JP3614827B2 - Flaxseed squeeze and method for producing the same - Google Patents

Description

【００３９】
表１に記載の結果から明らかなように、本発明の亜麻仁圧搾粕によれば、高い酸化安定性（保存安定性）を維持しつつも、良好な風味を発現していることが確認された。
【００４０】
（３） 栄養成分の検討
本発明の亜麻仁圧搾粕の栄養成分の分析を行い、亜麻仁種子でのそれとの比較を行った。 すなわち、亜麻仁圧搾粕および亜麻仁種子に関して、その水分、タンパク質、脂質、灰分、食物繊維について定量分析を行い、さらに、その分析値に基づいてカロリー値を求めた。
【００４１】
なお、水分は常圧加熱乾燥法で、タンパク質はケルダール分解法で、脂質はソックスレー抽出法で、灰分は直接灰化法で、そして、食物繊維は酵素−重量法によって定量分析を行った。 なお、糖質の量は、試料全重量から、水分、タンパク質、脂質、灰分、食物繊維の量を控除して得られた量とした。
【００４２】
さらに、各分析値にエネルギー換算係数を乗じて、各試料のカロリー値（エネルギー量）を求めた。 すなわち、タンパク質については４ｋｃａｌ／ｇ、脂質については９ｋｃａｌ／ｇ、糖質については４ｋｃａｌ／ｇの係数を乗じた。
【００４３】
これら分析の結果を、以下の表２にまとめた。
【００４４】
【表２】

【００４５】
表２に記載の結果から明らかなように、本発明の亜麻仁圧搾粕は、栄養バランスも良く、また、油分の低減により、亜麻仁種子と比較してカロリー値が半分以下にまでなっており、低カロリー化が実現されていた。
【００４６】
（４） 全窒素および水溶性窒素指数の検討
本発明の亜麻仁圧搾粕の全窒素および水溶性窒素指数の分析を行い、亜麻仁油粕と抽出粕とでのそれとの比較を行った。
【００４７】
実施例１（１） に記載の方法に従って、５種類の精選亜麻仁種子（いずれも吉原製油株式会社製）から本発明の亜麻仁圧搾粕Ａ〜Ｅを調製した。
【００４８】
同様に、実施例１（１）に記載の方法に従って、２種類の精選亜麻仁種子（いずれも吉原製油株式会社製）から、亜麻仁油粕Ｆ〜Ｇを調製した。
【００４９】
また、亜麻仁油粕Ｆをｎ−ヘキサンで脱脂して得たヘキサン抽出粕も準備した。
【００５０】
なお、各試料での全窒素（％）は、基準油脂分析法 （１．７．２−全窒素及び粗タンパク質（水蒸気吹き込み法）、基準油脂分析試験法（Ｉ）、日本油化学会制定、１９９６年版、社団法人日本油化学会）のケルダール法に従って測定した。 そして、各試料での水溶性窒素指数（％）は、基準油脂分析法 （１．８．２−水溶性窒素指数（２０℃法）、基準油脂分析試験法（Ｉ）、日本油化学会制定、１９９６年版、社団法人日本油化学会）に記載の手順に従って測定し、先に決定した全窒素値（％）に基づいて、水溶性窒素指数（％）を求めた。
【００５１】
各試料に関して決定された水溶性窒素指数（％）を、以下の表３にまとめた。
【００５２】
【表３】

【００５３】
表３に記載の結果から明らかなように、本発明の亜麻仁圧搾粕は、窒素含量、特に、水溶性窒素に富み、加工特性に優れていることが判明した。
【００５４】
（５） 亜麻仁圧搾粕［粉砕粕］の粒度の検討
本発明の亜麻仁圧搾粕の利用適性の改善を期して、亜麻仁圧搾粕を粉砕した。
【００５５】
すなわち、亜麻仁圧搾粕の粉砕方法と、それら粉砕方法によって得られた粉砕粕の粒度を決定し、亜麻仁圧搾粕を利用した食品での粉砕粕の粒度による影響を検討した。
【００５６】
まず、精選亜麻仁種子（ジョンソンシード社製：カナダ）の１００ｋｇを、コールドプレス実験機（ＡＰ−０８型；ライナルツ社）に適用して搾油を行い、亜麻仁圧搾粕を得た。
【００５７】
粉砕機として、ネアミル粉砕機を準備し、これに亜麻仁圧搾粕をそのまま適用した（粗粉砕は行わなかった）。 そして、得られた粉砕粕をメタノールに懸濁せしめて調製した測定試料（懸濁試料）を、レーザー式粒度測定機（ＳＨＩＭＡＤＺＵ ＳＡＬＤ−１０００；島津製作所）の回分セルに入れ、これを測定機本体に装着して、５〜５００μｍ（１６段階）の波長範囲で測定を行った。
【００５８】
ネアミル粉砕機の稼動条件を、以下の表４に示した。
【００５９】
【表４】

【００６０】
表４に記載の条件でネアミル粉砕機を稼動させて、亜麻仁圧搾粕の粉砕を行った。 この稼動条件では、亜麻仁圧搾粕の温度上昇は僅かであり、亜麻仁圧搾粕を、室温から１０℃前後高い温度で粉砕することができた。
【００６１】
ところで、ネアミル粉砕機によれば、図２のグラフに例示したように、粉砕粕の粒度分布の局在化が容易となり、とりわけ、粒径が５００μｍを超える粗大粒子を完全に排除できる点で有利である。 また、粉砕処理中の亜麻仁圧搾粕の温度上昇をほとんど招かず、コールドプレス処理によってもたらされる効果とも相俟って、亜麻仁圧搾粕の保存安定性の改善にも大きく貢献することが期待される。 また、本実施例で使用したネアミル粉砕機では、粉砕機本体への粉体化した亜麻仁圧搾粕の付着がほとんど無く、連続運転を円滑に行うことも可能となる。
【００６２】
実施例２：亜麻仁圧搾粕のクッキーへの利用適性の検討
（１） 亜麻仁圧搾粕を利用したクッキーの調製
実施例１に記載の亜麻仁圧搾粕、亜麻仁油粕および亜麻仁種子を利用してクッキーを調製した。 すなわち、以下の表５に記載の材料を混合して得た各生地を、１７０℃で、約１３分間、オーブンで焼成した。 なお、亜麻仁を全く用いずに調製したクッキー（亜麻仁不使用）を、対照とした。
【００６３】
【表５】

【００６４】
焼成したクッキーの風味について、熟練したパネラー１２名によって順位法により官能的に評価した。 すなわち、パネラー１２名に、４種類のクッキーを、風味の優れている順に判定させた。 そして、最も風味の優れているクッキーに３点、以下、順位を下げるごとに１点ずつ減じ、最も風味の劣っていたクッキーに０点を付与した。 各クッキーについて、パネラー各位の評点を集計して合計点を求め、それを官能検査結果とした。 その結果を、以下の表６に記した。
【００６５】
【表６】

【００６６】
表６に記載の結果から明らかなように、本発明の亜麻仁圧搾粕を利用したクッキーの評価が最も高く、本発明の亜麻仁圧搾粕が、クッキーへの利用適性に優れていることが明らかとなった。
【００６７】
（２） 亜麻仁圧搾粕を利用したクッキーでの酸化安定性の検討
実施例１に記載の亜麻仁圧搾粕、亜麻仁油粕および亜麻仁種子を利用してクッキーを調製した。 なお、亜麻仁を全く用いずに調製したクッキー（亜麻仁不使用）を、対照とした。 すなわち、以下の表７に記載の材料を混合して得た各生地を、１７０℃で、約１３分間、オーブンで焼成した。
【００６８】
【表７】

