficiently satisfactory in terms of bactericidal efficacy against heat-resistant spore-forming bacteria.

【0007】[0007]

【発明が解決しようとする課題】本発明は、上記従来の
課題及び現状等に鑑み、これを解消しようとするもので
あり、安全性に優れ、且つ耐熱性芽胞形成細菌に対して
高い増殖抑制効果を発現させることができる耐熱性芽胞
形成細菌増殖抑制剤を提供することを目的とする。
DISCLOSURE OF THE INVENTION The present invention has been made in view of the above-mentioned conventional problems and the present situation, and has been made in order to solve the problems. An object of the present invention is to provide a thermostable spore-forming bacterial growth inhibitor capable of exhibiting an effect.

【0008】[0008]

【課題を解決するための手段】本発明者らは、上記従来
の課題等を解決するため鋭意研究を重ねた結果、コーヒ
ー生豆を発酵させて得た発酵液に、耐熱性芽胞形成細菌
に対する増殖抑制効果を見い出し、本発明を完成するに
至ったのである。すなわち、本発明は、次の(1)及び(2)
に存する。 (1) コーヒー生豆を発酵させて得た発酵液を有効成分と
することを特徴とする耐熱性芽胞形成細菌増殖抑制剤。 (2) 発酵液には、下記分析データで示される成分が含有
される上記(1)記載の耐熱性芽胞形成細菌増殖抑制剤。 分析データ:分析用ODSカラム(YMC社製分析用ODSカラ
ム、YMC-PACK ODS-AQ AQ-312,6.0×150mm)を用いて、
カラム温度30℃、流速1.0ml/分、メタノール/
水/酢酸(20/80/0.3)を溶出液として行った
高速液体クロマトグラフイ―において、市販のコーヒー
飲料には存在せず、同条件で検出されるクロロゲン酸や
カフェインのより必ず前に溶出される二成分を含むこ
と。
Means for Solving the Problems The present inventors have conducted intensive studies in order to solve the above-mentioned conventional problems and the like. As a result, fermented liquid obtained by fermenting green coffee beans has been added to heat-resistant spore-forming bacteria. They found a growth inhibitory effect and completed the present invention. That is, the present invention provides the following (1) and (2)
Exists. (1) A heat-resistant spore-forming bacterial growth inhibitor comprising, as an active ingredient, a fermented liquid obtained by fermenting green coffee beans. (2) The heat-resistant spore-forming bacterial growth inhibitor according to the above (1), wherein the fermented liquid contains a component represented by the following analysis data. Analytical data: Using an analytical ODS column (analytical ODS column manufactured by YMC, YMC-PACK ODS-AQ AQ-312, 6.0 × 150 mm)
Column temperature 30 ° C., flow rate 1.0 ml / min, methanol /
In high performance liquid chromatography using water / acetic acid (20/80 / 0.3) as an eluent, chlorogenic acid and caffeine, which do not exist in commercial coffee drinks but are detected under the same conditions, must be used. Contains two components that are eluted before.

【0009】なお、本発明で規定する「耐熱性芽胞形成
細菌」とは、耐熱性を有する芽胞(胞子)を形成する細
菌をいい、具体的には、Bacillus属細菌(例えば、subt
ilis,cereus,stearothermophilus,megateriumな
ど)、Clostridium属細菌(例えば、ボツリヌス菌、spo
rpgenes,pertringensなど)、Actinomyces属細菌(例
えば、violaceusなど)等の細菌をいう。また、本発明
で規定する耐熱性芽胞形成細菌に対する「増殖抑制(効
果)」とは、液体培地中で微生物の増殖に供い観察され
る濁度の増減、並びに、通常法に従い所定の栄養を含ん
だ寒天培地と共にシャーレへ混釈後、培養期間を経た後
に計測しうるコロニー数での増減の差をいう。
The term "thermostable spore-forming bacterium" as defined in the present invention refers to a bacterium which forms a spore (spore) having heat resistance, and specifically, a bacterium belonging to the genus Bacillus (for example, subt.
ilis, cereus, stearothermophilus, megaterium, etc.), Clostridium bacteria (for example, Clostridium botulinum, spo
rpgenes, pertringens, etc.) and bacteria such as Actinomyces bacteria (eg, violaceus). The term “growth inhibition (effect)” for thermostable spore-forming bacteria as defined in the present invention refers to the increase or decrease in turbidity observed during the growth of microorganisms in a liquid medium, and the provision of a prescribed nutrient in accordance with ordinary methods. It refers to the difference in increase or decrease in the number of colonies that can be measured after a culture period after being poured into a petri dish together with a contained agar medium.

【0010】[0010]

【発明の実施の形態】以下に、本発明の実施の形態を詳
細に説明する。本発明における耐熱性芽胞形成細菌増殖
抑制剤は、コーヒー生豆を発酵させて得た発酵液を有効
成分とすることを特徴とするものである。
Embodiments of the present invention will be described below in detail. The heat-resistant spore-forming bacterial growth inhibitor of the present invention is characterized in that a fermented liquid obtained by fermenting green coffee beans is used as an active ingredient.

【0011】本発明に用いるコーヒー生豆としては、例
えば、ロブスタ種のインドネシアロブスタ等、リベリカ
種、アラビカ種のマンデリン、モカマタリ、ガテマラ、
キリマンジャロ、ブルーマウンテン、エチオピアモカ、
ハワイコナ、サントス等などが挙げられ、通常コーヒー
飲料に用いられるものであれば、特に限定されるもので
はない。ただし、これらのコーヒー生豆は、飲用に原料
として市販されているいずれのものであってもよいが、
コーヒー飲料を製造する以前の生豆であり、本発明では
焙煎された一切のコーヒー豆を除くものである。なお、
上記コーヒー生豆は、1種を単独で又は二種以上の混合
物として使用してもよい。
The green coffee beans used in the present invention include, for example, Robusta Indonesian Robusta, etc., Riberica and Arabica mandelins, Mocamatari, Guatemala, and the like.
Kilimanjaro, Blue Mountain, Ethiopia Mocha,
It is not particularly limited as long as it is commonly used for coffee beverages, such as Hawaii Kona and Santos. However, these green coffee beans may be any commercially available as a raw material for drinking,
It is green beans before producing a coffee beverage, and excludes all roasted coffee beans in the present invention. In addition,
The above green coffee beans may be used alone or as a mixture of two or more.

【0012】本発明において、コーヒー生豆を発酵させ
る際には、栄養物質を非共存で発酵させることができる
が、好ましくは、栄養物質の共存下にて発酵させること
が望ましい。栄養物質としては、コーヒー生豆を効率的
に発酵することができるものであれば、特に限定され
ず、例えば、0から5質量%(以下、単に「%」とい
う)のブドウ糖、ソイペプトンが0から1%、リン酸ニ
カリウムが0から0.5%、トリプトンが0から2%、
塩化ナトリウムが0から1%を含有する栄養培地が挙げ
られ、コーヒー生豆品種により異なるが、更に好ましく
は、ブドウ糖5%、ソイペプトン0.5%、リン酸ニカ
リウム0.1%、塩化ナトリウム1.0%を含有するも
のが望ましい。
In the present invention, when fermenting green coffee beans, nutrients can be fermented in the absence of nutrients, but preferably fermentation is performed in the coexistence of nutrients. The nutrient is not particularly limited as long as it can ferment green coffee beans efficiently. For example, 0 to 5% by mass (hereinafter, simply referred to as “%”) of glucose and soy peptone may be 0 to 5% by mass. 1%, dipotassium phosphate 0 to 0.5%, tryptone 0 to 2%,
A nutrient medium containing 0 to 1% of sodium chloride may be mentioned, and it varies depending on the type of green coffee bean. More preferably, glucose 5%, soypeptone 0.5%, dipotassium phosphate 0.1%, sodium chloride 1. Those containing 0% are desirable.

