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正交实验优化南极磷虾蛋白肽的纳滤脱盐工艺
李福后1, 黄岳磊1,2, 刘小芳2, 冷凯良2,3, 王灵昭1, 于源2, 苗钧魁2
1.江苏海洋大学食品科学与工程学院 江苏 连云港 222005;2.中国水产科学研究院 黄海水产研究所 农业农村部极地渔业可持续利用重点实验室 山东 青岛 266071;3.青岛海洋科学与技术试点国家实验室海洋药物与生物制品功能实验室 山东 青岛 266200
摘要:
为建立南极磷虾(Euphausia superba)蛋白肽纳滤脱盐工艺,以脱盐率和蛋白损失率为评价指标,通过单因素实验和正交实验对影响南极磷虾蛋白肽纳滤脱盐效果的主要因素(蛋白肽浓度、压力、循环次数)进行优化。结果显示,采用纳滤技术对南极磷虾蛋白肽进行脱盐处理的最佳工艺条件:蛋白肽浓度为3%、纳滤压力为1.2 MPa、循环次数3次,在该条件下,南极磷虾蛋白肽的脱盐率达到(86.35±2.11)%、蛋白损失率为(9.10±0.35)%。采用优化工艺获得的南极磷虾蛋白肽的盐分含量为(1.14±0.12)%,蛋白质含量为(92.73±2.29)%,相对分子质量主要分布于3000 Da以下,氨基酸组成合理且符合联合国粮农组织/世界卫生组织规定的标准。研究将为高品质南极磷虾蛋白肽产品开发提供技术支撑。
关键词:  南极磷虾  蛋白肽  正交实验  纳滤  脱盐
DOI:10.19663/j.issn2095-9869.20210901002
分类号:
基金项目:
Optimization of a nanofiltration desalination process for Antarctic krill peptides using orthogonal tests
LI Fuhou1, HUANG Yuelei1,2, LIU Xiaofang2, LENG Kailiang2,3, WANG Lingzhao1, YU Yuan2, MIAO Junkui2
1.Jiangsu Ocean University, School of Food Science and Engineering, Lianyungang, Jiangsu 222005, China;2.Yellow Sea Fisheries Research Institute, Chinese Academy of Fishery Sciences, Key Laboratory of Sustainable Development of Polar Fisheries, Ministry of Agriculture and Rural Affairs, Qingdao, Shandong 266071, China;3.Laboratory for Marine Drugs and Bioproducts, Pilot National Laboratory for Marine Science and Technology (Qingdao), Qingdao, Shandong 266200, China
Abstract:
Antarctic krill (Euphausia superba), an important group of marine zooplankton in the Southern Ocean, is the only fishery resource with extremely rich reserves and a low degree of development in the world. Antarctic krill is considered to be the greatest potential source of high-quality marine protein resources due to its abundant biomass and high protein content. Peptides prepared from Antarctic krill exhibit multiple physiological activities, including osteoporosis relief, glucose metabolism regulation, blood pressure amelioration, antioxidation, fatigue alleviation, and anti-aging activity. The production and development of Antarctic krill peptides has recently become an industry focus; however, existing research has been limited to the optimization of enzymatic hydrolysis processes, mainly involving the screening of suitable enzymes and the optimization of enzymatic hydrolysis conditions. Due to the high mineral content of Antarctic krill and the introduction of buffer salt in the process of enzymatic hydrolysis, current Antarctic krill peptides products have a high salt content, which leads to poor sensory experience and health risks. Hence, a process for desalination of Antarctic krill peptides is needed. Desalination methods for bioactive substances include dialysis, ultrafiltration, nanofiltration, electrodialysis, and macroporous resin adsorption. In the field of membrane separation, nanofiltration technology has been widely used in the purification, concentration, and desalination of food components owing to its advantages: low operation cost, no introduction of exogenous substances, no destruction of materials, and low rejection rate of monovalent ions. In order to improve product quality and ensure market expansion, the process of desalination of Antarctic krill peptides using nanofiltration technology was studied and optimized in this study. Defatted Antarctic krill powder was enzymatically hydrolyzed by alkaline protease to obtain Antarctic krill peptides for further use. The main factors affecting the desalination effect of Antarctic krill peptides (peptides concentration, nanofiltration pressure, and cycle times) were optimized by single-factor and orthogonal tests, using the desalination rate and protein loss rate as evaluation indexes. The experimental optimization ranges included peptides concentration of 1%~5%, nanofiltration pressure of 0.6~1.4 MPa and cycle times of 1~5. The salt contents of the samples before and after desalination were quantified using the silver nitrate titration method; the protein contents of the experimental samples were quantified using the Lowry colorimetric method. The quality indexes of the Antarctic krill peptides after treatment (including the basic nutritional composition: moisture content, protein content, ash content, salt content; amino acid composition; and molecular weight distribution) were systematically evaluated by the corresponding national standard methods. All experiments were performed in triplicate, and data were expressed as mean ± standard deviation. Excel 2016, IBM SPSS 20.0, and Origin 2018 were used for data analysis and chart drawing. Single-factor tests revealed that peptides concentration of 3%, nanofiltration pressure of 1.0 MPa and a cycle time of 2 could be selected as the design basis for the L9 (33) orthogonal test. The range value of the orthogonal test indicated that the degree of influence of the three factors on the desalination effect was as follows: peptides concentration > cycle times > nanofiltration pressure. The optimum conditions for desalting Antarctic krill peptides obtained by k value analysis were as follows: peptides concentration of 3.0%, nanofiltration pressure of 1.2 MPa and a cycle time of 3. Under the optimal condition, the desalination rate of the Antarctic krill peptides reached up to (86.35±2.11)%, and the protein loss rate was controlled at (9.10±0.35)%, demonstrating the feasibility of the process. The salt content of the Antarctic krill peptides after desalination was reduced to (1.14±0.12)% and the protein content was (92.73±2.29)%. The molecular weights of the Antarctic krill peptides after desalination were mainly distributed between 189 Da and 6500 Da, of which the proportion of peptides with molecular weight less than 3000 Da was (88.91±2.19)%, conforming to the molecular weight distribution range of bioactive peptides. The amount of essential amino acids in the Antarctic krill peptides after desalination accounted for (40.06±0.10)% of the total amino acids, and the ratio of essential amino acids to nonessential amino acids was (66.82±0.28)%. The amino acid compositions of the Antarctic krill peptides after desalination were ideal and met the standard stipulated by the FAO/WHO. The established nanofiltration desalination process presented good treatment effects, and the obtained peptides were of good quality and high nutritional value. The production of Antarctic krill protein-related products may be the next key development for the processing industry, since the sole high-value products of Antarctic krill at present are Antarctic krill oil and its derivatives. The established nanofiltration desalination process has practical application value and would provide technical support for the development of high-quality Antarctic krill peptides. This research provides scientific support for the efficient utilization of Antarctic krill resources.
Key words:  Antarctic krill (Euphausia superba)  Peptides  Orthogonal test  Nanofiltration  Desalination