Synergistic Effects of Food Ingredients and Vegetable Oils on Thermal Isomerization of Lycopene.

Recent investigations have demonstrated that some food ingredients and vegetable oils, such as onion, garlic, and sesame oil, enhanced thermal Z-isomerization of (all-E)-lycopene in tomatoes. However, the synergistic effects of these ingredients and oils have not yet been investigated. This study aims at clarifying how the combined use of lycopene Z-isomerization-promoting food ingredients and vegetable oils impacts thermal Z-isomerization of (all-E)-lycopene in tomato puree. Apart from a few exceptions, when olive oil was used as a reaction medium, the combined use of garlic, cabbage, broccoli, shiitake mushroom, and makonbu improved the total Z-isomer ratio of lycopene after heating compared to the separate use of the tested ingredients. However, when onion was used together with the other ingredients, the Z-isomer ratio significantly decreased compared to its individual use. Moreover, when garlic, cabbage, broccoli, shiitake mushroom, and makonbu were used with sesame and mustard oils, that exhibit higher Z-isomerizationpromoting effect than that of olive oil, the lycopene Z-isomerization reaction was further enhanced. However, when onion was combined with these oils, the Z-isomer ratio decreased compared to that measured upon the combined use of onion with olive oil. Our results on these synergistic effects are not only important for the food and drink manufacturing industries but also for daily home cooking.

Production of (Z)-Lycopene-Rich Tomato Concentrate: A Natural Catalyst-Utilized and Oil-Based Study for Practical Applications.

Since lycopene Z-isomers exhibit greater bioavailability and biological activity than the naturally occurring all-E-isomer, efficient manufacturing methods for (Z)-lycopene-rich materials are urgently needed. Herein, a method was developed for Z-isomerization of (all-E)-lycopene in tomato oleoresin using heat treatment and a natural catalyst, viz. allyl isothiocyanate (AITC). For practical application of this isomerization technology, no organic solvents were used, and instead, oils and fats were used as the reaction medium. The Z-isomerization of (all-E)-lycopene was promoted by heating (>120 °C) even when oil and fat media were used. Allyl isothiocyanate enhanced thermal Z-isomerization and improved the (5Z)-lycopene content, which shows higher biological activity compared to the other Z-isomers. The thermal isomerization efficiency with AITC was further improved by using certain vegetable oils such as argan and olive oils. In addition, the storage stability of (Z)-lycopene-rich tomato concentrates dispersed in olive oil was evaluated. The total Z-isomer ratio and lycopene concentration decreased with longer storage periods, and it was revealed that (5Z)-lycopene showed excellent storage stability among the mono-Z-isomers.

Isomerization of Commercially Important Carotenoids (Lycopene, ß-Carotene, and Astaxanthin) by Natural Catalysts: Isothiocyanates and Polysulfides.

Effects of natural catalysts, isothiocyanates and polysulfides, on Z-isomerization and decomposition of (all-E)-carotenoids (lycopene, ß-carotene, and astaxanthin) after heat treatment were investigated. When isothiocyanates were added to (all-E)-carotenoid solutions and heated, Z-isomerization and decomposition of carotenoids were enhanced and the degree differed depending on the isothiocyanate type. Interestingly, when polysulfides were applied in the same manner, in addition to promoting the Z-isomerization reaction, they markedly improved the thermal stability of carotenoids. Successively, we investigated the reaction characteristics of allyl isothiocyanate (AITC) and diallyl disulfide (DADS) using (all-E)-lycopene; that is, effects of the amount added, solvent used, and reaction temperature and time, as well as the combination use on Z-isomerization and decomposition of lycopene, were investigated. With increases in the amount added and reaction temperature and time, Z-isomerization of lycopene was promoted for both catalysts. The high-temperature treatment tests clearly showed that AITC induced thermal decomposition of lycopene, whereas DADS improved the lycopene stability. Moreover, the simultaneous use of AITC and DADS resulted in a synergetic effect on the Z-isomerization efficiency.