【0013】本発明において、コーヒー生豆を発酵させ
る際のコーヒー生豆の仕込み量は、仕込み量全量に対し
て、5から25%であり、好ましくは、10から20%
である。仕込み量が5%未満では、発酵の進みが遅く、
得られる耐熱性芽胞形成細菌抑制剤が少ないので耐熱性
芽胞形成細菌への効果が弱く、また、25%を越える仕
込み量では、コーヒー生豆が水分を吸収するため発酵濾
液(発酵液から不溶解物質等を分離・除去した溶液)が
十分に得られず、好ましくない。本発明では、コーヒー
生豆はそのままで、また、粉砕して用いてもよく、粉砕
はいかなる粒度に粉砕して用いてもよい。また、コーヒ
ー生豆は発酵させる前に品種により異なるが、の点から
加熱処理してもよい。その場合、60℃以上の温度、好
ましくは、60〜70℃で10から60分間の加熱処理
が好ましい。なお、通常の食用目的に用いられる焙煎さ
れたコーヒー豆は、煮沸に準じた熱湯で処理するもので
あり、上記加熱処理とは相違するものである。
In the present invention, the amount of green coffee beans to be fermented when green coffee beans are fermented is 5 to 25%, preferably 10 to 20%, based on the total amount of green coffee beans.
It is. If the charged amount is less than 5%, the progress of fermentation is slow,
Since the amount of the obtained heat-resistant spore-forming bacteria inhibitor is small, the effect on the heat-resistant spore-forming bacteria is weak. In addition, when the charged amount exceeds 25%, the green coffee beans absorb moisture, so that the fermentation filtrate (insoluble from the fermentation solution) A solution obtained by separating and removing substances and the like is not sufficiently obtained, which is not preferable. In the present invention, the green coffee beans may be used as they are, or may be ground and used, and the ground may be ground to any particle size. The green coffee beans vary depending on the variety before fermentation. In that case, a heat treatment at a temperature of 60 ° C. or higher, preferably 60 to 70 ° C., for 10 to 60 minutes is preferable. Note that roasted coffee beans used for normal edible purposes are treated with boiling water according to boiling, which is different from the above-described heat treatment.

【0014】本発明において、コーヒー生豆を発酵させ
る際には、pH4〜6.5の範囲、好ましくは、pH5
〜6の範囲で発酵させることが望ましい。発酵は当初p
H7から開始するが、pH4未満まで発酵させると、耐
熱性芽胞形成細菌への増殖抑制効果が劣り、6.5以上
の比較的発酵時間の少ないものでは効力が発現しないこ
とがある。発酵の開始時にpHを調整するアルカリ性化
合物としては、例えば、ナトリウム、カリウムなどのア
ルカリ金属の炭酸塩又は水酸化物、具体的には、炭酸ナ
トリウム、リン酸一ナトリウム、リン酸二ナトリウム、
炭酸カリウム、水酸化ナトリウム、水酸化カリウムなど
が挙げられる。好ましくは、炭酸ナトリウム、リン酸一
ナトリウム、リン酸二ナトリウム等の緩衝能を有するも
のが望ましい。また、上記発酵処理での反応温度は、特
に制限はないが、通常、20〜40℃、好ましくは、2
5〜37℃であり、発酵時間は、通常、24時間〜12
0時間である。また、本発明において行われる発酵に
は、接種し用いられる細菌菌株は不必要であり、コーヒ
ー生豆に天然に付着残存する微生物により、その発酵工
程は行われる。この発酵は、簡単な開放形タンクで十分
であるが、発酵槽として用いられるいかなる装置を用い
てもよく、例えば、柴田科学器械工業社より市販される
MDL-500型 バイオファーメンターを使用することがで
きる。
In the present invention, when fermenting green coffee beans, the pH is in the range of 4-6.5, preferably 5-5.
It is desirable to ferment in the range of ~ 6. Fermentation is initially p
The fermentation is started from H7, but when fermented to a pH of less than 4, the effect of inhibiting the growth of thermostable spore-forming bacteria is poor, and if the fermentation time is 6.5 or more, the effect may not be exhibited. Examples of the alkaline compound that adjusts the pH at the start of fermentation include, for example, carbonates or hydroxides of alkali metals such as sodium and potassium, specifically, sodium carbonate, monosodium phosphate, disodium phosphate,
Examples include potassium carbonate, sodium hydroxide, potassium hydroxide and the like. Preferably, those having a buffering capacity such as sodium carbonate, monosodium phosphate and disodium phosphate are desirable. The reaction temperature in the fermentation treatment is not particularly limited, but is usually 20 to 40 ° C, preferably 2 to 40 ° C.
5 to 37 ° C, and the fermentation time is usually 24 hours to 12 hours.
0 hours. Further, in the fermentation performed in the present invention, a bacterial strain to be inoculated and used is unnecessary, and the fermentation step is performed by a microorganism that naturally adheres to and remains on green coffee beans. For this fermentation, a simple open tank is sufficient, but any device used as a fermenter may be used, for example, commercially available from Shibata Scientific Instruments Co., Ltd.
An MDL-500 type bio-mentor can be used.

【0015】本発明の耐熱性芽胞形成細菌増殖抑制剤
は、コーヒー生豆の発酵を終えた発酵液(溶液)を有効
成分とするものであるが、好ましくは、この発酵液から
不溶解物質並びに微生物等を取り除いたコーヒー生豆発
酵濾液とすることが好ましい。発酵濾液を得る方法とし
ては、例えば、遠心分離、滅菌フィルター等のフィルタ
ー濾過、限外濾過等を使用する方法が挙げられ、不溶解
物質並びに微生物等を取り除くことができるものであれ
ば、いかなる方法を用いてもよい。本発明におけるコー
ヒー生豆の発酵から得られる発酵液とは、分析用ODSカ
ラム(YMC社製分析用ODSカラム、YMC-PACK ODS-AQ AQ-3
12,6.0×150mm)を用いて、流速 1.0ml/分、メタノー
ル/水/酢酸(20/80/0.3)を溶出液として行
った高速液体クロマトグラフイ―において、市販のコー
ヒー飲料には存在せず、同条件で検出されるクロロゲン
酸やカフェインより必ず前に溶出される二成分(耐熱性
芽胞形成細菌増殖抑制剤)を含むことをいう。
The heat-resistant spore-forming bacterial growth inhibitor of the present invention contains, as an active ingredient, a fermented liquid (solution) obtained by fermenting green coffee beans. It is preferable to use a green coffee bean fermentation filtrate from which microorganisms and the like have been removed. Examples of the method for obtaining a fermentation filtrate include, for example, a method using centrifugation, filter filtration using a sterilizing filter or the like, ultrafiltration, or the like, and any method capable of removing insoluble substances, microorganisms, and the like. May be used. The fermented liquid obtained from the fermentation of green coffee beans in the present invention refers to an analytical ODS column (analytical ODS column manufactured by YMC, YMC-PACK ODS-AQ AQ-3).
12,6.0 × 150 mm), high-speed liquid chromatography using methanol / water / acetic acid (20/80 / 0.3) as the eluent at a flow rate of 1.0 ml / min. It does not exist and means that it contains two components (a heat-resistant spore-forming bacterial growth inhibitor) that are always eluted before chlorogenic acid and caffeine detected under the same conditions.

