Food and Fermentation Industries >

2020 , Vol. 46 >Issue 21: 304 - 309

DOI: https://doi.org/10.13995/j.cnki.11-1802/ts.024364

Advances on the effects of ultra-high pressure on myofibrillar protein structure and its gel properties

  • LI Zhao ,
  • LI Ningning ,
  • LIU Yu ,
  • ZHAO Shengming ,
  • KANG Zhuangli ,
  • ZHU Mingming ,
  • JI Hongfang ,
  • HE Hongju ,
  • MA Hanjun
Expand
  • 1(School of Food Science, Henan Institute of Science and Technology, Xinxiang 453003,China);
    2(National Pork Processing Technology Research and Development Professional Center, Xinxiang 453003,China);
    3(Henan Province Engineering Technology Research Center of Animal Products Intensive Processing and Quality Safety Control, Xinxiang 453003,China)

Received date: 2020-05-11

  Revised date: 2020-06-16

  Online published: 2020-12-11

Fold

Abstract

Ultra-high pressure technology not only can reduce the microorganism, keep good flavor and quality in meat products, but also affect the disulfide bond, hydrogen bonding and hydrophobic interaction. It results in denaturation, gelation and depolymerization of proteins by the change of protein configuration. Therefore, ultra-high pressure technology could be used to improve the gel properties of meat production. This article briefly reviewed the effects of biochemical characteristics and chemical force of myofibrillar protein by ultra-high pressure technology. The mechanism of ultra-high pressure on gel properties of myofibrillar protein was emphasized. This study provides theoretical reference for the application of ultra-high pressure technology in gel-type meat products.

Key words: ultra-high pressure; myofibrillar protein; biochemical characteristics; chemical forces; gel properties

Cite this article

LI Zhao , LI Ningning , LIU Yu , ZHAO Shengming , KANG Zhuangli , ZHU Mingming , JI Hongfang , HE Hongju , MA Hanjun . Advances on the effects of ultra-high pressure on myofibrillar protein structure and its gel properties[J]. Food and Fermentation Industries, 2020 , 46(21) : 304 -309 . DOI: 10.13995/j.cnki.11-1802/ts.024364