【００６９】
次に、上記四試料の酸化安定性を評価すべく、以下の手順で、試験を行った。
【００７０】
まず、各クッキーの１００ｇを、個別のガラスビーカー（１０００ｍｌ容）に入れた。
【００７１】
これら各ビーカーを、約１０箇所のピンホールが穿設されたプラスティックフィルムで閉蓋し、５５℃に設定された通風恒温器内に置いた。 そして、経日的に各試料から油分を抽出して、その過酸化物価を測定した。 なお、油分の抽出は、ジエチルエーテルを用い、ソックスレー法によって行った。 また、過酸化物価（ｍｅｑ／ｋｇ）は、基準油脂分析法 （２．５．２−過酸化物価、基準油脂分析試験法（Ｉ）、日本油化学会制定、１９９６年版、社団法人日本油化学会）の酢酸・イソオクタン法に従って測定した。 その測定結果を、図３のグラフにまとめた。
【００７２】
図３のグラフから明らかな通り、本発明の亜麻仁圧搾粕を利用したクッキーと亜麻仁不使用のクッキーでは、保存期間を通じて過酸化物価の上昇はほとんど認められなかった。 一方で、亜麻仁種子や亜麻仁油粕を利用したクッキーでは、保存期間中での酸化が認められた。 特に、亜麻仁油粕を利用したクッキーでの過酸化物価の上昇は、急激であった。 なお、亜麻仁不使用のクッキーの過酸化物価がほとんど変化しなかったのは、亜麻仁不使用のクッキーでの油分の大半がバターに由来するものであり、過酸化物生成の原因となる不飽和結合が非常に少ないためと考えられる。
【００７３】
また、熟練したパネラー８名によって各試料の風味について官能評価を行った。
【００７４】
風味の評価方法は、４段階で評価して、その平均的な意見をとりまとめた。
【００７５】
上記した評価結果を、以下の表８にまとめた。
【００７６】
【表８】

【００７７】
風味に関しては、亜麻仁油粕を利用したクッキーでは、その調製当初から独特の異臭が認められ、保存期間が進むに従い、植物油の劣化による劣化臭が認められ、そして、最終期には強烈な変敗臭が発生した。 亜麻仁不使用の生地から調製したクッキーでは、保存期間が進むに従い、乳脂（バター）が劣化した時に生じる独特の劣化臭を呈した。 また、亜麻仁種子を利用したクッキーでは、乳脂特有の劣化臭を感じることはなかったが、保存期間が進むに従い、植物油の劣化による劣化臭が認められた。
【００７８】
これらに対して、本発明の亜麻仁圧搾粕を利用したクッキーでは、良好な風味が、保存期間中、安定して維持されていた。
【００７９】
実施例３：亜麻仁圧搾粕のパンへの利用適性の検討
（１） 亜麻仁圧搾粕を利用したパンの調製
実施例１に記載の亜麻仁圧搾粕を利用して３種類のパンを調製し、これらを実施例Ａ〜Ｃとした。 一方で、亜麻仁圧搾粕を全く用いずに調製したパンも３種類調製し、これらを比較例Ｘ〜Ｚとした。
【００８０】
具体的には、以下の表９に記載の材料を混合して各パン生地を得た。 いずれの実施例／比較例での材料も、小麦粉（強力粉および準強力粉）と亜麻仁圧搾粕との合計が１００重量部になるように配合してある。 表９の記載から明らかなように、小麦粉の一部を亜麻仁圧搾粕で代替置換することで加水量の増量が図れ、これにより、焼成後のパンの食感を柔軟ならしめ、しかも、しっとり感も改善された。
【００８１】
【表９】

【００８２】
各パン生地を、まず、以下の表１０に記載の条件に従って、混練および発酵を行った。 その後、同じく表１０に記載の条件に従って、これら生地を所定量に分割し、成型した後にねかせ（ベンチタイム）、次いで、ホイロおよび焼成を行った。
【００８３】
【表１０】

【００８４】
このようにして得られたパンを評価すべく、まず、ホイロの時間を測定し、生地の処理性を経験的に４段階評価した。 また、得られたパンの重量（焼成して１５分後）と体積を測定し、そこから比容積を算出した。 そして、得られたパンの外観、内質および風味を、熟練した８名のパネラーにに４段階評価してもらい、その平均的な意見をとりまとめた。 上記した評価結果を、以下の表１１にまとめた。
【００８５】
【表１１】

【００８６】
亜麻仁圧搾粕を５重量部または７．５重量部加えた実施例ＡおよびＢのパンでは、比較例Ｘ〜Ｚのパンと比較して、比容積の改善が認められた。 また、ビタミンＣを配合した材料から調製した実施例Ｃのパンでは、生地の処理性、体積、外観および内質の各項目において、飛躍的な改善が認められた。 さらに、全体的な傾向として、亜麻仁圧搾粕を加えた実施例Ａ〜Ｃのパンの方が、風味が良好であった。
【００８７】
このように、本発明の亜麻仁圧搾粕を加えることで、栄養価が向上するのみならず、加水量が増加し、とりわけ亜麻仁圧搾粕を５重量部または７．５重量部加えることで、パンの口当たりを良好ならしめるパンの体積向上が認められた。 特に、ビタミンＣをさらに添加することで、パンの体積向上がさらに改善された。
【００８８】
（２） 種生地と亜麻仁圧搾粕とを利用したパンの調製
実施例１に記載の亜麻仁圧搾粕を利用して３種類のパンを調製し、これらを実施例Ｄ〜Ｆとした。 一方で、亜麻仁圧搾粕を全く用いずに調製したパンも１種類調製し、これを比較例Ｗとした。
【００８９】
まず、実施例Ｄおよび比較例Ｗに関しては、以下の表１２に記載の材料を混合して各パン生地を得た。 これに対して、実施例ＥおよびＦにあっては、最初に、ビタミンＣと酵母の双方を含まない生地原料（種生地原料）を熱湯で混練して調製した種生地を冷蔵庫内に８時間置いて冷却保存した。 この種生地に対して、ビタミンＣと酵母の双方を含む生地原料（本生地原料）を加えて混合してパン生地とした。 いずれの実施例／比較例での材料も、小麦粉（強力粉）と亜麻仁圧搾粕との合計が１００重量部になるように配合してある。
【００９０】
表１２の記載から明らかなように、小麦粉の一部を亜麻仁圧搾粕で代替置換することで加水量の増量が図れ、これにより、焼成後のパンの食感を柔軟ならしめ、しかも、しっとり感も改善された。
【００９１】
【表１２】

【００９２】
各パン生地を、まず、以下の表１３に記載の条件に従って、混練および発酵を行った。 その後、同じく表１３に記載の条件に従って、これら生地を所定量に分割し、成型した後にねかせ（ベンチタイム）、次いで、ホイロおよび焼成を行った。
【００９３】
【表１３】

【００９４】
このようにして得られたパンの重量（焼成して１５分後）と体積を測定し、そこから比容積を算出した。 そして、得られたパンの外観、内質および風味を、熟練した８名のパネラーにに４段階評価してもらい、その平均的な意見をとりまとめた。 上記した評価結果を、以下の表１４にまとめた。
【００９５】
【表１４】

【００９６】
亜麻仁圧搾粕を５重量部加えた実施例Ｄ〜Ｆのパンでは、比較例Ｗのパンと比較して、比容積の改善に加えて、風味の面で飛躍的な改善が認められた。 また、実施例Ｄ〜Ｆのパンは、外観および内相の各項目においても同様の改善が認められた。 さらに、全体的な傾向として、亜麻仁圧搾粕を加えてなる実施例Ｄ〜Ｆのパンの方が、風味が良好であった。
【００９７】
このように、本発明の亜麻仁圧搾粕を加えることで、栄養価が向上するのみならず、加水量が増加し、とりわけ亜麻仁圧搾粕を５重量部加えることで、パンの口当たりを良好ならしめるパンの体積向上が認められた。 特に、ビタミンＣをさらに添加することで、パンの体積向上をさらに促し、生地物性が格段に改善されることが明らかになった。 とりわけ、種生地と本生地との２つのパン生地を利用して得たパンにおいて、体積増量が認められた他に、焼成後のパンの柔軟性としっとり感がさらに改善されていた。
【００９８】
（３） 亜麻仁圧搾粕［粉砕粕］を利用したパンの調製
実施例１（５） に記載の知見を踏まえて、以下の手順に従って、以下の３種類のパン（実施例Ｇ〜Ｉ）を調製した。
【００９９】
実施例Ｇ： 精選亜麻仁種子（吉原製油株式会社製）を、コールドプレス実験機（ＡＰ−０８型；ライナルツ社）に適用して搾油されて得られた亜麻仁圧搾粕を、パワーミル（粗粉砕機：株式会社ダルトン）、次いで、アトマイザー（微粉砕機：株式会社ダルトン）に適用して粉砕して、粉砕粕を得た。 なお、パワーミルの稼動条件は、通常運転とした。 一方で、アトマイザーの稼動条件は、主軸回転数を８５００ｒｐｍとし、２ｍ／ｍφのスクリーンを用いた。
【０１００】
実施例Ｈ： 精選亜麻仁種子（ジョンソンシード社製：カナダ）を、コールドプレス実験機（ＡＰ−０８型；ライナルツ社）に適用して搾油されて得られた亜麻仁圧搾粕を、ネアミル粉砕機にそのまま適用して（粗粉砕は行わなかった）、粉砕粕を得た。
【０１０１】
実施例Ｉ： 精選亜麻仁種子（吉原製油株式会社製）を、エキスペラー（ＨＰ１５０型；スエヒロ社）に適用して搾油されて得られたペラー粕を、実験用粉砕機（ＰＥＲＳＯＮＡＬ ＭＩＬＬ ＳＣＭ−４０Ａ；柴田科学器械工業）に適用して粉砕して、粉砕粕を得た。
【０１０２】
そして、以下の表１５に記載の材料を混合して各パン生地を得た。
【０１０３】
いずれの実施例での材料も、小麦粉（強力粉）と亜麻仁圧搾粕との合計が１００重量部になるように配合してある。
【０１０４】
【表１５】

