Potential Effect of Cavitation on the Physical Properties of Interesterified Soybean Oil Using High‐Intensity Ultrasound: A Long‐Term Storage Study

Youngs, Jack J.; Birkin, Peter R.; Truscott, Tadd; Martini, Silvana

doi:10.1002/aocs.12414

Cited by 2 publications

(1 citation statement)

References 19 publications

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“…HIU is defined as sound waves that operate at high power levels (10–10 000 W cm −2 ) and low frequencies (20–100 kHz), which are above the audible human frequency (Ye & Martini, 2014; Yao et al ., 2020). During HIU application, ultrasonic waves propagate through a medium by the oscillating motion of a transducer, generating cavities or bubbles (Martini, 2013; Lee et al ., 2020). A series of compression and rarefaction events in the material result in the formation and collapse of bubbles, known as cavitation (Patist & Bates, 2008; Gregersen et al ., 2019).…”

Section: Introductionmentioning

confidence: 99%

Degree of oxidation of sonicated soybean oil using various sonication process parameters

Legako

Martini

2022

Int J of Food Sci Tech

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Summary This research aimed to examine the effect of high‐intensity ultrasound (HIU) on the oxidation of soybean oil (SBO). Samples (5, 100, and 250 g) were sonicated at 25 °C using various sonication conditions: power level (settings 1, 5, and 9), tip size (12.7, 3.2, and 2 mm), and duration (5, 10, and 60 s). After sonication, the degree of oxidation of samples (sonicated and non‐sonicated SBO) were analysed using peroxide value (PV), oil stability index (OSI), and volatile compounds. Sonication was applied to obtain a range of absolute power (0–123.5 W), power density (0–14.2 W cm−3), and power intensity (0–1,120 W cm−2) values. The highest power density and power intensity were obtained with the highest HIU setting with the 3.2 mm tip. The highest power was obtained when HIU was applied using a 12.7 mm tip and setting 9 in 250 g of sample. No significant difference (P > 0.05) was observed in PV (0.20 ± 0.01 mEq kg−1) nor OSI (10.05 ± 0.04 h), among the various sonication conditions tested. In addition, no differences were observed in the volatile compounds obtained. These results show that HIU can be used under mild sonication conditions such as the ones needed to change the physical properties of lipids without causing oxidative deterioration.

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Section: Introductionmentioning

confidence: 99%

Degree of oxidation of sonicated soybean oil using various sonication process parameters

Legako

Martini

2022

Int J of Food Sci Tech

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Use of High-intensity Ultrasound to Structure Edible Fats

Silva

Giacomozzi

Martini

2022

Development of Trans-Free Lipid Systems and Their Use in Food Products

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The focus of this chapter is to summarize research regarding sonocrystallization of fats, including discoveries of how high-intensity ultrasound (HIU) has been used to accelerate fat crystallization and to structure low-saturated fats and oleogels. It reviews the main frequency, amplitude, time duration and pulses, power levels, and steps of crystallization or oleogelation where HIU should be applied to maximize the improvement of physical properties such as oil binding capacity, rheology, hardness, melting behavior, polymorphism, and microstructure. In addition, this chapter explains how to change from a batch lab condition to a continuous sheared system, like a scraped surface heat exchanger (SSHE). Moreover, effects of HIU on lipid oxidation and final food application are also discussed.

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Potential Effect of Cavitation on the Physical Properties of Interesterified Soybean Oil Using High‐Intensity Ultrasound: A Long‐Term Storage Study

Cited by 2 publications

References 19 publications

Degree of oxidation of sonicated soybean oil using various sonication process parameters

Degree of oxidation of sonicated soybean oil using various sonication process parameters

Use of High-intensity Ultrasound to Structure Edible Fats

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