JP2020110058A - 4-hydroxy-2,5-dimethyl-3(2h)-furanone-containing beverage - Google Patents
4-hydroxy-2,5-dimethyl-3(2h)-furanone-containing beverage Download PDFInfo
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- JP2020110058A JP2020110058A JP2019001711A JP2019001711A JP2020110058A JP 2020110058 A JP2020110058 A JP 2020110058A JP 2019001711 A JP2019001711 A JP 2019001711A JP 2019001711 A JP2019001711 A JP 2019001711A JP 2020110058 A JP2020110058 A JP 2020110058A
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- NCGJACBPALRHNG-UHFFFAOYSA-M sodium;2,4,6-trinitrobenzenesulfonate Chemical compound [Na+].[O-][N+](=O)C1=CC([N+]([O-])=O)=C(S([O-])(=O)=O)C([N+]([O-])=O)=C1 NCGJACBPALRHNG-UHFFFAOYSA-M 0.000 description 1
- 239000002904 solvent Substances 0.000 description 1
- 235000011496 sports drink Nutrition 0.000 description 1
- 239000003381 stabilizer Substances 0.000 description 1
- 238000001256 steam distillation Methods 0.000 description 1
- 125000001424 substituent group Chemical group 0.000 description 1
- 239000005720 sucrose Substances 0.000 description 1
- 238000003786 synthesis reaction Methods 0.000 description 1
- 235000019640 taste Nutrition 0.000 description 1
- 235000008521 threonine Nutrition 0.000 description 1
- 238000002834 transmittance Methods 0.000 description 1
- OUYCCCASQSFEME-UHFFFAOYSA-N tyrosine Natural products OC(=O)C(N)CC1=CC=C(O)C=C1 OUYCCCASQSFEME-UHFFFAOYSA-N 0.000 description 1
- 239000004474 valine Substances 0.000 description 1
- 235000013311 vegetables Nutrition 0.000 description 1
- 239000011782 vitamin Substances 0.000 description 1
- 229940088594 vitamin Drugs 0.000 description 1
- 229930003231 vitamin Natural products 0.000 description 1
- 235000013343 vitamin Nutrition 0.000 description 1
- 229910052725 zinc Inorganic materials 0.000 description 1
Landscapes
- Non-Alcoholic Beverages (AREA)
Abstract
Description
本発明は、透明容器に充填された4−ヒドロキシ−2,5−ジメチル−3(2H)−フラノン及びアミノ態窒素を含有する飲料に関する。より詳細には、透明容器に充填されてなる、光劣化が抑制された4−ヒドロキシ−2,5−ジメチル−3(2H)−フラノン及びアミノ態窒素を含有する飲料に関する The present invention relates to a beverage containing 4-hydroxy-2,5-dimethyl-3(2H)-furanone and amino nitrogen filled in a transparent container. More specifically, the present invention relates to a beverage containing 4-hydroxy-2,5-dimethyl-3(2H)-furanone with suppressed photodegradation and amino nitrogen filled in a transparent container.
透明なペットボトルやガラス瓶などの容器に充填された飲料は、缶や紙容器に比べて、内容物である飲料の色や量が外観上視認できるという利点がある。また、ペットボトルは、再度閉栓できるという利便性もあることから、ペットボトル入り飲料の需要が高まっている。2017年生産量ベースで最もシェアが高かった容器詰飲料は、ペットボトル入り飲料であり、全体の72.6%のシェアであったことが報告されている。 Beverages filled in transparent containers such as PET bottles and glass bottles have an advantage over the cans and paper containers in that the color and amount of the beverage as the content can be visually recognized. Further, since the PET bottle has the convenience that it can be closed again, the demand for the PET bottled beverage is increasing. It has been reported that the packaged beverage with the highest market share in 2017 was PET bottled beverages, which accounted for 72.6% of the total market share.
ところで、容器詰飲料は、コンビニエンスストアや大型食料品店などの店舗では、蛍光灯で飲料の横や真上から全体を明るく照らすショーケースに陳列されて販売されている。ショーケース内の照度は非常に高く、この照射によって陳列されている飲料中の成分が変化し、光劣化と称される品質劣化(色の変化、臭い(異臭)や異味の生成)を生じることがある。特に、ペットボトル等の透明容器に充填された飲料は、光劣化を生じやすい。そこで、飲料の光劣化を簡便に防止する方法が提案されている。例えば、プロポリスを含有させることによるオレンジジュースの光劣化防止方法(特許文献1)、セリン、グリシン、アラニン及びシトルリンを含有させることによるシトラール含有飲料の光劣化防止方法(特許文献2)、カラメルを含有させることによる茶飲料の光劣化防止方法(特許文献3)等がある。また、アスコルビン酸等の抗酸化剤を用いてインスタント緑茶における光劣化を抑制する方法も提案されている(特許文献4)。 By the way, packaged beverages are sold in stores such as convenience stores and large-scale grocery stores by being displayed in a showcase that brightly illuminates the whole with a fluorescent lamp from the side or directly above the beverage. The illuminance inside the showcase is very high, and the components in the beverage displayed by this irradiation change, which causes quality deterioration called color deterioration (color change, generation of odor (offensive odor) or taste). There is. In particular, beverages filled in transparent containers such as PET bottles are prone to photo-deterioration. Therefore, there has been proposed a method for easily preventing the light deterioration of the beverage. For example, a method for preventing photo-deterioration of orange juice by containing propolis (Patent Document 1), a method for preventing photo-deterioration of a citral-containing beverage by containing serine, glycine, alanine and citrulline (Patent Document 2), containing caramel There is a method for preventing photo-deterioration of tea beverages (Patent Document 3) and the like. Also, a method of suppressing photodegradation in instant green tea by using an antioxidant such as ascorbic acid has been proposed (Patent Document 4).
一方、4−ヒドロキシ−2,5−ジメチル−3(2H)−フラノンを含有する飲料としては、アミノ酸を40ppm以上、フラネオール(4−ヒドロキシ−2,5−ジメチル−3(2H)−フラノン)を50ppb以上含有する茶飲料(特許文献5)や、1〜1000ppbの4−ヒドロキシ−2,5−ジメチル−3(2H)−フラノンが添加された茶飲料(特許文献6)等が報告されている。 On the other hand, as a drink containing 4-hydroxy-2,5-dimethyl-3(2H)-furanone, 40 ppm or more of amino acids and furaneol (4-hydroxy-2,5-dimethyl-3(2H)-furanone) are used. Tea beverages containing 50 ppb or more (Patent Document 5), tea beverages containing 1 to 1000 ppb of 4-hydroxy-2,5-dimethyl-3(2H)-furanone (Patent Document 6), and the like have been reported. ..
4−ヒドロキシ−2,5−ジメチル−3(2H)−フラノンは、甘味強化剤としての作用を有することが知られている(特許文献6)。4−ヒドロキシ−2,5−ジメチル−3(2H)−フラノンについて、本発明者がさらに検討したところ、特に、特定量のアミノ態窒素とともに飲料に含有させた場合に、飴のような香ばしい好ましい香気を有する飲料が得られることが判明した。しかし、一方で、この飲料を透明容器に充填して保存した場合、光劣化を引き起こして香気が変化しやすいことも判明した。 4-Hydroxy-2,5-dimethyl-3(2H)-furanone is known to have an action as a sweetness enhancer (Patent Document 6). 4-hydroxy-2,5-dimethyl-3(2H)-furanone was further investigated by the present inventor, and in particular, when it was contained in a beverage together with a specific amount of amino nitrogen, a scent like candy was preferable. It was found that a scented beverage was obtained. However, on the other hand, it was also found that when this beverage was filled in a transparent container and stored, photodegradation was caused to easily change the aroma.
そこで、本発明は、光劣化により生じる異臭が抑制された4−ヒドロキシ−2,5−ジメチル−3(2H)−フラノンとアミノ態窒素とを含有する透明容器入り飲料を提供することを目的とする。 Then, an object of the present invention is to provide a drink in a transparent container containing 4-hydroxy-2,5-dimethyl-3(2H)-furanone in which the offensive odor caused by photodegradation is suppressed and amino nitrogen. To do.