【０１０５】
各パン生地を、まず、以下の表１６に記載の条件に従って、混練および発酵を行った。 その後、同じく表１６に記載の条件に従って、これら生地を所定量に分割し、成型した後にねかせ（ベンチタイム）、次いで、ホイロおよび焼成を行った。
【０１０６】
【表１６】

【０１０７】
このようにして得られた３つのパンを、約２ｃｍ厚にスライスした後に４等分し、外観、風味、食感および総合評価の４項目に関して、熟練した１２名のパネラーに順位法によって評価してもらった。 すなわち、各項目に関して、３つのパンに順位をつけるものであって、最良のものに１点、次に良いものに２点、そして、最も評価が低いものには３点を付与し、それらの合計点を集計した［つまり、合計点が小さいほど、評価が高くなる］。
【０１０８】
上記した評価結果を、以下の表１７にまとめた。
【０１０９】
【表１７】

【０１１０】
表１７に記載の結果から明らかなように、ネアミル粉砕機を利用して得た粉砕粕（実施例Ｈ）を用いたパンが、すべての評価項目において、他を寄せ付けない優れた結果を示した。
【０１１１】
実施例Ｈの粉砕粕を用いたパンでは、非常に目を凝らして見ない限り確認ができないくらいに、粉砕粕の粗大粒子の混入が少ない。 そのため、亜麻仁種子特有の風味や、粗大粒子の物理的性状に由来する粒状感を抑えることに成功している。 これに対して、実施例Ｇの粉砕粕では、数百ミクロン程度の粒径の粗大粒子がパンに多く残存するため、亜麻仁種子特有の風味や食感が感じられた。 さらに、実施例Ｉの粉砕粕では、ペラー粕自体に焦げ臭さに類似した風味がある上に、実施例ＧおよびＨの粉砕粕よりも熱履歴を受けているため、油由来の劣化臭も若干感じられた。
【０１１２】
そのため、亜麻仁種子特有の食感を好むパネラーは、粗大粒子を含む実施例Ｇの粉砕粕を利用したパンを選択し、一方で、癖のないパンを望むパネラーは実施例Ｈの粉砕粕を利用したパンを選択する傾向が認められた。 このことは、汎用的なパン材料としては、粉砕機能と分級機能とを兼ね備えたネアミル粉砕機を利用して得た粉砕粕（実施例Ｈ）が最も好適であることを指し示すに他ならないものである。
【０１１３】
なお、本願実施例２〜３では、本発明の亜麻仁圧搾粕［粉砕粕］のクッキーおよびパンへの応用例について例示した。 しかしながら、当業者であれば、同様の生地材料と周知の調理手法を用い、生地の焼成温度を適宜調整することで、他のベーカリー食品、例えば、マフィンなどを容易に製造できることは自明のことである。
【０１１４】
実施例４：焙煎粕の製造
実施例１に記載の亜麻仁圧搾粕３００ｇを、鉄製のフライパンで空煎りし、次いで、それを室温にまで冷却することによって、本発明の焙煎粕を得た。 そして、この焙煎粕を、サンプルミル（株式会社ダルトン）で粉砕した。
【０１１５】
同様に、実施例１に記載の亜麻仁種子３００ｇを、鉄製のフライパンで空煎りし、次いで、それを室温にまで冷却した。 冷却した焙煎済の亜麻仁種子を、サンプルミル（株式会社ダルトン）で粉砕して、焙煎亜麻仁種子の粉砕物を得た。 ところで、本実施例にあっては、粉砕した亜麻仁種子の油分が外気に露出し、それが著しく酸化することを見越して、油分の酸化影響を受けにくい、焙煎亜麻仁種子の粉砕物を利用した。
【０１１６】
これら粉砕物それぞれを、個別のガラスビーカー（１０００ｍｌ容）に入れた。
【０１１７】
次に、上記二試料の酸化安定性を評価すべく、以下の手順で、試験を行った。
【０１１８】
まず、個々のビーカーを、約１０箇所のピンホールが穿設されたプラスティックフィルムで閉蓋し、５５℃に設定された通風恒温器内に置いた。 そして、経日的に各試料から油分を抽出して、その過酸化物価を測定した。 なお、油分の抽出は、ジエチルエーテルを用いて、ソックスレー法によって行った。 また、過酸化物価（ｍｅｑ／ｋｇ）は、基準油脂分析法 （２．５．２−過酸化物価、基準油脂分析試験法（Ｉ）、日本油化学会制定、１９９６年版、社団法人日本油化学会）の酢酸・イソオクタン法に従って測定した。 また、実施例１に記載の亜麻仁圧搾粕と亜麻仁種子（非焙煎）についても測定を行った。 その測定結果を、図４のグラフにまとめた。
【０１１９】
図４のグラフから明らかな通り、亜麻仁種子（焙煎）では、急速に酸化が進むことが明らかとなった。 これに対して、本発明の焙煎粕は、焙煎を行っても、その熱安定性に何らの影響を受けていないことが明らかとなった。
【０１２０】
また、熟練したパネラー８名によって各試料の風味について官能評価を行った。
【０１２１】
風味の評価方法は、４段階で評価して、その平均的な意見をとりまとめた。
【０１２２】
上記した評価結果を、以下の表１８にまとめた。
【０１２３】
【表１８】

【０１２４】
表１８に記載の結果から明らかなように、亜麻仁種子（焙煎）では、保存に伴って劣化臭が増し、最終的には強烈な酸化変敗臭を呈した。 これに対して、本発明の焙煎粕は、長期保管によって香ばしい風味が若干希薄になったが、劣化臭の発生には至らなかった。 この結果から、本発明の亜麻仁圧搾粕に、焙煎処理を施しても、悪影響が及ばないことが明らかとなった。 つまり、本発明の焙煎粕が、保存時の経時的な油脂劣化に伴う風味劣化を招かないことを示唆するものに他ならない。
【０１２５】
実施例５：焙煎粕の食品への利用適性の検討
実施例４に記載の本発明の焙煎粕および焙煎した亜麻仁種子、実施例４に記載の手順に従って焙煎した圧搾油粕、および亜麻仁種子を利用してクッキーを調製した。 なお、亜麻仁を全く用いずに調製したクッキー（亜麻仁不使用）を、対照とした。 すなわち、以下の表１９に記載の材料を混合して得た各生地を、１７０℃で、約１３分間、オーブンで焼成した。
【０１２６】
【表１９】

