Journal of Fisheries & Livestock Production
Open Access

Cold chain management; Fish marketing; Seafood preservation; Post-harvest losses; Cold storage; Temperature-controlled logistics; Fish supply chain; Seafood safety; Fish quality assurance; Refrigeration technology; Transportation of perishable goods

Introduction

The cold chain plays a pivotal role in preserving the quality, safety, and market value of fish from the point of harvest to the consumer. With fish being highly perishable, an efficient and uninterrupted cold chain ensures minimal post-harvest losses, reduces spoilage, and maintains product freshness throughout the distribution process [1]. As global demand for seafood increases, advancements in cold chain technologies, infrastructure, and management are becoming essential to meet quality standards and regulatory requirements [2]. This paper explores the current state of cold chain systems in fish marketing, technological innovations, associated challenges, and strategies for sustainable development [3].

Discussion

An effective cold chain system is indispensable for maintaining the integrity and marketability of fish and seafood products. Given the perishable nature of fish, even slight deviations in temperature during storage or transport can lead to significant quality deterioration, economic losses, and health risks for consumers [4]. The discussion around cold chain in fish marketing centers on three main dimensions: infrastructure development, technological integration, and policy and regulatory frameworks [5]. Firstly, infrastructure gaps particularly in developing regions remain a critical barrier to efficient cold chain operations. Many fishing communities lack access to reliable cold storage, ice-making machines, and temperature-controlled vehicles [6]. These inadequacies lead to high post-harvest losses, reduced shelf life, and limited market access. Investing in decentralized cold chain units and upgrading existing facilities can greatly improve the marketing potential of fish products [7]. Secondly, technological advancements such as IoT-enabled sensors, GPS tracking, and real-time temperature monitoring have begun to transform the cold chain landscape. These tools enhance traceability and enable stakeholders to respond promptly to disruptions, thereby ensuring optimal storage conditions [8].

Blockchain technology is also emerging as a tool for maintaining transparent and immutable records throughout the seafood value chain, improving both food safety and consumer trust. Moreover, sustainability concerns are shaping cold chain strategies. Energy consumption and carbon footprint associated with refrigeration systems necessitate the adoption of eco-friendly practices [9]. Solar-powered cold storage, biodegradable packaging, and hybrid refrigeration units are gaining attention as greener alternatives. Policy and regulation also play a significant role. Government support in the form of subsidies, training programs, and public-private partnerships can boost infrastructure development and compliance with food safety standards. Harmonizing international standards for seafood cold chains is crucial for facilitating global trade and reducing quality disparities between markets [10].

Conclusion

The cold chain is a critical component of modern fish marketing, serving as the backbone for preserving quality, ensuring food safety, and extending the shelf life of highly perishable seafood products. As global demand for fish continues to grow, the importance of reliable, efficient, and sustainable cold chain systems cannot be overstated. Addressing infrastructure limitations, adopting smart technologies, and implementing environmentally conscious practices are essential steps toward minimizing post-harvest losses and maximizing market value. Furthermore, supportive policies and collaborative efforts across stakeholders from fishers to retailers are necessary to build resilient cold chain networks that meet both domestic and international standards. By prioritizing cold chain development, the fisheries sector can significantly enhance profitability, reduce waste, and contribute to a more sustainable and secure global food system. Ultimately, a robust cold chain system enhances not only the economic efficiency of fish marketing but also ensures food security, consumer health, and sustainability. To fully realize its benefits, coordinated efforts among fishers, processors, transporters, retailers, policymakers, and technologists are essential.

References

1. Deribe B, Taye M (2013) Growth performance and carcass characteristics of central highland goats in Sekota District, Ethiopia. Agricultural Advances 2: 250–258.

Google Scholar, Crossref, Indexed at

2. Banerjee A, Getachew A, Earmias E (2000) Selection and breeding strategies for increased productivity of goats in Ethiopia. The Opprotunities and Challenges for Enhancing Goat Production in East Africa. Proceedings of a Conference Held at Debub University, Awassa.

Google Scholar, Indexed at

3. Rekik M, Haile A, Mekuriaw Z, Abiebie A, Rischkowsky B, et al. (2016) Review of the reproductive performances of sheep breeds in Ethiopia. Review Paper 6: 117–126.

Google Scholar, Indexed at

4. CSA (2021) Federal Democratic Republic of Ethiopia Central Statistical Agency Agricultural Sample Survey 2020/21[ 2013 E.C.]. Volume II Report On. II (March).
5. Africa F (1996) Husbandry, Productivity and Producers Trait Preference of Goats in North Western Lowlands of Ethiopia. Open Journal of Animal Sciences 10: 313–335.

Google Scholar, Crossref

6. Minister B (2018) Performance evaluation of Abergelle goat under community based breeding program in selected districts, Northern Ethiopia. Livestock Research for Rural Development 30.

Google Scholar

7. Abegaz S, Sölkner J, Gizaw S, Dessie T, Haile A, et al. (2013) Description of production systems and morphological characteristics of Abergelle and Western lowland goat breeds in Ethiopia: implication for community-based breeding programmes. Animal Genetic Resources/Ressources Génétiques Animales/Recursos Genéticos Animales 53: 69–78.

Google Scholar, Crossref

8. Solomon A (2014) Design of community based breeding programs for two indigenous goat breeds of Ethiopia Design of community based breeding programs for two indigenous goat breeds of Ethiopia Co-supervisors.

Google Scholar, Indexed at

9. Taye M, Deribe B, Melekot MH (2013) Reproductive Performance of central highland goat under tradational managment in sekota district, Ethiopia. Asian Journal of Biological Sciences.

Google Scholar, Crossref, Indexed at

10. Amare B, Gobeze M, Wondim B (2020) Implementation of Community Based Breeding Program to Improve Growth Rate and Milk Production Performance of Abergelle Goat.  Online Journal of Animal and Feed Research.

Google Scholar, Crossref, Indexed at