Research shows that the gills and olfactory organs of salmon respond to low levels of H₂S by activating genes that trigger the immune system.

New findings on salmon’s response to H2S in landbased fish farms

Researchers from Nofima and international collaborators have made important discoveries about how Atlantic salmon react to prolonged exposure to low levels of hydrogen sulphide (H2S) in recirculating aquaculture system (RAS).

Published

The study, published in Ecotoxicology and Environmental Safety, provides valuable insight for land-based salmon farming. The results could have significant implications for fish health and welfare in these systems.

Hydrogen sulphide is a toxic gas that can form in recirculating aquaculture systems (RAS), particularly at higher salinity levels. Even low levels of H2S have been linked to health problems and mortality in salmon. The recently published study looked at how salmon are affected by being in water with low amounts of hydrogen sulphide over an extended period, which can occur during normal production in RAS.

Researchers from Nofima have investigated how salmon mucosal surfaces (i.e. skin, gills, and nose), which are the first line of defense against environmental threats, react to prolonged exposure to low, non-lethal levels of H2S.

One of the key findings that the researchers made is that when salmon are exposed to hydrogen sulphide, the gills and olfactory organ in particular react by activating genes that help the fish cope with stress and activate the immune responses. Another finding is that salmon mucosae have natural ability for detoxifying hydrogen sulphide. The researchers also identified several protein markers in the mucus from the skin and gills that can be used for non-invasive testing for H2S response.

“Our findings suggest that salmon can largely adapt to the low H2S levels we tested, without serious negative health effects,” says project leader Carlo C. Lazado from Nofima, adding: “This is good news for the aquaculture industry, but also underscores the importance of careful monitoring and control of H2S levels in RAS facilities.”

The results can contribute to better farming of Atlantic salmon in several ways. One of the most important points that the researchers highlight in the report is improved risk assessment and setting of limit values for H2S in RAS facilities. There is potential here for developing new standards to strengthen salmon’s resistance to H2S exposure.

The study represents an important step towards more sustainable and efficient land-based salmon farming, with a focus on fish welfare and production quality. The findings are particularly relevant for land-based fish farms where H2S levels may be higher than in open sea facilities. By monitoring and controlling H2S levels, as well as implementing measures to strengthen the fish’s natural defenses, farmers can ensure healthier and more productive fish.