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Food Beverages Processing | India no 1 Food Processing Magazine

Exploring Cutting-Edge Technologies for Sustainable Seafood Freezing

Pravarthika, R. and P. Karthickumar*

College of Fisheries Engineering, TNJFU, Nagapattinam

*[email protected]

1. Introduction

            Seafood is highly perishable because it spoils quickly due to the growth of bacteria and changes in its natural enzymes. To keep seafood safe to eat and maintain its quality, it’s crucial to preserve it properly. The most common ways to do this are chilling, refrigeration, and freezing. Among these, freezing is widely used to keep seafood fresh for longer periods. Freezing works by lowering the temperature of the seafood until it becomes solid, which helps prevent spoilage. However, as the demand for seafood grows worldwide, it’s important to ensure that the freezing methods used are not only effective but also sustainable. Traditional freezing methods, while useful, sometimes fail to preserve the delicate texture and flavor of seafood and may also have a negative impact on the environment.

            In recent years, new and innovative freezing technologies have emerged, offering better ways to preserve seafood. These include advanced methods like cryogenic freezing, high-pressure processing, and others such as cold plasma and infrared heating. These cutting-edge techniques not only improve the quality of frozen seafood but also help reduce environmental impact. This article explores these new technologies and how they can be applied to make seafood freezing more sustainable.

2. Limitations of Existing Freezing Technologies

            Traditional freezing methods, such as blast freezing, plate freezing, immersion freezing, brine freezing, and even the more advanced cryogenic freezing, each come with specific limitations that can impact the quality of seafood and its sustainability.

            Blast freezing is a widely used method where cold air is circulated over the product to freeze it quickly. However, despite being economical, it is relatively slow compared to more modern techniques. This longer freezing time can cause larger ice crystals to form within the seafood, which may damage the texture and quality of the product. Plate freezing is another method where seafood is pressed between cooled plates. While this method is efficient and can freeze large quantities at once, it requires the seafood to be packed in blocks, limiting flexibility and sometimes affecting the product’s final appearance and convenience.

            Immersion freezing involves directly immersing the seafood in a cold liquid refrigerant. While this method can freeze seafood rapidly, it is now rarely used due to concerns about the potential for cross-contamination and changes in the product’s flavor. Similarly, brine freezing is an older method still used in some regions. It involves submerging the seafood in a cold brine solution, which can alter the natural taste of the product, making it salty or even bitter if certain chemicals are used.

            Lastly, cryogenic freezing offers a rapid and efficient way to freeze seafood using liquid nitrogen or CO2. While it is the fastest method available, it is also the most expensive, making it less accessible for widespread use, particularly in regions with limited resources. Moreover, the extreme cold temperatures can sometimes cause surface damage to delicate seafood, affecting its texture. These limitations highlight the need for more sustainable and advanced freezing technologies that can better preserve the quality of seafood while minimizing environmental impact.

3. Benefits of Sustainable Freezing Technologies

            The adoption of sustainable freezing technologies is essential for addressing several critical challenges in the seafood industry. These advanced methods help in reducing overfishing by preserving large quantities of seafood without compromising quality, allowing for better management of natural resources. Sustainable freezing also minimizes contamination risks, ensuring safer food products by reducing the chances of microbial growth and spoilage. Moreover, these technologies are designed to preserve the texture, flavor, and nutritional value of seafood, leading to higher quality products. By extending the shelf life of seafood, sustainable freezing techniques reduce food waste and make seafood available year-round, regardless of seasonal availability. Additionally, these practices are often more energy-efficient and environmentally friendly, as they consume less energy and produce fewer emissions compared to traditional methods. Overall, sustainable freezing technologies not only benefit consumers by providing high-quality seafood but also contribute to the long-term health of the environment and the seafood industry.

4. Innovative Freezing Technologies

            Innovative freezing technologies are revolutionizing the seafood industry by addressing the limitations of traditional methods and enhancing the quality, shelf life, and safety of frozen seafood. Here’s a look at some of these cutting-edge technologies:

4.1 Pressure Shift Freezing

            In pressure shift freezing, seafood is subjected to high pressure while being cooled to very low temperatures. When the pressure is suddenly released, ice forms evenly throughout the product, resulting in a smoother texture and better water retention. Although this method produces high-quality results, it is currently costly and not widely used in commercial settings.

4.2 Impingement Freezing

            Impingement freezing uses high-velocity air jets to rapidly cool seafood by breaking the thin layer of warm air that surrounds it. This technique is especially effective for thin products like fish fillets, as it quickly freezes the surface, preserving the product’s texture and moisture. Impingement freezing is already being used commercially and is valued for its speed and efficiency.

