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Toxicity of drugs released into waterways partly depends on acidity, study shows

  • Toxicity of drugs released into waterways partly depends on acidity, study shows

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Universität Tübingen
The University of Tübingen has been a place of top-level research and excellent teaching for more than 500 years.

A study by researchers from the Universities of Tübingen and Athens has found that the toxicity of chemicals in lakes and rivers may vary by several orders of magnitude depending on the water's acidity. Professor Heinz Köhler from the University of Tübingen's Institute of Evolution and Ecology, working with colleagues from Athens and the German Environment Agency, tested the effect of 24 substances, most of which are used as drugs, on the development of fish embryos in realistic scenarios.

The team developed a model for the reliable prediction of the toxicity of ionizable chemicals in bodies of water. The findings were taken into account by the European Commission at the end of 2022 in setting environmental quality standards to limit the drug ibuprofen. The study has been published in the journal Water Research.

For medicines to have the maximum effect, their active ingredients are designed to be difficult for the human body to break down; after that, a large proportion of the dose is excreted unchanged. Due to the increasing use of medicines by an aging population, ever-greater quantities of many different drugs are entering the environment via wastewater.

The substances investigated in the study, such as the painkillers diclofenac and ibuprofen, the cholesterol-lowering drug clofibric acid and the beta-blocker metoprolol, are ionizable molecules. This means they may exist in a neutral or electrically charged form. Bodies of water may have widely varying acid-base ratios, measured as pH. "All these factors influence the absorption of the substances into the cells of living organisms, which they can damage," says Heinz Köhler.

Looking at worst-case scenarios

The zebrafish served as the test organism. Its developing eggs were exposed to the chemicals. In each case, what's known as the LC50 value was determined, which reflects the pollutant concentration at which 50 percent of the fish embryos die. In the study, the researchers tested the toxicity of the chemicals at up to four different pH values, ranging from slightly acidic to alkaline water, in more than 1,200 individual tests.

On average, the substances proved to be more toxic in their uncharged state than in their ionized form

"For some active pharmaceutical ingredients, such as diclofenac, the beta-blocker propanolol and the antidepressant fluoxetine, the LC50 value in fish embryos varied more than a thousand-fold between pH 5 and pH 9," Köhler says.

The researchers set up realistic worst-case scenarios so that pharmaceuticals did not cause too much damage to living organisms when released into water and the worst conceivable conditions coincided. On average, the substances proved to be more toxic in their uncharged state than in their ionized form.

Reliable simulations

The research team built their respective modeling approaches based on various assumptions about how effectively the respective drug molecules penetrate the cell membrane and what harmful effect they might have in the cells. To simulate toxicity at different ambient water pH levels, they compared six mathematical models.

"For practical application, we selected the model that made it possible to reliably replicate the different toxic effects on fish across three orders of magnitude," says the researcher.

According to Köhler and the second lead author of the study, Dr. Peter von der Ohe of the German Environment Agency, the study results should have an impact on the registration and authorization of chemicals in the EU and on the definition of environmental quality standards. With the EU water limit value for ibuprofen eight times lower than it would have been under the previous method, a start has been made, he adds.

"This study contributes to a better understanding of the toxicity of ionizable substances and has significantly improved the prediction of their toxicity. We expect that our results will also be taken into account in the registration and approval of chemicals in the future," say the two researchers.

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