Aspects of conceptualization, development, and simulation of an extracellular vesicles' bulk isolation device for cosmetic and therapeutic applications

Abstract

This paper discusses the concept and model to develop a prototype extracellular vesicle bulk-isolation device (EBID). It proposes an engineering design and potential ways to mitigate limitations in the currently available extracellular vesicle (EV) isolation techniques. A more convenient isolation technique is developed and presented to ensure production-scale isolation and purification of the specific size of EV (approximately 0.1 to 0.34 µm) from a large quantity of cell-culture media or biological fluid sources. A more appropriate design concept was established based on the chitosan-assisted precipitation of EV techniques and the membrane filtration technology-based prototype. After that, a novel theoretical model for bulk isolation of EVs was developed and presented using pressure-driven circulation and particulate flow in the EBID loop, where the EV production results from the biofluid flowing through the EBID membrane filter module (MFM). Governing equations are coupled with Darcy's law to investigate the biofluid flow behavior in the EBID MFM, therefore simulating the isolation process of EVs from their biofluids. The flow characteristics of the EV isolation process within the EBID MFM are theoretically simulated and discussed for improved isolation yield with a high degree of quality and purity.