【０１２７】
次に、上記五試料の酸化安定性を評価すべく、以下の手順で、試験を行った。
【０１２８】
まず、各クッキーの１００ｇを、個別のガラスビーカー（１０００ｍｌ容）に入れた。
【０１２９】
これら各ビーカーを、約１０箇所のピンホールが穿設されたプラスティックフィルムで閉蓋し、５５℃に設定された通風恒温器内に置いた。
【０１３０】
そして、経日的に各試料から油分を抽出して、その過酸化物価を測定した。
なお、油分の抽出は、ジエチルエーテルを用い、ソックスレー法によって行った。
また、過酸化物価（ｍｅｑ／ｋｇ）は、基準油脂分析法 （２．５．２−過酸化物価、基準油脂分析試験法（Ｉ）、日本油化学会制定、１９９６年版、社団法人日本油化学会）の酢酸・イソオクタン法に従って測定した。
【０１３１】
その測定結果を、図５のグラフにまとめた。
【０１３２】
図５のグラフから明らかな通り、焙煎亜麻仁種子や焙煎亜麻仁油粕を利用したクッキーでは、保存期間中での経時的な過酸化物価の上昇が認められた。 その反面で、本発明の焙煎粕を利用したクッキーは、亜麻仁を利用したクッキーの中でも、過酸化物価の上昇が一番緩やかであった。
【０１３３】
また、熟練したパネラー８名によって各試料の風味について官能評価を行った。
【０１３４】
風味の評価方法は、４段階で評価して、その平均的な意見をとりまとめた。
【０１３５】
上記した評価結果を、以下の表２０にまとめた。
【０１３６】
【表２０】

【０１３７】
表２０に記載の結果から明らかなように、本発明の焙煎粕は、長期保管による香ばしい風味が若干希薄になったが、劣化臭の発生には至らなかった。 むしろ、対照にあっては乳脂が劣化した時に生じる酸化臭を呈しており、本発明の焙煎粕では劣化臭は感じられなかった。 以上の結果から、本発明の焙煎粕を食品に応用しても、悪影響が及ばないことが明らかとなった。 つまり、本発明の亜麻仁圧搾粕を焙煎処理して得た焙煎粕を食品に応用しても、通常の油脂利用食品に認められるような、保存時の経時的な油脂劣化に伴う風味の劣化を招かないことを示唆するものに他ならない。
【０１３８】
なお、本実施例にあっては、本発明の焙煎粕のクッキーへの応用例について例示した。 しかしながら、当業者であれば、同様の生地材料と周知の調理手法を用い、生地の焼成温度を調整することで、他のベーカリー食品、例えば、マフィンやパンなどを容易に製造できることは自明のことである。
【０１３９】
【発明の効果】
このように本発明によると、所期の目的であった、風味良好で、しかも栄養バランスおよび保存安定性に優れた低カロリーの亜麻仁圧搾粕が実現される。
【０１４０】
また、本発明の亜麻仁圧搾粕は、その風味および保存性に優れるのみならず、油分の低減により食品への利用も図れ、またカロリー値の低減化も達成する。
【０１４１】
また、本発明の亜麻仁圧搾粕を焙煎してなる焙煎粕も、その風味および保存性に優れ、また、食品への利用も図れるなど、その有用性が期待される。
【０１４２】
さらに、本発明の亜麻仁圧搾粕の製造工程は、溶媒抽出の工程を必要としないため、圧搾粕にヘキサンなどの溶媒が残留する懸念が全く無いなどの、優れた作用効果を奏するのである。
【図面の簡単な説明】
【図１】本発明の亜麻仁圧搾粕の酸化安定性を示すグラフである。
【図２】ネアミル粉砕機によって得られた粉砕粕の粒度分布の関係を示すグラフである。
【図３】本発明の亜麻仁圧搾粕を用いたクッキーでの酸化安定性を示すグラフである。
【図４】本発明の焙煎粕の酸化安定性を示すグラフである。
【図５】本発明の焙煎粕を用いたクッキーでの酸化安定性を示すグラフである。[0001]
BACKGROUND OF THE INVENTION
TECHNICAL FIELD The present invention relates to a novel food material, in particular, a low calorie flaxseed press cake having good flavor and excellent nutritional balance and storage stability based on a press seed cake of flax seed.
[0002]
[Background Art and Problems to be Solved by the Invention]
Flaxseed seeds are seeds rich in nutrient components such as lignans, dietary fiber, and α-linolenic acid. Focusing on the nutritional composition of linseed seeds, flaxseed seeds themselves or pulverized products have been applied to bakery foods such as bread and cereal foods in North America and Northern Europe since ancient times. .
[0003]
By the way, flaxseed seeds contain about 40% by weight of oil, so it is difficult to maintain the quality in processing for food use, and the high calories brought by the oil is also the current trend toward low calories. It is contrary.
[0004]
Linseed seeds are usually partially defatted through a preparation process (selection of flaxseed seeds, coarse crushing, drying, heating, pressing) → oil pressing process, and processed into a flaxseed oil cake. However, in a series of steps of drying, heating and pressing, flaxseed seeds are exposed to a high temperature of 100 ° C. or higher, and the constituent components of the seeds often change. Flaxseed seeds are seeds rich in α-linolenic acid, but this α-linolenic acid has a very rapid oxidation, and exhibits a strong deterioration odor when the oxidation proceeds to a certain level. Of nature. Under such circumstances, the conventional linseed oil cake has been suppressed in calories by reducing the oil content, but in reality it cannot be put into practical use in terms of flavor.
[0005]
In addition, after the linseed oil cake is applied to the extraction process and further degreased, the solvent is removed to obtain the extracted cake. Like the flaxseed oil cake, this extract koji has a bad taste and is not suitable for edible applications, and the extraction solvent (for example, n-hexane) used in the solvent extraction step is still used after desolvation. There are many edible disadvantages, such as the presence of trace amounts in flaxseed extract. Furthermore, since the oil content of flaxseed extract is usually less than a few percent, most of α-linolenic acid, which is a useful component of flaxseed seed, is lost.
[0006]
[Means for Solving the Problems]
The present inventors have conducted extensive research in view of the above-mentioned problems recognized in the prior art. In particular, research on improving the production process has led to a method for pressing raw linseed seeds that brings about low-calorie flaxseed squeezed with a good flavor and excellent nutritional balance and storage stability, leading to the completion of the present invention. It was.
[0007]
That is, the gist of the present invention is that raw linseed seedsTen ~ 40 At ℃The linseed press cake obtained by pressing, the roast cake obtained by roasting the press cake, and use of these flaxseed press cake and roast cake. According to the configuration of the present invention, a low-calorie flaxseed press cake having good flavor and excellent nutritional balance and storage stability can be obtained.
[0008]
By the way, as oxidation of fats and oils, auto-oxidation, photo-oxidation, thermal oxidation, enzyme oxidation and the like are generally known. Among these, the flaxseed pressing lees of the present invention and the roasted product (roasted lees) thereof are particularly excellent in stability against auto-oxidation, as is apparent from the description of the examples described later. By using rice cake as food, foods having good flavor and taste, such as cookies and bread, are also provided.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
The present invention is described in detail below.
[0010]
The flaxseed seed used in the present invention can be used regardless of the production area, brand or grade. Using these linseed seeds as a starting material, the linseed press cake of the present invention is produced.
[0011]
Flaxseed seeds are first applied to the preparation process. First, seeds, stems and leaves, scratched seeds, immature seeds, etc. mixed with flaxseed seeds brought into the refinery are removed and flaxseed seeds are selected (selected). This seed selection is carried out by appropriately combining a sieve (sieving) method, wind separation using the specific gravity difference of the seed, removal of iron pieces by a magnet, and the like. In addition, by forming a uniform air layer on the tilted vibrating sieve plate, there is also a method for selecting only fine flaxseed seeds based on a slight difference in specific gravity of seeds (Kip Kelly method), a Glen separator, etc. Available.
[0012]
The selected flaxseed seeds are then optionally applied to the crushing and drying process.
[0013]
As will be described later, these crushing and drying steps are optional steps in the present invention, and care should be taken not to increase the temperature of the object to be treated even if these steps are performed. It is important to do.
[0014]
The crushing step is a step for physically crushing or cleaving the seed in order to take out the oil / fat portion contained in the seed, and preferably, a roughing roll (cracking roll) In a so-called sujiroru (single-stage pair roll), flaxseed seeds are crushed into about 4 to 8 parts.
[0015]
Next, the moisture content of the coarsely crushed linseed seeds is adjusted. For example, moisture adjustment can be performed by an operation such as stirring under reduced pressure.
[0016]
Finely selected flaxseed seeds or coarsely crushed flaxseed seed pieces are applied to the pressing process (oil extraction process). As a pressing method used in this step, in the present invention, a physical pressing method (cold pressing method) at a low temperature is used.
[0017]
