posted on 2021-07-28, 22:15authored byHuan Chen, Tao Shi, Yue Wang, Zhiyong Liu, Fangcen Liu, Huanyu Zhang, Xingwen Wang, Zhuoyue Miao, Baorui Liu, Mimi Wan, Chun Mao, Jia Wei
The ability of nanomotors to promote
the deep penetration of themselves
and the loaded drugs in diseased tissues has been proposed and confirmed.
However, whether such motion behavior of the nanomotors can also promote
deep penetration of micrometer-sized immune cells in the diseased
microenvironment, which is important for the immunotherapy of some
diseases, has not been mentioned. Herein, we construct a nitric oxide
(NO)-driven nanomotor that can move in the tumor microenvironment,
focusing on its motion behavior and the role of NO, the beneficial
product released during movement from this kind of nanomotor, in regulating
the infiltration behavior and activity of immune cells. It can be
found that the drug-loaded nanomotors with both NO-releasing ability
and motility can promote the normalization of the tumor vasculature
system and the degradation of the intrinsic extracellular matrix (ECM),
which can significantly improve the tumor infiltration ability of
T cells in vivo. The efficiency of T-cell infiltration in tumor tissue
in vivo increased from 2.1 to 28.2%. Both subcutaneous and intraperitoneal
implantation tumor models can validate the excellent antitumor effect
of drug-loaded NO-driven nanomotors. This combination of motility
of the power source from nanomotors and their physiological function
offers a design idea for therapeutic agents for the future immunotherapy
of many diseases.