本発明者らは、上記課題を解決するために鋭意検討した結果、カフェインが4−ヒドロキシ−2,5−ジメチル−3(2H)−フラノンとアミノ態窒素とを含有する飲料の光劣化臭の発生を抑制するのに優れた効果があることを見出し、本発明を完成するに至った。本発明は、これに限定されるものではないが、以下に関する。
(1)5〜1000ppbの4−ヒドロキシ−2,5−ジメチル−3(2H)−フラノンと、1〜30ppmのアミノ態窒素と、10〜130ppmのカフェインとを含有する飲料であって、以下の条件(i)〜(iv):
(i)濁度が0.15未満である;
(ii)Brixが1.0以下である;
(iii)pHが5.0〜7.0である;及び
(iv)飲料が透明容器に充填されている、
を満たす、前記飲料。
(2)透明容器がPETボトルである、(1)に記載の飲料。
(3)クロロフィル類をさらに含有する、(1)又は(2)に記載の飲料。
As a result of intensive studies to solve the above-mentioned problems, the present inventors have found that the photo-deteriorated odor of a beverage in which caffeine contains 4-hydroxy-2,5-dimethyl-3(2H)-furanone and amino nitrogen. It was found that there is an excellent effect of suppressing the occurrence of the above, and the present invention has been completed. The present invention relates to, but is not limited to, the following:
(1) A beverage containing 5 to 1000 ppb of 4-hydroxy-2,5-dimethyl-3(2H)-furanone, 1 to 30 ppm of amino nitrogen, and 10 to 130 ppm of caffeine. Conditions (i) to (iv):
(I) Turbidity is less than 0.15;
(Ii) Brix is 1.0 or less;
(Iii) pH is 5.0 to 7.0; and (iv) the beverage is filled in a transparent container,
The beverage, which satisfies:
(2) The beverage according to (1), wherein the transparent container is a PET bottle.
(3) The beverage according to (1) or (2), which further contains chlorophylls.
本発明によれば、4−ヒドロキシ−2,5−ジメチル−3(2H)−フラノンとアミノ態窒素とを含有する飲料において、透明容器に充填されていながらも光による劣化が抑制された飲料を提供することができる。本発明の透明容器入り飲料は、太陽光や蛍光灯の影響を受けやすい店頭に陳列された場合であっても、光曝露に伴う光劣化の発生が少ないという利点を有するので、ショーケースにおける長期の陳列販売が可能となる。また、本発明によれば、透明容器を用いていることから内容物を容器の外側から目視することができ、視覚的にアピールできる商品価値の高い容器詰飲料を提供することができる。 According to the present invention, in a beverage containing 4-hydroxy-2,5-dimethyl-3(2H)-furanone and amino nitrogen, a beverage in which deterioration due to light is suppressed even though it is filled in a transparent container. Can be provided. The beverage in the transparent container of the present invention has an advantage that there is little occurrence of photodegradation due to light exposure even when it is displayed in a store that is easily affected by sunlight or a fluorescent lamp, so that it can be used for a long time in a showcase. It will be possible to sell on display. Further, according to the present invention, since the transparent container is used, the contents can be visually observed from the outside of the container, and it is possible to provide a packaged beverage having a high commercial value that can be visually appealing.
本発明の飲料及び関連する方法について、以下に説明する。特に断りがない限り、本明細書において用いられる「ppm」、及び「ppb」は、重量/容量(w/v)のppm、及びppbを意味する。 The beverages of the present invention and related methods are described below. Unless otherwise specified, "ppm" and "ppb" used herein mean ppm by weight/volume (w/v), and ppb.
本発明の一態様は、
5〜1000ppbの4−ヒドロキシ−2,5−ジメチル−3(2H)−フラノンと、1〜30ppmのアミノ態窒素と、10〜130ppmのカフェインとを含有する飲料であって、以下の条件(i)〜(iv):
(i)濁度が0.15未満である;
(ii)Brixが1.0以下である;
(iii)pHが5.0〜7.0である;及び
(iv)飲料が透明容器に充填されている、
を満たす、前記飲料である。かかる構成を採用することによって、透明容器に飲料が充填された状態であっても、当該飲料の光劣化を抑制することができる。ここで、本明細書において「光劣化」とは、飲料が光に曝露されることによって生じる品質の劣化を意味する。飲料の品質劣化としては、例えば、異臭の発生、異味の発生、色調の変化等が挙げられる。本発明では特に、「光劣化の抑制」は「異臭の発生の抑制」を意味する。
One aspect of the present invention is
A beverage containing 5 to 1000 ppb of 4-hydroxy-2,5-dimethyl-3(2H)-furanone, 1 to 30 ppm of amino nitrogen, and 10 to 130 ppm of caffeine under the following conditions ( i) to (iv):
(I) Turbidity is less than 0.15;
(Ii) Brix is 1.0 or less;
(Iii) pH is 5.0 to 7.0; and (iv) the beverage is filled in a transparent container,
It is the said drink which satisfy|fills. By adopting such a configuration, it is possible to suppress photodegradation of the beverage even when the beverage is filled in the transparent container. As used herein, the term “photo-deterioration” means deterioration in quality caused by exposure of a beverage to light. Examples of the quality deterioration of beverages include the occurrence of off-flavor, the occurrence of off-taste, and the change in color tone. In the present invention, “suppression of photodegradation” means “suppression of generation of offensive odor”.
(4−ヒドロキシ−2,5−ジメチル−3(2H)−フラノン)
飲料の光劣化は、全ての飲料に同等に生じるわけではない。本発明の対象となる飲料は、4−ヒドロキシ−2,5−ジメチル−3(2H)−フラノンとアミノ態窒素とを特定量以上含有する飲料である。ここで、4−ヒドロキシ−2,5−ジメチル−3(2H)−フラノン(2,5-dimethyl-4-hydroxy-2H-furan-3-one、以下、「DMHF」と称する)は、フラネオールRとも称される物質である。
(4-hydroxy-2,5-dimethyl-3(2H)-furanone)
Light degradation of beverages does not occur equally for all beverages. The target beverage of the present invention is a beverage containing 4-hydroxy-2,5-dimethyl-3(2H)-furanone and amino nitrogen in a specific amount or more. Here, 4-hydroxy-2,5-dimethyl-3(2H)-furanone (2,5-dimethyl-4-hydroxy-2H-furan-3-one, hereinafter referred to as "DMHF") is a furaneol R. It is also called a substance.
本発明の飲料は、DMHFを5ppb以上1000ppb以下の濃度で含有する飲料である。本発明の所望の効果が顕著に得られるという観点から、DMHFの濃度は、15ppb以上が好ましく、20ppb以上がより好ましく、30ppb以上がさらに好ましく、40ppb以上が特に好ましい。また、飲料としての嗜好性の観点から、DMHFの濃度は1000ppb以下であり、500ppb以下がさらに好ましい。なお、飲料中のDMHF濃度は、質量分析計付きのガスクロマトグラフィー(GC/MS)を用いて測定することができる。 The beverage of the present invention is a beverage containing DMHF at a concentration of 5 ppb or more and 1000 ppb or less. From the viewpoint that the desired effect of the present invention can be remarkably obtained, the concentration of DMHF is preferably 15 ppb or higher, more preferably 20 ppb or higher, further preferably 30 ppb or higher, particularly preferably 40 ppb or higher. Further, from the viewpoint of palatability as a beverage, the concentration of DMHF is 1000 ppb or less, more preferably 500 ppb or less. The DMHF concentration in the beverage can be measured using gas chromatography with a mass spectrometer (GC/MS).
本発明の飲料に含有されるDMHFの由来は限定されず、植物などの天然原料に由来するものでもよいし、合成品であってもよい。DMHFを含有する香料組成物を用いると、飲料におけるDMHFの濃度を上記範囲となるように簡便に調整できることから、DMHFを含有する香料組成物を配合してなる飲料は、本発明の好ましい態様の一例である。 The origin of DMHF contained in the beverage of the present invention is not limited, and may be derived from a natural raw material such as a plant or a synthetic product. When a DMHF-containing flavor composition is used, the concentration of DMHF in the beverage can be easily adjusted to fall within the above range. Therefore, a beverage prepared by blending the DMHF-containing flavor composition is a preferred embodiment of the present invention. This is an example.
