New Biosensors for Testing Water
Biologists from the University of Tübingen are part of an interdisciplinary team which has developed novel biosensors that enable pharmaceutical products to be detected more effectively in water. These sensors can measure two types of pharmaceutical substances, beta-blockers and non-steroidal anti-inflammatory drugs (NSAIDs), in real-time and in low concentrations. The research was recently published in Water Research.
As a consequence of demographic change, the consumption of medicines is increasing in industrial nations. Large amounts of pharmaceutical agents are already deposited at waste treatment facilities through waste water. As these substances usually cannot be removed effectively, surface water organisms are subjected to a cocktail of drugs. Just a few micrograms per liter are enough to cause harmful side effects in fish.
In the joint project “EffPharm” biologists, biochemists and analytical chemists are working to find a solution to the problem. The project is funded by the German Environment Agency (UBA) and coordinated by ecotoxicologist Professor Rita Triebskorn. In this context, the working group headed by Dr. Manfred Frey from the Steinbeis Innovation Center for Cell Culture Technology at the Mannheim University of Applied Sciences has succeeded in developing cell-based biosensors for two classes of drugs. These biosensors can detect the binding of such substances to their target molecules (receptors) in treated waste water in real time.
At the University of Tübingen, Professor Rita Triebskorn and Professor Heinz Köhler from the Animal Physiological Ecology working group have demonstrated these biosensors to be able to detect very low concentrations of the drugs at levels which are harmful to water organisms. Dr. Marco Scheurer from the Water Technology Center in Karlsruhe showed that the new biosensors capture a large proportion of the compounds that had previously been detected by complex and time-intensive chemical analysis.
The newly developed biosensors have many more advantages in contrast to previous approaches. After the biosensor cell lines are exposed to drugs in water samples, a fluorescence signal appears within seconds. In contrast to conventional reporter gene assays, the biosensors detect the effect of chemicals in the cell in real-time and avoid misleading information which may occur in reporter gene assays that take several hours to generate a signal. Thanks to their mechanism of action, the biosensors can detect future beta-blockers or NSAIDS without knowing their exact chemical structure.
"It would be desirable for the technology developed here to be used in monitoring programs to determine the water quality and the cleaning performance of sewage treatment plants," says Professor Rita Triebskorn. "This would close an important gap in the plausibility chain between the detection of pharmaceutical substances in water and the health effects of the organisms concerned."
Bernhard, K., Stahl, C., Martens, R., Köhler, H., Triebskorn, R., Scheurer, M., & Frey, M. (2017). Two novel real time cell-based assays quantify beta-blocker and NSAID specific effects in effluents of municipal wastewater treatment plants. Water Research, 115, 74-83. doi:10.1016/j.watres.2017.02.036
This article has been republished from materials provided by the University of Tübingen. Note: material may have been edited for length and content. For further information, please contact the cited source.
Neurochoice Big Idea Initiative to Fight Opioid Epidemic in USANews
Neurochoice brings together neuroscientists, psychologists, public policy scholars and others to tackle drug addiction and find better treatments and policies for dealing with the problem.READ MORE
Foods From Uncoated Aluminium Menu Trays Contain High Aluminium LevelsNews
A BfR research project, which examined several foods prepared in line with the rules of the Cook&Chill process before being kept warm, found high levels of aluminium.READ MORE
Comments | 0 ADD COMMENT
Outsourcing in Clinical Trials Southern California
Sep 27 - Sep 28, 2017