JP2004121228A - Method for increasing polyphenol content of harvested plant - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for increasing a polyphenol effective for maintaining health without affecting appearance of a plant, a plant in which content of the polyphenol is increased and a device for carrying out the method. <P>SOLUTION: The device includes a means for housing the harvested plant and a means for irradiating UV lights. By the device, the UV rays in a specific wavelength region are irradiated to the harvested plant to increase the polyphenol content. <P>COPYRIGHT: (C)2004,JPO

Description

【００２７】
ポリフェノールが有する生理活性は、主として抗酸化作用とタンパク質機能調節作用に大別され、生体内で多彩な作用を示すが、その一方でポリフェノールは吸収性が低くしかも速やかに代謝排泄されるため副作用を示し難い。従って、ポリフェノールは健康維持食品成分として極めて優れているが、その速やかな代謝性故に健康維持のためには恒常的な摂取が必要である。
【００２８】
ポリフェノールが示す作用は、例えば、単純ポリフェノール類であるコーヒー酸では抗菌作用，炎症鎮静作用，抗腫瘍作用など、フラボノイド類であるアピゲニンでは糖尿病予防作用，心疾患予防作用，鎮静作用など、クリシンでは抗酸化作用，女性ホルモン抑制作用など、タンゲレチンではリウマチ予防作用などである。従って、ポリフェノール含有植物を毎日摂取すること、および植物中のポリフェノール含有量を増加させることは健康対策として非常に有益である。
【００２９】
紫外線の１日当たりの照射量は、０．５Ｊ／ｃｍ^２以上５０Ｊ／ｃｍ^２以下であることが好ましい。０．５Ｊ／ｃｍ^２未満ではその効果が乏しい場合があり、５０Ｊ／ｃｍ^２を超えると収穫後であっても植物細胞等への悪影響（例えば、ビタミンＣ含有量の減少など）が懸念されるからである。従って、１日当たりの紫外線照射量は、０．８Ｊ／ｃｍ^２以上がより好ましく、更に好ましくは１Ｊ／ｃｍ^２以上である。一方、１日当たりの紫外線照射量の上限は、照射日数にもよるが４０Ｊ／ｃｍ^２以下がより好ましく、３０Ｊ／ｃｍ^２以下が更に好ましく、２０Ｊ／ｃｍ^２以下がより一層好ましく、最適には１０Ｊ／ｃｍ^２以下である。尚、「Ｊ」は仕事量の単位であるので、紫外線が弱ければ１日あたりの照射時間は長くなり、反対に強ければ照射時間は短くなる。
【００３０】
本発明に係る収穫後植物のポリフェノール含有量を増加させるための装置は、収穫後植物を格納する手段、および紫外線を照射する手段を含有することを特徴とする。
【００３１】
「収穫後植物を格納する手段」は、収穫後植物を収納維持できる箱状のものであれば特に限定なく使用され得る。このような手段としては、例えばコンテナ（トラック，冷凍車，冷蔵車，保冷車，移動販売車，食品輸送車等に設置するものを含む），冷蔵庫，ショーウィンドウ，倉庫などを挙げることができる。
【００３２】
「紫外線を照射する手段」は、一定波長範囲にある紫外線を照射できるものであれば特に制限なく使用でき、例えば、紫外線ランプ等の一般的な紫外線照射装置を挙げることができる。
【００３３】
収穫後植物を格納する手段は、紫外線を外部に漏洩しないものであることが好ましい。本発明で使用される紫外線照射量は、環境や人体に悪影響を及ぼす程ではないが、全く害がないとは言い切れないからである。紫外線の漏洩を防止するには、紫外線を透過しない材質によって格納手段を構成するなどの必要がある。
【００３４】
本発明の装置は、紫外線の波長を調節する手段を有することが好ましい。ポリフェノールは、特定波長の紫外線に特に強い極大吸収を有し、植物は紫外線に対する防御手段としてポリフェノールを生合成すると考えられるため、特定波長の紫外線を照射することにより、目的とするポリフェノールを特に増加させることが可能だからである。
【００３５】
また、本発明の装置は、紫外線の照射量を調節する手段を有することが好ましい。適切な紫外線照射量は収穫後植物の種類により異なるので、植物に悪影響を及ぼさない範囲で効果的にポリフェノールを増加させるべく、被紫外線照射植物ごとに照射量を調整する必要があるからである。
【００３６】
本発明の装置は、収穫後植物を格納する上記手段の開扉時に、紫外線照射を停止する手段を有することが好ましい。紫外線が人体等に及ぼし得る影響を考慮すれば、植物の出し入れ時には、紫外線照射を一時的に停止することが好ましいと考えられるからである。
【００３７】
本発明は以上の様に構成されており、本発明によれば、生活習慣病の予防効果等を有し健康維持に極めて有益なポリフェノールを増加させた野菜等が得られるので、その日常的摂取によりポリフェノールの摂取量を増やすことができる。従って、本発明は、近年における健康志向に適合するものである。
【００３８】
以下に、実施例を示すことにより本発明を更に詳細に説明するが、本発明の範囲はこれらに限定されるものではない。
【００３９】
【実施例】
実施例１
（紫外線照射実験１）
パセリおよびホウレンソウの市販品を購入し、パセリについては１株を４等分したもの、ホウレンソウは１株を２等分したものを収穫後植物の試料とした。