The cold press method is a method in which a freshly selected raw linseed seed or the aforementioned coarsely crushed linseed seed piece is squeezed under a low temperature condition so that the object to be treated is not heated as much as possible. The pressing temperature in the cold press method is appropriately adjusted according to the type of flaxseed seeds and the specifications of the cold press machine to be used. In general, in order to leave the flavor components of flaxseed seeds, about 80 It is set to a temperature range of not higher than ° C., preferably not higher than about 40 ° C., more preferably from about 10 to about 40 ° C. Preferably, the residual oil content in the linseed press cake is not more than about 30% by weight, preferably about 0.1 to about 30% by weight, more preferably, taking into account the prevention of deterioration of the linseed press cake by fat oxidation. An amount of about 0.1 to about 20% by weight is preferred.
[0018]
In addition, the peroxide value determined after 300 g of the flaxseed squeeze of the present invention is collected in a 1000 ml beaker and placed in a ventilated incubator set at 55 ° C. for 3 weeks is preferably determined by fat oxidation. From the viewpoint of preventing deterioration of flaxseed squeezed koji, it is about 5 meq / kg or less, preferably about 3 meq / kg or less, more preferably about 1 meq / kg or less.
[0019]
Furthermore, as an oil press applicable to the cold press method, any oil press can be used as long as it is devised so as not to cause an increase in the temperature of an object to be processed during operation. For example, a screw press AP -08 type (Reinartz, Germany) can be suitably used in the present invention.
[0020]
Flaxseed press cake obtained through the pressing process by the cold press method can be used for food as it is. However, preferably, the object to be treated is further pulverized by a pulverizer while taking care not to receive heat as much as possible. Any pulverizer known in the art can be used as the pulverizer. For example, New Cosmizer (Dalton Co., Ltd.), Power Mill (Coarse Crusher: Dalton Co.), Atomizer (Fine Crusher) Machine: Dalton Co., Ltd. can be used alone or in combination, but in particular, a Neamill crusher (Fuji Paudal Co., Ltd., hereinafter simply referred to as “Nearmill crusher”) having both a crushing function and a classification function. Etc.) can be suitably used in the present invention.
[0021]
Based on the viewpoint of improving the food texture of the food using the flaxseed press cake of the present invention, the particle size distribution of the flaxseed press cake has an average particle size of 150 μm or less, and particles of 350 μm or less are about 95 of the total particles. % Distribution, preferably a distribution in which the average particle size is 75 μm or less and the particles of 250 μm or less occupy about 95% or more of all particles.
[0022]
The flaxseed press cake of the present invention thus obtained can be further roasted to obtain a roast cake. Conventionally, roasting flaxseed seeds has been known to give a desirable flavor like nuts, but due to the poor storage stability of roasted flaxseed seeds, its practicality was poor. However, in the linseed pressing lees of the present invention, even when roasting is performed, while maintaining a good flavor, the deterioration of the storage stability (that is, the flavor deterioration due to oil deterioration during the storage period) is almost unacceptable. In addition, as roasting conditions for the flaxseed pressing lees of the present invention, from the viewpoint of maintaining good flavor and storage stability, at about 50 to about 300 ° C., about 1 to about 90 minutes, preferably about 100 to about The roasting condition is set at 200 ° C. for about 1 to about 60 minutes.
[0023]
The flaxseed press cake of the present invention obtained through a pressing process by a cold press method is filled and stored in a known storage container such as a can, a glass bottle, plastic, or paper.
[0024]
Moreover, the foodstuffs which show favorable flavor and taste are obtained by adding the flaxseed pressing lees of this invention to cooking. For example, foods with good flavor can be provided by using the flaxseed press cake of the present invention for fried foods, fried foods, baked foods, and bakery foods such as cookies, muffins and breads.
[0025]
In particular, in the production of bread, it was prepared by kneading a seed dough that was prepared from a dough raw material that did not contain both vitamin C and yeast and that had been cooled and stored, and a dough raw material that contained both vitamin C and yeast. By using bread dough, it is possible to obtain a bread having an increased volume and a soft and moist texture.
[0026]
【Example】
Examples of the present invention will be specifically described below, but the present invention should not be construed as being limited by the disclosure of these examples.
[0027]
Example 1: Manufacture of flaxseed press cake and examination of its nutritional components
(1) Sample preparation
The following three samples were prepared using carefully selected Canadian flaxseed seeds as the flaxseed seeds.
[0028]
Flaxseed pressing: 100 kg of finely selected linseed seeds was applied to a screw press AP-08 type (manufactured by Linalz) oil press, and crude oil of linseed was squeezed at a shaft speed of 20 rpm to obtain 65 kg of linseed press cake (product of the present invention). .
[0029]
Linseed oil cake: 500 kg of carefully selected linseed seeds was applied to a HP-150 type (manufactured by Suehiro) oil squeezed crude oil at a shaft speed of 80 rpm to obtain 375 kg of linseed oil cake (conventional product).
[0030]
Flaxseed seed: 50 kg of carefully selected flaxseed seeds were prepared.
[0031]
(2) Evaluation of oxidation stability and flavor
The oxidative stability of the linseed press meal, the linseed oil meal and the linseed seed prepared in Example 1 (1) was measured according to the following procedure.
[0032]
First, 300 g of each of linseed press cake, linseed oil cake and linseed seed was pulverized with a sample mill (Dalton Co., Ltd.) and placed in an individual glass beaker (1000 ml capacity). Each of these beakers was closed with a plastic film having about 10 pinholes and placed in a ventilated thermostat set at 55 ° C. [Environment in this thermostat is a condition at room temperature. It is a condition that promotes accelerated deterioration about 10 times as compared with the above]. And the oil content was extracted from each sample chronologically and the peroxide value was measured.
[0033]
In addition, extraction of oil was performed by Soxhlet method using diethyl ether. The peroxide value (meq / kg) is determined based on the standard oil analysis method (2.5.2-Peroxide value, standard oil analysis test method (I), Japan Oil Chemists' Society, 1996 edition, Nippon Oil Chemical Co., Ltd.). ) And acetic acid / isooctane method.
[0034]
The measurement results are summarized in the graph of FIG. As can be seen from the graph of FIG. 1, flaxseed squeezed and flaxseed seeds maintained a peroxide value of less than 1 meq / kg even after storage at 55 ° C. for 3 weeks, and substantial deterioration progressed. I was not able to admit. In contrast, flaxseed oil cake was observed to oxidize during the storage period although it was mild.
[0035]
Moreover, sensory evaluation was performed about the flavor of each sample by eight skilled panelists.
[0036]
The flavor evaluation method was evaluated in four stages, and the average opinion was compiled.
[0037]
The evaluation results are summarized in Table 1 below.
[0038]
[Table 1]

