Spatially asymmetric cascade nanocatalysts for enhanced chemodynamic therapy
Minchao Liu, Hongyue Yu, Liang Chen, Tiancong Zhao, Meng Fang, Mengli Liu, Qiaoyu Zhou, Fatemah Farraj AlHarbi, Ahmed Mohamed El‐Toni, Fan Zhang, Dongyuan Zhao, Xiaomin Li
Abstract
Chemodynamic therapy (CDT) based on cascade catalytic nanomedicine has emerged as a promising cancer treatment strategy. However, most of the reported cascade catalytic systems are designed based on symmetric- or co-assembly of multiple catalytic active sites, in which their functions are difficult to perform independently and may interfere with each other. Especially in cascade catalytic system that involves fragile natural-enzymes, the strong oxidation of free-radicals toward natural-enzymes should be carefully considered, and the spatial distribution of the multiple catalytic active sites should be carefully organized to avoid the degradation of the enzyme catalytic activity. Herein, a spatially-asymmetric cascade nanocatalyst is developed for enhanced CDT, which is composed by a Fe 3 O 4 head and a closely connected mesoporous silica nanorod immobilized with glucose oxidase (mSiO 2 -GOx). The mSiO 2 -GOx subunit could effectively deplete glucose in tumor cells, and meanwhile produce a considerable amount of H 2 O 2 for subsequent Fenton reaction under the catalysis of Fe 3 O 4 subunit in the tumor microenvironment. Taking the advantage of the spatial isolation of mSiO 2 -GOx and Fe 3 O 4 subunits, the catalysis of GOx and free-radicals generation occur at different domains of the asymmetric nanocomposite, minimizing the strong oxidation of free-radicals toward the activity of GOx at the other side. In addition, direct exposure of Fe 3 O 4 subunit without any shelter could further enhance the strong oxidation of free-radicals toward objectives. So, compared with traditional core@shell structure, the long-term stability and efficiency of the asymmetric cascade catalytic for CDT is greatly increased by 138%, thus realizing improved cancer cell killing and tumor restrain efficiency.