Structural and functional modification of food proteins by high power ultrasound and its application in meat processing

In the field of agricultural and food processing, high power ultrasound (HPUS) is recognized as a green, physical and non-thermal technology in improving the safety and quality of foods. The functional properties of food proteins are responsible for texture, yield and organoleptic of food products which are the theoretical basis for food processing optimizing. HPUS treatment could provide the possibility for creating novel functional properties of new foods with desirable properties due to the modification of protein structure. In this article, an overview of the previous studies and recent progress of the relationship between structure modification and functional properties of food proteins using the HPUS technique were presented. The research results revealed that HPUS could significantly affect the conformation and structure of protein due to the cavitation effect resulting in the improvement of solubility, interfacial, viscosity, gelation and flavor binding properties of proteins. During meat processing, HPUS can modify the structure and thereby improve the functional properties of myofibrillar protein (MP), leading to the quality enhancement, low fat and/or salt products development and the shelf life extending. In view of this review, the recent findings of applications of HPUS in the production of meat products based on the modification of MP including curing, freezing/thawing and thermal processing have been summarized. Finally, the future considerations were presented in order to facilitate the progress of HPUS in meat industry and provided the suggestions based on the advanced protein modification by HPUS for the commercial utilization of HPUS in producing the innovative meat products.

[1]  K. Osako,et al.  Changes in protein properties and tissue histology of tuna meat as affected by salting and subsequent freezing. , 2019, Food chemistry.

[2]  Zbigniew J. Dolatowski,et al.  Effect of ultrasound treatment on water holding properties and microstructure of beef (m. semimembranosus) during ageing , 2008 .

[3]  Jayani Chandrapala,et al.  The effect of ultrasound on the physical and functional properties of skim milk , 2012 .

[4]  P. Allen,et al.  The effect of ultrasonic salting on protein and water-protein interactions in meat. , 2014, Food chemistry.

[5]  Farid Chemat,et al.  Applications of ultrasound in food technology: Processing, preservation and extraction. , 2011, Ultrasonics sonochemistry.

[6]  P. Allen,et al.  The acceleration of pork curing by power ultrasound: A pilot-scale production , 2014 .

[7]  F. Barba,et al.  Effect of extrusion on the anti-nutritional factors of food products: An overview , 2017 .

[8]  J. Boye,et al.  Comparative Study of the Effects of Processing on the Nutritional, Physicochemical and Functional Properties of Lentil , 2017 .

[9]  Guang-hong Zhou,et al.  Changes in calpain activity, protein degradation and microstructure of beef M. semitendinosus by the application of ultrasound. , 2018, Food chemistry.

[10]  S. Z. Ali,et al.  Rice protein aggregation during the flaking process. , 1998 .

[11]  Zhihang Zhang,et al.  Influence of extrinsic operational parameters on salt diffusion during ultrasound assisted meat curing , 2018, Ultrasonics.

[12]  William J Galush,et al.  Viscosity behavior of high-concentration protein mixtures. , 2012, Journal of pharmaceutical sciences.

[13]  Zoran Herceg,et al.  Influence of novel food processing technologies on the rheological and thermophysical properties of whey proteins , 2008 .

[14]  R. Holley,et al.  High hydrostatic pressure effects on the texture of meat and meat products. , 2010, Journal of food science.

[15]  Guang-hong Zhou,et al.  Effect of ultrasound treatment on functional properties of reduced-salt chicken breast meat batter , 2015, Journal of Food Science and Technology.

[16]  Wangang Zhang,et al.  Protein Oxidation: Basic Principles and Implications for Meat Quality , 2013, Critical reviews in food science and nutrition.

[17]  Javier Telis-Romero,et al.  Improving sensory acceptance and physicochemical properties by ultrasound application to restructured cooked ham with salt (NaCl) reduction. , 2018, Meat science.

[18]  Zhengyu Jin,et al.  Effect of oxidative modification on structural and foaming properties of egg white protein , 2018 .

[19]  Zhiwei Zhu,et al.  Effects of freezing on cell structure of fresh cellular food materials: A review , 2018 .

[20]  F W Pohlman,et al.  Effects of ultrasound and convection cooking to different end point temperatures on cooking characteristics, shear force and sensory properties, composition, and microscopic morphology of beef longissimus and pectoralis muscles. , 1997, Journal of animal science.

[21]  Xiaoquan Yang,et al.  Formation of soluble aggregates from insoluble commercial soy protein isolate by means of ultrasonic treatment and their gelling properties. , 2009 .

[22]  E. Li-Chan,et al.  Effects of ultrasound on structural and physical properties of soy protein isolate (SPI) dispersions , 2013 .

