Professor, University of Quebec at Rimouski (UQAR)M Sc oceanography (laboratory of marine ecotoxicology, environmental analytical chemistry), University of Quebec at Rimouski (UQAR)Research scientist, University of Quebec in Montreal (UQAM)Zhe Lu received funding from the Natural Sciences and Engineering Research Council of Canada, Environment and Climate Change Canada and UQAR-ISMER for this project.Abigaëlle Dalpé-Castilloux received funding from FRQNT and Regroupement des écotoxicologues du Québec.Magali Houde received funding from Environment and Climate Change Canada.University of Quebec in Montreal (UQAM) and University of Quebec in Rimouski (UQAR) provide funding as founding partners of The Conversation CA-FR.University of Quebec in Montreal (UQAM) and University of Quebec in Rimouski (UQAR) provide funding as members of The Conversation CA.Ultraviolet (UV) absorbers and industrial antioxidants are contaminants attracting growing interest as they are found in a wide range of products that are used daily.These products include sunscreens, anti-aging creams and shampoos, and materials such as plastics and textiles, both domestic or industrial.Primarily, their use is to protect our skin and other consumer goods from the sun's UV radiation or from naturally occurring oxidizing agents in the air.Read more: Flame retardants, a real danger for wildlifeGiven their high versatility, there are several entry points for these contaminants into aquatic environments.Commonly targeted sources are municipal wastewater treatment plants' effluents, since they collect water from routine domestic and industrial uses.To improve the current knowledge of the Quebec situation, I studied the evolution of these contaminants in the St. Lawrence River near Montreal during my master's degree.With my colleagues, we present here the conclusions of this study.This article is part of our series, The St. Lawrence River: In depth.Don't miss new articles on this mythical river of remarkable beauty.Our experts look at its fauna, flora and history, and the issues it faces.This series is brought to you by The Conversation.As people shower, rinse water containing residues of sunscreens, shampoo and other personal care products, goes to wastewater treatment plants.Similarly, swimming in more tourist areas can lead to direct contamination of waterways.Another source is plastic pollution, which enters the aquatic environment through direct dumping, for example when people leave debris on beaches.Indirect plastic discharge also occurs through their presence in the effluents of domestic wastewater treatment plants.As plastics degrade, for example through exposure to sunlight, salinity or the prolonged contact with waves, the compounds they contain (such as UV absorbers and industrial antioxidants) can migrate to the environment.As soon as they enter the environment, these contaminants can disperse into sediments, water, and even among aquatic organisms, thereby harmonizing biodiversity and ecosystem health.Indeed, some of these compounds are suspected of causing harmful effects, including disrupting the hormonal system in exposed aquatic organisms and promoting coral bleaching.However, it is important to gain a better understanding of their distribution and evolution in aquatic environments in order to assess the current risk to species exposed to these contaminants.To better understand the fate of pollutants of interest in the St. Lawrence ecosystem, several types of samples were studied from upstream and downstream of the Montréal wastewater treatment centre.We collected water, suspended matter (which are insoluble particles visible in the water), sediment and tissues from two fish species, northern pike and lake sturgeon.The analysis results found several contaminants, confirming their presence in the St. Lawrence ecosystem.In addition, affinity for suspended matter was observed, with higher concentrations for some contaminants, indicating the importance of improving our understanding of the risks associated with ingesting suspended matter.Indeed, the latter can be an important route of accumulation for organisms.In comparing the dominant contaminants in the two fish studied, we observed a major difference between lake sturgeon and northern pike.This discrepancy can be caused by different factors, such as dietary differences between the two organisms.Northern pike is an opportunistic carnivore that feeds on what is easily available.Its main diet consists of yellow perch, suckers, sunfish and others.In comparison, lake sturgeon is a bottom predator that feeds on small organisms such as larvae, crayfish and small molluscs.This difference in lifestyles leads to a difference in the way the organisms are exposed to pollution and therefore the extent of contamination by certain pollutants.For example, if a contaminant has a greater affinity for sediment, organisms living near the bottom may be more affected by it.The results also show that BHT, an industrial antioxidant, and its breakdown product, BHTQ, were the only compounds found in the brain of northern pike.The effects of these contaminants on the nervous system of aquatic organisms are not well known at this time.An earlier study, however, demonstrated that BHT can accumulate in the rat brain and can lead to an increase in the number of dead cells.To our knowledge, this is the first finding of these toxic compounds in the St. Lawrence.Found mainly in plastics and paints, UV328 is a molecule of international interest monitored by the Stockholm Convention for its damaging effects on the liver and its potential for hormonal disruption.Its presence has been detected primarily in lake sturgeon, water, suspended matter and sediments of the river.The study highlighted the presence of contaminants of interest in the St. Lawrence River and identified UV328 and BHT as being of greater concern.On the other hand, there is still insufficient knowledge to understand the impact of these contaminants on the various organisms living in the St. Lawrence, particularly in terms of the effects of long-term exposures.Moreover, it is important to remember that aquatic organisms are subject to a mixture of several pollutants and that it is therefore essential to have a better understanding of the consequences of their interactions on the health of organisms.This article was originally published in EnglishThe cold war double agent abandoned by the spy agencies he risked his life for — VictoriaPolitics with Michelle Grattan Podcast — Australian Capital TerritoryScience of Healthy Hearing Podcast — Subiaco, Western AustraliaExecutive Master of Public Administration—Course, Victoria4th National Indigenous Art Triennial: Ceremony — Brisbane, QueenslandCopyright © 2010–2022, The Conversation Media Group Ltd