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Critical Reviews in Food Science and Nutrition Volume 57, 2017 - Issue 17
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Original Articles

Recent developments in novel freezing and thawing technologies applied to foods

Xiao-Fei WuState Key Laboratory of Food Science and Technology, Jiangnan University, Wuxi, Jiangsu, China
,
Min ZhangState Key Laboratory of Food Science and Technology, Jiangnan University, Wuxi, Jiangsu, China;Jiangsu Province Key Laboratory of Advanced Food Manufacturing Equipment and Technology, Jiangnan University, ChinaCorrespondence[email protected]
,
Benu AdhikariSchool of Applied Sciences, RMIT University, Melbourne, Australia
&
Jincai SunXuzhou Branch, Haitong Food Group Company, Jiangsu Peixian, China;Zhejiang Pharmaceutical College, Ningbo, China
Pages 3620-3631 | Published online: 13 Jun 2017

References

  • Alemrajabi, A. A., Rezaee, F., Mirhosseini, M., and Esehaghbeygi, A. (2012). Comparative evaluation of the effects of electrohydrodynamic, oven, and ambient air on carrot cylindrical slices during drying process. Drying Technol. 30(1):88–96.
  • Archer, D. L. (2004). Freezing: an underutilized food safety technology?. Int. J. Food Microbiology. 90(2):127–138.
  • Awad, T., Moharram, H., Shaltout, O., Asker, D., and Youssef, M. (2012). Applications of ultrasound in analysis, processing and quality control of food: a review. Food Research International. 48(2):410–427.
  • Bai, Y., Sun, Y., Li, Z., and Kang, D. (2011). Study the optimum parameters of high voltage electrostatic field thawing. Procedia Eng. 16:679–684.
  • Basaran-Akgul, N., Basaran, P., and Rasco, B. (2008). Effect of temperature (− 5 °C to 130 °C) and fiber direction on the dielectric properties of beef semitendinosus at radio frequency and microwave frequencies. J. Food Sci. 73(6):E243–E249.
  • Boonsumrej, S., Chaiwanichsiri, S., Tantratian, S., Suzuki, T., and Takai, R. (2007). Effects of freezing and thawing on the quality changes of tiger shrimp (Penaeusmonodon) frozen by air-blast and cryogenic freezing. J. Food Eng. 80(1):292–299.
  • Cathcart, W., and Parker, J. (1946). Defrosting frozen foods by high-frequency heat. J.Food Sci. 11(4):341–344.
  • Chandrapala, J., Oliver, C. M., Kentish, S., and Ashokkumar, M. (2013). Use of power ultrasound to improve extraction and modify phase transitions in food processing. Food Rev. Int. 29(1):67–91.
  • Chemat, F., and Khan, M. K. (2011). Applications of ultrasound in food technology: processing, preservation and extraction. UltrasonicsSonochemistry. 18(4):813–835.
  • Cheng, X., Zhang, M., Xu, B., Adhikari, B., and Sun, J. (2015). The principles of ultrasound and its application in freezing related processes of food materials: a review. Ultrasonics Sonochemistry. 27:576–585.
  • Cheng, X.-F., Zhang, M., and Adhikari, B. (2014). Effects of ultrasound-assisted thawing on the quality of edamames [Glycine max (L.) Merrill] frozen using different freezing methods. Food Sci. Biotechnol. 23(4):1095–1102.
  • Chevalier, D., Le Bail, A., Chourot, J. M., and Chantreau, P. (1999). High pressure thawing of fish (whiting): influence of the process parameters on drip losses. LWT-Food Sci. Technol. 32(1):25–31.
  • Chevalier, D., Le Bail, A., and Ghoul, M. (2000). Freezing and ice crystals formed in a cylindrical food model: part II. Comparison between freezing at atmospheric pressure and pressure-shift freezing. J. Food Eng. 46(4):287–293.
  • Chevalier, D., Sequeira-Munoz, A., Le Bail, A., Simpson, B. K., and Ghoul, M. (2000). Effect of pressure shift freezing, air-blast freezing and storage on some biochemical and physical properties of turbot (Scophthalmusmaximus). LWT-Food Sci. Technol. 33(8):570–577.
  • Delgado, A. E., Zheng, L., and Sun, D.-W. (2009). Influence of ultrasound on freezing rate of immersion-frozen apples. Food Bioprocess Technol. 2(3):263–270.