4.3 Hydrofluidization Freezing

            Hydrofluidization freezing involves immersing seafood in a liquid refrigerant that is circulated rapidly to create turbulence. This process allows for rapid and uniform freezing, which helps maintain the product’s quality. It’s similar to immersion freezing but more efficient, and it’s particularly useful for freezing smaller seafood items evenly.

44 Ultrasonic-Assisted Freezing

            Ultrasonic-assisted freezing uses sound waves to create tiny bubbles in the seafood, which helps form smaller ice crystals. This results in a finer texture and better quality after thawing. Additionally, this method can speed up the freezing process and even deactivate certain enzymes, reducing the need for pre-treatment like blanching.

4.5 Electrostatic-Assisted Freezing

            This method applies an electric field to the seafood, aligning water molecules to control the formation of ice crystals. By inducing nucleation at specific points, electrostatic-assisted freezing can lead to more uniform freezing and better texture preservation. While promising, this technology is still in the early stages of research and development.

4.6 Magnetic Freezing

            Magnetic freezing uses magnetic fields to manipulate water molecules during the freezing process, preventing the formation of large ice crystals. This helps maintain the integrity of seafood cells, resulting in a product that retains its original texture and flavor after thawing. Some commercial systems, like the Cells Alive System (CAS) in Japan, are already using this technology with successful results.

4.7 Ice Structuring Proteins (ISPs)

            Ice structuring proteins, found naturally in some organisms like polar fish, are used to control ice crystal growth during freezing. By adding ISPs to seafood, manufacturers can reduce the formation of large ice crystals, leading to better texture and reduced drip loss when the product is thawed. These proteins are particularly useful for maintaining the quality of frozen seafood over extended periods.

4.8 Isochoric Freezing

            Isochoric freezing is an innovative method where seafood is frozen under constant volume rather than constant pressure. This process limits ice formation inside the product, preserving its structure and texture. Isochoric freezing is especially effective for delicate seafood, like fish fillets, as it closely mimics the texture of fresh products even after freezing.

            These innovative technologies are paving the way for more sustainable and higher-quality seafood freezing practices, benefiting both consumers and the environment

5. Future Trends in Freezing Technology

            The future of freezing technology in the food industry is shaped by advances in science and technology, along with economic factors. As the global population grows and the demand for food increases, there’s a greater need for efficient and large-scale food production. This has led to the development of better freezing equipment that can handle continuous processing, making it easier to preserve large quantities of food. Economic factors, such as personal income and the cost of frozen products, also play a crucial role. To remain competitive, food producers need to offer high-quality frozen foods at the lowest possible cost, which drives the ongoing improvements in freezing methods. The industry is focusing on faster freezing rates and reducing costs through better mechanical handling and process control. As consumers’ preferences evolve and their knowledge of the nutritional value of frozen foods grows, the demand for frozen products is expected to continue rising. The future of the frozen food industry will depend on the ability to develop new technologies that enhance both the quality of frozen foods and the efficiency of the freezing process.

6. Conclusion

            The seafood freezing industry is rapidly advancing with the introduction of innovative technologies designed to overcome the limitations of traditional freezing methods. These new approaches promise to improve the texture and flavor of frozen seafood, reduce energy consumption, and minimize waste, all while supporting sustainability. This article has provided an overview of these cutting-edge freezing technologies and their potential impact on the seafood industry, highlighting how they could shape the future of seafood preservation.

7. References

  • Fikiin, K. A., & Fikiin, A. G. (1998). Individual quick freezing of foods by hydrofluidisation and pumpable ice slurries. In K. Fikiin (Ed.), Advances in the Refrigeration Systems, Food Technologies and Cold Chain: Proceedings of IIR Conference (pp. 319–326). International Institute of Refrigeration.
  • Islam, M. N., Zhang, M., Adhikari, B., Xinfeng, C., & Xu, B.-G. (2014). The effect of ultrasound-assisted immersion freezing on selected physicochemical properties of mushrooms. International Journal of Refrigeration. https://doi.org/10.1016/j.ijrefrig.2014.02.012
  • Levy, J., Dumay, E., Kolodziejczyk, E., & Cheftel, J. C. (1999). Freezing kinetics of model oil-in-water emulsion under high pressure or by pressure release: Impact on ice crystals and oil droplets. Lebensmittel-Wissenschaft Und-Technologie, 32(7), 396–405.
  • Otero, L., Rodriguez, A. C., Pérez-Mateos, M., & Sanz, P. D. (2016). Effects of magnetic fields on freezing: Application to biological products. Comprehensive Reviews in Food Science and Food Safety, 15(3), 646–667.
  • Rubinsky, B., Perez, P. A., & Carlson, M. E. (2005). The thermodynamic principles of isochoric cryopreservation. Cryobiology, 50(2), 121–138. https://doi.org/10.1016/j.cryobiol.2004.11.004

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