References

[1] 励建荣, 王泓.超高压技术在食品工业中的应用及前景[J].现代食品科技,2006,22(1):171-173;180.
[2] 李双, 王成忠,唐晓璇.超高压技术在食品工业中的应用研究进展[J].山东食品发酵,2014(4):11-14.
[3] ESPEJO G G,HERNANDEZHERRERO M,JUAN B,et al.Inactivation of Bacillus spores inoculated in milk by ultra high pressure homogenization[J].Food Microbiology,2014:204-210.
[4] 刘旺, 冯美琴,孙健,等.超高压条件下亚麻籽胶对猪肉肌原纤维蛋白凝胶特性的影响[J].食品科学,2019,40(7):101-107.
[5] 崔燕, 宣晓婷,林旭东,等.超高压协同冷冻辅助脱壳对南美白对虾肌原纤维蛋白理化性质的影响[J].现代食品科技,2019,35(2):32-39.
[6] HERMANSSON A M.Gel characteristics structure as related to texture and waterbinding of blood plasma gels[J].Journal of Food Science,2006,47(6):1 965-1 972.
[7] 夏秀芳, 孔保华,张宏伟.肌原纤维蛋白凝胶形成机理及影响因素的研究进展[J].食品科学,2009,30(9):264-268.
[8] 李懿璇, 王悦,鲁小川,等.红曲红添加量对猪肉肌原纤维蛋白功能性质和结构的影响[J].食品与发酵工业,2020,46(2):173-179.
[9] 邓思瑶, 吕梁玉,杨文鸽,等.辐照对肌肉蛋白结构及其凝胶性能影响的研究进展[J].食品工业科技,2016,37(12):365-370.
[10] 郭丽萍, 熊双丽,黄业传.超高压结合热处理对猪肉蛋白质相互作用力及结构的影响[J].现代食品科技,2016,32(2):196-204.
[11] LIU J,SHIM Y Y,TIMOTHY J T,et al.Flaxseed gum a versatile natural hydrocolloid for food and non-food applications[J].Trends in Food Science & Technology,2018,75:146-157.
[12] 闫春子, 夏文水,许艳顺.超高压对草鱼肌原纤维蛋白结构的影响[J].食品与生物技术学报,2018,37(4):424-428.
[13] CHAPLEAU N,MANGAVEL C,COMPOINT J,et al.Effect of high-pressure processing on myofibrillar protein structure[J].Journal of the Science of Food and Agriculture,2004,84(1):66-74.
[14] WANG Y,ZHOU Y,LI P,et al.Combined effect of CaCl2 and high pressure processing on the solubility of chicken breast myofibrillar proteins under sodium-reduced conditions[J].Food Chemistry,2018,269:236-243.
[15] XUE S,XU X,SHAN H,et al.Effects of high-intensity ultrasound,high-pressure processing,and high-pressure homogenization on the physicochemical and functional properties of myofibrillar proteins[J].Innovative Food Science and Emerging Technologies,2018,45:354-360.
[16] ZHANG Z,YANG Y,ZHOU P,et al.Effects of high pressure modification on conformation and gelation properties of myofibrillar protein[J].Food Chemistry,2017,217:678-686.
[17] CHELH I,GATELLIER P,SANTÉ-LHOUTELLIER V.Technical note:A simplified procedure for myofibril hydrophobicity determination[J].Meat Science,2006,74(4):681-683.
[18] HE D,WANG X,AI M,et al.Molecular mechanism of high-pressure processing for improving the quality of low-salt Eucheuma spinosum chicken breast batters[J].Poultry Science,2019,98(6):2 670-2 678.
[19] VILLAMONTE G,JURY V,JUNG S,et al.Influence of xanthan gum on the structural characteristics of myofibrillar proteins treated by high pressure[J].Journal of Food Science,2015,80(1-3):C522-C531.
[20] LUO X,YANG R,ZHAO W,et al.Gelling properties of Spanish mackerel (Scomberomorus niphonius) surimi as affected by washing process and high pressure[J].International Journal of Food Engineering,2010,6(4):3.
[21] KITTIPHATTANABAWON P,BENJAKUL S,VISESSANGUAN W,et al.Cryoprotective effect of gelatin hydrolysate from blacktip shark skin on surimi subjected to different freeze-thaw cycles[J].LWT-Food Science and Technology,2012,47(2):437-442.
[22] WANG T,LI Z,MI N,et al.Effects of brown algal phlorotannins and ascorbic acid on the physiochemical properties of minced fish (Pagrosomus major) during freeze-thaw cycles[J].International Journal of Food Science & Technology,2017,52(3):706-713.
[23] 廖彩虎, 芮汉明,张立彦,等.超高压解冻对不同方式冻结的鸡肉品质的影响[J].农业工程学报,2010,26(2):331-337.
[24] CHENG L,SUN D,ZHU Z,et al.Effects of high pressure freezing (HPF) on denaturation of natural actomyosin extracted from prawn (Metapenaeus ensis)[J].Food Chemistry,2017,229:252-259.