  • Delgado, A., and Sun, D.-W. (2001). Heat and mass transfer models for predicting freezing processes—a review. J. Food Eng. 47(3):157–174.
  • Delgado, A., and Sun, D.-W. (2011). Ultrasound-assisted freezing. In: Ultrasound Technologies for Food and Bioprocessing, pp. 495–509. New York: Springer.
  • Deora, N., Misra, N., Deswal, A., Mishra, H., Cullen, P., and Tiwari, B. (2013). Ultrasound for improved crystallisation in food processing. Food Eng. Revi. 5(1):36–44.
  • Díaz-Teborio, L. M., García-Carreño, F. L., and Pacheco-Aguilar, R. (2007). Comparison of freezing and thawing treatments on muscle properties of whiteleg shrimp (Litopenaeusvannamei). J. Food Biochem. 31(5):563–576.
  • Donsì, F., Ferrari, G., and Pataro, G. (2010). Applications of pulsed electric field treatments for the enhancement of mass transfer from vegetable tissue. Food Eng. Rev. 2(2):109–130.
  • Dymek, K., Dejmek, P., Galindo, F. G., and Wisniewski, M. (2015). Influence of vacuum impregnation and pulsed electric field on the freezing temperature and ice propagation rates of spinach leaves. LWT-Food Sci. Technol. 64(1):497–502.
  • Evans, J. A. (2008). Frozen Food Science and Technology. Hoboken, New Jersey: Wiley Online Library.
  • Farag, K., Duggan, E., Morgan, D., Cronin, D., and Lyng, J. (2009). A comparison of conventional and radio frequency defrosting of lean beef meats: effects on water binding characteristics. Meat Sci. 83(2):278–284.
  • Farag, K., Lyng, J., Morgan, D., and Cronin, D. (2011). A comparison of conventional and radio frequency thawing of beef meats: effects on product temperature distribution. Food Bioprocess Technol. 4(7):1128–1136.
  • Faridnia, F., Ma, Q. L., Bremer, P. J., Burritt, D. J., Hamid, N., and Oey, I. (2015). Effect of freezing as pre-treatment prior to pulsed electric field processing on quality traits of beef muscles. Innovative Food Sci. Emerging Technol. 29:31–40.
  • Fernández-Martín, F., Otero, L., Solas, M. T., and Sanz, P. (2000). Protein denaturation and structural damage during high-pressure-shift freezing of porcine and bovine muscle. J. Food Sci. 65(6):1002–1008.
  • Fikiin, K. (2003). Novelties of Food Freezing Research in Europe and Beyond. INRA, Institut national de la rechercheagronomique. Paris.
  • Froid, I., and Sørensen, L. B. (2006). Recommendations for the Processing and Handling of Frozen Foods. 4th ed. International Institute of Refrigeration. Paris, France.
  • Fuchigami, M., Kato, N., and Teramoto, A. (1997). High‐pressure‐freezing effects on textural quality of carrots. J. Food Sci. 62(4):804–808.
  • Fuchigami, M., and Teramoto, A. (1997). Structural and textural changes in kinu-tofu due to high-pressure-freezing. J. Food Sci. 62(4):828–837.
  • Gambuteanu, C., and Alexe, P. (2013). Effects of ultrasound assisted thawing on microbiological, chemical and technological properties of unpackaged pork longissimusdorsi. Food Technol. 37(1):98–107.
  • Gambuteanu, C., and Alexe, P. (2015). Comparison of thawing assisted by low-intensity ultrasound on technological properties of pork Longissimusdorsi muscle. J. Food Sci. Technol. 52(4):2130–2138.
  • Grimi, N., Mamouni, F., Lebovka, N., Vorobiev, E., and Vaxelaire, J. (2010). Acoustic impulse response in apple tissues treated by pulsed electric field. Biosystems Eng. 105(2):266–272.
  • Grimi, N., Mamouni, F., Lebovka, N., Vorobiev, E., and Vaxelaire, J. (2011). Impact of apple processing modes on extracted juice quality: pressing assisted by pulsed electric fields. J. Food Eng. 103(1):52–61.
  • Hanenian, R., and Mittal, G. (2004). Effect of freezing and thawing on meat quality. J. Food Agriculture Environment. 2:74–80.
  • Haugland, A. (2002). Industrial thawing of fish: to improve quality, yield and capacity. Department of Energy and Process Engineering. Norwegian University of Science and Technology, Trondheim, Norway, p. 191.