(アミノ態窒素)
本発明の飲料は、1ppm以上30ppm以下のアミノ態窒素を含有する飲料である。本発明でいうアミノ態窒素の濃度(含有量)とは、遊離のα−アミノ酸の総量に該当する量であり、後述の方法にしたがって測定される濃度をいう。飲料中のアミノ態窒素の濃度が30ppmを超えると、アミノ態窒素成分(例えば、アミノ酸)自体の風味(特にアミノ酸含有飲料を加熱殺菌した場合に生じる加熱劣化臭)が飲料に影響を及ぼすことがあり、本発明の所望の効果が得られ難くなる。飲料中のアミノ態窒素の濃度は、25ppm以下が好ましく、20ppm以下がより好ましく、18ppm以下がさらに好ましい。
(Amino nitrogen)
The beverage of the present invention is a beverage containing 1 ppm or more and 30 ppm or less of amino nitrogen. The concentration (content) of amino nitrogen referred to in the present invention is the amount corresponding to the total amount of free α-amino acids, and means the concentration measured according to the method described below. If the concentration of amino nitrogen in the beverage exceeds 30 ppm, the flavor of the amino nitrogen component (for example, amino acid) itself (especially the heat-deteriorated odor generated when the amino acid-containing beverage is heat-sterilized) may affect the beverage. Therefore, it becomes difficult to obtain the desired effect of the present invention. The concentration of amino nitrogen in the beverage is preferably 25 ppm or less, more preferably 20 ppm or less, still more preferably 18 ppm or less.
本発明において、飲料中のアミノ態窒素の濃度は、2,4,6−トリニトロベンゼンスルホン酸ナトリウム(以下、TNBS)を用いたTNBS法により求める。TNBS法は、TNBSが遊離のα−アミノ酸と反応して生成する化合物が酸性で最大吸収を持つことを利用した測定方法である(Barret,D. and Edwards,B.F., Methods Enzymol., vol.45, pp.354-373, 1976)。具体的には、試料(飲料)を適度に希釈し、リン酸緩衝液とTNBS水溶液とを加え、所定時間、所定温度で反応させる。次いで、反応停止液を加え、340nmにおける吸光度を測定する。予め濃度既知のL−グリシンを用いて作成した検量線を用いて、試料(飲料)中のアミノ酸量をL−グリシンに相当するアミノ酸量(ppm)として算出する。このL−グリシンに相当するアミノ酸量(ppm)を、アミノ態窒素の濃度(ppm)とする。 In the present invention, the concentration of amino nitrogen in the beverage is determined by the TNBS method using sodium 2,4,6-trinitrobenzenesulfonate (hereinafter, TNBS). The TNBS method is a measurement method utilizing the fact that a compound formed by reacting TNBS with a free α-amino acid has an acid maximum absorption (Barret, D. and Edwards, BF, Methods Enzymol., vol. 45). , pp.354-373, 1976). Specifically, the sample (beverage) is appropriately diluted, a phosphate buffer solution and a TNBS aqueous solution are added, and the mixture is reacted at a predetermined temperature for a predetermined time. Then, a reaction stop solution is added and the absorbance at 340 nm is measured. The amino acid amount in the sample (beverage) is calculated as the amino acid amount (ppm) corresponding to L-glycine using a calibration curve prepared in advance using L-glycine of known concentration. The amino acid amount (ppm) corresponding to this L-glycine is defined as the concentration of amino nitrogen (ppm).
アミノ態窒素は、上述の通り、遊離のα−アミノ酸に該当するものであり、典型的には、これに限定されないが、アミノ酸である。アミノ酸としては、分子内にアミノ基とカルボキシ基とを有する化合物であれば特に限定されない。例えば、これらに限定されないが、テアニン、アルギニン、アスパラギン酸、スレオニン、セリン、グルタミン酸、グリシン、アラニン、システィン、バリン、メチオニン、イソロイシン、ロイシン、チロシン、フェニルアラニン、リジン、ヒスチジン、プロリンなどが挙げられる。アミノ酸は上記1種のみが含まれていてもよいし、2種以上が含まれていてもよい。 As described above, amino nitrogen corresponds to a free α-amino acid, and is typically, but not limited to, an amino acid. The amino acid is not particularly limited as long as it is a compound having an amino group and a carboxy group in the molecule. Examples include, but are not limited to, theanine, arginine, aspartic acid, threonine, serine, glutamic acid, glycine, alanine, cystine, valine, methionine, isoleucine, leucine, tyrosine, phenylalanine, lysine, histidine, proline and the like. The amino acid may contain only one type or two or more types.
アミノ酸等のアミノ態窒素は、アミノ態窒素を含有する天然物、特に植物から抽出したもの又はその精製品を用いてもよいし、化学合成等により工業的に製造したものを用いてもよい。本発明の好ましい実施形態としては、アミノ態窒素は植物抽出物由来のものである。植物抽出物は、植物の一部又は全体を、そのまま、或いは必要に応じて、乾燥、破砕、粉砕処理等を行った後に抽出することによって得ることができる。抽出手段は特に限定されず、エタノール等の有機溶媒、水又はそれらの混合物を用いた攪拌・振盪・浸漬抽出法や、減圧水蒸気蒸留抽出法、二酸化炭素等の超臨界流体を用いた超臨界ガス抽出法等、公知の抽出方法で行えばよい。 As the amino nitrogen such as amino acid, a natural product containing amino nitrogen, particularly a product extracted from a plant or a purified product thereof may be used, or a product industrially produced by chemical synthesis or the like may be used. In a preferred embodiment of the present invention, the amino nitrogen is derived from a plant extract. The plant extract can be obtained by extracting a part or whole of the plant as it is, or if necessary, after drying, crushing, pulverizing, etc., and then extracting. The extraction means is not particularly limited, and an organic solvent such as ethanol, a stirring/shaking/immersion extraction method using water or a mixture thereof, a reduced pressure steam distillation extraction method, a supercritical gas using a supercritical fluid such as carbon dioxide, etc. A known extraction method such as an extraction method may be used.
(カフェイン)
本発明の飲料におけるカフェインの濃度は、10ppm以上130ppm以下である。飲料に10ppm以上のカフェインを含有させることにより、DMHFとアミノ態窒素とを含有する飲料の光劣化臭を効果的に抑制することができる。飲料中のカフェイン濃度(含有量)は、15ppm以上が好ましく、20ppm以上がより好ましい。カフェイン濃度が10ppm以上であれば、本発明の効果を得ることができるが、カフェインは苦味成分として知られる成分であり、飲料中に高濃度で含有させた場合、後味に苦味が残り飲料の嗜好性を低下させることがある。かかる嗜好性の観点から、本発明の飲料におけるカフェインの濃度は130ppm以下であり、好ましくは120ppm以下であり、より好ましくは110ppm以下であり、さらに好ましくは100ppm以下である。カフェインの含有量は、高速液体クロマトグラフィー(HPLC)を用いた方法によって、測定及び定量できる。
(caffeine)
The concentration of caffeine in the beverage of the present invention is 10 ppm or more and 130 ppm or less. By adding 10 ppm or more of caffeine to the beverage, the photo-deteriorated odor of the beverage containing DMHF and amino nitrogen can be effectively suppressed. The caffeine concentration (content) in the beverage is preferably 15 ppm or more, more preferably 20 ppm or more. If the caffeine concentration is 10 ppm or more, the effect of the present invention can be obtained, but caffeine is a component known as a bitterness component, and when contained in a beverage at a high concentration, a bitterness remains in the aftertaste of the beverage. May reduce the palatability of. From the viewpoint of such palatability, the concentration of caffeine in the beverage of the present invention is 130 ppm or less, preferably 120 ppm or less, more preferably 110 ppm or less, and further preferably 100 ppm or less. The content of caffeine can be measured and quantified by a method using high performance liquid chromatography (HPLC).