[25] ZHOU A,LIN L,LIANG Y,et al.Physicochemical properties of natural actomyosin from threadfin bream (Nemipterus spp.) induced by high hydrostatic pressure[J].Food Chemistry,2014,156:402-407.
[26] HSU K,HWANG J,YU C,et al.Changes in conformation and in sulfhydryl groups of actomyosin of tilapia (Orechromis niloticus) on hydrostatic pressure treatment[J].Food Chemistry,2007,103(2):560-564.
[27] 胡飞华. 梅鱼鱼糜超高压凝胶化工艺及凝胶机理的研究[D].杭州:浙江工商大学,2010.
[28] CHEFTEL J C,CULIOLI J.Effects of high pressure on meat:A review[J].Meat Science,1997,46(3):211-236.
[29] HWANG J,LAI K,HSU K,et al.Changes in textural and rheological properties of gels from tilapia muscle proteins induced by high pressure and setting[J].Food Chemistry,2007,104(2):746-753.
[30] 杨慧娟. 超高压处理改善低脂低盐猪肉糜制品乳化凝胶特性研究[D].南京:南京农业大学,2017.
[31] YE T,DAI H,LIN L,et al.Employment of κ-carrageenan and high pressure processing for quality improvement of reduced NaCl surimi gels[J].Journal of Food Processing and Preservation,2019,43(9):14 074.
[32] 仪淑敏, 马兴胜,励建荣,等.超高压诱导鱼糜凝胶形成中水分特性及凝胶强度的相关性研究[J].中国食品学报,2015,15(7):26-31.
[33] 任云霞, 李亚楠,张坤生.超高压对添加变性淀粉的鸭肉肌原纤维蛋白的影响[J].食品研究与开发,2012,33(11):10-14.
[34] GROSSI A,OLSEN K,BOLUMAR T,et al.The effect of high pressure on the functional properties of pork myofibrillar proteins[J].Food Chemistry,2016,196:1 005-1 015.
[35] CHEN X,CHEN C,ZHOU Y,et al.Effects of high pressure processing on the thermal gelling properties of chicken breast myosin containing κ-carrageenan[J].Food Hydrocolloids,2014,40:262-272.
[36] KOC M,KOC B,SUSYAL G,et al.Improving functionality of whole egg powder by the addition of gelatine,lactose,and pullulan[J].Journal of Food Science,2011,76(9):S508-S515.
[37] ZHENG H,HAN M,YANG H,et al.The effect of pressure-assisted heating on the water holding capacity of chicken batters[J].Innovative Food Science & Emerging Technologies,2018,45:280-286.
[38] 陈燕婷, 林露,高星,等.超高压对带鱼鱼糜凝胶特性及其肌原纤维蛋白结构的影响[J].食品科学,2019,40(21):115-120.
[39] 王苑. 不同处理方式对肌原纤维蛋白和大豆分离蛋白混合凝胶特性的影响[D].南京:南京农业大学,2007.
[40] MA F,CHEN C,SUN G,et al.Effects of high pressure and CaCl2 on properties of salt-soluble meat protein gels containing locust bean gum[J].Innovative Food Science and Emerging Technologies,2012,14:31-37.
[41] ZHAGN H,PAN J,WU Z.Investigation of the effects of high pressure processing on the process of rigor in pork[J].Meat Science,2018,145:455-460.
[42] CAO Y,XIA T,ZHOU G,et al.The mechanism of high pressure-induced gels of rabbit myosin[J].Innovative Food Science and Emerging Technologies,2012,16:41-46.
[43] WU M,XIONG Y,CHEN J,et al.Rheology and microstructure of myofibrillar protein-plant lipid composite gels:Effect of emulsion droplet size and membrane type[J].Journal of Food Engineering,2011,106(4):318-324.
[44] CANDO D,HERRANZ B,BORDERÍAS A J,et al.Effect of high pressure on reduced sodium chloride surimi gels[J].Food Hydrocolloids,2015:176-187.
[45] WEI L,LI Y,WANG C,et al.Thermal gel properties and protein conformation of pork batters as affected by high pressure and temperature[J].International Journal of Food Properties,2019,22(1):1 492-1 500.
[46] 黄群,王希希,艾明艳,等.超高压对低盐海藻鸡肉糜品质的影响[J].食品科学,2018,39(19):96-102.
[47] 黄晓毅, 韩剑众,王彦波,等.差示扫描量热技术 (DSC) 在肉类研究中的应用进展[J].食品工业科技,2009,30(9):353-357.
[48] 张小燕,何军波,张如意,等.差示扫描量热法及其在猪肉凝胶机理探索中的应用[J].肉类工业,2014(12):18-20.
[49] 叶韬,戴慧敏,林琳,等.不同处理条件下鲢鱼糜凝胶水分状态和微观结构的特征[J].南方水产科学,2019,15(2):104-111.
Options
Outlines

/

Powered by Beijing Magtech Co. Ltd,.