Profiling the Physiological Roles in Fish Primary Cell Culture.

Simple Summary: The field of cell culture technology involves the cultivation of cells in a controlled environment, mimicking the natural conditions found in living organisms. This process is performed on a large scale, utilizing a specially designed culture medium. The goal is to create either undifferentiated individual cells or multicellular aggregates with minimal differentiation. The present paper offers a comprehensive overview of the advancements and applications of primary cell culture techniques in fish. It places a particular focus on revealing the physiological roles played by fish cells during their in vitro cultivation. Maintaining the functional characteristics of fish cells is of paramount importance, as it is essential for gaining a deeper understanding of the underlying mechanisms governing various physiological processes. To facilitate the use of fish cells in research and practical applications, it is crucial to standardize the separation techniques for these cells and optimize the conditions for their culture. This not only contributes to our knowledge of fish health, disease development, and drug discovery but also drives progress in the aquaculture industry. Fish primary cell culture has emerged as a valuable tool for investigating the physiological roles and responses of various cell types found in fish species. This review aims to provide an overview of the advancements and applications of fish primary cell culture techniques, focusing on the profiling of physiological roles exhibited by fish cells in vitro. Fish primary cell culture involves the isolation and cultivation of cells directly derived from fish tissues, maintaining their functional characteristics and enabling researchers to study their behavior and responses under controlled conditions. Over the years, significant progress has been made in optimizing the culture conditions, establishing standardized protocols, and improving the characterization techniques for fish primary cell cultures. The review highlights the diverse cell types that have been successfully cultured from different fish species, including gonad cells, pituitary cells, muscle cells, hepatocytes, kidney and immune cells, adipocyte cells and myeloid cells, brain cells, primary fin cells, gill cells, and other cells. Each cell type exhibits distinct physiological functions, contributing to vital processes such as metabolism, tissue regeneration, immune response, and toxin metabolism. Furthermore, this paper explores the pivotal role of fish primary cell culture in elucidating the mechanisms underlying various physiological processes. Researchers have utilized fish primary cell cultures to study the effects of environmental factors, toxins, pathogens, and pharmaceutical compounds on cellular functions, providing valuable insights into fish health, disease pathogenesis, and drug development. The paper also discusses the application of fish primary cell cultures in aquaculture research, particularly in investigating fish growth, nutrition, reproduction, and stress responses. By mimicking the in vivo conditions in vitro, primary cell culture has proven instrumental in identifying key factors influencing fish health and performance, thereby contributing to the development of sustainable aquaculture practices. [ABSTRACT FROM AUTHOR]