【0016】図1(a)は、市販コーヒー飲料の高速液
体クロマトグラフィーの結果を示す特性図であり、
(b)はコーヒー生豆発酵液の高速液体クロマトグラフ
ィーの結果を示す特性図である。この図1(a)及び
(b)を比較検討すれば、(b)のコーヒー生豆発酵液
には市販のコーヒー飲料には存在せず、同条件で検出さ
れるクロロゲン酸やカフェインより必ず前に溶出される
二成分が検出されていることが明らかであり、これらの
成分が後述するように耐熱性芽胞形成細菌抑制剤となる
ものである。
FIG. 1 (a) is a characteristic diagram showing the results of high performance liquid chromatography of a commercially available coffee beverage.
(B) is a characteristic diagram showing the results of high performance liquid chromatography of a green coffee bean fermented liquid. Comparing FIG. 1 (a) and FIG. 1 (b), the fermented liquid of green coffee beans of (b) is not present in a commercial coffee beverage, but is always higher than chlorogenic acid and caffeine detected under the same conditions. It is evident that two components eluted earlier have been detected, and these components serve as thermostable spore-forming bacterial inhibitors as described below.

【0017】本発明における耐熱性芽胞形成細菌増殖抑
制剤は、上述の如く、コーヒー生豆を栄養物質非共存あ
るいは共存下にて発酵させた発酵液を有効成分、好まし
くは滅菌フィルター等を用いて不溶解物質並びに微生物
等の夾雑物を除外した発酵濾液(水溶液)を有効成分と
しているものであり、野菜、果実、豆類、穀類、香辛
料、魚介類、畜肉類、清涼飲料などの加工食品等に用い
る保存料等として好適に使用できるものとなる。本発明
における耐熱性芽胞形成細菌増殖抑制剤の加工食品や香
粧品等に対する配合量は、清涼飲料などの加工食品の用
途等により異なるものであるが、加工食品の全量に対し
て、10ppm(0.001%)〜5%である。耐熱性
芽胞形成細菌増殖抑制剤の配合量が10ppm未満であ
ると、目的の耐熱性芽胞形成細菌への増殖抑制効果を発
揮することができず、また、5%を越えても、目的の耐
熱性芽胞形成細菌への増殖抑制効果は変わらないが、不
必要な呈色を示し、品質劣化を招く原因となることがあ
る。
As described above, the heat-resistant spore-forming bacterial growth inhibitor of the present invention is obtained by using a fermented liquid obtained by fermenting green coffee beans in the absence or presence of nutrients using an active ingredient, preferably a sterile filter or the like. Fermented filtrate (aqueous solution) excluding insoluble substances and contaminants such as microorganisms is used as an active ingredient. It can be suitably used as a preservative or the like to be used. The amount of the heat-resistant spore-forming bacterial growth inhibitor of the present invention in processed foods and cosmetics varies depending on the use of processed foods such as soft drinks. 0.001%) to 5%. If the compounding amount of the heat-resistant spore-forming bacterial growth inhibitor is less than 10 ppm, the desired heat-resistant spore-forming bacterium growth inhibitory effect cannot be exhibited. Although the effect of inhibiting the growth of germinal spore-forming bacteria does not change, it may show unnecessary coloration and cause deterioration in quality.

【0018】また、本発明は、コーヒー生豆を栄養物質
非共存あるいは共存下にて発酵させることにより、好ま
しくは、得た発酵液を更に滅菌フィルター等を用いて不
溶解物質並びに微生物等の夾雑物を除外することにより
容易に製造することができ、得た発酵液、好ましくは発
酵濾液は、耐熱性芽胞形成細菌に対する増殖抑制効果を
発現する耐熱性芽胞形成細菌増殖抑制剤となるものであ
る。
The present invention also provides a method of fermenting green coffee beans in the absence or presence of nutrients. Preferably, the obtained fermented solution is further subjected to the use of a sterilizing filter or the like to remove insoluble substances and microorganisms. The resulting fermentation liquor, preferably a fermentation filtrate, is a heat-resistant spore-forming bacterial growth inhibitor that exhibits a growth-suppressing effect on heat-resistant spore-forming bacteria. .

【0019】このように構成される本発明の耐熱性芽胞
形成細菌増殖抑制剤では、コーヒー生豆を発酵させるこ
とにより得られるものであり、得られた耐熱性芽胞形成
細菌増殖抑制剤は著しい耐熱性芽胞形成細菌に対する増
殖抑制効果を発現することとなる。また、本発明では、
天然物由来であるコーヒー生豆を出発原料として製造す
ることができるので、生分解性が良く、人体に対する安
全性も高いことが期待され、食品、清涼飲料等へ添加し
て使用できるものとなる。更に、本発明では、加工食品
の製造工程で制御困難な細菌芽胞の増殖を抑制できるの
で、製造工程で使用する場合は安定した製造品質を提供
することができ、また、本発明の耐熱性芽胞形成細菌増
殖抑制剤を添加した加工食品等の場合は、過度な加熱殺
菌を施す必要がないので、加熱による品質の劣化を極力
抑えることができ、香味豊かな加工食品などを提供で
き、更に熱に対して不安定な有用成分を有する加工食品
に対して配合しても細菌芽胞の増殖を抑制できるものと
なる。
The heat-resistant spore-forming bacterial growth inhibitor of the present invention thus constituted is obtained by fermenting green coffee beans, and the obtained heat-resistant spore-forming bacterial growth inhibitor is markedly resistant to heat. It exerts a growth inhibitory effect on sexually spore-forming bacteria. In the present invention,
Since raw coffee beans that are derived from natural products can be produced as a starting material, they are expected to have good biodegradability and high safety to the human body, and can be used by adding them to foods, soft drinks, etc. . Furthermore, in the present invention, it is possible to suppress the growth of bacterial spores that are difficult to control in the process of producing processed food, so that when used in the process of production, it is possible to provide stable production quality, and to use the heat-resistant spores of the present invention. In the case of processed foods and the like to which a forming bacteria growth inhibitor is added, it is not necessary to perform excessive heat sterilization, so that deterioration in quality due to heating can be suppressed as much as possible, and processed foods with a rich flavor can be provided. Even if it is added to a processed food having a useful component that is unstable with respect to, the growth of bacterial spores can be suppressed.

【0020】[0020]

【実施例】次に、試験例(実施例及び比較例)により、
本発明をさらに詳細に説明するが、本発明は下記実施例
等に限定されるものではない。
EXAMPLES Next, according to test examples (Examples and Comparative Examples),
The present invention will be described in more detail, but the present invention is not limited to the following examples.

