Design strategy of pH-sensitive triblock copolymer micelles for efficient cellular uptake by computer simulations

Efficient delivery of nanoparticles into specific cell interiors is of great importance in biomedicine. Recently, the pH-responsive micelle has emerged as one potential nanocarrier to realize such purpose since there exist obvious pH differences between normal tissues and tumors. Herein, by using dissipative particle dynamics simulation, we investigate the interaction of the pH-sensitive triblock copolymer micelles composed of ligand (L), hydrophobic block (C) and polyelectrolyte block (P) with cell membrane. It is found that the structure rearrangement of the micelle can facilitate its penetration into the lower leaflet of the bilayer. However, when the ligand-receptor specific interaction is weak, the micelles may just fuse with the upper leaflet of the bilayer. Moreover, the ionization degree of polyelectrolyte block and the length of hydrophobic block also play a vital role in the penetration efficiency. Further, when the sequence of the L, P, C beads in the copolymers is changed, the translocation pathways of the micelles may change from direct penetration to Janus engulfment. The present study reveals the relationship between the molecular structure of the copolymer and the uptake of the pH-sensitive micelles, which may give some significant insights into the experimental design of responsive micellar nanocarriers for highly efficient cellular delivery.