When Blood Parts Ways: Phase Separation in Microstructured Environments

Abstract: Understanding how red blood cell (RBC) suspensions navigate porous materials is critical for for both fundamental physiology, such as maternal-fetal exchange in the placenta, and transformative biomedical applications, including rapid, low-cost disease diagnostics from a single drop of blood in resource-constrained settings. Here we elucidate how RBC movement through fibrous microporous structures is influenced by cell aggregation agents, emphasizing the impact of their clustering, membrane flexibility, and confinement. By varying the volume fraction of the RBC (hematocrit) and aggregation strength, we reveal a surprising phase separation: a dense RBC core surrounded by a cell-free layer, an effect not previously reported in whole blood studies. This separation is shown to be more pronounced with rigidified cells and persists even at high hematocrit levels, unlike in healthy samples. By connecting RBC deformability and aggregability to pore-mediated phase dynamics, our study provides a foundation for new diagnostic tools capable of classifying blood disorders or evaluating blood quality using only a sheet of structured paper, seamlessly integrating fundamental fluid mechanics with translational biomedical innovation in a previously unexplored manner.