【００４０】
当該試料に対して、波長が３２０〜３８０ｎｍ（ＵＶ−Ａ）または２８０〜３２０ｎｍ（ＵＶ−Ｂ）の紫外線を、紫外線ランプ（アトー（株）製，ＵＶ−Ａ：ＤＦ−３６５，ＵＶ−Ｂ：ＤＦ−３１２）を用いて、１日当たり１．０Ｊ／ｃｍ^２の照射量で７日間照射した。照射時以外は、養液栽培用肥料（大塚化学（株），大塚ハウス１号を１．５ｇ／ｌと同２号を１ｇ／ｌの配合）中、１０℃の暗室内で保存した。
【００４１】
また、対照例として非照射群も同様に保存した。
【００４２】
パセリおよびホウレンソウ共に、紫外線の非照射群と、ＵＶ−Ａ照射群或いはＵＶ−Ｂ照射群との間に外見上の違いは観察されなかった。
【００４３】
（紫外線照射実験２）
市販のツルムラサキ及びかいわれ大根を収穫後植物の試料とし、上記紫外線照射実験１と同様にＵＶ−ＡとＵＶ−Ｂを照射した。
【００４４】
ツルムラサキに対しては、１日当たり１．０Ｊ／ｃｍ^２の照射量となる様に１日２回５分ずつ３日に亘り紫外線を照射した。
【００４５】
かいわれ大根に対しては、紫外線を対象に満遍なく照射できる様に対象の裏表から５分間ずつ紫外線照射を行なったこと以外は、ツルムラサキの場合と同様の条件で紫外線照射実験を行なった。
【００４６】
照射を行なっていないときは、養液栽培用肥料を用いず１０℃の暗室内で保存した。
【００４７】
また、対照例として非照射群も同様に保存した。
【００４８】
紫外線の非照射群と照射群との間に外見上の違いは観察されなかった。
【００４９】
（試料の処理）
上記最終照射の２４時間後に試料を水道水で洗浄し、可食部を細断した。これを液体窒素により凍結し、ホモジェナイザー（（株）日本精機製作所製）を用いて粉砕した後、２日間凍結乾燥した（到達真空度０．２Ｐａ）。
【００５０】
この凍結乾燥粉末５０ｍｇに２ｍｌの９０％メタノール水溶液（０．５％酢酸を含む）および内部標準として５０ｎｍｏｌのフラボン（ナカライテスク（株）製）を添加し、１分間ソニケーションした後（和研薬（株），マイクロソンＭＳ−５０使用）、３０００ｒｐｍで１０分間遠心分離し上清を回収した。
【００５１】
斯かる抽出操作を３回繰り返し、集めた上清を濃縮遠心機（タイテック（株）製）で乾固後、５００μｌのジメチルスルホキシド（ＤＭＳＯ）に溶解した。
【００５２】
これをメンブレンフィルター（Ｍｉｌｌｉｐｏｒｅ　Ｃｏ．製，０．２μｍ）で濾過後、高速クロマトグラフィー（ＨＰＬＣ）に供した。
【００５３】
（ＨＰＬＣ分析によるポリフェノールの同定と定量）
凍結乾燥試料の抽出液をＨＰＬＣに供し、各ピークにおけるリテンションタイムおよびＵＶスペクトルを市販標品のものと比較することによって、ポリフェノールを同定・定量した。
【００５４】
ＨＰＬＣ条件は、下表１に示す通りである。
【００５５】
【表１】

【００５６】
移動相は、溶離液Ａ（１０％メタノールを含む５０ｍＭリン酸二水素ナトリウム水溶液（ｐＨ３．３））、溶離液Ｂ（７０％メタノールを含む５０ｍＭリン酸二水素ナトリウム水溶液（ｐＨ３．３））の２液グラジエントを用いた。
【００５７】
リニアグラジエントの条件は、下表２に示す通りである。
【００５８】
【表２】

【００５９】
ＨＰＬＣ分析で市販標品と一致しなかったポリフェノールは、ＨＰＬＣにより分取した後、ＬＣ／ＭＳにより分子量を測定して構造を決定した。
【００６０】
（収穫後パセリの紫外線照射結果）
図１に示す通り、紫外線非照射パセリのＨＰＬＣ分析では主なピークが４つ得られた。当該ピークおよびそのＵＶスペクトラムを市販標品と比較したところ、ピークの１つはフラボノイド類のうちフラボン類であるアピゲニンのものであった。更に、配糖体のアグリコンを同定すべく試料を加水分解してＨＰＬＣ分析を行なったところ、残りの３ピークはアピゲニン配糖体であることが解かった。
【００６１】
パセリに含まれるポリフェノールがアピゲニン類であることが明らかとなったことから、紫外線非照射群、ＵＶ−Ａ照射群およびＵＶ−Ｂ照射群各群につき、アピゲニンとその配糖体の含有量をＨＰＬＣにより測定した。その結果を図２に示す。
【００６２】
当該結果によれば、アピゲニン配糖体の含有量は、紫外線照射による大きな変動は認められなかったが、アピゲニン含有量は、ＵＶ−Ａ照射群、ＵＶ−Ｂ照射群ともに非照射群に比して有意に増加した。従って、本発明の方法によれば、収穫後植物のポリフェノール含有量を増加し得ることが明らかとなった。
【００６３】
（収穫後ホウレンソウの紫外線照射結果）
紫外線非照射群、ＵＶ−Ａ照射群およびＵＶ−Ｂ照射群各群につき得られたＨＰＬＣクロマトグラムを図３に示す。
【００６４】
また、市販標品との比較により同定された各ポリフェノールの含有量をＨＰＬＣにより測定した。結果を表３に示す。
【００６５】
【表３】

【００６６】
表中の値は、試料数４の平均値±標準偏差である。また、表中「ＮＤ」は、検出限界以下であったことを示す。
【００６７】
当該結果によれば、ＵＶ−Ａ照射群は、被照射群と比較してパチュレチン配糖体、スピナセチン配糖体、ＴＭＭＧおよびＤＤＭＧが増加した。
【００６８】
一方、ＵＶ−Ｂ照射群では、保持時間８９分付近と９２分付近に新たなピークが検出された。保持時間とスペクトルを市販標品のものと比較して、これらをクリシンとタンゲレチンと同定した。加水分解を行なった後ＨＰＬＣ分析に供した場合も、これらのピークは被照射群およびＵＶ−Ａ照射群には表れず、ＵＶ−Ｂ照射群では同じ保持時間で検出された。従って、クリシンおよびタンゲレチンは、ＵＶ−Ｂ照射によって新たに合成されたフラボノイドであることが明らかとなった。また、ＵＶ−Ｂ照射群には、コーヒー酸類も被照射群に比べて豊富に含まれていた。従って、本発明の方法によれば、収穫後植物において既存のポリフェノール含有量を増加させ得るのみならず、紫外線照射前に存在しなかったポリフェノールを増加させ得ることが証明された。
【００６９】
（収穫後ツルムラサキの紫外線照射結果）
