Microplastics weathered by water are more likely to infiltrate an animal’s cells
Kasra Zarei for Environmental Health News
Microplastic
particles exposed to freshwater or saltwater environments are more likely than
original, non-exposed particles to be taken up into an animal's cells,
according to new research.
The
study offers new evidence that certain microplastics have more potential to
infiltrate animals' bodies than previously thought – and this could be of
particular concern for aquatic animals.
Microplastics,
or tiny pieces of plastic, are everywhere, including Mount Everest. Over
time, plastics discarded by humans break down into small pieces and spread
across the environment, especially marine and freshwater ecosystems, and are
consumed by organisms including mussels and zebrafish.
But
so much about microplastics has not been studied, including whether particles
can enter the cells of different animals and organisms and cause health risks,
or affect the environment.
"There are plenty of knowledge gaps," Christian Laforsch, professor of animal ecology at the University of Bayreuth and senior author of the study, told EHN. "For instance, microplastics go from the digestive tract into the tissue [of certain aquatic organisms], but no one knows exactly why."
In the new study, Laforsch and colleagues found that microplastics exposed to freshwater or saltwater for several weeks are around 10 times more likely to enter the cells of mice compared to pristine particles.
While the study was
only done using mice cells, it's possible that a similar relationship could be
observed in aquatic animals that encounter such non-pristine microplastics on a
regular basis, which could also have further unknown implications for their
predators (including humans).
These
microplastic particles develop a coating of other molecules and microorganisms
– acting somewhat like a "Trojan horse": other cells are more likely
to engulf the coated microplastic particles (compared to pristine, uncoated
particles), which can then potentially infiltrate an organism's circulatory
system.
However,
the results don't necessarily suggest that microplastics exposed to freshwater
or saltwater pose a greater health risk to human or other organisms – that
still needs to be studied further.
"We
can't make direct conclusions about the health effects [of the microplastics
studied]," Holger Kress, a professor of biological physics at the
University of Bayreuth who was also involved in the study, told EHN.
While
there is research about the health risks of inhaling
particulate matter, little is known about the health effects of
microplastics. Still, the new research adds one piece to a big puzzle.
Many
physical and biological properties – for instance, the texture, charge, or size
– of a particle may be responsible for the environmental and health effects of
microplastics. And understanding which properties are responsible is a
step-by-step scientific process.
"It
[the field of microplastics] is such a complex topic, but you have to start
somewhere," Laforsch said. "If we know what plastic properties might
be toxic, we can design properties that might not harm the environment."
Furthermore,
pristine particles have been primarily used in microplastic-related
toxicological studies to date. But plastic particles in nature are often far
from pristine.
"A
lot of plastics spend time spiraling through the environment, and the watershed
is an active vector to transport them to an aquatic environment," Janice
Brahney, an assistant professor of watershed sciences at Utah State University
who was not involved in the study, told EHN.
Brahney,
who recently published a study showing
how many microplastic particles accumulate in isolated areas of the United
States, notes that the microplastics she has observed through her previous work
have in fact not been pristine.
She
adds that because the plastics are so long-lived, "it's very plausible
that most environmental plastics will have some aquatic lifetime."
Pristine
microplastics are not very representative of those found in the environment,
both in terms of physical properties and how likely they are to get absorbed by
an organism. And this may cause scientists to reconsider how they study
microplastics in the laboratory going forward.
"The laboratory studies that only use pristine particles may strongly underestimate the strength of interaction between an organism's cells and the particles," Kress said.