【0021】〔試験例1:コーヒー生豆の発酵液による
耐熱性芽胞形成細菌に対する芽胞増殖抑制効果試験〕ト
リプトソイブイヨン培地(栄研化学社製)に、Bacillus
subtilis ATCC9372株芽胞の細菌芽胞濃度を1.75×
103cfu/ml となるよう常法により接種調製し、下記
に示す実施例1及び2のコーヒー生豆発酵液、並びに、
比較例1及び2を0.05%(1/2000質量部)添
加した培養用試験管を準備する。これらを光学系測定機
能を備えた小型振とう培養装置(バイオフォトレコーダ
ー TN−1506 ADVANTECH社製)を使用して、2
5℃の環境に保ちながら振とう培養し、経時的な濁度の
変化(測定波長660nm)を測定した。得られた微生
物増殖曲線において、濁度の数値が低い程、耐熱性芽胞
形成細菌に対する芽胞増殖抑制効果が高いことを表す。
これらの結果を図2に示す。
Test Example 1: Spore growth inhibitory effect test on heat-resistant spore-forming bacteria by fermented liquid of green coffee beans Bacillus was added to tryptic soy broth medium (manufactured by Eiken Chemical Co., Ltd.).
The bacterial spore concentration of the subtilis ATCC9372 strain spores was 1.75 ×
Inoculated and prepared by a conventional method so as to obtain 10 3 cfu / ml, and fermented liquids of green coffee beans of Examples 1 and 2 shown below, and
A culture test tube to which 0.05% (1/2000 parts by mass) of Comparative Examples 1 and 2 are added is prepared. Using a small shaking culture device (Bio Photo Recorder TN-1506 manufactured by ADVANTECH) equipped with an optical system measurement function,
Shaking culture was performed while maintaining the environment at 5 ° C., and changes in turbidity over time (measurement wavelength: 660 nm) were measured. In the obtained microorganism growth curve, the lower the value of turbidity, the higher the spore growth inhibitory effect on thermostable spore-forming bacteria.
These results are shown in FIG.

【0022】(実施例1)滅菌水に、コーヒー生豆(ブ
ラジル種)10%加えた水溶液を調製し、下記表1に示
す栄養培地(以下、単に「栄養源」という)を用いて
リン酸一ナトリウム(関東化学社製)1%水溶液でpH
を7.0に調製した後、25℃で24時間発酵させたも
のを実施例1とした。 (実施例2)滅菌水に、コーヒー生豆(マンデリン種)
20%加えた水溶液を調製し、下記表1に示す栄養源
を用いて炭酸ナトリウム(関東化学社製)1%水溶液で
pHを6.5に調製した後、32℃で30時間発酵させ
たものを実施例2とした。 (比較例1)ショ糖脂肪酸エステル(三菱化学製P-167
0)を比較例1とした。 (比較例2)ショ糖脂肪酸エステル(三菱化学製S-167
0)を比較例2とした。
(Example 1) An aqueous solution prepared by adding 10% of green coffee beans (Brazil) to sterilized water was prepared, and phosphoric acid was added using a nutrient medium (hereinafter, simply referred to as "nutrient source") shown in Table 1 below. PH with 1% aqueous solution of monosodium (Kanto Chemical)
Was adjusted to 7.0, and fermented at 25 ° C. for 24 hours. (Example 2) Raw coffee beans (manderin type) in sterile water
A 20% aqueous solution was prepared, and the pH was adjusted to 6.5 with a 1% aqueous solution of sodium carbonate (manufactured by Kanto Chemical Co., Ltd.) using the nutrients shown in Table 1 below, followed by fermentation at 32 ° C. for 30 hours. Was set to Example 2. (Comparative Example 1) Sucrose fatty acid ester (P-167 manufactured by Mitsubishi Chemical Corporation)
0) was taken as Comparative Example 1. (Comparative Example 2) Sucrose fatty acid ester (S-167 manufactured by Mitsubishi Chemical Corporation)
0) was designated as Comparative Example 2.

【0023】[0023]

【表1】 [Table 1]

【0024】図2に示すように、本発明となる実施例1
及び2は、比較例1(P-1670)及び比較例2(S-1670)
に較べ、Bacillus subtilis ATCC9372株芽胞に対して、
顕著な増殖抑制効果を示すことが判った。
As shown in FIG. 2, the first embodiment according to the present invention
And 2 are Comparative Example 1 (P-1670) and Comparative Example 2 (S-1670)
As compared to Bacillus subtilis ATCC9372 strain spores,
It was found that a remarkable growth inhibitory effect was exhibited.

【0025】〔試験例2:コーヒー生豆の発酵液による
耐熱性芽胞形成細菌に対する芽胞増殖抑制効果試験〕上
記試験例1と同様の細菌芽胞培地溶液および培養方法を
用いて、下記に示す実施例3及び4、比較例3及び4を
0.5%(1/200質量部)添加し、試験例1と同様
に発酵濾液を用いた経時的な濁度の変化を測定した。こ
れらの結果を図3に示す。
Test Example 2: Test of Spore Growth Inhibition Effect on Thermostable Spore-Forming Bacteria by Fermented Liquid of Coffee Beans Using the same bacterial spore medium solution and culture method as in Test Example 1 above, the following examples were used. 0.5% (1/200 parts by mass) of Comparative Examples 3 and 4 and Comparative Examples 3 and 4 were added, and the change in turbidity over time using the fermentation filtrate was measured in the same manner as in Test Example 1. These results are shown in FIG.

【0026】(実施例3)滅菌水に、コーヒー生豆(ガ
テマラ種)5重量%を加えた水溶液を調整し、表1に示
す栄養源を用いて水酸化カリウム(関東化学社製)1
重量%水溶液を用いてpHを8.5に調製した後、25
℃で50時間発酵させたものを実施例3とした。 (実施例4)滅菌水に、コーヒー生豆(サントス種)2
0重量%を加えた水溶液を調整し、表1に示す栄養源
を用いてリン酸一ナトリウム(関東化学社製)1重量%
水溶液を用いてpHを8.0に調製した後、25℃で2
0時間発酵させたものを実施例3とした。 (比較例3)ショ糖脂肪酸エステル(三菱化学製P-167
0)を比較例3とした。 (比較例4)ショ糖脂肪酸エステル(三菱化学製S-167
0)を比較例4とした。
Example 3 An aqueous solution was prepared by adding 5% by weight of green coffee beans (Gatema seeds) to sterilized water, and potassium hydroxide (manufactured by Kanto Chemical Co., Ltd.) 1 was prepared using the nutrients shown in Table 1.
After adjusting the pH to 8.5 using a weight% aqueous solution, 25
What fermented at 50 degreeC for 50 hours was set to Example 3. (Example 4) Raw coffee beans (Santos species) 2 in sterile water
An aqueous solution containing 0% by weight was prepared, and 1% by weight of monosodium phosphate (manufactured by Kanto Chemical Co., Ltd.) was used using the nutrients shown in Table 1.
After adjusting the pH to 8.0 using an aqueous solution, the pH was adjusted to 2 at 25 ° C.
Example 3 was fermented for 0 hours. (Comparative Example 3) Sucrose fatty acid ester (P-167 manufactured by Mitsubishi Chemical Corporation)
0) was taken as Comparative Example 3. (Comparative Example 4) Sucrose fatty acid ester (S-167 manufactured by Mitsubishi Chemical Corporation)
0) is Comparative Example 4.

