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Distinct adverse outcomes and lipid profiles of erythrocytes upon single and combined exposure to cadmium and microplastics
Summary
Researchers found that polystyrene microplastics and cadmium caused distinct types of anemia in mice when administered alone, with cadmium inducing microcytic hypochromic anemia while MPs caused polycythemia (overproduction of red blood cells). Combined exposure produced different erythrocyte lipid profiles than either contaminant alone, showing that MPs alter cadmium toxicity to red blood cells.
The growing accumulation of environmental microplastics (MPs) has become a global concern. MPs are capable to interact with other environmental contaminants leading to altered toxicity. Red blood cells (RBCs), are the target with highest priority for most of toxic xenobiotics after entering blood stream. Whether co-existence of MPs changes the toxicity of cadmium, a typical hemolysis inducer, in RBCs is unknown. We investigated the adverse effects of CdCl and Polystyrene-MPs (PS-MPs) on RBCs in mice. We found that CdCl induced mild microcytic hypochromic anemia while PS-MPs induced polycythemia vera, indicating distinct outcomes between them. Moreover, co-treatment of PS-MPs with CdCl did not change the phenotype of microcytic hypochromic anemia, indicating an antagonistic relationship between CdCl and PS-MPs. However, the lipid profiles were also distinct between single exposure and combined exposure to CdCl and PS-MPs. The significant changed lipids were mainly involved in altering the physiochemical or biological properties of RBCs, including decreased membrane components, disrupted bilayer thickness and intrinsic lipid curvature. These results indicated impaired membrane functions of RBCs. The altered lipid profiles observed in the current study may represent new and previously unrecognized harmful characteristics of cadmium and MPs on erythrocytes at low dose without apparent induction of anemia.
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