紫外線非照射群、ＵＶ−Ａ照射群およびＵＶ−Ｂ照射群各群につき、その含有フラボン類であるビテキシンとイソビテキシン、およびフラボノール類であるケンフェロールの配糖体含有量をＨＰＬＣにより測定した。その結果を図４に示す。
【００７０】
当該結果によれば、紫外線照射によってツルムラサキのポリフェノールが増加している。また、ビテキシンについては、ＵＶ−Ａによって特異的に増加していることが解かる。従って、特定波長域の紫外線照射によって、特定のポリフェノールを増加できることが明らかとなった。
【００７１】
（収穫後かいわれ大根の紫外線照射結果）
紫外線非照射群、ＵＶ−Ａ照射群およびＵＶ−Ｂ照射群各群につき、ケンフェロール配糖体の含有量をＨＰＬＣにより測定した。その結果を図５に示す。
【００７２】
当該結果により、紫外線照射によってかいわれ大根のポリフェノールが増加することが証明された。
【００７３】
実施例２　短期間照射実験
市販のパセリを購入し、上記実施例１では７日間に亘り紫外線を照射したのに対し、同様の条件で３日間照射した。その後、１日後（購入してから４日後），２日後，５日後において、主要なポリフェノール類であるアピゲニン配糖体の含有量を、上記実施例１と同様の条件でＨＰＬＣにより定量した。結果を図６に示す。
【００７４】
当該結果より、無処置のパセリでは収穫後にポリフェノールであるアピゲニン配糖体含有量が減少する一方で、３日間の紫外線照射であっても、収穫後植物のポリフェノール含有量を有意に増加できることが実証された。
【００７５】
実施例３　短期間照射実験
ツルムラサキについて、更に短期間である２日間のみ上記実施例１と同様の条件で紫外線照射し、その後１日（購入してから３日目）におけるポリフェノール含有量を定量した。結果を図７に示す。
【００７６】
当該結果によれば、ＵＶ−Ａ照射群では明確なポリフェノール含有量の増加は見られなかったものの、ＵＶ−Ｂ照射群では明らかな増加が観察された。
【００７７】
また、ツルムラサキについて１日間のみのＵＶ−Ｂ照射実験を同様に行ない、照射後１日および４日目において、ポリフェノール含有量の定量を行なった。結果を図８に示す。
【００７８】
図８に示す結果の通り、１日間の紫外線照射であっても、照射４日後には有意なポリフェノール含有量の増加が観察された。
【００７９】
実施例４　外観性状
本発明の条件では、植物外観に殆ど影響がないことを証明するために、ツルムラサキ，かいわれ大根およびホウレンソウに、７日間に亘って上記実施例１と同様の条件で紫外線照射を行ない、外観性状の変化を調べた。この間、紫外線を照射する時以外は、試料を冷蔵庫の野菜室で保存した。結果を図９に示す。
【００８０】
図９の通り、ＵＶ−Ａ照射またはＵＶ−Ｂ照射を受けた収穫後植物でも見た目は購入時と変化はなく、萎れや葉の黄色も見られなかった。従って、本願発明方法は、収穫後植物の外観に殆ど影響を及ぼさないことが実証された。
【００８１】
実施例５　栄養成分に与える影響
ツルムラサキとかいわれ大根は３日間、ホウレンソウには７日間に亘って上記実施例１と同様の条件で紫外線照射を行ない、照射後１日におけるビタミンＣ含有量を定量した。結果を図１０に示す。
【００８２】
図１０の結果によれば、ＵＶ−Ｂ照射後のツルムラサキとホウレンソウでは、ビタミンＣ含有量に若干の低下が見られたが、押並べて、紫外線照射による有意な差は観察されなかった。
【００８３】
また、上記試料についてβ−カロテンの含有量も定量したが明確な変化は見られなかったため、照射時間を短くして定量した。即ち、ホウレンソウで３日間、ツルムラサキでは２日間の紫外線照射を行ない。その１日後のβ−カロテン含有量を定量した。結果を図１１に示す。
【００８４】
図１１の結果によれば、ツルムラサキではβ−カロテン含有量は購入時と殆ど変わらず、ホウレンソウでは若干増えていた。
【００８５】
以上の結果より、本発明方法では、ポリフェノール以外の栄養素に殆ど影響を与えないことが実証された。
【００８６】
【発明の効果】
本発明に係る方法は、収穫後植物のポリフェノール含有量を有意に増加させることができ、且つ黄変等外見上の悪影響を及ぼすことも殆どない。従って、本発明の方法により処理された収穫後植物は、健康食品として非常に優れている。
【００８７】
また、本発明に係る装置は、上記方法を実施するものであるため非常に有用であるばかりでなく、産業的に生産し得るものであることから、産業の興隆を新たに実現することができるものである。
【図面の簡単な説明】
【図１】紫外線非照射パセリのＨＰＬＣクロマトグラム
【図２】収穫後パセリの紫外線照射前後におけるポリフェノール含有量の変化
【図３】紫外線照射前後の収穫後ホウレンソウのＨＰＬＣクロマトグラム
【図４】収穫後ツルムラサキの紫外線照射前後におけるポリフェノール含有量の変化
【図５】収穫後かいわれ大根の紫外線照射前後におけるポリフェノール含有量の変化
【図６】３日間の紫外線照射後におけるパセリのポリフェノール含有量の変化
【図７】２日間の紫外線照射後におけるツルムラサキのポリフェノール含有量の変化
【図８】１日間の紫外線照射後におけるツルムラサキのポリフェノール含有量の変化
【図９】紫外線照射後における収穫後植物の外観性状
【図１０】紫外線照射後における収穫後植物のビタミンＣ含有量の変化
【図１１】紫外線照射後における収穫後植物のβ−カロテン含有量の変化[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a method for increasing the polyphenol content of a post-harvest plant, a post-harvest plant having an increased polyphenol content by the method, and an apparatus for performing the method.
