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New Quantitative Tracer Helps to Investigate Bioaccumulation of Nanoplastics in Freshwater Ecosystems

Nanoplastics (NPs) can cause a variety of adverse effects, including physical damage, oxidative stress, impaired cell signaling, and developmental defects. The monitoring of NPs in the environment still remains a challenge due to their properties of small particle sizes, different shapes and chemical compositions, easy aggregation and sedimentation.

Besides environmental monitoring, fate and behavior studies of NPs in the laboratory and controlled field could provide reliable and quantitative data for the toxicity, distribution, and bioaccumulation of NPs. To this end, labeling NPs with a tracer represents an effective way to track or quantify NPs in complex environments. 

A research team led by Prof. GUO Rongbo and Prof. FU Shanfei at the Qingdao Institute of Bioenergy and Process Technology (QIBEBT), Chinese Academy of Sciences (CAS), has developed a method for size- and surface charge-tunable core-shell Au@Nanoplastics (Au@NPs) synthesis, which can be used to study the environmental fate of NPs in an artificial freshwater system.

The study was published in Analytical Chemistry on Aug. 11.

The core-shell Au@NPs was synthesized through a three-step process that included synthesis of the Au core, prepolymerization of styrene, and polymerization. The Au core enables quantitative detection of NPs, while the polystyrene shell exhibits NP properties. The size of the core-shell Au@NPs could be well controlled by adjusting the polymerization reaction time, as well as the amount of styrene used.

 

The Au@NPs showed excellent resistance to environmental factors (e.g., 1% hydrogen peroxide solution, simulating gastric fluid, acids, and alkalis) and high recovery rates (>80%) from seawater, lake water, sewage, waste sludge, soil, and sediment, enabling them ideal for environmental fate and behavior studies of NPs in a variety of complex environmental systems.


Related research was presented as a cover paper by Analytical Chemistry.


Figure 1 Synthesis and characterization of Au@NPs. (Image by FU Shanfei)


Figure 2 Environmental resistance, recovery rate, and environmental behavior of freshwater systems of Au@NPs. (Image by FU Shanfei)

 

 

(Text by ZHU Honglu)

Contact:

KONG Fengru

Qingdao Institute of Bioenergy and Bioprocess Technology, Chinese Academy of Sciences

Tel: 86-532-58261072

E-mail: kongfr@qibebt.ac.cn

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