  • He, X., Liu, R., Nirasawa, S., Zheng, D., and Liu, H. (2013). Effect of high voltage electrostatic field treatment on thawing characteristics and post-thawing quality of frozen pork tenderloin meat. J. Food Eng. 115(2):245–250.
  • He, X., Liu, R., Tatsumi, E., Nirasawa, S., and Liu, H. (2014). Factors affecting the thawing characteristics and energy consumption of frozen pork tenderloin meat using high-voltage electrostatic field. Innovative Food Sci. Emerging Technol. 22:110–115.
  • Holzwarth, M., Korhummel, S., Carle, R., and Kammerer, D. R. (2012). Evaluation of the effects of different freezing and thawing methods on color, polyphenol and ascorbic acid retention in strawberries (Fragaria× ananassa Duch.). Food Res. Int. 48(1):241–248.
  • Hsieh, C. W., Lai, C. H., Ho, W. J., Huang, S. C., and Ko, W. C. (2010). Effect of thawing and cold storage on frozen chicken thigh meat quality by high‐voltage electrostatic field. J. Food Sci. 75(4):M193–M197.
  • Indergård, E., Tolstorebrov, I., Larsen, H., and Eikevik, T. (2014). The influence of long-term storage, temperature and type of packaging materials on the quality characteristics of frozen farmed Atlantic Salmon (SalmoSalar). Int. J. Refrigeration. 41:27–36.
  • Jalté, M., Lanoisellé, J.-L., Lebovka, N. I., and Vorobiev, E. (2009). Freezing of potato tissue pre-treated by pulsed electric fields. LWT-Food Sci. Technol. 42(2):576–580.
  • James, S., and James, C. (2002). Thawing and tempering. Meat Refrigeration, Woodhead Publishing, Cambridge. 159–190.
  • Jason, A., and Sanders, H. (1962). Dielectric thawing of fish. 1. Experiments with frozen herrings. Food Technol. 16(6):101.
  • Jiang, H., Zhang, M., and Mujumdar, A. S. (2010). Physico-chemical changes during different stages of MFD/FD banana chips. J. Food Eng. 101(2):140–145.
  • Jiao, Y., Tang, J., and Wang, S. (2014). A new strategy to improve heating uniformity of low moisture foods in radio frequency treatment for pathogen control. J. Food Eng. 141:128–138.
  • Jones, C. D. (1992). Method of preparing and storing a free flowing, frozen alimentary dairy product. U.S. Patent No. 5,126,156. 30 June 1992.
  • Kalichevsky, M., Knorr, D., and Lillford, P. (1995). Potential food applications of high-pressure effects on ice-water transitions. Trends Food Sci. Technol. 6(8):253–259.
  • Khadatkar, R., Kumar, S., and Pattanayak, S. (2004). Cryofreezing and cryofreezer. Cryogenics. 44(9):661–678.
  • Kiani, H., and Sun, D.-W. (2011). Water crystallization and its importance to freezing of foods: a review. Trends Food Sci. Technolo. 22(8):407–426.
  • Kiani, H., Sun, D.-W., Delgado, A., and Zhang, Z. (2012). Investigation of the effect of power ultrasound on the nucleation of water during freezing of agar gel samples in tubing vials. UltrasonicsSonochemistry. 19(3):576–581.
  • Kiani, H., Zhang, Z., Delgado, A., and Sun, D.-W. (2011). Ultrasound assisted nucleation of some liquid and solid model foods during freezing. Food Res. Int. 44(9):2915–2921.
  • Kiani, H., Zhang, Z., and Sun, D.-W. (2015). Experimental analysis and modeling of ultrasound assisted freezing of potato spheres. UltrasonicsSonochemistry. 26:321–331.
  • Kidmose, U., and Kaack, K. (1999). Changes in texture and nutritional quality of green asparagus spears (Asparagus officinalis L.) during microwave blanching and cryogenic freezing. Acta Agriculturae Scandinavica, Section B-Plant Soil Sci. 49(2):110–116.
  • Kissam, A., Nelson, R., Ngao, J., and Hunter, P. (1982). Water‐thawing of fish using low frequency acoustics. J. Food Sci. 47(1):71–75.
  • Kocadağlı, T., Palazoğlu, T. K., and Gökmen, V. (2012). Mitigation of acrylamide formation in cookies by using Maillard reaction products as recipe modifier in a combined partial conventional baking and radio frequency post-baking process. Eur. Food Res. Technol. 235(4):711–717.