[0002]
[Prior art]
In recent years, lifestyle-related diseases caused by lifestyle habits such as eating habits and exercise habits have become a problem. Such lifestyle-related diseases are a general term for diseases caused by lifestyles that place a burden on the body, and include cancer, circulatory diseases, diabetes, osteoporosis and the like as typical examples. While these are fatal, they often progress without subjective symptoms, and it is very important to prevent them regularly.
[0003]
One of the preventive measures for lifestyle-related diseases is to improve dietary habits. Examples include not eating too much or ingesting multiple items. Recently, polyphenols contained in plant foods have been noted as having a preventive effect on lifestyle-related diseases (Non-Patent Document 1). -3).
[0004]
That is, since polyphenols exert antioxidant and protein function regulating activities as main physiological activities, aging is suppressed by the antioxidant effect, and cancer, arteriosclerosis, diabetes, cardiovascular disease, Alzheimer's disease, Parkinson's disease, By reducing amyloidosis, hepatitis, cataract and the like, and by regulating the activity of receptors and enzymes in the body, the toxicity of dioxin, the action of environmental hormones, allergy, inflammation, etc. are strongly suppressed.
[0005]
On the other hand, even if a large amount of polyphenol is ingested, its concentration in the body does not rise above a certain value, and is rapidly released from the body by metabolic excretion, so that it is less likely to cause side effects (Non-Patent Document 4). Therefore, it can be said that the constant intake of polyphenols from food is an ideal health measure.
[0006]
Here, polyphenol is a general term for compounds in which a benzene ring is substituted with a plurality of hydroxyl groups or methoxy groups, and is included in vegetables, fruits, teas and the like in plants as food. So-called flavonoids among such polyphenols are contained in plants, particularly at sites where they are often exposed to sunlight. This is considered to synthesize flavonoids having strong maximum absorption in the ultraviolet region in order to protect plants from harmful ultraviolet light contained in sunlight. In recent years, it has been reported that the amount of flavonoids significantly increases when ultraviolet rays are artificially irradiated during the growth process.
[0007]
However, when a growing crop is irradiated with excessive ultraviolet rays, the gene itself is harmed, resulting in appearance disorders such as yellowing of leaves and poor growth. Therefore, it is not preferable to irradiate the growing plants with ultraviolet rays.
[0008]
On the other hand, from the viewpoint of maintaining health, it is very significant to increase the amount of polyphenols contained in plant foods in order to consume as much polyphenols as possible every day.
[0009]
[Non-patent document 1]
Meyer A. S. Et al., Food Chemistry, 61, 71-75 (1998).
[Non-patent document 2]
Kanagawa K. et al. Et al., Journal of Agricultural and Food Chemistry (J. Agric. Food Chem.), 43, 404-409 (1995).
[Non-Patent Document 3]
Ashida H .; Et al., FEBS Letters, 476, 213-217 (2000).
[Non-patent document 4]
Conque J. et al. A. Et al., Journal of Nutrition (J. Nutr.), 128, 593-597 (1998).
[0010]
[Problems to be solved by the invention]
Thus, the problem to be solved by the present invention is to increase the polyphenol content that is effective for maintaining health without affecting the appearance of the plant, to increase the polyphenol content of the plant, and to increase the polyphenol content of the plant. To provide an apparatus for the same.
[0011]
[Means for Solving the Problems]
The present inventors have conducted intensive research to solve the above-mentioned problems, and found that by irradiating plants with ultraviolet rays even after harvesting, it is possible to increase the content of polyphenols without affecting the appearance. We have completed the present invention.
[0012]
That is, the method according to the present invention is characterized in that the polyphenol content of a plant after harvest is increased by irradiating ultraviolet rays in a specific wavelength range. UV irradiation after harvesting can increase the polyphenol content while suppressing the effect on the appearance of the plant.
[0013]
In the method, a preferable wavelength of the ultraviolet light is 240 nm or more and 320 nm or less, or 300 nm or more and 400 nm or less, and a preferable ultraviolet irradiation dose is 0.5 J / cm per day. ² More than 50J / cm ² It is as follows. This is because such an ultraviolet ray and its irradiation amount have been proved to be highly effective by the examples described later.
[0014]
Further, the plant according to the present invention is a post-harvest plant, wherein the polyphenol content has been increased by the above method. The plant is extremely useful as a food product having an increased polyphenol content without substantially impairing the appearance.