本発明に用いられるカフェインは、特に制限されないが、市販の試薬、純品(カフェイン含量98%以上の精製品)、粗精製品(カフェイン含量50〜98%)の他、カフェインを含有する植物(コーヒー豆、茶葉、コーラの実等)の抽出物又はその濃縮物の形態でも用いることができる。カフェインを植物の抽出物又はその濃縮物の形態で用いる場合、抽出する原料としては、緑茶、紅茶、烏龍茶、プーアル茶などのカメリア・シネンシス(Camellia sinensis)に属する茶葉類;アカネ科コフィア属に属するコーヒー豆類を用いることができる。なかでも、本発明の効果の顕著さから、緑茶抽出物が好適に用いられる。 Caffeine used in the present invention is not particularly limited, but commercially available reagents, pure products (purified products having a caffeine content of 98% or more), crude purified products (caffeine content of 50 to 98%), and caffeine can be used. It can also be used in the form of an extract of the contained plant (coffee beans, tea leaves, cola fruit, etc.) or a concentrate thereof. When caffeine is used in the form of a plant extract or a concentrate thereof, as a raw material for extraction, tea leaves belonging to Camellia sinensis such as green tea, black tea, oolong tea, and puer tea are included in the genus Coffea. The coffee beans that belong can be used. Among them, green tea extract is preferably used because of the remarkable effect of the present invention.
本発明は、特定量のカフェインを用いてDMHFとアミノ態窒素とを含有する飲料の光劣化臭を抑制することを特徴とする。DMHFは空気中に拡散しにくい性質を持っているため口中に残りやすい。特にDMHFとアミノ態窒素とを含有する飲料は、飲んだ後も甘い香りが持続するという特徴を有する。しかし、特定量以上のDMHFとアミノ態窒素とを含有する飲料が光劣化を受けると、飲んだ後の甘い香りが変化して、不快な香りとして知覚されるようになる。本発明は、特定量のカフェインを含有させることにより、光劣化による不快な香り(光劣化臭)を抑制する。ここで、「光劣化を抑制する」とは、対照物(例えば、DMHFの濃度が5〜1000ppbであり、アミノ態窒素の濃度が1〜30ppmであり、濁度が0.15未満であり、Brixが1.0以下であり、pHが5.0〜7.0であり、カフェインの濃度が10ppm未満の飲料)と比較して、光劣化による異臭(本明細書中、光劣化臭ともいう)の強さが小さくなっていることをいう。光劣化臭の強さは、例えば専門パネルによる官能評価により決定できる。 The present invention is characterized by using a specific amount of caffeine to suppress the photo-deteriorating odor of a beverage containing DMHF and amino nitrogen. DMHF has a property of being less likely to diffuse into the air, and is likely to remain in the mouth. In particular, a beverage containing DMHF and amino nitrogen has a characteristic that a sweet scent lasts even after drinking. However, when a beverage containing a specific amount or more of DMHF and amino nitrogen is subjected to photodegradation, the sweet scent after drinking changes and is perceived as an unpleasant scent. The present invention suppresses an unpleasant scent due to photodegradation (photodegraded odor) by containing a specific amount of caffeine. Here, “suppressing photodegradation” means a control substance (for example, the concentration of DMHF is 5 to 1000 ppb, the concentration of amino nitrogen is 1 to 30 ppm, the turbidity is less than 0.15, Brix is 1.0 or less, pH is 5.0 to 7.0, and the off-flavor due to photodegradation (in the present specification, photodegradation odor is also compared to a beverage having a concentration of caffeine of less than 10 ppm). I say) means that the strength is getting smaller. The intensity of the photo-deteriorated odor can be determined by, for example, sensory evaluation by a specialized panel.
(濁度及び透明飲料)
本発明の飲料は、濁度が0.15未満である。本発明において飲料の濁度は、液体の濁度を測定する公知の手法を用いて波長680nmにおける吸光度を測定することにより、数値化することができる。具体的には、飲料を500mL容PETボトルに500mL充填して20℃にし、上下に10回撹拌してから10秒静置後に飲料の上部(飲料の上端より5cm以内の部分)より取得される飲料の波長680nmにおける吸光度を測定して、飲料の濁度を求めることができる。吸光度の測定には、例えば、紫外可視分光光度計(UV−1600(株式会社島津製作所製)など)を用いることができる。
(Turbidity and transparent beverage)
The beverage of the present invention has a turbidity of less than 0.15. In the present invention, the turbidity of a beverage can be quantified by measuring the absorbance at a wavelength of 680 nm using a known method for measuring the turbidity of a liquid. Specifically, 500 mL of the PET bottle is filled with 500 mL of the beverage, the temperature is set to 20° C., the mixture is stirred 10 times up and down, and then left still for 10 seconds, and then obtained from the upper portion of the beverage (portion within 5 cm from the upper end of the beverage). The turbidity of the beverage can be determined by measuring the absorbance of the beverage at a wavelength of 680 nm. For measuring the absorbance, for example, an ultraviolet-visible spectrophotometer (UV-1600 (manufactured by Shimadzu Corporation) or the like) can be used.
本発明の飲料は、好ましくは透明な飲料である。ここで、「飲料が透明である」とは、いわゆるスポーツドリンクのような白濁や、混濁果汁のような濁りがなく、水のように視覚的に透明な飲料をいう。飲料の濁度は、上述の通り、0.15未満である。飲料が不透明である、すなわち濁度が高い場合、より光曝露の影響を受けやすくなり、本発明の効果が顕著には得られないことがある。 The beverage of the present invention is preferably a transparent beverage. Here, “the beverage is transparent” means a beverage that is visually transparent like water without white turbidity such as so-called sports drinks and turbidity such as cloudy fruit juice. The turbidity of the beverage is less than 0.15, as described above. If the beverage is opaque, that is, has a high turbidity, it may be more susceptible to light exposure, and the effect of the present invention may not be remarkably obtained.
(Brix)
本発明の飲料は、Brixが1.0以下である。本発明の飲料のBrixは、好ましくは0.8以下であり、より好ましくは0.6以下である。飲料に糖類などの可溶性固形分が多く含まれる場合、これら可溶性固形分により、光劣化臭がマスキングされることがある。一方、Brixが1.0以下と低く抑えられた飲料は、マスキング成分として作用する可溶性固形分が少ないためにDMHFとアミノ態窒素による光劣化臭が顕著に知覚され得る。本発明は、光劣化臭が知覚されやすい可溶性固形分の少ない飲料においても光劣化臭を抑制することができる。本発明において、Brixは、糖度計や屈折計などを用いて得られるBrix(ブリックス)値によって評価することができる。ブリックス値は、20℃で測定された屈折率を、ICUMSA(国際砂糖分析統一委員会)の換算表に基づいてショ糖溶液の質量/質量パーセントに換算した値である。単位は「°Bx」、「%」または「度」で表示される。
(Brix)
Brix of the beverage of the present invention is 1.0 or less. The Brix of the beverage of the present invention is preferably 0.8 or less, more preferably 0.6 or less. When the beverage contains a large amount of soluble solids such as sugars, the soluble solids may mask the photo-deteriorated odor. On the other hand, a beverage whose Brix is suppressed to a low value of 1.0 or less has a small amount of soluble solids acting as a masking component, and thus a photo-deteriorated odor due to DMHF and amino nitrogen can be noticeably perceived. INDUSTRIAL APPLICABILITY The present invention can suppress the photo-deteriorated odor even in a beverage having a low soluble solid content in which the photo-degraded odor is easily perceived. In the present invention, Brix can be evaluated by the Brix value obtained by using a sugar meter, a refractometer, or the like. The Brix value is a value obtained by converting the refractive index measured at 20° C. into the mass/mass percent of the sucrose solution based on the conversion table of ICUMSA (International Union for the Analysis of Sugars). The unit is displayed as “°Bx”, “%” or “degree”.
(pH)
本発明の飲料は、pH(20℃)が5.0〜7.0であり、好ましくは5.5〜6.5の中性飲料である。飲料が酸性(例えば、pH4.5以下)である場合、飲料中の酸味成分により、光劣化臭がマスキングされることがある。しかし、中性飲料は、マスキング成分として作用する酸味成分が少ないためにDMHFとアミノ態窒素による光劣化臭が顕著に知覚され得る。本発明は、光劣化臭が知覚されやすい中性飲料においても光劣化臭を抑制することができる。飲料のpH調整は、炭酸水素ナトリウム、水酸化ナトリウム等のpH調整剤を用いて適宜行うことができる。飲料のpHは市販のpHメーターを使用して容易に測定することができる。
(PH)
The beverage of the present invention has a pH (20°C) of 5.0 to 7.0, and is preferably a neutral beverage of 5.5 to 6.5. When the beverage is acidic (for example, pH 4.5 or less), the sour component in the beverage may mask the photo-deteriorated odor. However, since the neutral beverage has few sour components that act as masking components, the photo-deteriorated odor due to DMHF and amino nitrogen can be noticeably perceived. INDUSTRIAL APPLICABILITY The present invention can suppress the photo-deteriorated odor even in a neutral beverage in which the photo-deteriorated odor is easily perceived. The pH of the beverage can be adjusted using a pH adjusting agent such as sodium hydrogen carbonate or sodium hydroxide. The pH of the beverage can be easily measured using a commercially available pH meter.