  • LeBail, A., Chevalier, D., Mussa, D., and Ghoul, M. (2002). High pressure freezing and thawing of foods: a review. Int. J. Refrigeration. 25(5):504–513.
  • Li, B., and Sun, D.-W. (2002). Novel methods for rapid freezing and thawing of foods—a review. J. Food Eng. 54(3):175–182.
  • Li, B., and Sun, D.-W. (2002). Effect of power ultrasound on freezing rate during immersion freezing of potatoes. J. Food Eng. 55(3):77–282.
  • Li, W., Wang, P., Xu, X., Xing, T., and Zhou, G. (2014). Use of low-field nuclear magnetic resonance to characterize water properties in frozen chicken breasts thawed under high pressure. Eur. Food Res. Technol. 239(2):183–188.
  • Lind, M. L., Harrison, D. L., and Kropf, D. H. (1971). Freezing and thawing rates of lamb chops: effects on palatability and related characteristics. J. Food Sci. 36(4):629–631.
  • Llave, Y., Liu, S., Fukuoka, M., and Sakai, N. (2015). Computer simulation of radiofrequency defrosting of frozen foods. J. Food Eng. 152:32–42.
  • Llave, Y., Terada, Y., Fukuoka, M., and Sakai, N. (2014). Dielectric properties of frozen tuna and analysis of defrosting using a radio-frequency system at low frequencies. J. Food Eng. 139:1–9.
  • Loginova, K., Lebovka, N., and Vorobiev, E. (2011). Pulsed electric field assisted aqueous extraction of colorants from red beet. J. Food Eng. 106(2):127–133.
  • Lund, B. M. (2000). The Microbiological Safety and Quality of Food, pp. 122–145. Aspen. Press, Gaithersburg, MD.
  • Marra, F., Lyng, J., Romano, V., and McKenna, B. (2007). Radio-frequency heating of foodstuff: solution and validation of a mathematical model. J. Food Eng. 79(3):998–1006.
  • Marra, F., Zhang, L., and Lyng, J. G. (2009). Radio frequency treatment of foods: review of recent advances. J. Food Eng. 91(4):497–508.
  • Martino, M. N., Otero, L., Sanz, P., and Zaritzky, N. (1998). Size and location of ice crystals in pork frozen by high-pressure-assisted freezing as compared to classical methods. Meat Sci. 50(3):303–313.
  • Miles, C., Morley, M., and Rendell, M. (1999). High power ultrasonic thawing of frozen foods. J. Food Eng. 39(2):151–159.
  • Misra, N., Tiwari, B., Raghavarao, K., and Cullen, P. J. (2011). Nonthermal plasma inactivation of food-borne pathogens. Food Eng. Rev. 3(3–4):159–170.
  • Mousakhani-Ganjeh, A., Hamdami, N., and Soltanizadeh, N. (2015). Impact of high voltage electric field thawing on the quality of frozen tuna fish (Thunnusalbacares). J. Food Eng. 156:39–44.
  • Muadklay, J., and Charoenrein, S. (2008). Effects of hydrocolloids and freezing rates on freeze—thaw stability of tapioca starch gels. Food Hydrocolloids. 22(7):1268–1272.
  • Mujumdar, A. S., and Law, C. L. (2010). Drying technology: trends and applications in postharvest processing. Food Bioprocess Technol. 3(6):843–852.
  • Navarro, A., Martino, M., and Zaritzky, N. (1995). Effect of freezing rate on the rheological behaviour of systems based on starch and lipid phase. J. Food Eng. 26(4):481–495.
  • Norton, T., and Sun, D.-W. (2008). Recent advances in the use of high pressure as an effective processing technique in the food industry. Food Bioprocess Technol. 1(1):2–34.
  • Okamoto, A., and Suzuki, A. (2002). Effects of high hydrostatic pressure-thawing on pork meat. Progress Biotechnol. 19:571–576.
  • Orlowska, M., Havet, M., and Le-Bail, A. (2009). Controlled ice nucleation under high voltage DC electrostatic field conditions. Food Res. Int. 42(7):879–884.
  • Pan, B. S., and Yeh, W.-T. (1993). Biochemical and morphological changes in grass shrimp (Penaeusmonodon) muscle following freezing by air blast and liquid nitrogen methods. J. Food Biochem. 17(3):147–160.
  • Pham, Q. T. (2008). Advances in food freezing/thawing/freeze concentration modelling and techniques. Japan Soc. Food Eng. 9(1):21–32.