[0015]
Furthermore, an apparatus according to the present invention is an apparatus for performing the above method, wherein the apparatus includes a unit for storing a plant after harvest, and a unit for irradiating ultraviolet rays. With the device, the invention can be suitably implemented.
[0016]
In the device, as the above-mentioned means for storing the plants after harvesting, those which do not leak ultraviolet rays to the outside are suitable. This is because the amount of ultraviolet irradiation used in the present invention is not so bad as to have an adverse effect on the environment and the human body, but it cannot be said that there is no harm at all.
[0017]
Further, the apparatus preferably further includes a means for adjusting the wavelength of the ultraviolet light, a means for adjusting the irradiation amount of the ultraviolet light, and a means for stopping the irradiation of the ultraviolet light when the means for storing the plant after harvest is opened. is there. Again, this is to minimize the adverse effects of ultraviolet rays on the human body.
[0018]
BEST MODE FOR CARRYING OUT THE INVENTION
The most significant feature of the method according to the invention is that it significantly increases the polyphenol content with little apparent damage to the plants after harvesting. That is, in the past, it was known that there was a close relationship between the polyphenol content and the irradiation amount of ultraviolet rays including sunlight during the growth process of a plant. It has also been found that the content of polyphenols can be increased by carrying out post-harvesting and that irradiation of ultraviolet light after harvesting does not easily impair the appearance of plants.
[0019]
Hereinafter, embodiments of the present invention exhibiting such characteristics and effects thereof will be described.
[0020]
The method according to the present invention is to increase the polyphenol content of a plant after harvest by irradiating ultraviolet rays in a specific wavelength range. Here, “increase” means to increase the total amount of polyphenols in the plant after harvesting by ultraviolet irradiation, and not only to increase the existing polyphenol content but also to generate polyphenols that did not exist before. included. In fact, the present inventor has found that polyphenols that did not exist before irradiation may be produced depending on the plant species, the wavelength range of irradiation ultraviolet light, and the like (see Examples described later). In addition, since the polyphenol content may decrease after harvest depending on the plant species, the `` increase '' of the present invention does not necessarily mean that the polyphenol always increases after the treatment according to the present invention as compared to after the harvest. In some cases, it means that the polyphenol content is increased as compared with the case of no treatment.
[0021]
The general wavelength range of “ultraviolet light” is extremely wide, from 1 to 400 nm, but the ultraviolet light used in the present invention is mainly in the range of near ultraviolet light (300 to 400 nm) and far ultraviolet light (200 to 300 nm). Plants biosynthesize polyphenols having strong maximum absorption in the ultraviolet region as a means of protecting against harmful ultraviolet light, but most of these polyphenols have maximum absorption in the range of 200 to 400 nm.
[0022]
The "ultraviolet light" used is preferably UV-B having a wavelength of 240 nm or more and 320 nm or less, or UV-A having a wavelength of 300 nm or more and 400 nm or less. This is because flavonoids in particular among polyphenols have strong maximum absorption in these wavelength ranges. In consideration of such reasons and convenience of the ultraviolet lamp used, UV-B is more preferably 280 nm or more and 285 nm or less, and UV-A is more preferably 320 nm or more and 380 nm or less.
[0023]
The irradiation light used in the present invention is ultraviolet light in a specific wavelength range. That is, it is ultraviolet light (preferably 200 to 400 nm) in a wavelength range according to the irradiated plant to be used or the polyphenol to be increased, and does not use light containing random ultraviolet light such as sunlight. Embodiments are preferred. Certainly, ultraviolet rays having the wavelength used in the present invention are included in sunlight, and the irradiation amount can be controlled within the range specified by the present invention by adjusting the exposure time. However, under the influence of light other than the regulation according to the present invention, plants biosynthesize carbohydrates, lipids, proteins, and the like.However, after harvest, plants cannot absorb nutrients from outside the body, and biosynthesis does not occur. Internal components are used. As a result, or due to the heat of sunlight, the plant may appear whitish or yellowish, resulting in an appearance impairment. In addition, a mode in which sunlight is irradiated through a filter that transmits only ultraviolet light having a specific wavelength can be considered, but it is difficult to use such a filter in terms of both technical and cost aspects. On the other hand, in the present invention, polyphenols are selectively biosynthesized by irradiating ultraviolet rays with a specific wavelength, and biosynthesis of polyphenols alone does not consume nutrients in a living body more than necessary. Incidentally, in the present invention, it is preferable to irradiate only ultraviolet rays in a specific wavelength range, and light having a wavelength outside the specified range does not hit the plant after harvesting as much as possible. , Within the scope of the present invention.
[0024]
In the present invention, "post-harvest plants" are targeted. This is because, when targeting a plant that is in the process of growth, ultraviolet rays may damage a gene, or the like, resulting in an appearance disorder such as yellowing of a leaf or poor growth.
[0025]
“Polyphenol” is a generic term for compounds in which a plurality of hydroxyl groups or methoxy groups are substituted on the benzene ring, and exists in plants as a glycoside in which a saccharide is bonded to a portion called aglycone. Here, sugar as a constituent component of polyphenol mainly exerts only a stabilizing action, and thus the classification of polyphenol depends on the structure of aglycone. That is, polyphenols are classified into simple polyphenols having a monocyclic structure, anthraquinones having a polycyclic structure, and flavonoids having a polycyclic structure, depending on the type of aglycone. Flavonoids are further classified into six types. You. The main classes of polyphenols and typical examples are shown below.
[0026]
Embedded image

[0027]
The physiological activities of polyphenols are mainly classified into antioxidant activity and protein function regulating activity, and exhibit various actions in vivo.On the other hand, polyphenols have low absorption and are rapidly metabolized and excreted. Hard to show. Therefore, although polyphenols are extremely excellent as a health-maintaining food ingredient, they require constant intake for maintaining health due to their rapid metabolism.
