食品与发酵工业 >

2025 , Vol. 51 >Issue 23: 277 - 285

DOI: https://doi.org/10.13995/j.cnki.11-1802/ts.042456

研究报告

基于超声辅助深共晶溶剂法的废弃虾蟹壳中虾青素高效提取

  • 邱月 ,
  • 岳澳冬 ,
  • 张建友
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  • (浙江工业大学 食品科学与工程学院,浙江 杭州,310014)
第一作者:博士,讲师(张建友教授为通信作者,E-mail:zhjianyou@zjut.edu.cn)

收稿日期: 2025-02-21

  修回日期: 2025-04-24

  网络出版日期: 2025-12-25

基金资助

国家重点研发计划子课题项目(2019YFD0901604-02)

收起

Efficient extraction of astaxanthin from waste shrimp shells using ultrasound-assisted deep eutectic solvent method

  • QIU Yue ,
  • YUE Aodong ,
  • ZHANG Jianyou
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  • (College of Food Science and Technology, Zhejiang University of Technology, Hangzhou 310014, China)

Received date: 2025-02-21

  Revised date: 2025-04-24

  Online published: 2025-12-25

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摘要

废弃虾蟹壳中蕴含高抗氧化活性物质——虾青素,传统有机溶剂提取法危害环境且对虾青素活性影响较大。因此,该文采用超声辅助深共晶溶剂提取法来获取虾青素。通过对比不同百里香酚/油酸摩尔配比组成的深共晶溶剂极性、黏度、pH值以及红外光谱特性,结合单因素与响应面分析,确定最优提取工艺参数为百里香酚/油酸摩尔比3∶1,料液比1∶20(g∶mL),超声时间68 min,功率320 W,虾青素提取量达49.5 μg/g。超声辅助深共晶溶剂提取法获得的虾青素溶液具有较高的DPPH自由基清除能力,是化学合成虾青素的1.36倍。虾青素的百里香酚/油酸深共晶溶液相比丙酮溶液具有更高的热稳定性、光稳定性、pH稳定性。该研究实现了虾蟹壳中虾青素的绿色、高效提取和活性保持,为废弃虾蟹壳的资源化提供了新策略和技术支持。

关键词: 深共晶溶剂; 虾青素; 绿色提取

本文引用格式

邱月 , 岳澳冬 , 张建友 . 基于超声辅助深共晶溶剂法的废弃虾蟹壳中虾青素高效提取[J]. 食品与发酵工业, 2025 , 51(23) : 277 -285 . DOI: 10.13995/j.cnki.11-1802/ts.042456

Abstract

The study investigates an ultrasound-assisted deep eutectic solvent extraction method for astaxanthin from waste shrimp shells, addressing the environmental concerns and activity preservation challenges associated with conventional organic solvent extraction methods.Through a comprehensive analysis of deep eutectic solvents composed of different ratios of thymol to oleic acid, the optimal extraction parameters were identified, which were a thymol/oleic acid molar ratio of 3∶1, a solid-to-liquid ratio of 1∶20 (g∶mL), an ultrasound duration of 68 minutes, and a power of 320 W, yielding an astaxanthin extraction of 49.5 μg/g.The extracted astaxanthin exhibited a superior DPPH free radical scavenging capacity, 1.36 times higher than chemically synthesized astaxanthin.Additionally, the astaxanthin preserved in the thymol/oleic acid deep eutectic solvent showed enhanced thermal, photochemical, and pH stability compared to acetone solutions.This research offers a green, efficient strategy for astaxanthin extraction from shrimp shells, maintaining its bioactivity and providing a novel approach for the resource utilization of shrimp and crab shell waste.

Key words: deep eutectic solvent; astaxanthin; environmentally friendly extraction