(透明容器入り飲料)
本発明の飲料は、透明容器に充填されてなる飲料である(本明細書中、透明容器入り飲料とも称する)。本発明の透明容器入り飲料は、内容物を目視でき、光劣化も抑制されていることから、消費者への安心感を与えることができる。ここで、本明細書において「透明容器」とは、容器に充填等された飲料を外部から視認できる容器を意味する。透明容器の概念には、容器の一部分においてその外部から内容物を視認できることも包含される。透明容器としては、例えば可視光700nmにおける透過率が40%以上、好ましくは50%以上の容器を挙げることができる。具体的には、透明プラスチックボトルおよび透明ガラス瓶が例示でき、特に透明PETボトルが本発明で好適に用いられる。容器の色は限定されないが、無色のものが好ましい。
(Beverage in transparent container)
The beverage of the present invention is a beverage filled in a transparent container (also referred to as a beverage in a transparent container in the present specification). Since the beverage in the transparent container of the present invention can be visually inspected for its contents and is suppressed from being deteriorated by light, it can give a consumer a sense of security. Here, in the present specification, the “transparent container” means a container in which the beverage filled in the container can be visually recognized from the outside. The concept of the transparent container also includes the fact that the contents can be seen from the outside of a part of the container. Examples of the transparent container include a container having a transmittance of visible light of 700 nm of 40% or more, preferably 50% or more. Specifically, a transparent plastic bottle and a transparent glass bottle can be exemplified, and a transparent PET bottle is particularly preferably used in the present invention. The color of the container is not limited, but a colorless one is preferable.
また、透明容器は容器の一部または全部がフィルム等で覆われていてもよい。例えば、内容表示用のラベル・印刷部分は不透明あるいは半透明でそれ以外の部分が透明な容器や、意匠性を有する透明部分・不透明部分が複数箇所で異なるように組み合わされている容器、看視窓程度の大きさの透明部分のみを有する不透明容器など、内容物が視認できる透明部分が存在する限りにおいてその透明領域については限定されない。 Further, the transparent container may be covered with a film or the like in part or in whole. For example, a container for displaying the content label/printed part is opaque or semi-transparent and the other part is transparent, or a container in which the transparent and opaque parts with design characteristics are combined in different places. The transparent region is not limited as long as there is a transparent portion in which the contents can be visually recognized, such as an opaque container having only a transparent portion having a size of a window.
(クロロフィル類)
ところで、近年ではLED照明が普及し、LEDは蛍光灯と比較して紫外線量が少ないことから、光劣化を生じにくいといわれている。しかしながら、クロロフィル類を含有する飲料は、クロロフィル類が光増感物質として作用するために、LED照明下においても短期間で著しい光劣化を引き起こす可能性がある。クロロフィル類の光増感酸化反応は、DMHFやアミノ態窒素の光酸化と異なるため、クロロフィル類を含有する飲料は、より一層光劣化を引き起こしやすいと考えられる。
(Chlorophylls)
By the way, in recent years, LED lighting has become widespread, and LEDs are said to be less prone to photodegradation because they have a smaller amount of ultraviolet rays than fluorescent lamps. However, beverages containing chlorophylls may cause significant photodegradation in a short period of time even under LED illumination because chlorophylls act as photosensitizers. Since the photosensitized oxidation reaction of chlorophylls is different from the photooxidation of DMHF and amino nitrogen, it is considered that the beverage containing chlorophylls is more likely to cause photodegradation.
本発明の飲料は、このようなDMHFとアミノ態窒素とクロロフィル類とを含有している状態においても光劣化の抑制に関する顕著な効果を発揮する。クロロフィル類は、葉緑素とも呼ばれ、光合成の明反応で光エネルギーを吸収する役割をもつ化学物質である。クロロフィル類は、4つのピロールからなる環構造であるテトラピロールに、フィトールと呼ばれる長鎖アルコールがエステル結合した基本構造をもつ。天然に存在するクロロフィル類は、一般にテトラピロール環の中心にマグネシウム等の金属が配位した構造を有する。この金属が脱離し、2つの水素で置換された物質はフェオフィチンと呼ばれる。本明細書では、クロロフィルとフェオフィチンを合わせてクロロフィル類と呼ぶこととする。クロロフィル類は、テトラピロール環の種類および結合している置換基によって区別され、発見された順にアルファベットが付与されているが、本明細書においてクロロフィル類の濃度をいうときは、クロロフィルa(C55H72O5N4M)及びクロロフィルb(C55H70O6N4M)(Mは中心金属を意味する)を対象としてこれらの合計量を指す。なお、中心金属(M)は特に限定されないが、本発明の効果を享受できる点から、Zn、Cu又はFeであることが好ましい。 The beverage of the present invention exerts a remarkable effect regarding suppression of photodegradation even in a state containing such DMHF, amino nitrogen and chlorophylls. Chlorophyll, also called chlorophyll, is a chemical substance that absorbs light energy in the light reaction of photosynthesis. Chlorophyll has a basic structure in which a long-chain alcohol called phytol is ester-bonded to tetrapyrrole, which is a ring structure composed of four pyrroles. Naturally occurring chlorophylls generally have a structure in which a metal such as magnesium is coordinated to the center of a tetrapyrrole ring. A substance in which this metal is eliminated and replaced with two hydrogen atoms is called pheophytin. In the present specification, chlorophyll and pheophytin are collectively referred to as chlorophylls. Chlorophylls are distinguished by the type of tetrapyrrole ring and the substituents attached to them, and the alphabetical letters are given in the order in which they were discovered. In the present specification, when referring to the concentration of chlorophylls, chlorophyll a (C 55 H 72 O 5 N 4 M) and chlorophyll b (C 55 H 70 O 6 N 4 M) (M means central metal) are referred to as their total amounts. The central metal (M) is not particularly limited, but is preferably Zn, Cu or Fe from the viewpoint that the effect of the present invention can be enjoyed.
クロロフィル類としては、市販のクロロフィル製剤を使用することができ、具体的には、これに限定されないが、和光純薬工業株式会社製クロロフィルaなどを使用することができる。クロロフィル類の製造方法や由来は特に限定されないが、クロロフィル類は植物体の葉緑素であるため、茶葉、緑黄色野菜などの植物体を適当な溶媒に抽出して得られる抽出液を、クロロフィル類抽出液として飲料に添加することができる。 As the chlorophyll, a commercially available chlorophyll preparation can be used, and specifically, but not limited to, chlorophyll a manufactured by Wako Pure Chemical Industries, Ltd. can be used. The production method and origin of chlorophylls are not particularly limited, but since chlorophylls are chlorophylls of plants, tea leaves, extracts obtained by extracting plants such as green-yellow vegetables into a suitable solvent, chlorophyll extract Can be added to the beverage as.
飲料中のクロロフィル類の濃度は、10〜2500ppb程度が好ましく、20〜2000ppbがより好ましく、50〜1500ppbがさらに好ましい。飲料中のクロロフィル類の濃度は、分光光度計(例えば日立社製、U−3210)を用いた吸光光度法により、測定することができる。 The concentration of chlorophylls in the beverage is preferably about 10 to 2,500 ppb, more preferably 20 to 2,000 ppb, still more preferably 50 to 1,500 ppb. The concentration of chlorophylls in the beverage can be measured by an absorptiometric method using a spectrophotometer (for example, U-3210 manufactured by Hitachi Ltd.).
(他の成分)
本発明の飲料には、本発明の効果を妨げない範囲で、通常の飲料と同様に、各種添加剤、例えば、香料、ビタミン、色素類、酸化防止剤、乳化剤、保存料、調味料、エキス類、pH調整剤、品質安定剤などを配合してもよい。
(Other ingredients)
The beverage of the present invention, as long as the effect of the present invention is not impaired, as with ordinary beverages, various additives, for example, flavors, vitamins, pigments, antioxidants, emulsifiers, preservatives, seasonings, extracts. You may mix|blend a class, pH adjuster, a quality stabilizer, etc.
