Effect of high-pressure processing on the physicochemical stability of yellowfin tuna (Thunnus albacares) during chilled storage

C.K. Kamalakanth; Ginson Joseph; J. Bindu; K. K. Asha; T.K. S. Gopal

doi:10.21077/ijf.2026.73.1.169857-14

Authors

C.K. Kamalakanth
Ginson Joseph School of Industrial Fisheries, Cochin University of Science and Technology (CUSAT), Kochi, Kerala, India
J. Bindu Central Institute of Fisheries Technology, Cochin 682029, Kerala, India
K. K. Asha
T.K. S. Gopal Kerala University of Fisheries and Ocean Studies

https://doi.org/10.21077/ijf.2026.73.1.169857-14

Keywords:

High Pressure Processing, Tuna, Physicochemical Changes, Chilled Storage

Abstract

The effect of pressurisation on the physicochemical properties of yellowfin tuna (Thunnus albacares) during low-temperature storage was studied. Tuna chunks were vacuumsealed in EVOH multilayer pouches and subjected to pressure treatments of 100, 200, and 300 MPa at 25°C for 5 min. Unpressurised samples, which underwent no pressure treatment, were maintained as controls. All samples were stored at 2±1°C throughout the study for subsequent analysis. At regular intervals, all samples were evaluated for biochemical indicators, including pH, trimethylamine (TMA), total volatile base nitrogen (TVB-N), and thiobarbituric acid (TBA), and physical parameters such as hardness and hue. pH in the samples increased slightly on storage. TBA content enhanced proportionally with the level of pressurisation of the samples and exhibited higher content in 300 MPa-treated samples. In contrast, TMA and TVB-N content in the tuna chunks showed an inverse relationship with pressurisation level, and lower levels of volatile base nitrogenous compounds were found in pressurised samples than in unpressurised samples. Application of pressure increased the hardness and lightness (L* values) of the samples. The control samples became unacceptable on the 20th day of storage, whereas all pressurised samples maintained better quality even up to 30 days. Among the samples, those treated with 200 MPa, exhibited the lowest lipid oxidation along with minimal changes in colour and texture.

Keywords: Chilled Storage, High Pressure Processing, Physicochemical Changes, Tuna

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Author Biographies

J. Bindu, Central Institute of Fisheries Technology, Cochin 682029, Kerala, India

Principal Scientist & Head (Fish Processing Division)

Central Institute of Fisheries Technology, Cochin 682029, Kerala, India
K. K. Asha

Principal Scientist & SIC (Scientist-in-Charge), Mumbai Regional Centre,

Central Institute of Fisheries Technology, Cochin 682029, Kerala, India
T.K. S. Gopal, Kerala University of Fisheries and Ocean Studies

Emeritus Scientist, Kerala University of Fisheries and Ocean Studies

Panangad P.O., Pin- 682 506, Kochi, Kerala, India

References

Amanatidou, A., Schlüter, O., Lemkau, K., Gorris, L.G.M., Smid, E.J. and Knorr, D., 2000. Effect of combined application of high pressure treatment and modified atmospheres on the shelf life of fresh Atlantic salmon. Innovative Food Science & Emerging Technologies, 1(2), pp.87-98.

Angsupanich, K. and Ledward, D.A., 1998. High pressure treatment effects on cod (Gadus morhua) muscle. Food Chemistry, 63(1), pp.39-50.

APHA 1998. Standard Methods for the Examination of Water and Waste Water 20th Ed (Washington: APHA).

Ashie, I.N., Smith, J.P. and Simpson, B.K., 1996. Spoilage and shelf-life extension of fresh fish and shellfish. Critcal Reviews Food Science and Nutrition, 36 (1-2), pp. 87-121.

Bourne, M.C. 1978. Texture profile analysis. Food Technology, 32, pp.62-66.

Cann, D. L., Smith, G. L. and Houston, N. G., 1983. Further studies on marine fish stored under modified atmosphere packaging. Aberdeen: Ministry of Agriculture Fisheries and Food, Torry Research Station.

Chang, G.W., Chang, W.L. and Lew, K.B., 1976. Trimethylamine‐specific electrode for fish quality control. Journal of Food Science, 41(3), pp.723-724.

Cheftel, J.C. and Culioli, J., 1997. Effects of high pressure on meat: A review. Meat Science, 46(3), pp.211-236.

Chevalier, D., Le Bail, A. and Ghoul, M., 2001. Effects of high pressure treatment (100–200 MPa) at low temperature on turbot (Scophthalmus maximus) muscle. Food Research International, 34(5), pp.425-429.

Connell, J. J. 1995. Control of fish quality (4th ed.). London: Fishing News Books Limited.

Conway, E. J. 1962. Microdiffusion Analysis and Volumetric Error (5th ed). Parch Goskey and Sockwood, London.

Erkan, N. and Üretener, G., 2010. The effect of high hydrostatic pressure on the microbiological, chemical and sensory quality of fresh gilthead sea bream (Sparus aurata). European Food Research and Technology, 230(4), pp.533-542.

Flores, S.C. and Crawford, D.L., 1973. Postmortem quality changes in iced pacific shrimp (Pandalus jordani). Journal of Food Science, 38(4), pp.575-579.