[23]  T J Mason,et al.  Power ultrasound in meat processing. , 2015, Meat science.

[24]  Guang-hong Zhou,et al.  Power ultrasonic on mass transport of beef: Effects of ultrasound intensity and NaCl concentration , 2016 .

[25]  S. H. Lee,et al.  Skeletal muscle fiber type and myofibrillar proteins in relation to meat quality. , 2010, Meat science.

[26]  Weibiao Zhou,et al.  High-intensity ultrasound production of Maillard reaction flavor compounds in a cysteine-xylose model system. , 2015, Ultrasonics sonochemistry.

[27]  Kumari Shikha Ojha,et al.  Sustainable and consumer-friendly emerging technologies for application within the meat industry: An overview. , 2016, Meat science.

[28]  Muhan Zhang,et al.  Effects of different ultrasound power on physicochemical property and functional performance of chicken actomyosin. , 2018, International journal of biological macromolecules.

[29]  J. Keurentjes,et al.  Calorimetric study of the energy efficiency for ultrasound-induced radical formation. , 2002, Ultrasonics.

[30]  S. Anandan,et al.  The study of changes in raw meat salting using acoustically activated brine. , 2019, Ultrasonics sonochemistry.

[31]  Oscar E. Pérez,et al.  Comparative study of high intensity ultrasound effects on food proteins functionality , 2012 .

[32]  M. M. Youssef,et al.  Applications of ultrasound in analysis, processing and quality control of food: A review , 2012 .

[33]  I. Norton,et al.  University of Birmingham The effect of ultrasound treatment on the structural, physical and emulsifying properties of animal and vegetable proteins , 2015 .

[34]  S. Nakai,et al.  Relationships of Hydrophobicity and Net Charge to the Solubility of Milk and Soy Proteins , 2006 .

[35]  B. Li,et al.  High intensity ultrasound modified ovalbumin: Structure, interface and gelation properties. , 2016, Ultrasonics sonochemistry.

[36]  Haifeng Zhao,et al.  Effects of oxidative modification on gel properties of isolated porcine myofibrillar protein by peroxyl radicals. , 2014, Meat science.

[37]  A. Jambrak,et al.  Ultrasonic effect on physicochemical and functional properties of α -lactalbumin , 2010 .

[38]  M. Añón,et al.  Gelation of soybean proteins induced by sequential high-pressure and thermal treatments , 2009 .

[39]  N. Mehta,et al.  Characterization of heat-stable whey protein: Impact of ultrasound on rheological, thermal, structural and morphological properties. , 2018, Ultrasonics sonochemistry.

[40]  Guang-hong Zhou,et al.  Use of High-Intensity Ultrasound to Improve Functional Properties of Batter Suspensions Prepared from PSE-like Chicken Breast Meat , 2014, Food and Bioprocess Technology.

[41]  Guang-hong Zhou,et al.  Effects of Oxidation in Vitro on Structures and Functions of Myofibrillar Protein from Beef Muscles. , 2019, Journal of agricultural and food chemistry.

[42]  Siyi Pan,et al.  Effect of different oils and ultrasound emulsification conditions on the physicochemical properties of emulsions stabilized by soy protein isolate. , 2018, Ultrasonics sonochemistry.

[43]  Larissa de Lima Alves,et al.  O ultrassom no amaciamento de carnes , 2013 .

[44]  D. J. Morgan,et al.  An Evaluation of the Potential of High-Intensity Ultrasound for Improving the Microbial Safety of Poultry , 2012, Food and Bioprocess Technology.

[45]  M. Guo,et al.  Effects of ultrasound treatment on physicochemical and emulsifying properties of whey proteins pre- and post-thermal aggregation , 2017 .

[46]  Liu Lu,et al.  Effect of power ultrasound pre-treatment on the physical and functional properties of reconstituted milk protein concentrate , 2014 .

[47]  M. Mohammadifar,et al.  Effect of ultrasound treatments on functional properties and structure of millet protein concentrate. , 2018, Ultrasonics sonochemistry.

[48]  Weibiao Zhou,et al.  Generating Maillard reaction products in a model system of d-glucose and l-serine by continuous high-intensity ultrasonic processing , 2016 .

[49]  M. Ma,et al.  Influence of high-intensity ultrasound on foaming and structural properties of egg white. , 2018, Food research international.

[50]  F. Toldrá,et al.  Effect of ultrasound pretreatment and Maillard reaction on structure and antioxidant properties of ultrafiltrated smooth-hound viscera proteins-sucrose conjugates. , 2017, Food chemistry.