DMHFは、イチゴ、パイナップル、トマト、ソバ、緑茶、鰹節といった食品の香り成分として知られている成分であり、本発明の飲料の好適な態様としては、これらに限定されないが、イチゴやパイナップル等のフレーバーが付加された水飲料(いわゆる、フレーバーウォーター)が挙げられる。また、茶飲料も好ましい。「茶飲料」とは、茶葉の抽出物や穀類の抽出物を主成分として含有する飲料であり、具体的には、緑茶、ほうじ茶、ブレンド茶、麦茶、マテ茶、ジャスミン茶、紅茶、ウーロン茶、杜仲茶などが挙げられる。茶飲料の中でも緑茶風味飲料は、本発明の効果がより顕著に発現することから特に好適な態様の一例である。なお、ここでいう緑茶風味飲料は、緑茶抽出物を含有し、且つ緑茶の風味を呈する飲料を意味する。 DMHF is a component known as a scent component of foods such as strawberries, pineapples, tomatoes, buckwheat, green tea, and bonito flakes, and suitable embodiments of the beverage of the present invention include, but are not limited to, strawberries and pineapples. Water drinks with a flavor added (so-called flavor water) can be mentioned. Tea beverages are also preferred. The "tea beverage" is a beverage containing an extract of tea leaves or an extract of cereals as a main component, and specifically, green tea, hoji tea, blended tea, barley tea, mate tea, jasmine tea, black tea, oolong tea, For example, Tochu tea. Among the tea beverages, the green tea flavored beverage is an example of a particularly preferable aspect because the effects of the present invention are more significantly exhibited. The green tea flavored beverage here means a beverage containing a green tea extract and exhibiting the flavor of green tea.
(加熱殺菌飲料)
本発明の飲料は、好ましくは加熱殺菌処理を経て得られる閉栓された容器入り飲料とすることができる。加熱殺菌の条件は、例えば、食品衛生法に定められた条件と同等の効果が得られる方法を選択することができ、具体的には、60〜150℃で1秒間〜60分間とすることができる。容器として耐熱性容器(ガラス等)を使用する場合には、レトルト殺菌(110〜140℃、1〜数十分間)を行うこともできる。また、容器として非耐熱性容器(PETボトル等)を用いる場合は、例えば、調合液を予めプレート式熱交換器等で高温短時間殺菌後(UHT殺菌:110〜150℃、1〜数十秒間)し、一定の温度まで冷却した後、容器に充填することができる。
(Heating pasteurized beverage)
The beverage of the present invention can be preferably a beverage in a closed container obtained through heat sterilization treatment. As the condition of heat sterilization, for example, a method capable of obtaining the same effect as the condition stipulated in the Food Sanitation Law can be selected, and specifically, it may be 1 second to 60 minutes at 60 to 150°C. it can. When a heat resistant container (glass or the like) is used as the container, retort sterilization (110 to 140° C., 1 to several tens of minutes) can be performed. When a non-heat-resistant container (PET bottle or the like) is used as the container, for example, the preparation liquid is preliminarily sterilized by a plate heat exchanger at a high temperature for a short time (UHT sterilization: 110 to 150°C, 1 to several tens of seconds). ), and after cooling to a constant temperature, the container can be filled.
(方法)
本発明は、別の側面では飲料の製造方法であり、具体的には、DMHFとアミノ態窒素とカフェインとを含有する飲料の製造方法である。当該方法は、以下の工程:
飲料中のDMHFの濃度を5〜1000ppbに調整する工程、
飲料中のアミノ態窒素の濃度を1〜30ppmとなるように調整する工程、
飲料中のカフェインの濃度を10〜130ppmに調整する工程、
飲料の濁度を0.15未満に調整する工程、
飲料のBrixを1.0以下に調整する工程、
飲料のpHを5.0〜7.0に調整する工程、及び
得られた飲料を透明容器に充填する工程
を含む。
(Method)
The present invention, in another aspect, is a method for producing a beverage, specifically, a method for producing a beverage containing DMHF, amino nitrogen, and caffeine. The method comprises the following steps:
Adjusting the concentration of DMHF in the beverage to 5-1000 ppb,
A step of adjusting the concentration of amino nitrogen in the beverage to be 1 to 30 ppm,
A step of adjusting the concentration of caffeine in the beverage to 10 to 130 ppm,
Adjusting the turbidity of the beverage to less than 0.15,
Adjusting the Brix of the beverage to 1.0 or less,
It includes a step of adjusting the pH of the beverage to 5.0 to 7.0 and a step of filling the obtained beverage in a transparent container.
飲料中の各種成分の濃度、並びに飲料の濁度、Brix、及びpHを調整する方法は、本発明の飲料に関して上記した通りであるか、それらから自明である。そのタイミングも限定されない。例えば、充填工程以外の上記工程は、同時に行ってもよいし、別々に行ってもよいし、工程の順番を入れ替えてもよい。最終的に得られた飲料が、上記の条件を満たせばよい。また各種成分の濃度、並びに飲料の濁度、Brix、及びpHの好ましい範囲は、飲料に関して上記した通りである。 The concentration of the various components in the beverage and the method of adjusting the turbidity, Brix, and pH of the beverage are as described above or obvious from the beverage of the present invention. The timing is also not limited. For example, the above steps other than the filling step may be performed simultaneously, separately, or the order of the steps may be changed. The beverage finally obtained may satisfy the above conditions. The preferred ranges of the concentrations of various components and the turbidity of the beverage, Brix, and pH are as described above for the beverage.
上記の製法は、飲料において光劣化を抑制することができる。従って、当該製法は、別の側面では、飲料の光劣化を抑制する方法ともいえる。 The above production method can suppress photodegradation in beverages. Therefore, the said manufacturing method can also be said to be the method of suppressing the photodegradation of a drink from another side.
以下、実験例を示して本発明の詳細を具体的に説明するが、本発明はこれに限定されるものではない。また、本明細書において、特に記載しない限り、数値範囲はその端点を含むものとして記載される。 Hereinafter, details of the present invention will be specifically described with reference to experimental examples, but the present invention is not limited thereto. Further, in the present specification, unless otherwise stated, the numerical range is described as including its endpoints.
本実施例中、飲料中の各成分量は以下の方法により測定した。
(DMHFの定量方法)
バイアル瓶(容量20ml)に試料溶液を5g量り取り、1.5gのNaClを加えた後、スペルコ社製SPME(DVB/CAR/PDMS)を用いた固相マイクロ抽出法にて気相部のDMHFを40℃で20分間抽出した。抽出後、GC/MS測定に供した。定量値は標準添加法で算出した。GC/MS測定条件は以下の通りである。
装置:GC:Agilent Technologies社製 GC7890B
MS:Agilent Technologies社製 5977A
カラム:Inert cap pure WAX 30m×0.25mmi.d. df=0.25μm
定量イオン:DMHF m/z=128
温度条件:40℃(5分)〜10℃/分〜260℃
キャリアガス流量:He 1.2ml/分
注入口温度:250℃
インターフェイス温度:250℃
イオン源温度:230℃。
In this example, the amount of each component in the beverage was measured by the following method.
(Method for quantifying DMHF)
5 g of the sample solution was weighed in a vial (capacity: 20 ml), 1.5 g of NaCl was added, and then DMHF of the gas phase was obtained by solid phase microextraction using SPME (DVB/CAR/PDMS) manufactured by Supelco. Was extracted at 40° C. for 20 minutes. After extraction, it was subjected to GC/MS measurement. The quantitative value was calculated by the standard addition method. The GC/MS measurement conditions are as follows.
Device: GC: Agilent Technologies GC7890B
MS: 5977A manufactured by Agilent Technologies
Column: Inert cap pure WAX 30 m×0.25 mm i. d. df=0.25 μm
Quantitative ion: DMHF m/z=128
Temperature condition: 40°C (5 minutes) to 10°C/minute to 260°C
Carrier gas flow rate: He 1.2 ml/min Inlet port temperature: 250°C
Interface temperature: 250℃
Ion source temperature: 230°C.
