Project description:Microplastics represent a growing environmental concern for the oceans due to their potential capability to adsorb different classes of pollutants, thus representing a still unexplored source of exposure for aquatic organisms. In this study polystyrene (PS) microplastics were characterized for their capability to adsorb pyrene (PYR) as model compound for polycyclic aromatic hydrocarbons, and transfer this chemical to filter feeding mussels Mytilus galloprovincialis. Gene expression analyses of Mytilus galloprovincialis exposed to polystyrene (PS) microplastics and to polystyrene contaminated with pyrene (PS-PYR) have been performed trough a DNA microarray platform.

Project description:Microplastics (MPs) as widespread contamination pose high risk for aquatic organisms.Intestinal microbiotahas have high interaction with immune system of host body. In this study, intestinal microbiota of zebrafish after Polystyrene (PS-MPs) exposure were characterized by 16S rDNA amplicon sequencing. We found that 100nm and 200μm PS-MPs exposure significantly increased diversity of intestinal microbiota and all the three sizes of PS-MPs increased abundance of pathogenic bacteria.

Project description:Nanoplastics represent an emerging class of global environmental contaminants; however, their potential to interfere with human developmental processes remains largely unexplored. This study investigated the impact of exposure to polystyrene nanoplastics (PS-NP) on the de novo formation, differentiation, and function of human liver organoids derived from induced pluripotent stem cells (hiPSCs), a sophisticated model of early organogenesis.

Project description:Aims: Polystyrene microplastics (PS-MPs) are emerging environmental pollutants, but their impact on lung cancer treatment remains unclear. This study investigates how PS-MPs affect radiotherapy efficacy in lung cancer, focusing on their role in ferroptosis regulation and NF-κB pathway activation. Results: PS-MPs were rapidly internalized by lung cancer cells and remained detectable across multiple passages. Exposure to PS-MPs promoted lung cancer cell proliferation, increased mitochondrial length, and elevated Ki67 and c-Myc expression. Following ionizing radiation, PS-MPs significantly attenuated radiation-induced ferroptosis, as evidenced by reduced mitochondrial damage, lipid peroxidation, and GSH depletion. Transcriptomic analysis revealed that PS-MPs activated the NF-κB pathway, leading to increased phosphorylation of IKKβ, IκBα degradation, and enhanced nuclear translocation of NF-κB. In vivo, PS-MPs accumulated in lung tumor-bearing mice, reducing radiotherapy efficacy by increasing tumor volume and weight while decreasing survival rates. Knockdown of NF-κB restored ferroptosis sensitivity and mitigated PS-MPs-induced radioresistance, confirming the NF-κB-dependent inhibition of ferroptosis. Innovation and Conclusion: This study provides the first evidence that PS-MPs impair radiotherapy efficacy in lung cancer by suppressing ferroptosis via NF-κB activation. Unlike previous research focusing on microplastic toxicity in normal tissues, our findings highlight their oncological impact and potential role as an environmental factor influencing cancer therapy resistance. These results emphasize the need for further investigation into microplastics as emerging disruptors of redox homeostasis in oncology and their broader implications for environmental and cancer research.

Project description:Microplastics (MPs) as widespread contamination pose high risk for aquatic organisms. However, current understanding of MP toxicities are based on cell population-averaged measurements. Here we used single-cell RNA sequencing to provide the transcriptome heterogeneity of 12000 intestinal cells obtained from zebrafishes exposed to 100nm, 5μm and 200μm polystyrene MPs (PS-MPs) for 21 days. Eight intestinal cell populations were identified. We found that all the three sizes of PS-MPs induced dysfunction of intestinal immune cells (including phagosome and regulation of immune system process).

Project description:We combined human induced pluripotent stem cells (hiPSCs) and 3D printing to mass-produced liver Disse space-like organoids in microspheres hydrogels (DOs). After 5 days of co-culture, the cells within the microspheres were aggregated and developed into liver organoids, composed of iPSC-derived hepatocytes, endothelial cells, and hepatic stellate cells (LX2). These organoids mirrored the hepatotoxicity of polystyrene microplastics (PS-MPs), TBBPA, and complexes MPTA with healthy and patient-derived organoids.

Project description:In the past years, the research focus on the effects of microplastics (MP) on aquatic organisms extended from marine systems towards freshwater systems. An important freshwater model organism in the MP field is the cladoceran Daphnia, which plays a central role in lacustrine ecosystems and has been established as a test organism in ecotoxicology. To investigate the effects of MP on Daphnia magna, we performed a chronic exposure experiment with polystyrene MP under strictly standardized conditions. Chronic exposure of D. magna to PS microparticles led to a significant reduction in body length and number of offspring. To shed light on underlying molecular mechanisms induced by microplastic ingestion in D. magna, we assessed the effects of PS-MP at the proteomic level.

Project description:To assess the cellular effects of polystyrene (PS) micro- and nanoparticles, human pulmonary fibroblasts (HPFs) were exposed to spherical PS particles of two diameters (100 nm and 1 µm) across multiple concentrations. For 100 nm particles, the concentrations were 0.1 g/L (A), 0.01 g/L (B), and 0.001 g/L (C); for 1 µm particles, 0.1 g/L (A), 0.05 g/L (D), 0.01 g/L (B), and 0.001 g/L (C) were tested. In summary, our data show that both particle size and concentration critically influence the cellular response to microplastics. At low concentrations (0.001 g/L), smaller particles (100 nm) induced transcriptional activation of mitochondrial and biosynthetic genes, suggesting early metabolic adaptation. In contrast, high concentrations (0.1 g/L), particularly of larger particles (1 µm), led to suppression of metabolic, mitochondrial, and proteostatic pathways, indicating functional impairment and potential cellular stress.

Project description:Microplastics are defined as plastics ranging in size from 0.1μm to 5mm. Currently, research is being conducted across various fields to examine the effects of microplastics. Some studies demonstrated negative impacts on cells and mice. However, there is a lack of research on the effects by long-term exposure to microplastics. Most of the papers evaluated cytotoxicity with period of less than 2 months. Therefore, in this study, we investigated the potential issues that may arise from prolonged exposure through food mixed with Polystyrene microplastic (PS-MP) for over a year. We divided our study into short, mid, and long-term periods to assess cytotoxicity through Glucose tolerance test, Insulin tolerance test, analysis of insulin and c-peptide levels, hanging, grip, treadmill, Y-maze and open field tests, Respiratory Exchange Ratio, Energy Expenditure, Activity, and body composition. Through this, we comprehensively examined potential issues related to mouse behavior, muscle, metabolism and other factors. After dissection, RNA sequencing was carried out to investigate the effects on genes. For further verification, RT-qPCR was conducted. To summarize, our study provides evidence suggesting that treatment of microplastics for a short term has adverse effects, but with prolonged exposure, their effects tend to diminish.

Project description:Plastic is widely used in daily life, but it also brings serious environmental pollution. Plastic products can degrade into microplastic particles after physical, chemical, and biological processes, and microplastic particles can further degrade into nanoplastic particles. Microplastics and nanoplastic particles exist in water, atmosphere, and food, and enter the human body through the digestive and respiratory tracts, causing harm to animal and human health. In this study, Caenorhabditis elegans was exposed to a culture medium containing polystyrene plastic particles at a concentration of 1000 μ g/L to detect the healthy lifespan of the nematodes, further revealing the impact of polystyrene nanoparticles on human health and providing a theoretical basis for further evaluating the biological toxicity effects and potential health risks of polystyrene nanoparticles.