Abstract
Thermal stabilities of four major components (l-menthol, l-menthone, piperitone, and l-menthyl acetate) of Japanese mint essential oil were evaluated via subcritical water treatment. To improve experimental throughput for measuring compound stabilities, a small-scale subcritical water treatment method using ampoule bottles was developed and employed. A mixture of the four major components was treated in subcritical water at 180–240 °C for 5–60 min, and then analyzed by gas chromatography. The results indicated that the order of thermal resistance, from strongest to weakest, was: l-menthyl acetate, l-menthol, piperitone, and l-menthone. In individual treatments of mint flavor components, subsequent conversions of l-menthyl acetate to l-menthol, l-menthol to l-menthone, l-menthone to piperitone, and piperitone to thymol were observed in individual treatments at 240 °C for 60 min. As the mass balance between piperitone and thymol was low, the hydrothermal decomposition of the components was considered to have occurred intensely during, or after the conversion. These results explained the degradation of mint essential oil components under subcritical water conditions and provided the basis for optimizing the extraction conditions of mint essential oils using subcritical water.
Highlights
Mint essentials oils are well-known and popular products for their cooling and invigorating effects
Small-scale subcritical water treatment of the four components (l-menthol, l-menthone, piperitone, and l-menthyl acetate) with an excellent throughput was successfully performed in batch mode
The results indicated that the residual ratio of l-menthol decreased to 89.3% at 180 ◦ C after 60 min
Summary
Mint essentials oils are well-known and popular products for their cooling and invigorating effects. Mint essential oils are generally obtained from Japanese mint (Mentha arvensis L.), peppermint (Mentha piperita, L.), and spearmint (Mentha spicata L.). L-Menthol is the most abundant component in the Japanese mint and peppermint essential oils, while l-carvone is the most abundant component in Molecules 2020, 25, 1953; doi:10.3390/molecules25081953 www.mdpi.com/journal/molecules. Molecules 2020, 25, 1953 spearmint essential oil [1,2]. Hydrodistillation is the most universal and conventional method for obtaining essential oil from mint [4]. Hydrodistillation requires three hours for a batch extraction of rosemary essential oil [5]. Subcritical water treatment was reportedly more efficient than hydrodistillation in the extraction of marjoram essential oil [6]
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