(カフェインの定量方法)
カフェインの測定方法にはHPLCを用いた。具体的測定方法は、以下のとおり。
・HPLC装置:TOSOH HPLCシステム LC8020 modelIII
・カラム:TSKgel ODS80T sQA(4.6mm×150mm)
・カラム温度:40℃
・移動相A:水-アセトニトリル-トリフルオロ酢酸(90:10:0.05)
・移動相B:水-アセトニトリル-トリフルオロ酢酸(20:80:0.05)
・検出:UV275nm
・注入量:20μL
・流速:1mL/min.
・グラジエントプログラム:
時間(分) %A %B
0 100 0
5 92 8
11 90 10
21 90 10
22 0 100
29 0 100
30 100 0
・標準物質:カフェイン(和光純薬試薬)。
(Method for quantifying caffeine)
HPLC was used as the method for measuring caffeine. The specific measurement method is as follows.
-HPLC device: TOSOH HPLC system LC8020 modelIII
・Column: TSKgel ODS80T sQA (4.6 mm×150 mm)
・Column temperature: 40℃
-Mobile phase A: water-acetonitrile-trifluoroacetic acid (90:10:0.05)
-Mobile phase B: water-acetonitrile-trifluoroacetic acid (20:80:0.05)
・Detection: UV275nm
・Injection volume: 20 μL
-Flow rate: 1 mL/min.
・Gradient program:
Hours (minutes) %A %B
0 100 0
5 92 8
11 90 10
21 90 10
22 0 100
29 0 100
30 100 0
-Standard substance: caffeine (Wako Pure Chemicals Reagent).
(アミノ態窒素の濃度の測定)
アミノ態窒素の濃度の測定は、前述の通り、TNBS法を用いて遊離のα−アミノ酸の量を測定することにより行った。まず、0.5mLの試料(飲料)に対して、2mLのリン酸緩衝溶液、及び2mLの0.1%TNBS水溶液を加えて攪拌混合し、45℃で90分間反応を行った。反応終了後、反応停止液を加えて反応を停止させた。反応停止後1時間以内に、反応液の波長340nmにおける吸光度を、紫外可視分光光度計(日本分光社製 V−550)を用いて測定した。標準物質として、0.1〜0.5mMのL−グリシンを使用した。
(Measurement of amino nitrogen concentration)
The amino nitrogen concentration was measured by measuring the amount of free α-amino acid using the TNBS method, as described above. First, to 0.5 mL of a sample (beverage), 2 mL of a phosphate buffer solution and 2 mL of a 0.1% TNBS aqueous solution were added, mixed with stirring, and reacted at 45° C. for 90 minutes. After the reaction was completed, a reaction stop solution was added to stop the reaction. Within 1 hour after stopping the reaction, the absorbance of the reaction solution at a wavelength of 340 nm was measured using an ultraviolet-visible spectrophotometer (V-550 manufactured by JASCO Corporation). As a standard substance, 0.1-0.5 mM L-glycine was used.
<実験1:DMHF含有飲料の評価(1)>
DMHFとして東京化成のフラネオール(純度:>99%)を、アミノ酸としてテアニン(太陽化学、サンテアニン)を用いた。水溶液中のDMHF及びアミノ態窒素の最終濃度が、表1に記載の濃度となるように、DMHF及びアミノ酸を水(pH7の純水)に溶解した。種々の濃度のDMHF含有溶液(pH≒7、Brix:0)を加熱殺菌した後、500mgずつを透明PETボトルに充填して透明容器入り飲料を製造した。また、加熱殺菌した種々の濃度のDMHF含有溶液を缶に充填し、対照飲料とした。なお、加熱殺菌したDMHF含有溶液はいずれもpHが7.0、Brixは0であり、濁度(OD680nm)は0.15未満であった。
<Experiment 1: Evaluation of DMHF-containing beverage (1)>
Furanol (purity: >99%) from Tokyo Kasei was used as DMHF, and theanine (Taiyo Kagaku, Santheanine) was used as the amino acid. DMHF and amino acids were dissolved in water (pure water of pH 7) so that the final concentrations of DMHF and amino nitrogen in the aqueous solution were the concentrations shown in Table 1. DMHF-containing solutions of various concentrations (pH≈7, Brix:0) were sterilized by heating, and then 500 mg each was filled in a transparent PET bottle to manufacture a beverage in a transparent container. Further, cans were filled with DMHF-containing solutions that had been sterilized by heating and had various concentrations, and used as control beverages. The heat-sterilized DMHF-containing solutions had a pH of 7.0, a Brix of 0, and a turbidity (OD680 nm) of less than 0.15.
透明PETボトル飲料を光照射(10,000ルクス、25℃、1週間)し、照射後の飲料の風味を評価した。評価は、光照射しなかった缶入り飲料を基準とし、光劣化による異臭(光劣化臭)の強弱を、基準と比較した相対評価として3段階評価(◎:光劣化臭が弱い、○:光劣化臭がやや弱い、×:光劣化臭が強い)で行った。なお、評価は専門パネル5名が光劣化臭の強弱について各自で評価した後、パネル全員で協議して決定した。 The transparent PET bottle beverage was irradiated with light (10,000 lux, 25° C., 1 week), and the flavor of the beverage after irradiation was evaluated. The evaluation was based on a canned beverage that was not irradiated with light, and the relative strength of the offensive odor (photo-deteriorated odor) due to photo-deterioration was compared to the standard. Deterioration odor is slightly weak, x: Light deterioration odor is strong). In addition, the evaluation was made by 5 panelists who evaluated the intensity of the photo-deteriorated odor by themselves and then discussed with all panel members.
結果を表1に示す。5ppb以上のDMHFと1ppm以上のアミノ態窒素とを含有する溶液は、光劣化臭が発生した。 The results are shown in Table 1. A solution containing 5 ppb or more of DMHF and 1 ppm or more of amino nitrogen generated a photo-deteriorated odor.
<実験2:DMHF含有飲料の評価(2)>
実験1のアミノ酸をアルギニン(味の素ヘルシーサプライ、L−アルギニン)に変える以外は、実験1と同様にしてDMHFとアミノ態窒素とを含有する溶液を調製し、評価した。得られたいずれの溶液も、濁度(OD680nm)は0.15未満であり、Brixは1.0以下であった。結果を表2に示す。アミノ酸としてアルギニンを用いた場合も、5ppb以上のDMHFと1ppm以上のアミノ態窒素とを含有する溶液は、光劣化臭が発生した。
<Experiment 2: Evaluation of DMHF-containing beverage (2)>
A solution containing DMHF and amino nitrogen was prepared and evaluated in the same manner as in Experiment 1 except that the amino acid in Experiment 1 was changed to arginine (Ajinomoto Healthy Supply, L-arginine). Each of the obtained solutions had a turbidity (OD680 nm) of less than 0.15 and a Brix of 1.0 or less. The results are shown in Table 2. Even when arginine was used as the amino acid, a solution containing 5 ppb or more of DMHF and 1 ppm or more of amino nitrogen generated a photo-deteriorated odor.
<実験3:DMHF含有飲料の評価(3)>
実験1の試料1−12及び実験2の試料2−12について、クエン酸及びクエン酸ナトリウムを用いて種々のpHとなるように調整した。得られたいずれの溶液も、濁度(OD680nm)は0.15未満であり、Brixは1.0以下であった。実験1と同様にして、光劣化臭の強弱を評価した。結果を表3に示す。pH5.0以上の飲料ではDMHFとアミノ態窒素由来の香調の変化による光劣化臭が感じられたのに対し、pH4.5以下の飲料では、酸味成分により光劣化臭がマスキングされていた。
<Experiment 3: Evaluation of DMHF-containing beverage (3)>
Sample 1-12 of Experiment 1 and Sample 2-12 of Experiment 2 were adjusted to various pHs using citric acid and sodium citrate. Each of the obtained solutions had a turbidity (OD680 nm) of less than 0.15 and a Brix of 1.0 or less. In the same manner as in Experiment 1, the intensity of photo-deteriorated odor was evaluated. The results are shown in Table 3. In the beverage having a pH of 5.0 or more, the photo-deteriorated odor was felt due to the change in the fragrance tone derived from DMHF and amino nitrogen, whereas in the beverage having a pH of 4.5 or less, the photo-deteriorated odor was masked by the sour component.
