The proliferation of microplastics and per- and polyfluoroalkyl substances (PFAS), known as "forever chemicals," represents a pressing global environmental and health crisis. These persistent pollutants are now ubiquitous, found in everything from drinking water and food to human blood and organs, with PFAS linked to significant health risks, including cancer. Microplastics can act as vectors for other contaminants like PFAS, exacerbating their environmental impact. However, a fundamental understanding of how these pollutants, with their complex sizes, and chemical compositions, interact with living systems at the cellular level is critically lacking.
The METABOLISM project addresses this knowledge gap by aiming to adapt and develop advanced physicochemical and biophysical techniques to understand the adsorption, attachment, and mechanical disruption of fluid interfaces and lipid bilayers—which mimic cell membranes—in the presence of these contaminants. The project's central objective is to create an integrated platform to simultaneously image and measure interfacial changes, thereby quantifying the dysfunction induced by pollutants. By investigating these interactions, METABOLISM seeks to provide crucial new knowledge on the health impacts of micro- and nanoplastic pollution and highlight the urgent need for improved remediation strategies.