  • Phoon, P. Y., Galindo, F. G., Vicente, A., and Dejmek, P. (2008). Pulsed electric field in combination with vacuum impregnation with trehalose improves the freezing tolerance of spinach leaves. J. Food Eng. 88(1):144–148.
  • Puértolas, E., Luengo, E., Álvarez, I., and Raso, J. (2012). Improving mass transfer to soften tissues by pulsed electric fields: fundamentals and applications. Annual Rev. Food Sci. Technol. 3:263–282.
  • Purvis, T., Mattucci, M. E., Crisp, M. T., Johnston, K. P., and Williams, R. O. (2007). Rapidly dissolving repaglinide powders produced by the ultra-rapid freezing process. AAPS PharmSciTech. 8(3):E52–E60.
  • Rasmussen, C., and Olson, R. (1972). Freezing methods as related to cost and quality. Food Technol. 26(12):32–47.
  • Rouillé, J., Lebail, A., Ramaswamy, H., and Leclerc, L. (2002). High pressure thawing of fish and shellfish. J. Food Eng. 53(1):83–88.
  • Saclier, M., Peczalski, R., and Andrieu, J. (2010). Effect of ultrasonically induced nucleation on ice crystals' size and shape during freezing in vials. Chem. Eng. Sci. 65(10):3064–3071.
  • Sagar, V., and Kumar, P. S. (2010). Recent advances in drying and dehydration of fruits and vegetables: a review. J. Food Sci. Technol. 47(1):15–26.
  • Saulis, G. (2010). Electroporation of cell membranes: the fundamental effects of pulsed electric fields in food processing. Food Eng. Rev. 2(2):52–73.
  • Schlisselberg, D. B., Kler, E., Kalily, E., Kisluk, G., Karniel, O., and Yaron, S. (2013). Inactivation of foodborne pathogens in ground beef by cooking with highly controlled radio frequency energy. Int. J. Food Microbiol. 160(3):219–226.
  • Shayanfar, S., Chauhan, O., Toepfl, S., and Heinz, V. (2014). Pulsed electric field treatment prior to freezing carrot discs significantly maintains their initial quality parameters after thawing. Int. J. Food Sci. Technol. 49(4):1224–1230.
  • Sigfusson, H., Ziegler, G. R., and Coupland, J. N. (2004). Ultrasonic monitoring of food freezing. J. Food Eng. 62(3):263–269.
  • Singh, A., Orsat, V., and Raghavan, V. (2012). A comprehensive review on electrohydrodynamic drying and high-voltage electric field in the context of food and bioprocessing. Drying Technol. 30(16):1812–1820.
  • Soyer, A., Özalp, B., Dalmış, Ü., and Bilgin, V. (2010). Effects of freezing temperature and duration of frozen storage on lipid and protein oxidation in chicken meat. Food Chem. 120(4):1025–1030.
  • Stinco, C. M., Fernández-Vázquez, R., Heredia, F. J., Meléndez-Martínez, A. J., and Vicario, I. M. (2013). Bioaccessibility, antioxidant activity and colour of carotenoids in ultrafrozen orange juices: influence of thawing conditions. LWT-Food Sci. Technol. 53(2):458–463.
  • Tao, Y., and Sun, D.-W. (2015). Enhancement of food processes by ultrasound: a review. Critical Rev. Food Sci. Nutrition. 55(4):570–594.
  • Taylor, A. C. (1960). The physical state transition in the freezing of living cells. Annals the New York Acad. Sci. 85(2):595–609.
  • Tekle, E., Oubrahim, H., Dzekunov, S. M., Kolb, J. F., Schoenbach, K. H., and Chock, P. (2005). Selective field effects on intracellular vacuoles and vesicle membranes with nanosecond electric pulses. Biophysical J. 89(1):274–284.
  • Toner, M., Cravalho, E. G., and Karel, M. (1990). Thermodynamics and kinetics of intracellular ice formation during freezing of biological cells. J. Appl. Phys. 67(3):1582–1593.
  • Uyar, R., Bedane, T. F., Erdogdu, F., Palazoglu, T. K., Farag, K. W., and Marra, F. (2015). Radio-frequency thawing of food products—a computational study. J. Food Eng. 146:163–171.
  • Uyar, R., Erdogdu, F., and Marra, F. (2014). Effect of load volume on power absorption and temperature evolution during radio-frequency heating of meat cubes: a computational study. Food Bioproducts Process. 92(3):243–251.
