Red blood Cell-derived Extracellular Vesicles as biomaterials: the opportunity of freezing-induced accelerated aging

Red blood cell-derived extracellular vesicles (RBC-EVs) are emerging as promising biomaterials for next-generation drug delivery, due to their inherent biocompatibility, immune evasion capabilities, and minimal oncogenic risk. However, their clinical translation remains limited by unresolved challenges related to heterogeneity, reproducibility, and long-term storage.

This study proposes a method that leverages freezing-induced ageing for obtaining highly homogeneous RBC-EV batches, an important step towards using RBC-EVs as healthcare biomaterials and advancing their clinical translation in EV-based nanomedicine.

This method was made possible thanks to the analytical support of discontinuous sucrose density gradient and high-resolution interferometric nanoparticle tracking analysis, which allowed the identification of a bimodal subpopulation distribution, in terms of vesicle size, interferometric contrast, and subpopulation profiles, in freshly prepared samples, and then tracked how long-term cold storage at -80 °C channeled this heterogeneity into a monomodal population.

Finally, we evaluated the functionality of homogenized RBC-EV samples by assessing surface-associated enzymatic activity and uptake in cancer cell lines, demonstrating that freeze-thaw-induced accelerated-aging provides a viable strategy for producing RBC-EV preparations that retain membrane integrity and remain readily internalized by cells.

These findings offer valuable insights into the optimization and standardization of RBC-EV handling and storage protocols, providing a foundation for their reliable integration into EV-based therapeutic applications.