[51]  Timothy J. Mason,et al.  Physical properties of ultrasound treated soy proteins , 2009 .

[52]  H. Feng,et al.  Modifying the physicochemical properties of pea protein by pH-shifting and ultrasound combined treatments. , 2017, Ultrasonics sonochemistry.

[53]  Xinglian Xu,et al.  Solubilization of myofibrillar proteins in water or low ionic strength media: Classical techniques, basic principles, and novel functionalities , 2017, Critical reviews in food science and nutrition.

[54]  Tian Ding,et al.  Preparation of modified whey protein isolate with gum acacia by ultrasound maillard reaction , 2019, Food Hydrocolloids.

[55]  Xiaozhi Tang,et al.  Effects of pulsed ultrasound on rheological and structural properties of chicken myofibrillar protein. , 2017, Ultrasonics sonochemistry.

[56]  M. Nikolić,et al.  Structure and antioxidant activity of β-lactoglobulin-glycoconjugates obtained by high-intensity-ultrasound-induced Maillard reaction in aqueous model systems under neutral conditions. , 2013, Food chemistry.

[57]  Baodong Zheng,et al.  Influence of ultrasound-assisted alkali treatment on the structural properties and functionalities of rice protein , 2018 .

[58]  M. Hubinger,et al.  Structural and emulsifying properties of sodium caseinate and lactoferrin influenced by ultrasound process , 2017 .

[59]  R. Mawson,et al.  Quality properties of pre- and post-rigor beef muscle after interventions with high frequency ultrasound. , 2014, Ultrasonics sonochemistry.

[60]  G. Kılıç,et al.  Ultrasound in the meat industry: general applications and decontamination efficiency. , 2015, International journal of food microbiology.

[61]  D. Julian McClements,et al.  Advances in the application of ultrasound in food analysis and processing , 1995 .

[62]  Guang-hong Zhou,et al.  Effects of ultrasonic assisted cooking on the chemical profiles of taste and flavor of spiced beef. , 2018, Ultrasonics sonochemistry.

[63]  M. Guo,et al.  Effects of high intensity ultrasound on acid-induced gelation properties of whey protein gel. , 2017, Ultrasonics sonochemistry.

[64]  S. Barbut Pale, soft, and exudative poultry meat--Reviewing ways to manage at the processing plant. , 2009, Poultry science.

[65]  Amir Amiri,et al.  Application of ultrasound treatment for improving the physicochemical, functional and rheological properties of myofibrillar proteins. , 2018, International journal of biological macromolecules.

[66]  P. Panja Green extraction methods of food polyphenols from vegetable materials , 2017, Current Opinion in Food Science.

[67]  S. Lonergan,et al.  Biochemistry of postmortem muscle - lessons on mechanisms of meat tenderization. , 2010, Meat science.

[68]  Wangang Zhang,et al.  Contribution of nitric oxide and protein S-nitrosylation to variation in fresh meat quality. , 2018, Meat science.

[69]  Fereidoon Shahidi,et al.  Antioxidative activity and functional properties of protein hydrolysate of yellow stripe trevally (Selaroides leptolepis) as influenced by the degree of hydrolysis and enzyme type , 2007 .

[70]  C. S. Saini,et al.  Improvement of functional properties of sunflower protein isolates near isoelectric point: Application of heat treatment , 2018, LWT.

[71]  Weibiao Zhou,et al.  Effects of high-intensity ultrasound on Maillard reaction in a model system of d-xylose and l-lysine. , 2017, Ultrasonics sonochemistry.

[72]  S. Jafari,et al.  Influence of drying on functional properties of food biopolymers: From traditional to novel dehydration techniques , 2016 .

[73]  D. Knorr,et al.  Potential food applications of high-pressure effects on ice-water transitions , 1995 .

[74]  E. Huff-Lonergan,et al.  Progress in reducing the pale, soft and exudative (PSE) problem in pork and poultry meat. , 2008, Meat science.

[75]  Zhanmei Jiang,et al.  Effect of ultrasound on the structure and functional properties of transglutaminase-crosslinked whey protein isolate exposed to prior heat treatment , 2019, International Dairy Journal.

[76]  Guang-hong Zhou,et al.  Inactivation of Escherichia coli O157:H7 and Bacillus cereus by power ultrasound during the curing processing in brining liquid and beef. , 2017, Food research international.

[77]  Peng Zhou,et al.  Effects of high intensity ultrasound modification on physicochemical property and water in myofibrillar protein gel. , 2017, Ultrasonics sonochemistry.