【0027】図3に示すように、本発明となる実施例3
及び4は、比較例3(P-1670)及び比較例4(S-1670)
に較べ、Bacillus subtilis ATCC9372株芽胞に対して、
顕著な増殖抑制効果を示すことが判った。
FIG. 3 shows a third embodiment of the present invention.
And 4 are Comparative Example 3 (P-1670) and Comparative Example 4 (S-1670)
As compared to Bacillus subtilis ATCC9372 strain spores,
It was found that a remarkable growth inhibitory effect was exhibited.

【0028】〔試験例3:ミルクコーヒー飲料中での芽
胞増殖抑制効果試験〕コーヒー豆(キリマンジャロ種/
ハワイコナ種;60/40%)75gを95℃の熱湯1リッ
トルに加え、静置後20分間抽出した後、プレートクー
ラーで急冷して得たコーヒー溶液の900gに牛乳10
0gとグラニュー糖70gを入れ、撹拌溶解してミルク
コーヒーを調製した。このミルクコーヒーに1mlあた
り103個となるようBacillus stearothermophilus ATC
C7953株芽胞液を添加し、更に、下記に示す実施例5及
び6、並びに、比較例5及び6を0.05%(1/20
00質量部)添加し、滅菌した密閉容器に充填後、55
℃、3カ月保存した際の検出される芽胞菌由来の微生物
数を常法に従い標準寒天培地へ混釈後、32℃、5日間
培養した後に計測されたコロニー数により評価した。こ
れらの結果を下記表2に示す。
[Test Example 3: Spore growth inhibitory effect test in milk coffee beverage] Coffee beans (Kilimanjaro sp./
(Hawaii Kona seed; 60/40%) 75 g was added to 1 liter of hot water at 95 ° C., allowed to stand, extracted for 20 minutes, and then quenched with a plate cooler to 900 g of a coffee solution to obtain 10 g of milk.
0 g and granulated sugar (70 g) were added and dissolved by stirring to prepare milk coffee. Bacillus stearothermophilus ATC so that this milk coffee has 10 3 per ml
C7953 strain spore solution was added, and the following Examples 5 and 6 and Comparative Examples 5 and 6 were added to 0.05% (1/20
After the addition and filling in a sterilized closed container, 55
The number of microorganisms derived from spores detected after storage at 3 ° C. for 3 months was evaluated by the number of colonies counted after culturing at 32 ° C. for 5 days after pour-out into a standard agar medium according to a conventional method. The results are shown in Table 2 below.

【0029】(実施例5)滅菌水に、コーヒー生豆(ガ
テマラ種)15%を加えた水溶液を調整し、下記表1に
示す栄養源を用いて水酸化カリウム(関東化学社製)
1%水溶液を用いてpHを7.0に調製した後、25℃
で24時間発酵させたものを実施例5とした。 (実施例6)滅菌水に、コーヒー生豆(ガテマラ種)2
0%を加えた水溶液を調整し、表1に示す栄養源を用
いて炭酸カリウム(関東化学社製)1重量%水溶液を用
いてpHを7.5に調製した後、25℃で28時間発酵
させたものを実施例6とした。 (比較例5)ショ糖脂肪酸エステル(三菱化学製P-167
0)を比較例5とした。 (比較例6)ショ糖脂肪酸エステル(三菱化学製S-167
0)を比較例6とした。
Example 5 An aqueous solution was prepared by adding 15% of green coffee beans (Gatema seeds) to sterilized water, and potassium hydroxide (manufactured by Kanto Kagaku Co., Ltd.) was prepared using the nutrients shown in Table 1 below.
After adjusting the pH to 7.0 using a 1% aqueous solution, 25 ° C.
Example 5 was obtained by fermenting for 24 hours. (Example 6) Raw coffee beans (Gatemala species) 2 in sterile water
An aqueous solution containing 0% was prepared, and the pH was adjusted to 7.5 using a 1% by weight aqueous solution of potassium carbonate (manufactured by Kanto Kagaku) using the nutrients shown in Table 1, and then fermented at 25 ° C. for 28 hours. This was used as Example 6. (Comparative Example 5) Sucrose fatty acid ester (P-167 manufactured by Mitsubishi Chemical Corporation)
0) was taken as Comparative Example 5. (Comparative Example 6) Sucrose fatty acid ester (S-167 manufactured by Mitsubishi Chemical Corporation)
0) is Comparative Example 6.

【0030】[0030]

【表2】 [Table 2]

【0031】上記表2の結果から明らかなように、本発
明となる実施例5及び6は、比較例5及び比較例6に較
べ、検出される微生物数が顕著に低いことが判った。
As is evident from the results in Table 2, the number of detected microorganisms was significantly lower in Examples 5 and 6 according to the present invention than in Comparative Examples 5 and 6.

【0032】〔試験例4:加熱したコーヒー生豆の発酵
液によるミルクコーヒー飲料中での芽胞増殖抑制効果試
験〕コーヒー豆(キリマンジャロ種/ハワイコナ種;60
/40%)75gを95℃の熱湯1リットルに加え、静置
後20分間抽出した後、プレートクーラーで急冷して得
たコーヒー溶液の900gに牛乳100gとグラニュー
糖70gを入れ、撹拌溶解してミルクコーヒーを調製し
た。このミルクコーヒーに1mlあたり103個となる
ようBacillus stearothermophilus ATCC7953株芽胞液を
添加し、更に、下記に示す実施例7及び8、並びに、比
較例7及び8を0.05%(1/2000質量部)添加
し、滅菌した密閉容器に充填後、55℃、3カ月保存し
た際の検出される芽胞菌由来の微生物数を常法に従い標
準寒天培地へ混釈後、32℃、5日間培養した後に計測
されたコロニー数により評価した。これらの結果を下記
表3に示す。
Test Example 4: Test of Suppressing Spore Growth in Milk Coffee Beverage by Fermented Liquid of Heated Green Coffee Beans Coffee Beans (Kilimanjaro / Hawaii Kona; 60
Add 75 g to 1 liter of hot water at 95 ° C., extract for 20 minutes after standing, add 100 g of milk and 70 g of granulated sugar to 900 g of a coffee solution obtained by rapid cooling with a plate cooler, and stir to dissolve. Milk coffee was prepared. Bacillus stearothermophilus ATCC7953 strain spore solution was added to this milk coffee so that the number of Bacillus stearothermophilus ATCC7953 strain became 10 3 cells / ml, and the following Examples 7 and 8 and Comparative Examples 7 and 8 were added to 0.05% (1/2000 mass). Part) was added and filled in a sterilized airtight container. After storage at 55 ° C. for 3 months, the number of microorganisms derived from spores detected was mixed with a standard agar medium according to a conventional method, and then cultured at 32 ° C. for 5 days. It was evaluated by the number of colonies counted later. The results are shown in Table 3 below.

