Persistent hormone distortion continues to affect fish populations

Despite Regulations, Hormone Distortion in English Rivers Persists

Despite two decades of regulations and infrastructure upgrades, the issue of hormone distortion among fish populations in English rivers persists, raising concerns among scientists. While the exposure of wild roach to hormone-altering chemicals has reduced compared to two decades ago, the existing levels still raise alarms.

The Phenomenon of Endocrine Disruption

The phenomenon of endocrine disruption, which triggers male fish to develop female proteins and generate eggs in their testes, has been acknowledged since the 1980s. The treated sewage that enters rivers carries a mixture of chemicals linked to the female sex hormone, oestrogen, encompassing naturally occurring substances and those commonly found in everyday items such as plastics, shampoos, and sunscreens. As wild fish absorb these chemicals through their gills, they can develop a blend of both male and female biological traits, commonly referred to as being ‘intersex.’

Persistent Concerns

A recent study published in Environmental Science and Technology unveils that despite efforts to enhance sewage treatment facilities and impose stricter regulations, the concern of fish hormone disruption persists. Dr. Alice Baynes from Brunel University London emphasizes that while the severity of male fish displaying female characteristics has diminished in many revisited sites, the impact of endocrine-disrupting chemicals on wild fish downstream from wastewater treatment plants in England remains evident.

Research on Roach Fish

For the past four decades, researchers have been studying the roach, a resilient and small silvery fish prevalent in UK rivers and many parts of Europe. In the 1990s and early 2000s, ecotoxicologists examined over 50 locations along UK rivers, both upstream and downstream from wastewater treatment facilities, for signs of endocrine disruption in fish. Some of the most adversely affected fish were found in rivers near Leeds, where high levels of alkylphenols—detergents used in textile production—were concentrated. These alkylphenols are closely regulated by the EU’s Water Framework Directive. The study also investigated the factors driving endocrine disruption, including naturally excreted oestrogens from both men and women, as well as pharmaceutical oestrogens used in contraceptives and hormone replacement therapy (HRT).

Ongoing Concerns

Although not mandated by regulations, many wastewater treatment plants have modernized over the past two decades. The Environment Agency commissioned the latest research to determine if endocrine disruption remains a concern. The recent study, conducted by a team from Brunel University London and the University of Exeter, revisited ten of the original river sites. Overall, wastewater treatment facilities now release fewer oestrogens into rivers. However, at 60% of the revisited sites, male roaches displayed intersex traits, with egg cells present in their testes. This irreversible alteration worsens with continuous exposure and negatively impacts breeding. Additionally, 90% of the sites showed male fish with elevated concentrations of female egg proteins, a sensitive indicator of estragon exposure, exceeding natural levels.

Water Treatment Methods

Various water treatment methods exhibit varying degrees of efficacy in removing oestrogens from wastewater. Processes like the activated sludge method, involving the infusion of oxygen into sewage tanks, are more efficient than methods like trickling filters, which involve passing sewage over stones. Incorporating tertiary treatments like sand filters and reed beds further enhance the removal process. A notable case is the Great Billing facility on the River Nene, which transitioned from trickling filters to the activated sludge process around 2001. This change correlated with fewer intersex roaches and reduced levels of female egg proteins in male fish. Among the rivers studied, the River Arun exhibited the highest prevalence of sex-reversed fish at 10.7%, where fish displayed entirely male or female genitalia but had the opposite genetic sex. In contrast, the River Lea and River Nene showed no instances of this phenomenon. Furthermore, the upstream section of the River Arun reported the highest count of intersex male fish at 40%. Other studied rivers included the Trent, Lea, Witham, Eye, Avon, Arun, and Bourne.

Call for Action

Dr. Baynes notes an intriguing shift in trends, mentioning that in the past, the extent of the issue was often linked to the size of the sewage treatment facility. However, recent findings indicate that some larger treatment plants, having received more investments and improvements, now exhibit better water quality compared to smaller facilities in towns and villages. This underlines the necessity for smaller sewage treatment plants to enhance their processes significantly to contribute to the health of river ecosystems.

SDGs, Targets, and Indicators

1. Which SDGs are addressed or connected to the issues highlighted in the article?

• SDG 6: Clean Water and Sanitation
• SDG 14: Life Below Water
• SDG 15: Life on Land

2. What specific targets under those SDGs can be identified based on the article’s content?

• SDG 6.3: By 2030, improve water quality by reducing pollution, eliminating dumping, and minimizing release of hazardous chemicals and materials.
• SDG 14.1: By 2025, prevent and significantly reduce marine pollution of all kinds, particularly from land-based activities, including marine debris and nutrient pollution.
• SDG 15.1: By 2020, ensure the conservation, restoration, and sustainable use of terrestrial and inland freshwater ecosystems and their services.

3. Are there any indicators mentioned or implied in the article that can be used to measure progress towards the identified targets?

• Indicator for SDG 6.3: Concentration of endocrine-disrupting chemicals in rivers and their impact on fish populations.
• Indicator for SDG 14.1: Presence of hormone-altering chemicals in rivers and their effect on fish populations.
• Indicator for SDG 15.1: Prevalence of intersex traits in fish populations as a result of exposure to endocrine-disrupting chemicals.

SDGs, Targets, and Indicators

4. Create a table with three columns titled ‘SDGs, Targets, and Indicators” to present the findings from analyzing the article. In this table, list the Sustainable Development Goals (SDGs), their corresponding targets, and the specific indicators identified in the article.

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Source: envirotech-online.com

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