[0039]
As is clear from the results shown in Table 1, according to the flaxseed pressing lees of the present invention, it was confirmed that a good flavor was expressed while maintaining high oxidation stability (storage stability). .
[0040]
(3) Examination of nutritional components
The nutritional components of the flaxseed pressing lees according to the present invention were analyzed and compared with those of flaxseed seeds. That is, with respect to flaxseed squeezed and linseed seeds, the moisture, protein, lipid, ash and dietary fiber were quantitatively analyzed, and the caloric value was determined based on the analysis values.
[0041]
Water was analyzed by atmospheric pressure drying, protein was Kjeldahl decomposition, lipid was Soxhlet extraction, ash was directly ashed, and dietary fiber was quantitatively analyzed by enzyme-weight method. The amount of carbohydrate was obtained by subtracting the amount of water, protein, lipid, ash, and dietary fiber from the total weight of the sample.
[0042]
Furthermore, the caloric value (energy amount) of each sample was obtained by multiplying each analysis value by an energy conversion coefficient. That is, 4 kcal / g for proteins, 9 kcal / g for lipids, and 4 kcal / g for carbohydrates were multiplied.
[0043]
The results of these analyzes are summarized in Table 2 below.
[0044]
[Table 2]

[0045]
As is apparent from the results shown in Table 2, the flaxseed press cake of the present invention has a good nutritional balance, and due to the reduction in oil content, the caloric value is less than half that of flaxseed seeds, Caloricization was realized.
[0046]
(4) Examination of total nitrogen and water-soluble nitrogen index
The total nitrogen and water-soluble nitrogen index of the flaxseed pressing lees according to the present invention was analyzed, and the flaxseed oil lees and extracted lees were compared.
[0047]
According to the method described in Example 1 (1), flaxseed squeeze A to E of the present invention were prepared from five kinds of carefully selected flaxseed seeds (all produced by Yoshiwara Oil Co., Ltd.).
[0048]
Similarly, according to the method described in Example 1 (1), linseed oil cakes F to G were prepared from two kinds of carefully selected linseed seeds (both manufactured by Yoshiwara Oil Co., Ltd.).
[0049]
In addition, a hexane-extracted cocoon obtained by defatting linseed oil cake F with n-hexane was also prepared.
[0050]
In addition, the total nitrogen (%) in each sample is the reference oil analysis method (1.7.2-total nitrogen and crude protein (water vapor blowing method), reference oil analysis test method (I), Japan Oil Chemists' Society established, It was measured according to the Kjeldahl method of the 1996 edition of the Japan Oil Chemists' Society. And the water-soluble nitrogen index (%) in each sample is based on the standard oil analysis method (1.8.2-water-soluble nitrogen index (20 ° C method), standard oil analysis test method (I), Japan Oil Chemists' Society established. , 1996 edition, Japan Oil Chemists' Society), and the water-soluble nitrogen index (%) was determined based on the previously determined total nitrogen value (%).
[0051]
The water-soluble nitrogen index (%) determined for each sample is summarized in Table 3 below.
[0052]
[Table 3]

[0053]
As is apparent from the results shown in Table 3, it was found that the flaxseed press cake of the present invention is rich in nitrogen content, particularly water-soluble nitrogen, and has excellent processing characteristics.
[0054]
(5) Examination of grain size of flaxseed squeezed rice cake
The flaxseed press cake was pulverized for the purpose of improving the applicability of the flaxseed press cake of the present invention.
[0055]
That is, the pulverization method of the flaxseed pressing lees and the particle size of the pulverized lees obtained by these pulverization methods were determined, and the influence of the particle size of the pulverized lees in foods using the flaxseed pressing lees was examined.
[0056]
First, 100 kg of carefully selected flaxseed seeds (manufactured by Johnson Seed: Canada) was applied to a cold press experimental machine (AP-08 type; Linalz) to carry out oil extraction to obtain flaxseed pressed rice cake.
[0057]
As a pulverizer, a Neamill pulverizer was prepared, and flaxseed pressing was applied as it was (no coarse pulverization was performed). Then, a measurement sample (suspension sample) prepared by suspending the obtained pulverized soot in methanol is put into a batch cell of a laser particle size measuring machine (SHIMADZU SALD-1000; Shimadzu Corporation), and this is measured with the measuring machine main body. And measurement was performed in a wavelength range of 5 to 500 μm (16 steps).
[0058]
The operating conditions of the Neamill grinder are shown in Table 4 below.
[0059]
[Table 4]

[0060]
The Neamill grinder was operated under the conditions shown in Table 4 to grind flaxseed pressing. Under these operating conditions, the temperature increase of the flaxseed squeezed rice cake was slight, and the flaxseed squeezed rice cake could be crushed at a temperature higher by about 10 ° C. from room temperature.
[0061]
By the way, according to the Neamill pulverizer, as illustrated in the graph of FIG. 2, the particle size distribution of the pulverized soot can be easily localized, and particularly advantageous in that coarse particles having a particle diameter exceeding 500 μm can be completely eliminated. It is. Moreover, it hardly raises the temperature of the flaxseed squeezed during the pulverization process, and it is expected to contribute greatly to the improvement of the storage stability of the flaxseed squeezed mash, combined with the effect brought about by the cold press treatment. Further, in the near mill pulverizer used in this example, the powdered linseed squeeze hardly adheres to the pulverizer body, and the continuous operation can be performed smoothly.
[0062]
Example 2: Examination of applicability of flaxseed press cake to cookies
(1) Preparation of cookies using flaxseed pressing
Cookies were prepared using the flaxseed press meal, the flaxseed oil cake and the flaxseed seeds described in Example 1. That is, each dough obtained by mixing the materials shown in Table 5 below was baked in an oven at 170 ° C. for about 13 minutes. A cookie prepared without using flaxseed (without flaxseed) was used as a control.
[0063]
[Table 5]

[0064]
About the flavor of the baked cookie, it was sensorially evaluated by the ranking method by 12 skilled panelists. That is, 12 panelists were allowed to determine the four types of cookies in the order of their flavor. Then, 3 points were given to the cookie with the most excellent flavor, and 1 point was assigned to each cookie, and 0 point was given to the cookie with the least flavor. For each cookie, the panelists' scores were aggregated to obtain a total score, which was used as the sensory test result. The results are shown in Table 6 below.
[0065]
[Table 6]

[0066]
As is clear from the results shown in Table 6, the evaluation of the cookie using the flaxseed press cake of the present invention is the highest, and it is clear that the flaxseed press cake of the present invention is excellent in suitability for use in cookies. It was.
[0067]
(2) Examination of oxidation stability in cookies using flaxseed pressing
Cookies were prepared using the flaxseed press meal, the flaxseed oil cake and the flaxseed seeds described in Example 1. A cookie prepared without using flaxseed (without flaxseed) was used as a control. That is, each dough obtained by mixing the materials shown in Table 7 below was baked in an oven at 170 ° C. for about 13 minutes.
[0068]
[Table 7]

[0069]
Next, in order to evaluate the oxidation stability of the above four samples, a test was performed according to the following procedure.
[0070]
First, 100 g of each cookie was placed in a separate glass beaker (1000 ml capacity).
[0071]
Each of these beakers was closed with a plastic film having about 10 pinholes and placed in a ventilator set at 55 ° C. And the oil content was extracted from each sample chronologically and the peroxide value was measured. In addition, extraction of oil was performed by Soxhlet method using diethyl ether. The peroxide value (meq / kg) is determined based on the standard oil analysis method (2.5.2-Peroxide value, standard oil analysis test method (I), Japan Oil Chemists' Society, 1996 edition, Nippon Oil Chemical Co., Ltd.). ) And acetic acid / isooctane method. The measurement results are summarized in the graph of FIG.
[0072]
As is clear from the graph of FIG. 3, almost no increase in the peroxide value was observed during the storage period in the cookie using the linseed press cake of the present invention and the cookie not using linseed. On the other hand, in the cookies using flaxseed seeds and flaxseed oil cake, oxidation during the storage period was observed. In particular, the increase in the peroxide value in cookies using linseed oil cake was rapid. The peroxide value of the linseed-free cookie remained almost unchanged because most of the oil in the linseed-free cookie is derived from butter, which is an unsaturated bond that causes peroxide formation. This is probably because there is very little.
[0073]
Moreover, sensory evaluation was performed about the flavor of each sample by eight skilled panelists.
[0074]
The flavor evaluation method was evaluated in four stages, and the average opinion was compiled.
[0075]
The above evaluation results are summarized in Table 8 below.
[0076]
[Table 8]

[0077]
As for the flavor, the cookie using flaxseed oil cake has a peculiar odor from the beginning of its preparation, a deterioration odor due to the deterioration of the vegetable oil is observed as the storage period progresses, and a strong foul odor in the final period There has occurred. Cookies prepared from flaxseed-free dough exhibited a unique deterioration odor that occurred when milk fat (butter) deteriorated as the storage period progressed. In addition, the cookies using flaxseed seeds did not feel the deterioration odor peculiar to milk fat, but as the storage period progressed, the deterioration odor due to deterioration of the vegetable oil was recognized.
[0078]
On the other hand, in the cookie using the flaxseed press cake of the present invention, a good flavor was stably maintained during the storage period.
[0079]
Example 3: Examination of applicability of flaxseed squeezed rice cake to bread
(1) Preparation of bread using flaxseed pressing
Three types of breads were prepared using the flaxseed pressing powder described in Example 1, and these were designated as Examples A to C. On the other hand, three types of breads prepared without using any flaxseed squeezed rice cake were also prepared, and these were designated as Comparative Examples X to Z.
[0080]
Specifically, each bread dough was obtained by mixing the materials shown in Table 9 below. The materials in any of the examples / comparative examples are blended so that the total of the flour (strong flour and semi-strong flour) and the flaxseed press cake is 100 parts by weight. As is clear from the description in Table 9, the amount of water added can be increased by substituting a portion of the flour with flaxseed press cake, thereby making the texture of the baked bread soft and moist. Was also improved.
[0081]
[Table 9]

