We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Impacts of extracellular polymeric substances on the behaviors of micro/nanoplastics in the water environment
Summary
This review examines how extracellular polymeric substances produced by microorganisms interact with micro- and nanoplastics in aquatic environments. Researchers found that these natural polymers can form coatings on plastic particles that enhance pollutant adsorption and promote sinking, influencing how microplastics are transported, distributed, and ultimately removed from the water column.
Increasing pollution of microplastics (MPs) and nanoplastics (NPs) has caused widespread concern worldwide. Extracellular polymeric substances (EPS) are natural organic polymers mainly produced by microorganisms, the major components of which are polysaccharides and proteins. This review focuses on the interactions that occur between EPS and MPs/NPs in the water environment and evaluates the effects of these interactions on the behaviors of MPs/NPs. EPS-driven formation of eco-corona, biofilm, and "marine snow" can incorporate MPs and NPs into sinking aggregates, resulting in the export of MPs/NPs from the upper water column. EPS coating greatly enhances the adsorption of metals and organic pollutants by MPs due to the larger specific surface area and the abundance of functional groups such as carboxyl, hydroxyl and amide groups. EPS can weaken the physical properties of MPs. Through the synergistic action of different extracellular enzymes, MPs may be decomposed into oligomers and monomers that can enter microbial cells for further mineralization. This review contributes to a comprehensive understanding of the dynamics of MPs and NPs in the water environment and the associated ecological risks.
Sign in to start a discussion.
More Papers Like This
Agglomeration of nano- and microplastic particles in seawater by autochthonous and de novo-produced sources of exopolymeric substances
Nano- and microplastic particles in seawater were found to readily form agglomerates with naturally produced exopolymeric substances, altering their surface properties, size, and sinking behavior compared to pristine particles. The study demonstrates that natural organic matter in seawater fundamentally changes how plastic particles behave and interact with marine organisms and sediments.
Molecular assembly of extracellular polymeric substances regulating aggregation of differently charged nanoplastics and subsequent interactions with bacterial membrane
Researchers used molecular simulations and experiments to study how bacteria produce natural coatings that change the behavior of nanoplastics in water. These biological coatings altered how nanoplastics clump together and interact with bacterial cell membranes, depending on the plastic's surface charge. Understanding these interactions is important because biological coatings in real environments could change how nanoplastics move through ecosystems and affect living organisms.
Sinking of microbial-associated microplastics in natural waters
Researchers investigated how microbial biofilm colonization of microplastics affects their buoyancy and sinking behavior in natural waters, finding that biological ballasting from attached microorganisms can significantly increase particle density and promote vertical transport toward sediments. The results suggest that biofouling is a key mechanism driving the removal of microplastics from surface waters.
Impact of different modes of adsorption of natural organic matter on the environmental fate of nanoplastics
Natural organic matter in water can stabilize nanoplastics by coating their surfaces and preventing them from clumping together and settling out, with different types of organic matter working through different physical mechanisms. Understanding this stabilization effect is important for predicting how long nanoplastics remain suspended in aquatic environments.
Interplay between microplastics and natural organic matter in association with environmental processes
This review explores how microplastics interact with natural organic matter—the dissolved and particulate carbon that permeates soils and waterways—and how these interactions alter microplastic transport, surface chemistry, and biological availability. Because natural organic matter coats microplastics and changes their behavior, ignoring this interplay leads to underestimates of how far and how dangerously microplastics spread through ecosystems.