Water–triglyceride interfaces limit permeability and diffusion of aroma molecules in butter

IF 1.8 3区 农林科学 Q3 FOOD SCIENCE & TECHNOLOGY
Tobias Benedikt Koch, Heiko Briesen
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引用次数: 0

Abstract

Insight into the dynamics of aroma molecules in bulk phases and at water–triglyceride interfaces is crucial for elucidating the aroma release mechanisms in complex dairy products such as butter. This study employs classical, all‐atom molecular dynamics simulations with umbrella sampling to investigate the energetics and kinetics of key aroma‐active compounds, including diacetyl, ‐decalactone, and butyric acid, at interfaces of 1,3‐dipalmitoyl‐2‐oleoylglycerol (POP) in water. The chemical properties of aroma compounds, including polarity, hydrogen bonding, and van der Waals interactions, play a pivotal role in their interaction with interfacial molecules, resulting in unique profiles of the potential of mean force and diffusivity. In particular, ‐decalactone preferentially resides at the interface and accumulates in the triglyceride phase. Aroma permeability through the complexly organized water–triglyceride interface significantly decreases from ‐decalactone to butyric acid, with a less pronounced reduction for diacetyl. Surprisingly, this trend in aroma permeability at interfaces does not coincide with trends in aroma diffusion within both pure bulk phases. This discrepancy is attributed to local, heterogeneous molecular structuring at water–triglyceride interfaces, impeding the interfacial permeation processes and leading to local aroma confinement.Practical Application: Employing a water–POP interface as a case study, the methodology investigates aroma compound diffusion within bulk phases, delineating limitations in aroma permeability in dairy products with extended water–triglyceride interfaces. This is a substep in the aroma release process, contributing to the interpretation of perception studies by sensory panels in human sensory experiments and fostering a deeper understanding of the intricate dynamics inherent to individual compounds.
水-甘油三酯界面限制了黄油中香气分子的渗透和扩散
洞察芳香分子在体相和水-三酸甘油酯界面上的动态对于阐明黄油等复杂乳制品的芳香释放机制至关重要。本研究采用经典的全原子分子动力学模拟和伞状采样,研究了关键香气活性化合物(包括双乙酰、癸内酯和丁酸)在水中 1,3-二棕榈酰-2-油酰甘油(POP)界面处的能量学和动力学。芳香化合物的化学特性,包括极性、氢键和范德华相互作用,在它们与界面分子的相互作用中起着关键作用,从而产生独特的平均力和扩散势能曲线。特别是,癸内酯优先驻留在界面上,并在甘油三酯相中积聚。从-癸内酯到丁酸,通过组织复杂的水-甘油三酯界面的香气渗透性明显下降,而双乙酰的下降则不太明显。令人惊讶的是,界面香气渗透性的这一趋势与两种纯体相中的香气扩散趋势并不一致。这种差异归因于水-三酸甘油酯界面的局部异质分子结构,阻碍了界面渗透过程,导致局部香气封闭:实际应用:该方法以水-持久性有机污染物界面为案例,研究了芳香化合物在体相内部的扩散,划定了具有扩展的水-三酸甘油酯界面的乳制品在芳香渗透性方面的限制。这是香气释放过程中的一个子步骤,有助于人类感官实验中感官小组对感知研究的解释,并加深对单个化合物内在复杂动态的理解。
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来源期刊
CiteScore
5.50
自引率
0.00%
发文量
101
审稿时长
6-16 weeks
期刊介绍: The European Journal of Lipid Science and Technology is a peer-reviewed journal publishing original research articles, reviews, and other contributions on lipid related topics in food science and technology, biomedical science including clinical and pre-clinical research, nutrition, animal science, plant and microbial lipids, (bio)chemistry, oleochemistry, biotechnology, processing, physical chemistry, and analytics including lipidomics. A major focus of the journal is the synthesis of health related topics with applied aspects. Following is a selection of subject areas which are of special interest to EJLST: Animal and plant products for healthier foods including strategic feeding and transgenic crops Authentication and analysis of foods for ensuring food quality and safety Bioavailability of PUFA and other nutrients Dietary lipids and minor compounds, their specific roles in food products and in nutrition Food technology and processing for safer and healthier products Functional foods and nutraceuticals Lipidomics Lipid structuring and formulations Oleochemistry, lipid-derived polymers and biomaterials Processes using lipid-modifying enzymes The scope is not restricted to these areas. Submissions on topics at the interface of basic research and applications are strongly encouraged. The journal is the official organ the European Federation for the Science and Technology of Lipids (Euro Fed Lipid).
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