[0082]
Each bread dough was first kneaded and fermented according to the conditions described in Table 10 below. Then, according to the conditions described in Table 10, the dough was divided into predetermined amounts, molded and then squeezed (bench time), then proofed and fired.
[0083]
[Table 10]

[0084]
In order to evaluate the bread thus obtained, first, the proofing time was measured, and the processability of the dough was evaluated empirically in four stages. Further, the weight (15 minutes after baking) and volume of the obtained bread were measured, and the specific volume was calculated therefrom. Then, the experienced bread panelists evaluated the appearance, quality and flavor of the obtained bread by four levels, and the average opinions were compiled. The above evaluation results are summarized in Table 11 below.
[0085]
[Table 11]

[0086]
In the breads of Examples A and B to which 5 parts by weight or 7.5 parts by weight of flaxseed pressing was added, an improvement in specific volume was observed as compared with the breads of Comparative Examples X to Z. Further, in the bread of Example C prepared from the material containing vitamin C, dramatic improvements were observed in each of the items of dough processability, volume, appearance, and internal quality. Furthermore, as a general tendency, the breads of Examples A to C to which flaxseed press cake was added had a better flavor.
[0087]
Thus, by adding the flaxseed press cake of the present invention, not only the nutritional value is improved, but also the amount of water is increased, and in particular, by adding 5 parts by weight or 7.5 parts by weight of flaxseed press cake, An increase in the volume of the bread that gave a good mouthfeel was observed. In particular, the addition of vitamin C further improved the volume of bread.
[0088]
(2) Preparation of bread using seed dough and flaxseed press
Three types of bread were prepared using the flaxseed squeeze described in Example 1, and these were designated as Examples D to F. On the other hand, one type of bread prepared without using flaxseed squeezed rice cake was also prepared, and this was designated as Comparative Example W.
[0089]
First, for Example D and Comparative Example W, the ingredients listed in Table 12 below were mixed to obtain bread dough. On the other hand, in Examples E and F, first, a seed dough prepared by kneading dough raw material (seed dough raw material) that does not contain both vitamin C and yeast with hot water in a refrigerator for 8 hours. Stored refrigerated. To this seed dough, a dough material containing both vitamin C and yeast (main dough material) was added and mixed to obtain a bread dough. The materials in any of the examples / comparative examples are blended so that the total amount of flour (strong flour) and linseed press cake is 100 parts by weight.
[0090]
As is clear from the description in Table 12, the amount of water added can be increased by substituting a portion of the flour with flaxseed pressing, thereby making the texture of the bread after baking soft and moist. Was also improved.
[0091]
[Table 12]

[0092]
Each bread dough was first kneaded and fermented according to the conditions described in Table 13 below. Thereafter, according to the conditions described in Table 13, the dough was divided into a predetermined amount, molded and then squeezed (bench time), then proofed and fired.
[0093]
[Table 13]

[0094]
The weight (volume 15 minutes after baking) and volume of the bread thus obtained were measured, and the specific volume was calculated therefrom. Then, the experienced bread panelists evaluated the appearance, quality and flavor of the obtained bread by four levels, and the average opinions were compiled. The above evaluation results are summarized in Table 14 below.
[0095]
[Table 14]

[0096]
In the breads of Examples D to F to which 5 parts by weight of flaxseed press was added, in addition to the improvement in specific volume, a dramatic improvement in terms of flavor was recognized as compared with the bread of Comparative Example W. Moreover, the improvement of the bread | pan of Example DF was recognized also about each item of an external appearance and an internal phase. Furthermore, as an overall trend, the breads of Examples D to F, to which flaxseed press cake was added, had a better flavor.
[0097]
Thus, the addition of the flaxseed press cake of the present invention not only improves the nutritive value, but also increases the amount of water, and in particular, the addition of 5 parts by weight of flaxseed press cake makes the bread feel good An increase in volume was observed. In particular, it has been clarified that further addition of vitamin C further increases the volume of bread and dramatically improves the physical properties of the dough. In particular, in the bread obtained using two doughs of the seed dough and the main dough, the volume increase was recognized, and the softness and moist feeling of the bread after baking were further improved.
[0098]
(3) Preparation of bread using flaxseed press
Based on the findings described in Example 1 (5), the following three types of breads (Examples GI) were prepared according to the following procedure.
[0099]
Example G: Refined flaxseed seed (Yoshihara Oil Co., Ltd.) was applied to a cold press experimental machine (AP-08 type; Linalz), and the flaxseed press cake obtained by squeezing was used as a power mill (coarse crusher: Dalton Co., Ltd.) ), And then applied to an atomizer (fine pulverizer: Dalton Co., Ltd.) and pulverized to obtain a pulverized soot. The operating condition of the power mill was normal operation. On the other hand, the operating condition of the atomizer was a spindle speed of 8500 rpm and a 2 m / mφ screen.
[0100]
Example H: Applying carefully selected flaxseed seed (Johnson Seed: Canada) to a cold press experimental machine (AP-08 type; Linalz) and then applying the flaxseed press cake as it is to a Neamill grinder (Coarse pulverization was not performed), and pulverized soot was obtained.
[0101]
Example I: A finely divided flaxseed seed (manufactured by Yoshiwara Oil Co., Ltd.) applied to an expeller (HP150 type; Suehiro Co., Ltd.). ) And pulverized to obtain a pulverized soot.
[0102]
And the material of the following Table 15 was mixed and each bread dough was obtained.
[0103]
The material in any Example is mix | blended so that the sum total of wheat flour (strong flour) and a linseed press cake may be 100 weight part.
[0104]
[Table 15]

[0105]
Each bread dough was first kneaded and fermented according to the conditions described in Table 16 below. Then, according to the conditions described in Table 16, the dough was divided into a predetermined amount, and after molding, it was twisted (bench time), then proofed and fired.
[0106]
[Table 16]

[0107]
The three breads thus obtained were sliced into approximately 2 cm thicknesses and then divided into 4 equal parts, and evaluated by the ranking method by 12 skilled panelists regarding the four items of appearance, flavor, texture and comprehensive evaluation. I got it. In other words, for each item, the ranking is given to the three breads, one point is given to the best item, two points are given to the next best item, and three points are given to the item having the lowest evaluation. The total points were aggregated [that is, the smaller the total points, the higher the evaluation].
[0108]
The above evaluation results are summarized in Table 17 below.
[0109]
[Table 17]