【0033】〔実施例7〕滅菌水に、予め水溶液中で6
5℃、30分の加熱を施したコーヒー生豆(ガテマラ
種)15重量%を加えた水溶液を調整し、下記表1に示
す栄養源を用いてリン酸二ナトリウム(関東化学社
製)1重量%水溶液を用いてpHを6.5に調製した
後、25℃で41時間発酵させたものを実施例7とし
た。 〔実施例8〕滅菌水に、予め水溶液中で70℃、40分
の加熱を施したコーヒー生豆(ガテマラ種)10重量%
を加えた水溶液を調整し、下記表1に示す栄養源を用
いて炭酸ナトリウム(関東化学社製)1重量%水溶液を
用いてpHを8.0に調製した後、25℃で25時間発
酵させたものを実施例8とした。 〔比較例7〕ショ糖脂肪酸エステル(三菱化学製P-167
0)を比較例7とした。 〔比較例8〕ショ糖脂肪酸エステル(三菱化学製S-167
0)を比較例8とした。
Example 7 In sterile water, 6
An aqueous solution to which 15% by weight of green coffee beans (Gatemala sp.) Heated at 5 ° C. for 30 minutes was added, and 1% by weight of disodium phosphate (manufactured by Kanto Kagaku) using the nutrients shown in Table 1 below. % Was adjusted to 6.5 using an aqueous solution, and fermented at 25 ° C. for 41 hours. [Example 8] 10% by weight of green coffee beans (Gatemaara species) previously heated in sterile water at 70 ° C for 40 minutes in an aqueous solution
Was adjusted to pH 8.0 using a 1% by weight aqueous solution of sodium carbonate (manufactured by Kanto Kagaku) using the nutrients shown in Table 1 below, and then fermented at 25 ° C. for 25 hours. This was designated as Example 8. [Comparative Example 7] Sucrose fatty acid ester (P-167 manufactured by Mitsubishi Chemical Corporation)
0) is Comparative Example 7. [Comparative Example 8] Sucrose fatty acid ester (S-167 manufactured by Mitsubishi Chemical Corporation)
0) is Comparative Example 8.

【0034】[0034]

【表3】 [Table 3]

【0035】上記表3の結果から明らかなように、本発
明となる実施例7及び8は、比較例7及び比較例8に較
べ、検出される微生物数が顕著に低いことが判った。
As is evident from the results in Table 3, the number of microorganisms detected in Examples 7 and 8 according to the present invention was significantly lower than that in Comparative Examples 7 and 8.

【0036】〔試験例5:大豆煮豆中での芽胞増殖抑制
効果試験〕市販の大豆100gを500mlの水道水に
入れ、60分間加熱調理した。終了後余分な煮汁を棄
て、常温に戻してから大豆煮豆を得た。無菌下でビニー
ル袋を開封し、この大豆煮豆10gと、103個/10
gとなるようBacillus stearothermophilus ATCC7953株
芽胞液を摂取し、更に、下記に示す実施例9及び10、
並びに、比較例9及び10を0.05%(1/2000
質量部)添加し、混合した後に充填後、55℃、の恒温
室に3カ月保存した。試験毎に検出される芽胞菌由来の
微生物数は、常法に従い標準寒天培地へ混釈後、32
℃、5日間培養した後に計測されたコロニー数により評
価した。これらの結果を下記表4に示す。
[Test Example 5: Spore growth inhibitory effect test in boiled soybeans] 100 g of commercially available soybeans were put into 500 ml of tap water and cooked for 60 minutes. After the completion, the excess broth was discarded, and the temperature was returned to room temperature. Opening the plastic bag under sterile, and this soybean boiled beans 10 g, 10 3 cells / 10
g of Bacillus stearothermophilus ATCC7953 strain spore fluid, and the following Examples 9 and 10,
And Comparative Examples 9 and 10 were 0.05% (1/2000).
After adding, mixing and filling, the mixture was stored in a constant temperature room at 55 ° C. for 3 months. The number of spore-derived microorganisms detected in each test was 32
The evaluation was performed based on the number of colonies counted after culturing at 5 ° C. for 5 days. The results are shown in Table 4 below.

【0037】〔実施例9〕滅菌水に、予め水溶液中で6
5℃、30分の加熱を施したコーヒー生豆(マンデリン
種)10%を加えた水溶液を調整し、下記表1に示す栄
養源を用いてリン酸二ナトリウム(関東化学社製)1
重量%水溶液を用いてpHを6.0に調製した後、30
℃で44時間発酵させたものを実施例9とした。 〔実施例10〕滅菌水に、予め水溶液中で50℃、35
分の加熱を施したコーヒー生豆(ガテマラ種)20重量
%を加えた水溶液を調整し、下記表1に示す栄養源を
用いて炭酸ナトリウム(関東化学社製)1%水溶液を用
いてpHを7.0に調製した後、32℃で20時間発酵
させたものを実施例10とした。 〔比較例9〕ショ糖脂肪酸エステル(三菱化学製P-167
0)を比較例7とした。 〔比較例10〕ショ糖脂肪酸エステル(三菱化学製S-16
70)を比較例8とした。
[Example 9] In sterile water, 6
An aqueous solution containing 10% of green coffee beans (mandellin species) heated at 5 ° C. for 30 minutes was prepared, and disodium phosphate (manufactured by Kanto Chemical Co., Ltd.) 1 was prepared using the nutrients shown in Table 1 below.
After adjusting the pH to 6.0 using a weight% aqueous solution,
Example 9 was fermented at 44 ° C. for 44 hours. Example 10 Sterile water and 50 ° C., 35
An aqueous solution containing 20% by weight of green coffee beans (Gatema seeds) heated for 1 minute was prepared, and the pH was adjusted using a 1% aqueous solution of sodium carbonate (manufactured by Kanto Kagaku) using the nutrients shown in Table 1 below. After adjusting to 7.0 and fermenting at 32 ° C. for 20 hours, Example 10 was used. [Comparative Example 9] Sucrose fatty acid ester (P-167 manufactured by Mitsubishi Chemical Corporation)
0) is Comparative Example 7. [Comparative Example 10] Sucrose fatty acid ester (S-16 manufactured by Mitsubishi Chemical Corporation)
70) was designated as Comparative Example 8.

【0038】[0038]

【表4】 [Table 4]

【0039】上記表4の結果から明らかなように、本発
明となる実施例9及び10は、比較例9及び比較例10
に較べ、検出される微生物数が顕著に低いことが判っ
た。
As is clear from the results in Table 4 above, Examples 9 and 10 according to the present invention correspond to Comparative Examples 9 and 10
It was found that the number of detected microorganisms was significantly lower than that of

【0040】〔試験例6:生つぶあん中での芽胞増殖抑
制効果試験〕市販の小豆100gを500mlの水道水
に入れ、30分間加熱処理し、余分な煮汁を棄てた後、
再度500mlの新しい水道水を入れ60分間加熱調理
した。終了後余分な煮汁を棄て、常温に戻してから小豆
をつぶし、つぶあんを得た。無菌下でビニール袋を開封
し、このつぶあん10gと、103個/10gとなるよ
うBacillus stearothermophilus ATCC7953株芽胞液を接
取し、更に、下記に示す実施例11及び12、並びに、
比較例11及び12を0.05%(1/2000質量
部)添加し、混合した後に充填後、55℃の恒温室に3
カ月保存した。試験毎に検出される芽胞菌由来の微生物
数は、常法に従い標準寒天培地へ混釈後、32℃、5日
間培養した後に計測されたコロニー数により評価した。
これらの結果を下記表5に示す。
Test Example 6: Spore growth inhibitory effect test in fresh tsubuan 100 g of commercially available red beans were placed in 500 ml of tap water, heat-treated for 30 minutes, and excess broth was discarded.
500 ml of fresh tap water was added again and cooked for 60 minutes. After completion, the excess broth was discarded, the temperature was returned to room temperature, and the red beans were crushed to obtain crushed beans. Opening the plastic bag under sterile, and this Tsubuan 10 g, sets the Bacillus stearothermophilus ATCC7953 strain spores solution such as a 10 3/10 g, further, Examples 11 and 12 below, as well as,
After adding Comparative Examples 11 and 12 in an amount of 0.05% (1/2000 parts by mass), mixing and filling, the mixture was placed in a 55 ° C.
Stored for months. The number of spore-derived microorganisms detected in each test was evaluated by the number of colonies counted after culturing at 32 ° C for 5 days after pour- ing into a standard agar medium according to a conventional method.
The results are shown in Table 5 below.