[78]  T. Mason,et al.  Ultrasound-enhanced mass transfer in Halal compared with non-Halal chicken. , 2011, Journal of the science of food and agriculture.

[79]  J. Weiss,et al.  Structural and functional changes in ultrasonicated bovine serum albumin solutions. , 2007, Ultrasonics sonochemistry.

[80]  I. Undeland,et al.  Tuning the pH-shift protein-isolation method for maximum hemoglobin-removal from blood rich fish muscle. , 2016, Food chemistry.

[81]  B. Kong,et al.  The comparison of ultrasound-assisted immersion freezing, air freezing and immersion freezing on the muscle quality and physicochemical properties of common carp (Cyprinus carpio) during freezing storage. , 2019, Ultrasonics sonochemistry.

[82]  Sergey Shestakov,et al.  Applications of sonochemistry in Russian food processing industry. , 2014, Ultrasonics sonochemistry.

[83]  Mei Ching Tan,et al.  Characterisation of improved foam aeration and rheological properties of ultrasonically treated whey protein suspension , 2015 .

[84]  Da‐Wen Sun,et al.  Effects of electric fields and electromagnetic wave on food protein structure and functionality: A review , 2018 .

[85]  Guang-hong Zhou,et al.  Quality changes of pork during frozen storage: comparison of immersion solution freezing and air blast freezing , 2019, International Journal of Food Science & Technology.

[86]  E. Márquez‐Ríos,et al.  Effects of high-energy ultrasound on the functional properties of proteins. , 2016, Ultrasonics sonochemistry.

[87]  K. Eskridge,et al.  Consumer sensory acceptance and value of domestic, Canadian, and Australian grass-fed beef steaks. , 2005, Journal of animal science.

[88]  J. D. Kemp,et al.  Effects of Low Frequency Ultrasound on Properties of Restructured Beef Rolls , 1983 .

[89]  Bing Li,et al.  Novel methods for rapid freezing and thawing of foods - a review , 2002 .

[90]  Guang-hong Zhou,et al.  Improvement of tenderness and water holding capacity of spiced beef by the application of ultrasound during cooking , 2018 .

[91]  C. A. Miles,et al.  High power ultrasonic thawing of frozen foods , 1999 .

[92]  Y. H. Kim,et al.  Effects of aging/freezing sequence and freezing rate on meat quality and oxidative stability of pork loins. , 2018, Meat science.

[93]  J. Kerry,et al.  Salt reduction strategies in processed meat products – A review , 2017 .

[94]  S. Sureshkumar,et al.  Factors influencing meat emulsion properties and product texture: A review , 2017, Critical reviews in food science and nutrition.

[95]  Qian Chen,et al.  Influence of ultrasound-assisted immersion freezing on the freezing rate and quality of porcine longissimus muscles. , 2018, Meat science.

[96]  Kasiviswanathan Muthukumarappan,et al.  Quality changes and freezing time prediction during freezing and thawing of ginger , 2015, Food science & nutrition.

[97]  Weibiao Zhou,et al.  Kinetic study of high-intensity ultrasound-assisted Maillard reaction in a model system of d-glucose and glycine. , 2018, Food chemistry.

[98]  Guang-hong Zhou,et al.  High pressure processing alters water distribution enabling the production of reduced-fat and reduced-salt pork sausages. , 2015, Meat science.

[99]  M. Ashokkumar,et al.  Functionalised dairy streams: Tailoring protein functionality using sonication and heating. , 2018, Ultrasonics sonochemistry.

[100]  Guang-hong Zhou,et al.  Effects of power ultrasound on oxidation and structure of beef proteins during curing processing. , 2016, Ultrasonics sonochemistry.

[101]  Karina D. Martínez,et al.  Modification of foaming properties of soy protein isolate by high ultrasound intensity: Particle size effect. , 2015, Ultrasonics sonochemistry.

[102]  Guang-hong Zhou,et al.  Effects of ultrasound‐assisted frying on the physiochemical properties and microstructure of fried meatballs , 2019, International Journal of Food Science & Technology.

[103]  Timothy J. Mason,et al.  Effect of ultrasound treatment on solubility and foaming properties of whey protein suspensions , 2008 .

[104]  Da‐Wen Sun,et al.  Enhancement of Food Processes by Ultrasound: A Review , 2015, Critical reviews in food science and nutrition.

[105]  Guang-hong Zhou,et al.  Effects of ultrasound on the beef structure and water distribution during curing through protein degradation and modification. , 2017, Ultrasonics sonochemistry.

[106]  J. Ngao,et al.  Water‐Thawing of Fish Using Low Frequency Acoustics , 1982 .