参考文献

[1] BOENISH R, KRITZER J P, KLEISNER K, et al.The global rise of crustacean fisheries[J].Frontiers in Ecology and the Environment, 2022, 20(2):102-110.
[2] GONG Z K, WANG H L, TANG J L, et al.Coordinated expression of astaxanthin biosynthesis genes for improved astaxanthin production in Escherichia coli[J].Journal of Agricultural and Food Chemistry, 2020, 68(50):14917-14927.
[3] LIU X J, ZHOU L S, XIE J T, et al.Astaxanthin isomers:A comprehensive review of isomerization methods and analytic techniques[J].Journal of Agricultural and Food Chemistry, 2023, 71(50):19920-19934.
[4] GUAN L Y, JI R Y, ZANG J C, et al.Both hemocyanin and β-1, 3-glucan-binding protein from the shrimp shell of litopenaeus vannamei are responsible for its color change from brown to red during thermal processing[J].Journal of Agricultural and Food Chemistry, 2024, 72(42):23544-23553.
[5] 程婉婷, 陈世钰, 贤凤, 等.酸性低共熔溶剂的理化特性及其与虾青素溶解度的相关性研究[J].化学试剂, 2023, 45(2):106-113.
CHENG W T, CHEN S Y, XIAN F, et al.Physicochemical properties of acidic deep eutectic solvents and the correlation with astaxanthin solubility[J].Chemical Reagents, 2023, 45(2):106-113.
[6] 钱建瑛, 王雨露, 李恒, 等.利用沼虾废弃物制备富含虾青素的食用油和虾露调味液的工艺研究[J].中国调味品, 2022, 47(11):99-104.
QIAN J Y, WANG Y L, LI H, et al.Study on preparation of edible oil and shrimp sauce flavoring liquid rich in astaxanthin from Macrobrachium rosenbergii waste[J].China Condiment, 2022, 47(11):99-104.
[7] 李念, 陈露珠, 安鑫, 等.3种虾壳中虾青素提取工艺优化及其抗氧化活性比较[J].上海海洋大学学报, 2022, 31(1):298-308.
LI N, CHEN L Z, AN X, et al.Optimization of extraction process and comparison of antioxidant activities of astaxanthin from three kinds of shrimp shells[J].Journal of Shanghai Ocean University, 2022, 31(1):298-308.
[8] 孙兆远, 侯会绒, 孔令伟.结合型虾青素酶法水解工艺的研究[J].食品研究与开发, 2017, 38(12):35-39.
SUN Z Y, HOU H R, KONG L W.Optimizing hydrolysis techniques of bound astaxanthin compounds by papain[J].Food Research and Development, 2017, 38(12):35-39.
[9] TOMÉ L I N, BAIÃO V, DA SILVA W, et al.Deep eutectic solvents for the production and application of new materials[J].Applied Materials Today, 2018, 10:30-50.
[10] SU W J, XU W H, POLYAKOV N E, et al.Zero-waste utilization and conversion of shrimp shell by mechanochemical method[J].Journal of Cleaner Production, 2023, 425:139028.
[11] MUSSAGY C U, SANTOS-EBINUMA V C, HERCULANO R D, et al.Ionic liquids or eutectic solvents? Identifying the best solvents for the extraction of astaxanthin and β-carotene from Phaffia rhodozyma yeast and preparation of biodegradable films[J].Green Chemistry, 2022, 24(1):118-123.
[12] ZHANG H, TANG B K, ROW K H.A green deep eutectic solvent-based ultrasound-assisted method to extract astaxanthin from shrimp byproducts[J].Analytical Letters, 2014, 47(5):742-749.
[13] GUAN W, CHANG N, YANG L L, et al.Determination and prediction for the polarity of ionic liquids[J].Journal of Chemical & Engineering Data, 2017, 62(9):2610-2616.
[14] 刘宇航, 相欢, 黄卉, 等.低共熔溶剂提取虾壳中虾青素工艺优化及机理初探[J].南方水产科学, 2024, 20(3):164-172.
LIU Y H, XIANG H, HUANG H, et al.Optimization of process and mechanism of extracting astaxanthin from shrimp shells with deep eutectic solvent[J].South China Fisheries Science, 2024, 20(3):164-172.
[15] LIU R G, LI Y, ZHOU C F, et al.Pickering emulsions stabilized with a Spirulina protein-chitosan complex for astaxanthin delivery[J].Food & Function, 2023, 14(9):4254-4266.
[16] PANDEY A, RAI R, PAL M, et al.How polar are choline chloride-based deep eutectic solvents?[J].Physical Chemistry Chemical Physics, 2014, 16(4):1559-1568.
[17] FLORINDO C, MCINTOSH A J S, WELTON T, et al.A closer look into deep eutectic solvents:Exploring intermolecular interactions using solvatochromic probes[J].Physical Chemistry Chemical Physics, 2018, 20(1):206-213.
