Characterization and application of a microemulsion as model system for lipophilic phytochemicals in high-pressure processing

Svenja Tauber, Simon Fehn, Mario Schmidt, Uwe Schwarzenbolz, Volker Böhm
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Abstract

High-pressure processing (HPP) is considered as gentle preservation technique for especially heat-sensitive food ingredients. So far, the focus has been on the fact that it is called a nonthermal process and high pressure can affect bioavailability, but it is questionable whether the high pressure affects the ingredients themselves. By using an o/w-microemulsion (ME) as a model system, it was possible to investigate the influence of pressure, especially on lipophilic compounds (e.g., carotenoids and vitamin E), without the complexity of a food matrix. The ME consisted of Capryol® TM 90, Tween® 80 or 20, Transcutol® HP and distilled water. Lipophilic and hydrophilic compounds were introduced to the oil phase and to the aqueous phase, respectively. Storage experiments confirmed the applicability for β-carotene and α-tocopherol. HPP of MEs, performed for 10 min at room temperature (RT) and up to 600 MPa, resulted in pressure stability of β-carotene (exceptional at 400 MPa; −11%) and α-tocopherol. Multicomponent ME showed that both had a positive effect on the stability of chlorophyll a/b during HPP. An ME environment was used to facilitate co-oxidation of β-carotene via lipoxygenase (LOX) from an Edamame-based crude enzyme extract and lyophilized LOX-1 from soybeans during storage (RT and 4°C, dark conditions) and HPP treatment. A loss of β-carotene occurred after addition of linoleic acid, whereas effects of added α-tocopherol could be related to β-carotene protection. Overall, the introduced ME for studying HPP effects on lipophilic food ingredients showed promising results as versatile model system for future investigations regarding interactions of phytochemicals.

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将微乳液作为亲脂植物化学物质高压加工模型系统的表征与应用
高压加工(HPP)被认为是一种温和的保存技术,尤其适用于对热敏感的食品配料。迄今为止,人们关注的焦点一直是它被称为非热处理工艺,以及高压会影响生物利用率,但高压是否会影响成分本身则是个问题。通过使用水包油型微乳液(ME)作为模型系统,可以研究压力的影响,尤其是对亲脂性化合物(如类胡萝卜素、维生素 E)的影响,而不需要复杂的食品基质。ME 由 Capryol® TM 90、Tween® 80 或 20、Transcutol® HP 和蒸馏水组成。亲脂性和亲水性化合物分别被引入油相和水相。贮藏实验证实了β-胡萝卜素和α-生育酚的适用性。在室温(RT)和高达 600 兆帕的压力下对 ME 进行 10 分钟的 HPP,可使 β-胡萝卜素(在 400 兆帕的压力下异常稳定;-11%)和 α-生育酚具有压力稳定性。多组分 ME 显示,这两种物质在 HPP 期间对叶绿素 a/b 的稳定性都有积极影响。在贮藏(RT 和 4°C,黑暗条件下)和 HPP 处理期间,ME 环境被用来促进β-胡萝卜素通过脂肪氧化酶的共氧化作用。添加亚油酸后,β-胡萝卜素会损失,而添加α-生育酚可能与保护β-胡萝卜素有关。总之,为研究 HPP 对亲脂性食品成分的影响而引入的 ME 显示出良好的效果,可作为未来研究植物化学物质相互作用的多功能模型系统。本文受版权保护。
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