[0028]
The effects of polyphenols include, for example, caffeic acid, a simple polyphenol, antibacterial, sedative, and antitumor effects, apigenin, a flavonoid, antidiabetic, cardiovascular, and sedative effects of chrysin. Tangeretin has an effect of preventing rheumatism, such as an oxidizing effect and a female hormone suppressing effect. Therefore, taking a polyphenol-containing plant daily and increasing the polyphenol content in the plant are very beneficial as health measures.
[0029]
The daily dose of ultraviolet rays is 0.5 J / cm ² More than 50J / cm ² The following is preferred. 0.5J / cm ² If less than 50 J / cm, the effect may be poor. ² This is because, if it exceeds the limit, even after harvesting, adverse effects on plant cells and the like (for example, decrease in vitamin C content) may be concerned. Therefore, the amount of ultraviolet irradiation per day is 0.8 J / cm ² More preferably, more preferably 1 J / cm ² That is all. On the other hand, the upper limit of the amount of ultraviolet irradiation per day depends on the number of irradiation days, but is 40 J / cm. ² The following is more preferable, and 30 J / cm ² The following is more preferable, and 20 J / cm ² The following is even more preferred, optimally 10 J / cm ² It is as follows. Since “J” is a unit of work, the irradiation time per day becomes longer when the ultraviolet ray is weak, and the irradiation time becomes shorter when the ultraviolet ray is strong.
[0030]
An apparatus for increasing the polyphenol content of a post-harvest plant according to the present invention is characterized in that it comprises means for storing the post-harvest plant and means for irradiating ultraviolet light.
[0031]
The “means for storing plants after harvesting” can be used without particular limitation as long as they are box-shaped capable of storing and maintaining plants after harvesting. Examples of such means include containers (including those installed in trucks, refrigerated vehicles, refrigerated vehicles, refrigerated vehicles, mobile sales vehicles, food transport vehicles, etc.), refrigerators, shop windows, warehouses, and the like.
[0032]
The "means for irradiating ultraviolet light" can be used without particular limitation as long as it can irradiate ultraviolet light in a certain wavelength range, and examples thereof include a general ultraviolet irradiation device such as an ultraviolet lamp.
[0033]
It is preferable that the means for storing the plants after harvesting does not leak ultraviolet rays to the outside. This is because the amount of ultraviolet irradiation used in the present invention is not so bad as to have an adverse effect on the environment and the human body, but it cannot be said that there is no harm at all. In order to prevent the leakage of ultraviolet rays, it is necessary to form the storage means with a material that does not transmit ultraviolet rays.
[0034]
The device of the present invention preferably has means for adjusting the wavelength of ultraviolet light. Polyphenols have a particularly strong maximum absorption of ultraviolet light of a specific wavelength, and plants are thought to biosynthesize polyphenols as a means of protection against ultraviolet light. Because it is possible.
[0035]
Further, the apparatus of the present invention preferably has means for adjusting the irradiation amount of ultraviolet rays. This is because the appropriate amount of UV irradiation varies depending on the type of plant after harvesting, and thus it is necessary to adjust the amount of irradiation for each UV-irradiated plant in order to effectively increase polyphenols within a range that does not adversely affect the plant.
[0036]
The apparatus of the present invention preferably has means for stopping the irradiation of ultraviolet rays when the above-mentioned means for storing the plants after harvesting is opened. This is because it is considered preferable to temporarily stop the irradiation of the ultraviolet rays when putting the plant in and out, in consideration of the effect that the ultraviolet rays may have on the human body and the like.
[0037]
The present invention is constituted as described above, and according to the present invention, it is possible to obtain a vegetable or the like having an effect of preventing lifestyle-related diseases or the like and having an increased amount of polyphenol which is extremely useful for maintaining health. Thus, the intake of polyphenols can be increased. Therefore, the present invention is compatible with recent health consciousness.
[0038]
Hereinafter, the present invention will be described in more detail by way of examples, but the scope of the present invention is not limited thereto.
[0039]
【Example】
Example 1
(UV irradiation experiment 1)
Commercial products of parsley and spinach were purchased. For parsley, one strain was divided into four equal parts, and for spinach, one strain was divided into two equal parts.
[0040]
UV light having a wavelength of 320 to 380 nm (UV-A) or 280 to 320 nm (UV-B) is applied to the sample by an ultraviolet lamp (UV-A: DF-365, UV-B: manufactured by ATTO Corporation). 1.0 J / cm per day using DF-312) ² For 7 days. Except for the irradiation, the solution was stored in a dark room at 10 ° C. in a fertilizer for hydroponics (Otsuka Chemical Co., Ltd., Otsuka House No. 1 of 1.5 g / l and No. 2 of 1 g / l).
[0041]
In addition, a non-irradiated group was similarly preserved as a control.
[0042]
In both parsley and spinach, no apparent difference was observed between the UV-irradiated group and the UV-A-irradiated group or UV-B-irradiated group.
[0043]
(UV irradiation experiment 2)
Commercially available purple radish and Japanese radish were used as plant samples after harvesting, and irradiated with UV-A and UV-B in the same manner as in the above-described ultraviolet irradiation experiment 1.
[0044]
1.0 J / cm per day for Tsurumurasaki ² Was irradiated twice a day for 5 minutes for 3 days.
[0045]
An ultraviolet irradiation experiment was performed on the radish under the same conditions as in the case of Tsurumurasaki except that ultraviolet irradiation was performed from the front and back of the object for 5 minutes so that the object could be evenly irradiated with ultraviolet light.
