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Grazing zooplankton severely impacted by nanoplastic particles

Close-up of grazing zooplankton, daphnia
Grazing zooplankton, daphnia, which are an important source of food for fish, were found to be particularly vulnerable (Photo: Erik Selander/Lund University)

Researchers at Lund University in Sweden have studied how nanoplastic affects aquatic organisms in lakes and rivers. The results are surprising and the researchers are the first to show that some species are being wiped out, while others – such as cyanobacteria that contribute to algal blooms – are completely unaffected.

Every year, the amount of plastic in the world’s oceans increases by between five and 13 million tonnes. Over time, plastic breaks down into micro and nanoparticles that are invisible to the naked eye. Researchers at Lund University have investigated how these small plastic particles affect organisms in aquatic ecosystems. 

They found that some species of grazing zooplankton, daphnia, which are an important source of food for fish, were particularly vulnerable. Phytoplankton diatoms were also severely impacted. However, other types of algae, such as blue-green algae (cyanobacteria), which contribute to algal blooms, were completely unaffected.

“We don’t yet know why some collapse while others continue to thrive as usual. If the concentrations of nanoplastics increase, even those that can handle a few particles at present will also likely suffer,” says Lars-Anders Hansson, professor of aquatic ecology.
 

Container with artificial wetlands
The researchers conducted the study in artificial wetlands (Photo: Mikael Ekvall)

The researchers conducted the study in artificial wetlands, which are made as similar to natural systems as possible. Therefore, the results are likely to be transferable to natural ecosystems. Variations in the impact on different organisms lead to significant changes in the food chain and ecosystem processes, such as fewer grazing zooplankton and more extensive algal blooms.

“The concentrations of nanoplastics we used are low, quite close to the concentrations already present in our waters,” says Lars-Anders Hansson.

The researchers will now continue their experiments to find out how these insidious nanoplastic particles, which can penetrate cell membranes, affect different species in lakes and rivers.

“Taking a broader perspective, our study provides knowledge and the basis for future decision-making on how to deal with the obvious problems posed by plastic, even if it is also an excellent material in many aspects of our everyday lives,” says Lars-Anders Hansson.

Publication:

Link to the article in Communications Earth & Environment:

Nanoplastics rewire freshwater food webs