[18] CHEN Y, YU D K, LU Y H, et al.Volatility of deep eutectic solvent choline chloride:N-methylacetamide at ambient temperature and pressure[J].Industrial & Engineering Chemistry Research, 2019, 58(17):7308-7317.
[19] JANČÍKOVÁ V, MAJOVÁ V, JABLONSKÝ M.Acidity and pH of DES-like mixtures and the possibilities of their determination[J].Journal of Molecular Liquids, 2024, 394:123728.
[20] LIU Y T, CHEN Y N, XING Y J.Synthesis and characterization of novel ternary deep eutectic solvents[J].Chinese Chemical Letters, 2014, 25(1):104-106.
[21] KHEZELI T, DANESHFAR A, SAHRAEI R.A green ultrasonic-assisted liquid-liquid microextraction based on deep eutectic solvent for the HPLC-UV determination of ferulic, caffeic and cinnamic acid from olive, almond, sesame and cinnamon oil[J].Talanta, 2016, 150:577-585.
[22] ABO-HAMAD A, HAYYAN M, ALSAADI M A, et al.Potential applications of deep eutectic solvents in nanotechnology[J].Chemical Engineering Journal, 2015, 273:551-567.
[23] SHARAYEI P, AZARPAZHOOH E, ZOMORODI S, et al.Optimization of ultrasonic-assisted extraction of astaxanthin from green tiger (Penaeus semisulcatus) shrimp shell[J].Ultrasonics Sonochemistry, 2021, 76:105666.
[24] RUEN-NGAM D, SHOTIPRUK A, PAVASANT P.Comparison of extraction methods for recovery of astaxanthin from Haematococcus pluvialis[J].Separation Science and Technology, 2010, 46(1):64-70.
[25] XU Y, PAN S Y.Effects of various factors of ultrasonic treatment on the extraction yield of all-trans-lycopene from red grapefruit (Citrus paradise Macf.)[J].Ultrasonics Sonochemistry, 2013, 20(4):1026-1032.
[26] LOU Z X, WANG H X, ZHANG M, et al.Improved extraction of oil from chickpea under ultrasound in a dynamic system[J].Journal of Food Engineering, 2010, 98(1):13-18.
[27] RI L, HO R.Comparison of ionic liquids and deep eutectic solvents as additives for the ultrasonic extraction of astaxanthin from marine plants[J].Journal of Industrial and Engineering Chemistry, 2016, 39:87-92.
[28] DOS SANTOS C, PADILHA C E A, DAMASCENO K S F S C, et al.Astaxanthin recovery from shrimp residue by solvent ethanol extraction using choline chloride:Glycerol deep eutectic solvent as adjuvant[J].Journal of the Brazilian Chemical Society, 2021, 32:1030-1039.
[29] ROSELLÓ-SOTO E, KOUBAA M, MOUBARIK A, et al.Emerging opportunities for the effective valorization of wastes and by-products generated during olive oil production process:Non-conventional methods for the recovery of high-added value compounds[J].Trends in Food Science & Technology, 2015, 45(2):296-310.
[30] CHENG W T, XIAN F, ZHOU Z L, et al.Solubility and stability of carotenoids in ammonium- and phosphonium-based ionic liquids:Effect of solvent nature, temperature and water[J].Molecules, 2023, 28(8):3618.
[31] LI F Y, MAO S, ZHOU X B, et al.The Cyperus esculentus starch-based bioactive films:Characterisation, UV-shielding and antioxidant capacity[J].International Journal of Food Science & Technology, 2023, 58(8):4446-4454.
[32] CELEBIOGLU A, YILDIZ Z I, UYAR T.Thymol/cyclodextrin inclusion complex nanofibrous webs:Enhanced water solubility, high thermal stability and antioxidant property of thymol[J].Food Research International, 2018, 106:280-290.
[33] SANCHEZ-FERNANDEZ A, PREVOST S, WAHLGREN M.Deep eutectic solvents for the preservation of concentrated proteins:The case of lysozyme in 1∶2 choline chloride∶glycerol[J].Green Chemistry, 2022, 24(11):4437-4442.
[34] LI N, FAN M C, LI Y, et al.Stability assessment of crocetin and crocetin derivatives in gardenia yellow pigment and Gardenia fruit pomace in presence of different cooking methods[J].Food Chemistry, 2020, 312:126031.
[35] ZHANG Y Q, ZHAO X Y, MA Y, et al.Comparison of blue discoloration in radish root among different varieties and blue pigment stability analysis[J].Food Chemistry, 2021, 340:128164.
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