[0046]
When no irradiation was performed, the cells were stored in a dark room at 10 ° C. without using fertilizer for hydroponics.
[0047]
In addition, a non-irradiated group was similarly preserved as a control.
[0048]
No apparent difference was observed between the non-irradiated group and the irradiated group.
[0049]
(Sample processing)
24 hours after the final irradiation, the sample was washed with tap water, and the edible portion was shredded. This was frozen with liquid nitrogen, pulverized using a homogenizer (manufactured by Nippon Seiki Seisaku-sho, Ltd.), and then freeze-dried for 2 days (attained vacuum of 0.2 Pa).
[0050]
To 50 mg of this lyophilized powder, 2 ml of a 90% aqueous methanol solution (containing 0.5% acetic acid) and 50 nmol of flavone (manufactured by Nacalai Tesque, Inc.) as an internal standard were added and sonicated for 1 minute (Wakken Pharmaceutical Co., Ltd.). (Use Microson MS-50) and centrifuged at 3000 rpm for 10 minutes to recover the supernatant.
[0051]
Such an extraction operation was repeated three times, and the collected supernatant was dried with a concentrating centrifuge (manufactured by Taitec Corporation) and then dissolved in 500 μl of dimethyl sulfoxide (DMSO).
[0052]
This was filtered through a membrane filter (Millipore Co., 0.2 μm), and then subjected to high-performance chromatography (HPLC).
[0053]
(Identification and quantification of polyphenols by HPLC analysis)
The extract of the lyophilized sample was subjected to HPLC, and the polyphenol was identified and quantified by comparing the retention time and UV spectrum of each peak with those of a commercial sample.
[0054]
HPLC conditions are as shown in Table 1 below.
[0055]
[Table 1]

[0056]
The mobile phases were eluent A (50 mM aqueous sodium dihydrogen phosphate containing 10% methanol (pH 3.3)) and eluent B (50 mM aqueous sodium dihydrogen phosphate containing 70% methanol (pH 3.3)). A two-part gradient was used.
[0057]
The conditions of the linear gradient are as shown in Table 2 below.
[0058]
[Table 2]

[0059]
Polyphenols that did not match the commercially available sample in HPLC analysis were fractionated by HPLC, and the molecular weight was measured by LC / MS to determine the structure.
[0060]
(Results of UV irradiation of parsley after harvest)
As shown in FIG. 1, four main peaks were obtained by HPLC analysis of the non-irradiated parsley. When this peak and its UV spectrum were compared with a commercial sample, one of the peaks was that of apigenin, a flavone among the flavonoids. Further, the sample was hydrolyzed to identify the aglycone of the glycoside and analyzed by HPLC, and it was found that the remaining three peaks were apigenin glycosides.
[0061]
Since it was revealed that the polyphenols contained in parsley were apigenins, the content of apigenin and its glycoside was determined by HPLC for each of the non-UV irradiation group, UV-A irradiation group and UV-B irradiation group. Was measured by The result is shown in FIG.
[0062]
According to the results, the content of apigenin glycoside did not significantly change due to ultraviolet irradiation, but the apigenin content was higher in both the UV-A irradiation group and the UV-B irradiation group than in the non-irradiation group. Significantly increased. Therefore, it was clarified that the method of the present invention can increase the polyphenol content of the plant after harvest.
[0063]
(Results of UV irradiation of spinach after harvest)
FIG. 3 shows HPLC chromatograms obtained for each of the UV non-irradiation group, the UV-A irradiation group, and the UV-B irradiation group.
[0064]
The content of each polyphenol identified by comparison with a commercial sample was measured by HPLC. Table 3 shows the results.
[0065]
[Table 3]

[0066]
The values in the table are the mean ± standard deviation of 4 samples. “ND” in the table indicates that the value was below the detection limit.
[0067]
According to the results, in the UV-A irradiation group, the amount of patchuretin glycoside, spinacetin glycoside, TMMG and DDMG increased in comparison with the irradiated group.
[0068]
On the other hand, in the UV-B irradiation group, new peaks were detected at around 89 minutes and 92 minutes of the retention time. Retention times and spectra were compared to those of commercial standards and identified as chrysin and tangeretin. When subjected to HPLC analysis after hydrolysis, these peaks did not appear in the irradiated group and the UV-A irradiation group, but were detected in the UV-B irradiation group at the same retention time. Therefore, it was revealed that chrysin and tangeretin are flavonoids newly synthesized by UV-B irradiation. In addition, the UV-B irradiation group contained abundant coffee acids as compared with the irradiation group. Therefore, it has been proved that the method of the present invention can increase not only the existing polyphenol content in the post-harvest plant but also the polyphenol that was not present before the irradiation with ultraviolet light.
[0069]
(Results of UV irradiation of Tsurumurasaki after harvest)
Glycoside contents of vitexin and isovitexin, which are flavones, and kaempferol, which is a flavonol, were measured by HPLC for each of the UV non-irradiation group, the UV-A irradiation group, and the UV-B irradiation group. The result is shown in FIG.
[0070]
According to the result, the polyphenol of Tsurumurasaki was increased by ultraviolet irradiation. In addition, it can be seen that vitexin is specifically increased by UV-A. Therefore, it has been clarified that specific polyphenols can be increased by irradiation with ultraviolet rays in a specific wavelength range.
[0071]
(Results of UV irradiation of radish after harvest)
The content of kaempferol glycoside was measured by HPLC for each of the UV non-irradiation group, the UV-A irradiation group and the UV-B irradiation group. The result is shown in FIG.
[0072]
The results proved that the polyphenols of radish were increased by ultraviolet irradiation.
