Numerical study of opposed zero-net-mass-flow jet-induced erythrocyte mechanoporation

With the advantages of biosafety and efficiency, increasing attention has been paid to the devices for gene and macromolecular drug delivery based on mechanoporation. The transient pore formation on the cell membrane allows cargo transportation when the membrane areal strain is beyond the critical pore value and below the lysis tension threshold. Based on this principle, we propose a method to apply the proper fluid stress on cells moving in a microchannel under the action of zero-net-mass-flux (ZNMF) jets. In this study, an immersed finite element method (IFEM) is adopted to simulate the interaction between the cells and the fluid fields so as to investigate the cell movement and deformation in this mechanoporation system. To evaluate the efficiency of the cargo delivery, a pore integral is defined as the mean pore rate when the cell passes through the jet region. By analyzing the effects of the parameters, including the pressure gradient along the microchannel, the jet amplitude, and the jet frequency, on the pore integrals, a group of optimized parameters for cargo delivery efficiency are obtained. Additionally, the stability and safety of this system are analyzed in detail. These results are helpful in designing the mechanoporation devices and improving their efficiency of drug delivery.

Automated summary

Gene and macromolecular drug delivery devices based on mechanoporation have attracted increasing attention due to their advantages in biosafety and efficiency. This study proposes a method to apply fluid stress on cells moving in a microchannel under zero-net-mass-flux (ZNMF) jets, allowing cargo transportation through transient pore formation. The immersed finite element method (IFEM) is used to simulate the interaction between cells and fluid fields, investigating cell movement and deformation in this mechanoporation system. By optimizing parameters such as pressure gradient, jet amplitude, and jet frequency, the efficiency of cargo delivery can be improved. Additionally, the stability and safety of the system are analyzed in detail. This research provides valuable insights for designing mechanoporation devices and enhancing drug delivery efficiency.