<実験4:カフェインによる光劣化抑制作用(1)>
60ppmのDMHFと20ppmのアミノ態窒素とを含有する溶液(実験1の試料1−12、実験2の試料2−12)に、溶液中のカフェイン濃度が表4に記載の濃度となるように、丸善薬品産業株式会社製)(純度:>99%)を添加して溶解した。各種カフェイン濃度のDMHF溶液を加熱殺菌した後、500mgずつを透明PETボトルに充填して透明容器入り飲料を製造した。また、加熱殺菌した種々の濃度のDMHF含有溶液を缶に充填して対照飲料とした。なお、加熱殺菌した飲料はいずれもpHが5.0〜7.0の範囲内であった。また、濁度(OD680nm)は0.15未満であり、Brixは1.0以下であった。
<Experiment 4: Photodegradation suppression effect of caffeine (1)>
In a solution containing 60 ppm of DMHF and 20 ppm of amino nitrogen (Sample 1-12 of Experiment 1, Sample 2-12 of Experiment 2), the concentration of caffeine in the solution should be the concentration shown in Table 4. Maruzen Yakuhin Sangyo Co., Ltd.) (purity: >99%) was added and dissolved. After sterilizing DMHF solutions having various caffeine concentrations by heating, 500 mg each was filled in a transparent PET bottle to manufacture a beverage in a transparent container. Further, the cans were filled with DMHF-containing solutions that had been sterilized by heating and had various concentrations to prepare a control beverage. The heat-sterilized beverages all had a pH in the range of 5.0 to 7.0. The turbidity (OD680 nm) was less than 0.15, and the Brix was 1.0 or less.
得られた各種容器詰め飲料について、実験1と同様にして、光劣化臭の強弱を評価した。結果を表4に示す。DMHFを60ppb及びアミノ態窒素を20ppm含有する飲料は光劣化臭を発生するが、10ppm以上のカフェインを含有させることによって、光劣化臭を抑制できることが分かった。カフェインを多量に配合した場合、カフェインの苦味が飲料の嗜好性を低下させると評価したパネルが存在したことから、飲料中のカフェインの濃度の上限は、130ppm以下とすることが好ましいことが示唆された。 For each of the various packaged beverages obtained, the strength of the photo-deteriorated odor was evaluated in the same manner as in Experiment 1. The results are shown in Table 4. It was found that a beverage containing 60 ppb of DMHF and 20 ppm of amino nitrogen produces a photo-deteriorated odor, but the photo-deteriorated odor can be suppressed by containing 10 ppm or more of caffeine. When a large amount of caffeine was blended, there was a panel evaluated that the bitterness of caffeine reduces the palatability of the beverage, so the upper limit of the concentration of caffeine in the beverage is preferably 130 ppm or less. Was suggested.
<実験5:カフェインによる光劣化抑制作用(2)>
実験1の試料1−6、1−10、1−13及び1−14、実験2の試料2−6、2−10、2−13及び2−14について、カフェインの最終濃度が10ppmとなるようにカフェインを添加した以外は、実験3と同様にして透明PETボトル入り飲料を製造し、評価した。なお、得られたいずれの溶液も、濁度(OD680nm)は0.15未満であり、pHは5.0〜7.0の範囲内であり、Brixは1.0以下であった。結果を表5に示す。5ppb以上のDMHFと1ppm以上のアミノ態窒素とを含有する飲料について、カフェインを10ppm含有させることにより光劣化臭を抑制することができた。
<Experiment 5: Caffeine suppresses photodegradation (2)>
For samples 1-6, 1-10, 1-13 and 1-14 of experiment 1 and samples 2-6, 2-10, 2-13 and 2-14 of experiment 2, the final concentration of caffeine is 10 ppm. A transparent PET bottled beverage was produced and evaluated in the same manner as in Experiment 3 except that caffeine was added as described above. The turbidity (OD680 nm) of each of the obtained solutions was less than 0.15, the pH was in the range of 5.0 to 7.0, and the Brix was 1.0 or less. The results are shown in Table 5. Regarding the beverage containing DMHF of 5 ppb or more and amino nitrogen of 1 ppm or more, the photo-deteriorated odor could be suppressed by containing 10 ppm of caffeine.
<実験6:カフェインによる光劣化抑制作用(3)>
純水を茶抽出液に変えること以外は、実験4と同様にして透明PETボトル入りの緑茶風味飲料を製造した。具体的には、市販の茶葉『お茶の丸幸 低カフェイン緑茶ティーバッグ』を用い、茶葉の500倍の質量の80℃の湯で30秒抽出し、遠心分離処理して清澄化を行った後、炭酸水素ナトリウム及びL−アスコルビン酸を加えてpH6.1に調整し、茶抽出液とした(カフェイン含有量:5ppm、アミノ態窒素含有量:5ppm、クロロフィル類含有量:50ppb)。この茶抽出液に、DMHF含有量が60ppbとなるように実験1で用いたDMHFを添加した。このDMHFを含有する試料溶液(試料6−1)に、溶液中のカフェインの最終濃度が表6に記載の濃度となるように、カフェイン(丸善薬品産業株式会社製)を添加して溶解した。各種カフェイン濃度のDMHF含有溶液にをUHT殺菌し、500mgずつを透明PETボトルに充填して透明容器入り飲料を製造した。また、UHT殺菌した種々の濃度のDMHF含有溶液を缶に充填して対照飲料とした。なお、UHT殺菌した飲料はいずれもpHが5.0〜7.0の範囲内であった。また、濁度(OD680nm)は0.15未満であり、Brixは1.0以下であった。
<Experiment 6: Caffeine suppresses photodegradation (3)>
A green tea flavored beverage in a transparent PET bottle was produced in the same manner as in Experiment 4 except that pure water was changed to tea extract. Specifically, after using commercially available tea leaves "Ocha no Maruyuki Low Caffeine Green Tea Tea Bag", it was extracted with hot water at a temperature of 80°C, which is 500 times as much as the mass of tea leaves, for 30 seconds, clarified by centrifugation. , Sodium hydrogen carbonate and L-ascorbic acid were added to adjust the pH to 6.1 to obtain a tea extract (caffeine content: 5 ppm, amino nitrogen content: 5 ppm, chlorophylls content: 50 ppb). The DMHF used in Experiment 1 was added to the tea extract so that the DMHF content was 60 ppb. To this sample solution containing DMHF (Sample 6-1), caffeine (manufactured by Maruzen Pharmaceutical Co., Ltd.) was added and dissolved so that the final concentration of caffeine in the solution would be the concentration shown in Table 6. did. The DMHF-containing solutions having various caffeine concentrations were subjected to UHT sterilization, and 500 mg each was filled in a transparent PET bottle to manufacture a beverage in a transparent container. Further, cans were filled with UHT-sterilized DMHF-containing solutions of various concentrations to prepare control beverages. The pH of all the beverages sterilized by UHT was within the range of 5.0 to 7.0. The turbidity (OD680 nm) was less than 0.15, and the Brix was 1.0 or less.
得られた各種容器詰め飲料について、実験1と同様にして、光劣化臭の強弱を評価した。結果を表6に示す。カフェインの一部として茶抽出液を用い、またクロロフィル類を含有する飲料においても、光劣化臭の抑制作用が得られた。 For each of the various packaged beverages obtained, the strength of the photo-deteriorated odor was evaluated in the same manner as in Experiment 1. The results are shown in Table 6. The tea extract was used as a part of the caffeine, and the effect of suppressing the photo-deteriorated odor was also obtained in the beverage containing chlorophylls.
Claims (3)
(i)濁度が0.15未満である;
(ii)Brixが1.0以下である;
(iii)pHが5.0〜7.0である;及び
(iv)飲料が透明容器に充填されている、
を満たす、前記飲料。 A beverage containing 5 to 1000 ppb of 4-hydroxy-2,5-dimethyl-3(2H)-furanone, 1 to 30 ppm of amino nitrogen, and 10 to 130 ppm of caffeine under the following conditions ( i) to (iv):
(I) Turbidity is less than 0.15;
(Ii) Brix is 1.0 or less;
(Iii) pH is 5.0 to 7.0; and (iv) the beverage is filled in a transparent container,
The beverage, which satisfies:
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| WO2022176835A1 (en) * | 2021-02-19 | 2022-08-25 | サントリーホールディングス株式会社 | Tea beverage |
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