Hultin, H O, Mc-Donald, R. E., and Kelleher, S. D. 1982. Lipid oxidation in fish muscle microsomes. In: R. E. Martin., G. J. Flick, C. E. Hebard, & D. R. Ward. (Eds.). Chemistry and Biochemistry of Marine Food Products. AVI Publishing Co., Westport, CT. pp.1.

Hurtado, J.L., Montero, P. and Borderias, A.J., 2000. Extension of shelf life of chilled hake (Merluccius capensis) by high pressure. Food Science and Technology International, 6(3), pp.243-249.

Hyashi, R. 1989. Application of high pressure to food processing and preservation: Philosophy and development. In the Engineering and Food Species, E.E.L. and Schubert, H(ed), Elsevier Applied Science, England, 815.

Khayat, A., and Schwall, D., 1983. Lipid oxidation in seafood. Food Technology, 37(7), pp. 13-40.

Lakshmanan, P. T., 2000. Fish spoilage and quality assessment. In T. S. G. Iyer, M. K. Kandoran, Mary Thomas. and P. T. Mathew (Eds.), Quality assurance in seafood processing, Cochin, Society of Fisheries Technologists (India), pp. 26–40.

Ledward, D.A., 1998. High pressure processing of meat and fish. In Fresh novel foods by high pressure (Vol. 186, pp. 165-176). Espoo: VTT Biotechnology and Food Research.

Ludorff, W. and Meyer, V., 1973. Fische und Fischerzeugnisse Paul Parey. Verlag, Berlin und Hambg.[Google Scholar], pp.148-153.

Matser, A.M., Stegeman, D., Kals, J. and Bartels, P.V., 2000. Effects of high pressure on colour and texture of fish. International Journal of High Pressure Research, 19(1-6), pp.109-115.

Meilgaard, M., Civille, G. V. and Carr, B. T. 1999. Sensory evaluation techniques (3rd ed.). Boca Raton, Fla, CRC Press.

Miyake, M.P., Guillotreau, P., Sun, C.H. and Ishimura, G., 2010. Recent developments in the tuna industry: stocks, fisheries, management, processing, trade and markets. FAO Fisheries and Aquaculture Technical Paper. No. 543. Rome, FAO. 125.

Ohshima, T., Nakagawa, T. and Koizumi, C., 1992. Effect of high pressure on the enzymatic degradation of phospholipids in fish muscle during storage. In E. G. Bligh, Seafood science and technology (pp. 64-75). VTT Biotechnology and Food Research.

Ohshima, T., Ushio, H. and Koizumi, C., 1993. High-pressure processing of fish and fish products. Trends in Food Science & Technology, 4(11), pp.370-375.

Özoğul, F. and Özoğul, Y., 2000. Comparision of methods used for determination of total volatile basic nitrogen (TVB-N) in rainbow trout (Oncorhynchus mykiss). Turkish Journal of Zoology, 24(1), pp.113-120.

Ramirez-Suarez, J.C. and Morrissey, M.T., 2006. Effect of high pressure processing (HPP) on shelf life of albacore tuna (Thunnus alalunga) minced muscle. Innovative Food Science & Emerging Technologies, 7(1-2), pp.19-27.

Sequeira-Munoz, A., Chevalier, D., LeBail, A., Ramaswamy, H.S. and Simpson, B.K., 2006. Physicochemical changes induced in carp (Cyprinus carpio) fillets by high pressure processing at low temperature. Innovative Food Science & Emerging Technologies, 7(1-2), pp.13-18.

Tanaka, M., Zhuo, X, Y., Nagashima, Y. and Taguchi, T., 1991. Effect of high pressure on the lipid oxidation in sardine meat. Nippon Suisan Gakkaishi, 57(5), pp.957-963.

Tarladgis, B.G., Watts, B.M., Younathan, M.T. and Dugan Jr, L., 1960. A distillation method for the quantitative determination of malonaldehyde in rancid foods. Journal of the American Oil Chemists Society, 37(1), pp.44-48.

Torres, J.A. and Velazquez, G., 2005. Commercial opportunities and research challenges in the high pressure processing of foods. Journal of Food Engineering, 67(1-2), pp.95-112.

Varlik, C., Baygar, T., Özden, Ö., Erkan, N. and Mol, S., 2000. Sensory evaluation and determination of some physical and chemical characteristics of shrimp during gold storage. Turkish Journal of Veterinary & Animal Sciences, 24(3), pp.181-186.

Wu, T.H. and Bechtel, P.J., 2008. Ammonia, dimethylamine, trimethylamine, and trimethylamine oxide from raw and processed fish by-products. Journal of Aquatic Food Product Technology, 17(1), pp.27-38.

Yagiz, Y., Kristinsson, H.G., Balaban, M.O. and Marshall, M.R., 2007. Effect of high pressure treatment on the quality of rainbow trout (Oncorhynchus mykiss) and mahi mahi (Coryphaena hippurus). Journal of Food Science, 72(9), pp.C509-C515.

Yagiz, Y., Kristinsson, H.G., Balaban, M.O., Welt, B.A., Ralat, M. and Marshall, M.R., 2009. Effect of high pressure processing and cooking treatment on the quality of Atlantic salmon. Food Chemistry, 116(4), pp.828-835.

Zare, Z., 2004. High pressure processing of fresh tuna fish and its effects on shelf life (Doctoral dissertation, McGill University Montreal, Quebec, Canada).