[0110]
As is clear from the results shown in Table 17, the bread using the pulverized rice cake (Example H) obtained by using the Neamill grinder showed excellent results that did not come apart in all evaluation items. .
[0111]
In the bread using the pulverized pestle of Example H, the coarse particles of the pulverized pestle are so small that they cannot be confirmed unless they are looked very closely. Therefore, it has succeeded in suppressing the graininess derived from the flaxseed seed-specific flavor and the physical properties of coarse particles. On the other hand, in the pulverized koji of Example G, many coarse particles having a particle size of about several hundred microns remain in the bread, so that the flavor and texture peculiar to flaxseed seeds were felt. Furthermore, in the pulverized mash of Example I, the pellar cocoon itself has a flavor similar to the burnt odor, and also receives a heat history than the pulverized mash of Examples G and H. I felt a little.
[0112]
Therefore, panelists who prefer the texture specific to flaxseed seeds select bread using the ground grinds of Example G containing coarse particles, while panelers who want bread without crumbs use the ground grinds of Example H There was a tendency to select baked bread. This indicates that the most suitable bread material is the pulverized grinder (Example H) obtained using a Neamill grinder that has both a crushing function and a classification function. is there.
[0113]
In Examples 2 to 3 of the present application, application examples of the flaxseed pressing lees [pulverized lees] of the present invention to cookies and breads were illustrated. However, it is obvious that those skilled in the art can easily produce other bakery foods such as muffins by appropriately adjusting the baking temperature of the dough using the same dough material and a well-known cooking technique. is there.
[0114]
Example 4: Production of roasted rice cake
300 g of the flaxseed pressing lees described in Example 1 was roasted in an iron frying pan and then cooled to room temperature to obtain the roasting lees of the present invention. And this roasting cake was grind | pulverized with the sample mill (Dalton Co., Ltd.).
[0115]
Similarly, 300 g of the flaxseed seed described in Example 1 was roasted in an iron frying pan, and then it was cooled to room temperature. The cooled roasted linseed seeds were pulverized with a sample mill (Dalton Co., Ltd.) to obtain a pulverized product of roasted linseed seeds. By the way, in this example, in consideration of the fact that the oil content of the pulverized flaxseed seed is exposed to the outside air and it is significantly oxidized, a pulverized product of roasted linseed seed that is less susceptible to the oxidative effect of the oil content was used. .
[0116]
Each of these pulverized products was placed in a separate glass beaker (1000 ml capacity).
[0117]
Next, in order to evaluate the oxidation stability of the two samples, a test was performed according to the following procedure.
[0118]
First, each beaker was closed with a plastic film having about 10 pinholes and placed in a ventilator set at 55 ° C. And the oil content was extracted from each sample chronologically and the peroxide value was measured. In addition, extraction of the oil component was performed by the Soxhlet method using diethyl ether. The peroxide value (meq / kg) is determined based on the standard oil analysis method (2.5.2-Peroxide value, standard oil analysis test method (I), Japan Oil Chemists' Society, 1996 edition, Nippon Oil Chemical Co., Ltd.). ) And acetic acid / isooctane method. Moreover, it measured also about the linseed squeeze described in Example 1 and the linseed seed (non-roasted). The measurement results are summarized in the graph of FIG.
[0119]
As is clear from the graph of FIG. 4, it was revealed that the flaxseed seed (roasted) rapidly oxidizes. On the other hand, it became clear that the roasting cake of the present invention was not affected at all by the thermal stability even after roasting.
[0120]
Moreover, sensory evaluation was performed about the flavor of each sample by eight skilled panelists.
[0121]
The flavor evaluation method was evaluated in four stages, and the average opinion was compiled.
[0122]
The above evaluation results are summarized in Table 18 below.
[0123]
[Table 18]

[0124]
As apparent from the results shown in Table 18, the flaxseed seeds (roasted) increased in deterioration with storage and finally exhibited a strong oxidative deterioration odor. On the other hand, the roasted rice cake of the present invention was slightly diluted in fragrant flavor by long-term storage, but did not lead to the generation of a deteriorated odor. From this result, it became clear that even if the flaxseed press cake of the present invention is subjected to roasting treatment, no adverse effect is exerted. In other words, this is nothing but a suggestion that the roasted koji of the present invention does not cause the flavor deterioration accompanying the fat and oil deterioration over time during storage.
[0125]
Example 5: Examination of applicability of roast rice cake to food
Cookies were prepared using the roasted potatoes and roasted flaxseed seeds of the invention described in Example 4, the pressed oil cake roasted according to the procedure described in Example 4, and the linseed seeds. A cookie prepared without using flaxseed (without flaxseed) was used as a control. That is, each dough obtained by mixing the materials shown in Table 19 below was baked in an oven at 170 ° C. for about 13 minutes.
[0126]
[Table 19]

[0127]
Next, in order to evaluate the oxidation stability of the above five samples, a test was performed according to the following procedure.
[0128]
First, 100 g of each cookie was placed in a separate glass beaker (1000 ml capacity).
[0129]
Each of these beakers was closed with a plastic film having about 10 pinholes and placed in a ventilator set at 55 ° C.
[0130]
And the oil content was extracted from each sample chronologically and the peroxide value was measured.
In addition, extraction of oil was performed by Soxhlet method using diethyl ether.
The peroxide value (meq / kg) is determined based on the standard oil analysis method (2.5.2-Peroxide value, standard oil analysis test method (I), Japan Oil Chemists' Society, 1996 edition, Nippon Oil Chemical Co., Ltd.). ) And acetic acid / isooctane method.
[0131]
The measurement results are summarized in the graph of FIG.
[0132]
As is clear from the graph of FIG. 5, in the cookies using roasted linseed seeds and roasted linseed oil cake, an increase in the peroxide value over time during the storage period was observed. On the other hand, in the cookies using the roasted rice cake of the present invention, the increase in the peroxide value was the slowest among the cookies using flaxseed.
[0133]
Moreover, sensory evaluation was performed about the flavor of each sample by eight skilled panelists.
[0134]
The flavor evaluation method was evaluated in four stages, and the average opinion was compiled.
[0135]
The above evaluation results are summarized in Table 20 below.
[0136]
[Table 20]

[0137]
As apparent from the results shown in Table 20, the roasted koji of the present invention was slightly diluted with a fragrant flavor by long-term storage, but did not cause deterioration odor. Rather, the control had an oxidative odor that was generated when milk fat deteriorated, and the roasted koji of the present invention did not feel a deteriorated odor. From the above results, it became clear that even if the roasted rice cake of the present invention is applied to food, there is no adverse effect. In other words, even when the roasted rice cake obtained by roasting the flaxseed pressed rice cake of the present invention is applied to foods, the flavor associated with the deterioration of fats and oils during storage, as observed in normal oil-based foods It is nothing but a suggestion that it will not cause deterioration.
[0138]
In addition, in the present Example, the application example to the cookie of the roasted rice cake of this invention was illustrated. However, it is obvious that those skilled in the art can easily produce other bakery foods, such as muffins and breads, by adjusting the baking temperature of the dough using the same dough material and a well-known cooking technique. It is.
[0139]
【The invention's effect】
As described above, according to the present invention, a low-calorie flaxseed squeezed pomace, which is the intended purpose, has a good flavor, and is excellent in nutritional balance and storage stability.
[0140]
Moreover, the flaxseed pressing lees according to the present invention are not only excellent in flavor and preservability, but also can be used for foods by reducing the oil content, and the caloric value can also be reduced.
[0141]
In addition, the roasted rice cake obtained by roasting the flaxseed pressed rice cake of the present invention is expected to be useful because it is excellent in flavor and storage and can be used for food.
[0142]
Furthermore, since the production process of the flaxseed pressing lees according to the present invention does not require a solvent extraction step, there are excellent effects such as no concern that a solvent such as hexane remains in the pressing lees.
[Brief description of the drawings]
BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a graph showing the oxidative stability of flaxseed press according to the present invention.
FIG. 2 is a graph showing the relationship of the particle size distribution of pulverized soot obtained by a Neamill pulverizer.
FIG. 3 is a graph showing the oxidative stability of cookies using the flaxseed press cake of the present invention.
FIG. 4 is a graph showing the oxidation stability of the roasted rice cake of the present invention.
FIG. 5 is a graph showing the oxidative stability of cookies using the roasting cake of the present invention.

Claims (11)

Raw linseed seeds obtained by squeezing at 10 ~ 40 ° C.,
Furthermore , the flaxseed squeezed rice cake is characterized in that the average particle size is 150 μm or less and particles of 350 μm or less occupy 95 % or more of all particles . The linseed press cake according to claim 1, wherein a residual oil content of the linseed press cake is 0.1 to 30% by weight. The peroxide value determined after placing 300 g of the flaxseed squeezed in a 1000 ml beaker for 3 weeks in a ventilator set at 55 ° C. is 5 meq / kg or less. 2. Flaxseed squeezed rice cake as described in 2. The flaxseed pressing lees according to any one of claims 1 to 3, wherein the water-soluble nitrogen index in the total nitrogen content of the flaxseed pressing lees is 30 to 50%. A food prepared by using the flaxseed pressing lees according to any one of claims 1 to 4. 6. The food product according to claim 5, wherein the food product is a cookie, muffin or bread. The food according to claim 6, wherein the bread further contains vitamin C. From bread dough prepared by kneading dough ingredients containing both vitamin C and yeast to seed dough prepared from dough ingredients that do not contain both vitamin C and yeast and cooled and stored The food according to claim 6 or 7, which is produced. A roasted rice cake obtained by roasting the flaxseed press cake according to any one of claims 1 to 4. A food prepared using the roasting cake according to claim 9. A method of manufacturing a linseed squeezed cake, raw linseed seeds were squeezed 10 ~ 40 ° C., and step only contains recovering the resulting spent grains,
A method for producing flaxseed squeeze, characterized in that the average particle diameter of the squeezed squeezed powder is 150 μm or less, and particles of 350 μm or less occupy 95 % or more of all the particles .

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