【0041】〔実施例11〕滅菌水に、予め水溶液中で
65℃、30分の加熱を施したコーヒー生豆(サントス
種)15%を加えた水溶液を調整し、下記表1に示す栄
養源を用いてリン酸二ナトリウム(関東化学社製)1
%水溶液を用いてpHを7.5に調製した後、25℃で
26時間発酵させたものを実施例11とした。 〔実施例12〕滅菌水に、予め水溶液中で60℃、35
分の加熱を施したコーヒー生豆(ガテマラ種)16%を
加えた水溶液を調整し、表1に示す栄養源を用いて炭
酸ナトリウム(関東化学社製)1%水溶液を用いてpH
を8.5に調製した後、25℃で34時間発酵させたも
のを実施例12とした。 〔比較例11〕ショ糖脂肪酸エステル(三菱化学製P-16
70)を比較例11とした。 〔比較例12〕ショ糖脂肪酸エステル(三菱化学製S-16
70)を比較例12とした。
Example 11 An aqueous solution was prepared by adding 15% of green coffee beans (Santos species) previously heated in an aqueous solution to 65 ° C. for 30 minutes in sterile water, and the nutrient sources shown in Table 1 below were prepared. Disodium phosphate (Kanto Chemical) 1
% Was adjusted to 7.5 using an aqueous solution, and fermented at 25 ° C. for 26 hours. Example 12 In sterile water, an aqueous solution was previously prepared at 60 ° C., 35
An aqueous solution to which 16% of green coffee beans (Gatamara sp.) Heated for 1 minute was added was prepared, and the pH was adjusted using a 1% aqueous solution of sodium carbonate (manufactured by Kanto Chemical Co.) using the nutrients shown in Table 1.
Was adjusted to 8.5 and then fermented at 25 ° C. for 34 hours. [Comparative Example 11] Sucrose fatty acid ester (P-16 manufactured by Mitsubishi Chemical Corporation)
70) was set as Comparative Example 11. [Comparative Example 12] Sucrose fatty acid ester (S-16 manufactured by Mitsubishi Chemical Corporation)
70) was set as Comparative Example 12.

【0042】[0042]

【表5】 [Table 5]

【0043】上記表5の結果から明らかなように、本発
明となる実施例11及び12は、比較例11及び比較例
12に較べ、検出される微生物数が顕著に低いことが判
った。
As is clear from the results shown in Table 5, the number of detected microorganisms in Examples 11 and 12 according to the present invention was significantly lower than those in Comparative Examples 11 and 12.

【0044】〔試験例7:コーヒー発酵抽出濾液を用い
た生つぶあん中での芽胞増殖抑制効果試験〕市販の小豆
150gを500mlの水道水に入れ、45分間加熱処
理し、余分な煮汁を棄てた後、再度500mlの新しい
水道水を入れ60分間加熱調理した。終了後余分な煮汁
を棄て、常温に戻してから小豆をつぶし、つぶあんを得
た。無菌下でビニール袋を開封し、このつぶあんを10
gと、103個/10gとなるようBacillus stearothe
rmophilus ATCC7953株芽胞液を接種し、更に、下記に示
す実施例13及び14,並びに比較例13及び14を
0.03%(1/3333質量部)添加し、混合した後
に充填後、55℃の恒温室に3カ月保存した。試験毎に
検出される芽胞菌由来の微生物数は、常法に従い標準寒
天培地へ混釈後、32℃、5日間培養した後に計測され
たコロニー数により評価した。これらの結果を下記表6
に示す。
[Test Example 7: Test of Spore Growth Inhibition Effect in Fresh Tsubuan Using Coffee Fermented Extract Filtrate] 150 g of commercially available red beans were put into 500 ml of tap water, heated for 45 minutes, and excess broth was discarded. Thereafter, 500 ml of fresh tap water was added again and cooked for 60 minutes. After completion, the excess broth was discarded, the temperature was returned to room temperature, and the red beans were crushed to obtain crushed beans. Open the plastic bag under sterile conditions and
g and Bacillus stearothe to be 103 pieces / 10g
rmophilus ATCC7953 strain spores were inoculated, 0.03% (1/3333 parts by mass) of Examples 13 and 14 and Comparative Examples 13 and 14 shown below were added, mixed, filled, and filled at 55 ° C. It was stored in a constant temperature room for 3 months. The number of spore-derived microorganisms detected in each test was evaluated by the number of colonies counted after culturing at 32 ° C for 5 days after pour- ing into a standard agar medium according to a conventional method. The results are shown in Table 6 below.
Shown in

【0045】〔実施例13〕滅菌水に、予め水溶液中で
60℃、45分の過熱を施したコーヒー生豆(マンデリ
ン種)20重量%を加えた水溶液を調整し、下記表1に
示す栄養源 を用いてリン酸二ナトリウム(関東化学社
製)1重量%水溶液を用いてpHを7.0に調製した
後、25℃で26時間発酵させ、滅菌フィルター(デユ
ラポアメンブレンフィルター、日本ミリポア社)5μm
次いで0.22μmの同様のメンブレンフィルターで濾
過したものを実施例13とした。 〔実施例14〕滅菌水に、予め水溶液中で60℃、35
分の過熱を施したコーヒー生豆(ガテマラ種)20重量
%を加えた水溶液を調整し、表1に示す栄養源 を用い
て炭酸ナトリウム(関東化学社製)1重量%水溶液を用
いてpHを8.0に調製した後、25℃で25時間発酵
させ滅菌フィルター(デユラポアメンブレンフィルタ
ー、日本ミリポア社)5μm次いで0.22μmの同様の
メンブレンフィルターで濾過したものを実施例14とし
た。 〔比較例13〕ショ糖脂肪酸エステル(三菱化学製P-16
70)を比較例13とした。 〔比較例14〕ショ糖脂肪酸エステル(三菱化学製S-16
70)を比較例14とした。
Example 13 An aqueous solution was prepared by adding 20% by weight of green coffee beans (manderin type) preliminarily heated in an aqueous solution to 60 ° C. for 45 minutes in sterile water, and the nutrients shown in Table 1 below were prepared. After adjusting the pH to 7.0 using a 1% by weight aqueous solution of disodium phosphate (manufactured by Kanto Chemical Co., Ltd.) using a source, fermentation was performed at 25 ° C. for 26 hours, and a sterilizing filter (Durapore membrane filter, Nippon Millipore) was used. 5μm
Next, Example 13 was filtered through a similar membrane filter of 0.22 μm. [Example 14] In sterile water, previously in an aqueous solution at 60 ° C, 35
An aqueous solution containing 20% by weight of green coffee beans (Gatamara sp.) Overheated for one minute was prepared, and the pH was adjusted using a 1% by weight aqueous solution of sodium carbonate (manufactured by Kanto Kagaku) using the nutrients shown in Table 1. After adjusting to 8.0, the mixture was fermented at 25 ° C. for 25 hours and filtered with a sterile filter (Durapore membrane filter, Nippon Millipore) 5 μm and then with a similar membrane filter of 0.22 μm to obtain Example 14. [Comparative Example 13] Sucrose fatty acid ester (P-16 manufactured by Mitsubishi Chemical Corporation)
70) was set as Comparative Example 13. [Comparative Example 14] Sucrose fatty acid ester (S-16 manufactured by Mitsubishi Chemical Corporation)
70) was set as Comparative Example 14.