[0073]
Example 2 Short-term irradiation experiment
A commercially available parsley was purchased and irradiated with ultraviolet light for 7 days in Example 1 above, but irradiated for 3 days under the same conditions. After 1 day (4 days after purchase), 2 days, and 5 days later, the content of apigenin glycoside, which is a major polyphenol, was quantified by HPLC under the same conditions as in Example 1 above. FIG. 6 shows the results.
[0074]
The results demonstrate that untreated parsley reduces the content of apigenin glycoside, which is a polyphenol, after harvest, but can significantly increase the polyphenol content of harvested plants even with 3 days of UV irradiation. Was done.
[0075]
Example 3 Short-term irradiation experiment
With respect to Tsurumurasaki, ultraviolet irradiation was performed under the same conditions as in Example 1 for a shorter period of 2 days, and then the polyphenol content was determined on the 1st day (3rd day after purchase). FIG. 7 shows the results.
[0076]
According to the results, a clear increase in the polyphenol content was not observed in the UV-A irradiation group, but a clear increase was observed in the UV-B irradiation group.
[0077]
In addition, a UV-B irradiation experiment was carried out on Tsurumurasaki only for one day in the same manner, and on the first and fourth days after the irradiation, the polyphenol content was quantified. FIG. 8 shows the results.
[0078]
As shown in the results shown in FIG. 8, a significant increase in the polyphenol content was observed 4 days after the irradiation, even when the ultraviolet irradiation was performed for one day.
[0079]
Example 4 Appearance properties
Under the conditions of the present invention, in order to prove that there is almost no effect on the appearance of the plant, ultraviolet irradiation was carried out on the vines, i.e., radish and spinach, for 7 days under the same conditions as in Example 1 above, and The changes were examined. During this time, the samples were stored in the refrigerator's vegetable room, except when irradiating with ultraviolet light. FIG. 9 shows the results.
[0080]
As shown in FIG. 9, the appearance of the harvested plants that received UV-A irradiation or UV-B irradiation did not change from the time of purchase, and no wilting or yellow leaves were observed. Therefore, it was demonstrated that the method of the present invention hardly affected the appearance of the plant after harvest.
[0081]
Example 5 Effect on Nutrient Components
The radish, called Tsumurasasaki, was irradiated with ultraviolet rays for 3 days and spinach for 7 days under the same conditions as in Example 1 above, and the vitamin C content one day after the irradiation was quantified. The results are shown in FIG.
[0082]
According to the results shown in FIG. 10, although a slight decrease in the vitamin C content was observed between the pineapple and the spinach after the UV-B irradiation, a significant difference due to the ultraviolet irradiation was not observed.
[0083]
The content of β-carotene was also quantified in the above sample, but no clear change was observed. That is, ultraviolet irradiation is performed for 3 days in spinach and for 2 days in Tsurumurasaki. One day later, the β-carotene content was determined. The results are shown in FIG.
[0084]
According to the results of FIG. 11, the content of β-carotene was almost the same in the case of Tsurumurasaki and that in the case of spinach, and was slightly increased in the case of spinach.
[0085]
From the above results, it was demonstrated that the method of the present invention hardly affected nutrients other than polyphenol.
[0086]
【The invention's effect】
The method according to the present invention can significantly increase the polyphenol content of the post-harvest plants and has almost no apparent adverse effects such as yellowing. Therefore, the post-harvest plants treated by the method of the present invention are very excellent as health foods.
[0087]
Further, the apparatus according to the present invention is not only very useful because it implements the above method, but also can be industrially produced, so that the rise of industry can be newly realized. Things.
[Brief description of the drawings]
Fig. 1 HPLC chromatogram of parsley without UV irradiation
Fig. 2 Changes in polyphenol content before and after UV irradiation of parsley after harvest
FIG. 3. HPLC chromatogram of post-harvest spinach before and after UV irradiation
FIG. 4 Changes in polyphenol content before and after UV irradiation of Tsurumurasaki after harvest
FIG. 5: Changes in polyphenol content before and after ultraviolet irradiation of dried radish after harvest
FIG. 6: Change in polyphenol content of parsley after 3 days of UV irradiation
FIG. 7: Change in polyphenol content of T. murasaki after ultraviolet irradiation for 2 days
FIG. 8: Change in polyphenol content of Tsurumurasaki after one-day ultraviolet irradiation
FIG. 9: Appearance of harvested plants after UV irradiation
FIG. 10. Changes in vitamin C content of post-harvest plants after UV irradiation
FIG. 11: Changes in β-carotene content of post-harvest plants after UV irradiation

Claims (10)

A method characterized by increasing the polyphenol content of a plant after harvest by irradiating ultraviolet rays in a specific wavelength range. The method according to claim 1, wherein the wavelength of the ultraviolet light is 240 nm or more and 320 nm or less. The method according to claim 1, wherein the wavelength of the ultraviolet light is 300 nm or more and 400 nm or less. The method according to any one of claims 1 to 3, wherein the irradiation amount of the ultraviolet ray is 0.5 J / cm ² or more and 50 J / cm ² or less per day. A post-harvest plant, wherein the polyphenol content is increased by the method according to claim 1. Apparatus for carrying out the method according to any of claims 1 to 4, characterized in that it comprises means for storing the harvested plants and means for irradiating with ultraviolet light. 7. The apparatus according to claim 6, wherein said means for storing plants after harvesting does not leak ultraviolet light to the outside. 8. The apparatus according to claim 6, further comprising means for adjusting the wavelength of the ultraviolet light. The apparatus according to any one of claims 6 to 8, further comprising a means for adjusting an irradiation amount of the ultraviolet light. The apparatus according to any one of claims 6 to 9, further comprising means for stopping irradiation of ultraviolet rays when the means for storing the plants after harvesting is opened.

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