Cropotova Janna, Kvangarsnes Kristine, Rustad Turid, Stangeland Janne, Roda Gabriella, Fanzaga Melissa, Bartolomei Martina, Lammi Carmen
Department of Biological Sciences Ålesund, Norwegian University of Science and Technology, Ålesund, Norway.
Department of Biotechnology and Food Science, Norwegian University of Science and Technology, Trondheim, Norway.
Front Nutr. 2024 Sep 4;11:1446485. doi: 10.3389/fnut.2024.1446485. eCollection 2024.
Fish protein hydrolysates (FPH) obtained by enzymatic hydrolysis allows for smart valorization of fish side streams. However, further treatments are normally needed to enhance bioactive and functional properties of the obtained FPH. At present, the commonly used methods to improve functional properties of FPH include chemical and enzymatic modification. Chemical treatments often cause environmental problems, while the enzymatic modification method requires the use of quite expensive enzymes. In recent years, emerging technologies such as ultrasound treatment (US-treatment) have shown great potential in protein modification with high efficiency and safety, low energy consumption, and low nutritional destructiveness. In this study, high-power ultrasound treatments were applied to fish protein hydrolysates (FPH) extracted from Atlantic mackerel () side streams to improve their quality parameters. The effect of three different treatments of 300 W, 450 W and 600 W at the operating frequency of 20 kHz for 10 min on the physicochemical, structural, and functional characteristics of FPH, were examined. The results have shown that with an increase in ultrasound power, the protein solubility of FPH increased linearly, and the changes were significant for all US-treated samples compared to control (untreated) samples. US-treatment significantly increased the degree of hydrolysis of FPH samples treated with 450 W and 600 W compared to control samples. The carbonyl content of FPH increased (significantly for 450 W and 600 W), while thiol groups decreased (significantly for 300 W and 450 W). This indicated that some US-treatments induced oxidation of FPH, however the values of the protein oxidation were low. Amino acid composition of FPH revealed that US-treatment increased the proportion of essential amino acids in the sample treated with 300 W and 450 W, but the increase was not significant. After the US-treatment, all FPH samples became lighter and less yellowish and reddish, which suggest potentially higher attractiveness to consumers. In addition, the antioxidant activity was assessed using the DPPH, FRAP, and ABTS assays and the cell-free dipeptidyl peptidase IV (DPP-IV) inhibitory activity was also measured. Moreover, these biological activities were measured at cellular level utilizing human intestinal Caco-2 cells. Specifically, the FPH capacity to lower HO-induced reactive oxygen species (ROS) and lipid peroxidation levels was used to measure its antioxidant activity. The findings suggest that hydrolysates could find use as ingredients for promoting health.
通过酶解获得的鱼蛋白水解物(FPH)能够实现鱼副产物的智能增值。然而,通常需要进一步处理以增强所得FPH的生物活性和功能特性。目前,改善FPH功能特性的常用方法包括化学修饰和酶修饰。化学处理常常会引发环境问题,而酶修饰方法需要使用相当昂贵的酶。近年来,诸如超声处理(US处理)等新兴技术在蛋白质修饰方面展现出巨大潜力,具有高效、安全、低能耗以及低营养破坏性等优点。在本研究中,采用高功率超声处理从大西洋鲭鱼副产物中提取的鱼蛋白水解物(FPH),以改善其质量参数。考察了在20kHz工作频率下,300W、450W和600W三种不同处理持续10分钟对FPH的物理化学、结构和功能特性的影响。结果表明,随着超声功率的增加,FPH的蛋白质溶解度呈线性增加,与对照(未处理)样品相比,所有经超声处理的样品变化均显著。与对照样品相比,450W和600W处理的FPH样品经超声处理后水解度显著增加。FPH的羰基含量增加(450W和600W时显著),而巯基减少(300W和450W时显著)。这表明某些超声处理会诱导FPH氧化,不过蛋白质氧化值较低。FPH的氨基酸组成显示,300W和450W处理的样品经超声处理后必需氨基酸比例增加,但增加不显著。超声处理后,所有FPH样品颜色变浅,黄色和红色变淡,这表明对消费者可能具有更高的吸引力。此外,使用DPPH、FRAP和ABTS法评估抗氧化活性,并测定无细胞二肽基肽酶IV(DPP-IV)抑制活性。此外,利用人肠道Caco-2细胞在细胞水平上测定这些生物活性。具体而言,用FPH降低HO诱导的活性氧(ROS)和脂质过氧化水平的能力来测定其抗氧化活性。研究结果表明,水解物可作为促进健康的成分。
