Feasibility of ultrasound-assisted optimized process of high purity rice bran protein extraction

Bernardi, Sílvia; Kalschne, Daneysa Lahis; Menegotto, Anne Luize Lupatini; Flores, Éder Lisandro Moraes; Barin, Juliano Smanioto; Fuchs, Renata Hernandez Barros; Colla, Eliane; Canan, Cristiane

doi:10.1590/0103-8478cr20200012

Cited by 6 publications

(4 citation statements)

References 23 publications

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“…The defatted rice bran protein was extracted by ultrasound‐assisted extraction at two different frequencies: 37 and 80 kHz. The maximum protein yield was recovered at a lower frequency (15.07%) 43 . A similar pattern of results was seen in ultrasound‐assisted extraction of watermelon seed protein.…”

Section: Resultssupporting

confidence: 77%

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Determination of process parameters and precipitation methods for potential large‐scale production of sugar beet leaf protein concentrate

Akyüz,

Tekin,

Aksoy

et al. 2023

J Sci Food Agric

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BACKGROUNDSugar beet is one of the most produced industrial plants in the world, and during manufacturing it produces a large quantity of leaf waste. Because this waste is rich in protein, this study aimed to identify an efficient method for producing large‐scale protein concentrate from sugar beet leaves.RESULTSResults showed that protein extraction from fresh leaves was more effective than from dried leaves. Maximum protein extraction was achieved at pH 9, compared with pH 7 or 8. Blanching as a pretreatment reduced protein yield during isoelectric precipitation, with a yield of 2.31% compared to 20.20% without blanching. Consequently, blanching was excluded from the extraction process. After extraction, isoelectric precipitation, heat coagulation, and isoelectric–ammonium sulfate precipitation were compared. Although the latter resulted in the highest protein yield, Fourier transform infrared analysis revealed that excessive salt was not removed during dialysis, making it unsuitable for scale‐up due to its additional cost and complexity. Therefore, isoelectric precipitation was selected as the appropriate method for protein precipitation from sugar beet leaves. To increase yield, extractions were assisted by ultrasound or enzyme addition. Ultrasound‐assisted extraction resulted in an increased protein yield from 20.20% to 28.60%, while Pectinex Ultra SP‐L‐assisted extraction was the most effective, increasing protein yield from 20.20% to 38.09%.CONCLUSIONProteins were extracted from fresh sugar beet leaves using optimum conditions (50 °C, 30 min, pH 9) and precipitated at isoelectric point, with enzymatic‐assisted extraction yielding the maximum protein recovery. © 2023 The Authors. Journal of The Science of Food and Agriculture published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry.

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Section: Resultssupporting

confidence: 77%

“…The maximum protein yield was recovered at a lower frequency (15.07%). 43 A similar pattern of results was seen in ultrasound-assisted extraction of watermelon seed protein. A higher protein yield of 87% was obtained at ultrasound power of 90 W), frequency 25 kHz, and duty cycle 75%.…”

Section: Determination Of Effectivity Of Ultrasound Processsupporting

confidence: 63%

Determination of process parameters and precipitation methods for potential large‐scale production of sugar beet leaf protein concentrate

Akyüz,

Tekin,

Aksoy

et al. 2023

J Sci Food Agric

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“…The cavitational shear force generated during ultrasonication can destroy the non-covalent bonds (such as hydrogen bonds and hydrophobic bonds) between protein molecules or within the molecules, so that the compact structure of protein aggregates is opened, and the particle size is reduced to improve extraction rate. 24,25 Zhao et al 26 used ultrasonic-assisted extraction of Dolichos lablab L. protein (DLP), and found that the particle size of DLP was significantly smaller and the extraction rate significantly improved compared to traditional extraction methods. Wang et al 27 also found that the particle size of pea protein extracted by ultrasonic-assisted extraction was significantly smaller, and the biological activity of the extracted protein was also significantly enhanced.…”

Section: Introductionmentioning

confidence: 99%

“…Ultrasound is widely used as a green, safe and reliable technology. The cavitational shear force generated during ultrasonication can destroy the non‐covalent bonds (such as hydrogen bonds and hydrophobic bonds) between protein molecules or within the molecules, so that the compact structure of protein aggregates is opened, and the particle size is reduced to improve extraction rate 24,25 . Zhao et al 26 .…”

Section: Introductionmentioning

confidence: 99%

Ultrasound‐assisted reverse micelle extraction and characterization of tea protein from tea residue

et al. 2022

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BACKGROUND In this study, ultrasonic‐assisted reverse micelles were used to extract tea protein from tea residues. First, the extraction conditions of ultrasonic power, ionic strength and pH were optimized by response surface methodology. Then, structural comparison of ultrasonic‐assisted reverse micelle extraction of tea protein (UARME) and ultrasonic‐assisted alkali extraction (UAAE) were performed using scanning electron microscopy (SEM), Fourier transform infrared (FTIR) spectroscopy and amino acid composition. RESULTS The optimum process conditions were determined as follows: ultrasonic power 300 W, KCl 0.15 mol L−1, pH 8. The extraction rate was 46.29%, which was close to the theoretical value (46.44%). SEM showed that the protein particles extracted by UARME were smaller than those by UAAE. The results of FTIR spectroscopy showed that the protein extracted by UARME had higher α‐helix, β‐sheet and β‐turn, and the contents were 20%, 62.3% and 17.1%, respectively. The content of random coil was 0%, which was significantly lower than that of alkali extraction, indicating that the secondary structure of protein extracted by UARME was more orderly. By comparing the amino acid composition of the two methods, the amino acid content of tea protein extracted by UARME was significantly higher than that of UAAE. CONCLUSION The biological activity of tea protein is closely related to its structure. Compared with alkali extraction, reverse micelles can better protect the secondary structure of proteins, which is of great significance for studying their functional properties. © 2022 Society of Chemical Industry.

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Ultrasound: a suitable technology to improve the extraction and techno-functional properties of vegetable food proteins

Bernardi

Lupatini-Menegotto

Kalschne

et al. 2021

Plant Foods Hum Nutr

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Feasibility of ultrasound-assisted optimized process of high purity rice bran protein extraction

Cited by 6 publications

References 23 publications

Determination of process parameters and precipitation methods for potential large‐scale production of sugar beet leaf protein concentrate

Determination of process parameters and precipitation methods for potential large‐scale production of sugar beet leaf protein concentrate

Ultrasound‐assisted reverse micelle extraction and characterization of tea protein from tea residue

Ultrasound: a suitable technology to improve the extraction and techno-functional properties of vegetable food proteins

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