The Long-Term Fate of the Sonoporated Pancreatic Cancer Cells is Uncorrelated With the Degree of Model Molecular Loading.

Studies have determined that ultrasound-activated microbubbles can increase the membrane permeability of tumor cells by triggering membrane perforation (sonoporation) to improve drug loading. However, because of the distinct cavitation events adjacent to each cell, the degree of drug loading appeared to be heterogeneous. The relationship between the long-term fate trend and the degree of drug loading remains unclear. To investigate the time-lapse viability of diversity loading cells, fluorescein isothiocyanate–dextran (FITC-dextrans) was used as a molecular model mixed with 2% v/v SonoVue microbubbles (Bracco, Milan, Italy) and exposed to various peak negative pressures (0.25 MPa, 0.6 MPa, 1.2 MPa), 1 MHz frequency and 300 μs pulse duration. To select a suitable parameter, the cavitation activity was measured, and the cell analysis was performed by flow cytometry under these acoustic pressures. The sonoporated cells were then categorized into 3 sub-groups by flow cytometry according to the various fluorescence intensity distributions to analyze their long-term fate. We observed that the stable cavitation occurred at 0.25 MPa and microbubbles underwent ultra-harmonic emission, and obvious broadband signals were observed at 0.6 MPa and 1.2 MPa, suggesting the occurs of inertial cavitation. The cell analysis further showed the maximum delivery efficiency and cell viability at 0.6 MPa, and it was selected for the following experiment. The categorization displayed that the fluorescence intensity of FITC-dextrans in sub-groups 2 and 3 were approximate 5.62-fold and 19.53-fold higher than that in sub-group 1, respectively. After separation of these sub-groups, the apoptosis and necrosis ratios in all 3 sub-groups of sonoporated cells gradually increased with increasing culture time and displayed no significant difference in either the apoptosis (p > 0.05) or necrosis (p > 0.05) ratio after 6 h and 24 h of culture, respectively. Further analysis using Western blot verified that the long-term fate of sonoporated cells involves the mitochondrial signaling proteins. These results provide better insight into the role of cavitation-enhanced permeability and a critical guide for acoustic cavitation designs.