【0046】[0046]

【表6】 [Table 6]

【0047】上記表6の結果から明らかなように、本発
明となる実施例13及び14は、比較例13及び比較例
14に較べ、検出される微生物数が顕著に低いことが判
った。
As is clear from the results shown in Table 6, the number of detected microorganisms was significantly lower in Examples 13 and 14 according to the present invention than in Comparative Examples 13 and 14.

【0048】上記試験例1〜7(図2〜3、表2〜6を
含む)の結果を総合的に考察すると、コーヒー生豆を発
酵させて得られる発酵液または発酵濾液を有効成分とす
る耐熱性芽胞形成細菌増殖抑制剤は、顕著な耐熱性芽胞
形成細菌に対する増殖抑制効果を発現することが判明し
た。
Comprehensively considering the results of the above Test Examples 1 to 7 (including FIGS. 2 and 3 and Tables 2 to 6), the fermented liquid or the fermented filtrate obtained by fermenting green coffee beans is used as the active ingredient. It was found that the thermostable spore-forming bacterial growth inhibitor exhibited a remarkable growth-suppressing effect on thermostable spore-forming bacteria.

【0049】[0049]

【発明の効果】本発明によれば、耐熱性芽胞形成細菌に
対して高い増殖抑制作用を有し、しかも生分解性がよ
く、人体に対する安全性にも優れた耐熱性芽胞形成細菌
増殖抑制剤が提供される。
Industrial Applicability According to the present invention, a heat-resistant spore-forming bacterial growth inhibitor which has a high growth inhibitory activity against heat-resistant spore-forming bacteria, has good biodegradability, and is excellent in safety to the human body. Is provided.

【図面の簡単な説明】[Brief description of the drawings]

【図1】(a)及び(b)は市販コーヒー飲料とコーヒ
ー生豆発酵液との高速液体クロマトグラフィーの結果を
示す特性図である。
1 (a) and 1 (b) are characteristic diagrams showing the results of high performance liquid chromatography between a commercially available coffee beverage and a fermented liquid coffee bean.

【図2】実施例1及び2と比較例1及び2における耐熱
性芽胞形成細菌増殖抑制効果を示す特性図である。
FIG. 2 is a characteristic diagram showing the effect of inhibiting the growth of thermostable spore-forming bacteria in Examples 1 and 2 and Comparative Examples 1 and 2.

【図3】実施例3及び4と比較例3及び4における耐熱
性芽胞形成細菌増殖抑制効果を示す特性図である。
FIG. 3 is a characteristic diagram showing the effect of inhibiting the growth of thermostable spore-forming bacteria in Examples 3 and 4 and Comparative Examples 3 and 4.

Claims (2)

【特許請求の範囲】[Claims] 【請求項1】 コーヒー生豆を発酵させて得た発酵液を
有効成分とすることを特徴とする耐熱性芽胞形成細菌増
殖抑制剤。
1. A heat-resistant spore-forming bacterial growth inhibitor comprising, as an active ingredient, a fermented liquid obtained by fermenting green coffee beans.
【請求項2】 発酵液には、下記分析データで示される
成分が含有される請求項1記載の耐熱性芽胞形成細菌増
殖抑制剤。 分析データ:分析用ODSカラム(YMC社製分析用ODSカラ
ム、YMC-PACK ODS-AQ AQ-312,6.0×150mm)を用いて、
カラム温度30℃、流速1.0ml/分、メタノール/
水/酢酸(20/80/0.3)を溶出液として行った
高速液体クロマトグラフイ―において、市販のコーヒー
飲料には存在せず、同条件で検出されるクロロゲン酸や
カフェインより必ず前に溶出される二成分を含むこと。
2. The heat-resistant spore-forming bacterial growth inhibitor according to claim 1, wherein the fermented liquid contains a component represented by the following analysis data. Analytical data: Using an analytical ODS column (analytical ODS column manufactured by YMC, YMC-PACK ODS-AQ AQ-312, 6.0 × 150 mm)
Column temperature 30 ° C., flow rate 1.0 ml / min, methanol /
In high performance liquid chromatography using water / acetic acid (20/80 / 0.3) as an eluent, it was not present in commercially available coffee beverages, and was always present before chlorogenic acid and caffeine detected under the same conditions. Contain two components eluted in
JP36798399A 1999-12-24 1999-12-24 Proliferation inhibitor against heat-resistant end spore- forming bacterium Pending JP2001178431A (en)

Priority Applications (1)

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Country Link
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Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2006502394A (en) * 2002-10-02 2006-01-19 マックス−プランク−ゲゼルシャフト ツール フェルデルング デア ヴィッセンシャフテン エー. ファオ. Apparatus and method for liquid sample extraction
WO2006101196A1 (en) * 2005-03-24 2006-09-28 Suntory Limited Method of processing fresh coffee beans by using surface-treated coffee fruits
WO2006101195A1 (en) * 2005-03-24 2006-09-28 Suntory Limited Novel microorganism and method of processing fresh coffee beans by using the same
WO2010001872A1 (en) 2008-07-03 2010-01-07 日清紡ホールディングス株式会社 Preservative material and storage method for liquid

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2006502394A (en) * 2002-10-02 2006-01-19 マックス−プランク−ゲゼルシャフト ツール フェルデルング デア ヴィッセンシャフテン エー. ファオ. Apparatus and method for liquid sample extraction
WO2006101196A1 (en) * 2005-03-24 2006-09-28 Suntory Limited Method of processing fresh coffee beans by using surface-treated coffee fruits
WO2006101195A1 (en) * 2005-03-24 2006-09-28 Suntory Limited Novel microorganism and method of processing fresh coffee beans by using the same
US8343558B2 (en) 2005-03-24 2013-01-01 Suntory Holdings Limited Microorganism and method of processing green coffee beans using the same
US8545910B2 (en) 2005-03-24 2013-10-01 Suntory Holdings Limited Method of processing green coffee beans by using surface-treated coffee cherries
WO2010001872A1 (en) 2008-07-03 2010-01-07 日清紡ホールディングス株式会社 Preservative material and storage method for liquid

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