  • Van Buggenhout, S., Messagie, I., Maes, V., Duvetter, T., Van Loey, A., and Hendrickx, M. (2006). Minimizing texture loss of frozen strawberries: effect of infusion with pectinmethylesterase and calcium combined with different freezing conditions and effect of subsequent storage/thawing conditions. Eur. Food Res. Technol. 223(3):395–404.
  • Vorobiev, E., and Lebovka, N. (2006). Extraction of intercellular components by pulsed electric fields. In Pulsed Electric Fields Technology for the Food Industry, pp. 153–193. New York: Springer.
  • Walkling-Ribeiro, M., Noci, F., Cronin, D. A., Lyng, J. G., and Morgan, D. J. (2010). Shelf life and sensory attributes of a fruit smoothie-type beverage processed with moderate heat and pulsed electric fields. LWT-Food Sci. Technol. 43(7):1067–1073.
  • Wang, Y., Zhang, L., Johnson, J., Gao, M., Tang, J. et al. (2014). Developing hot air-assisted radio frequency drying for in-shell macadamia nuts. Food Bioprocess Technol. 7(1):278–288.
  • Wang, Z., Wu, H., Zhao, G., Liao, X., Chen, F. et al. (2007). One-dimensional finite-difference modeling on temperature history and freezing time of individual food. J. Food Eng. 79(2):502–510.
  • Wen, X., Hu, R., Zhao, J. H., Peng, Y., and Ni, Y. Y. (2015). Evaluation of the effects of different thawing methods on texture, colour and ascorbic acid retention of frozen hami melon (Cucumismelo var. saccharinus). Int. J. Food Sci. Technol. 50(5):1116–1122.
  • Wiktor, A. D., Chudoba, T., and Witrowa-Rajchert, D. (2012). Influence of pulsed electric field on air freezing of apple tissue. Presented at International Conference of Agricultural Engineering CIGR-AgEng2012 Monographe.
  • Wiktor, A., Schulz, M., Voigt, E., Witrowa-Rajchert, D., and Knorr, D. (2015). The effect of pulsed electric field treatment on immersion freezing, thawing and selected properties of apple tissue. J. Food Eng. 146:8–16.
  • Work, T. M., Bushway, A. A., Work, R. W., and Pelletier, R. C. (1997). The effect of cryogenic freezing on the quality of soft and hard shell lobsters (Homarusamericanus). J. Aquatic Food Product Technol. 6(1):53–64.
  • Xin, Y., Zhang, M., and Adhikari, B. (2014). The effects of ultrasound-assisted freezing on the freezing time and quality of broccoli (Brassica oleracea L. var. botrytis L.) during immersion freezing. Int. J. Refrigeration. 41:82–91.
  • Xu, B., Zhang, M., Bhandari, B., and Cheng, X. (2014). Influence of power ultrasound on ice nucleation of radish cylinders during ultrasound-assisted immersion freezing. Int. J. Refrigeration. 46:1–8.
  • Xu, B.-G., Zhang, M., Bhandari, B., Cheng, X.-F. and Sun, J. (2015). Effect of ultrasound immersion freezing on the quality attributes and water distributions of wrapped red radish. Food Bioprocess Technol. 8(6):1366–1376.
  • Xu, Z., Guo, Y., Ding, S., An, K., and Wang, Z. (2014). Freezing by immersion in liquid CO2 at variable pressure: response surface analysis of the application to carrot slices freezing. Innovative Food Sci. Emerging Technol. 22:167–174.
  • Yaldagard, M., Mortazavi, S. A., and Tabatabaie, F. (2008). The principles of ultra high pressure technology and its application in food processing/preservation: a review of microbiological and quality aspects. African J. Biotechnol. 7(16):2739–2767.
  • Yu, S., Ma, Y., Zheng, X., Liu, X., and Sun, D.-W. (2012). Impacts of low and ultra-low temperature freezing on retrogradation properties of rice amylopectin during storage. Food Bioprocess Technol. 5(1):391–400.
  • Zhu, S., Ramaswamy, H., and Simpson, B. (2004). Effect of high-pressure versus conventional thawing on color, drip loss and texture of Atlantic salmon frozen by different methods. LWT-Food Sci. Technol. 37(3):291–299.
  • Zhu, X., Guo, W., Wu, X., and Wang, S. (2012). Dielectric properties of chestnut flour relevant to drying with radio-frequency and microwave energy. J. Food Eng. 113(1):143–150.

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