Principles and Methods of Counteracting Harmful Salmon–Arthropod Interactions in Salmon Farming: Addressing Possibilities, Limitations, and Future Options

Prashanna Guragain,Anna Solvang Båtnes,Atle M Bones,Yngvar Olsen,Per Winge,Max Tkachov

doi:10.3389/fmars.2021.701793

Prashanna Guragain, Anna Solvang Båtnes + Show 4 more

Open Access

https://doi.org/10.3389/fmars.2021.701793

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Abstract

The arthropod salmon louse (Lepeophtheirus salmonis) is a major threat to Atlantic salmon aquaculture and wild salmonids. Essentially like in monoculture, very high concentrations of susceptible hosts may result in high reproduction and severe production of waves of pests. Pest management is crucial both for fish health and protection of wild fish populations from aquaculture influence. Various methods have been utilized to control salmon lice infestations, such as pesticide use, physical treatments, construction modifications, fallowing, breeding, vaccination, and biological control. Most of the methods are partially successful, but none completely fulfills the necessary pest control strategy. Like in agriculture, lice/pest management is an arms race, but the marine environment makes it even more difficult to precisely hit the target pest and avoid unintended negative effects on general wildlife. In this study, we provide an overview of the methods and principles of salmon lice management and address current possibilities and limitations. We also highlight the potential of emerging strategies and enabling technologies, like genome editing, RNA interference, and machine learning, in arthropod management in aquaculture.

Highlights

Human population is projected to increase to 11.2 billion by the end of the century, and the buying power is expected to continue to increase (UN Economic & Social Affairs, 2019)
Agricultural losses due to arthropods are enormous (Bradshaw et al, 2016), and major attention has been paid to the study of terrestrial arthropods
Medical treatment has been widely used to combat the problem of sea lice, as it is the most productive and predictable measure (Aaen et al, 2015)

Summary

INTRODUCTION

Human population is projected to increase to 11.2 billion by the end of the century, and the buying power is expected to continue to increase (UN Economic & Social Affairs, 2019). The use of antibiotics in salmon farming in Norway alone has, for example, been reduced from approximately 2.13 μg/kg fish in 2006 to 0.14 μg/kg fish in 2019 (Directorate of Fisheries, 2020; Norwegian Institute of Public Health, 2020) mainly due to mass vaccination of juvenile salmonids During these years, the use of antibiotics has been drastically reduced in Scotland and Canada (Love et al, 2020). Salmon lice have a significant effect on salmonids during the marine part of their life cycle since they feed on fish mucus, blood, and epidermal tissues (Costello, 2006) The effects of these parasites on fish include physiological stress, growth reduction, immune system suppression, and osmoregulation imbalance (Johnson et al, 2004; Costello, 2006).

MEDICAL METHODS

Preventive Methods

Preventive methods Lice Skirt

Findings

Physical Methods