While monitoring data does exist for pharmaceuticals in rivers around the world, for many countries there is limited or no data.
Monitoring all of the pharmaceuticals we use in all rivers is extremely challenging, but the team at York say the new model could help to fill the data gaps.
The model will give scientists and drug manufacturers the ability to estimate the concentrations of pharmaceutical in Europe’s rivers. In the future it could be expanded to other regions of the world.
Known as ePiE (exposure to Pharmaceuticals in the Environment), the model uses prescription data to estimate the levels of drugs in the continent’s waterways, taking into account population, climate, river flow and geochemical factors.
The model has already been used in a pilot study to estimate levels of a selection of pharmaceuticals in the Ouse basin in the UK, and has identified three drugs (an antidepressant, antihistamine and painkiller) which could potentially be impacting on fish due to their high concentrations.
Areas at risk
Professor Alistair Boxall from the University’s Department of Environment and Geography and a co-author on the paper, said: “This model will allow us to identify which pharmaceuticals are potentially posing the most risk to the environment across Europe and the areas in Europe most at risk.
“To experimentally monitor pharmaceuticals, you have to physically take a sample from a river and then analyse the sample using sensitive instrumentation. This is expensive and time-consuming and, practically, it would be a mammoth task to sample every river system in Europe.
“This new model allows us to quickly determine the levels of pharmaceuticals across Europe at a very fine spatial resolution. It will allow us to much better characterise the risks that pharmaceuticals pose to river systems across Europe and help us to focus mitigation efforts to reduce risks.
“There are similar models that have been developed for the catchment and country level, but ePiE allows us to understand environmental exposure for the whole of Europe.”
Source : University of York