Nanoclustered Cascaded Enzymes for Targeted Tumor Starvation and Deoxygenation-Activated Chemotherapy without Systemic Toxicity

Nanoclustered Cascaded Enzymes for Targeted Tumor Starvation and Deoxygenation-Activated Chemotherapy without Systemic Toxicity

Intratumoral glucose depletion-induced cancer starvation represents an important strategy for anticancer therapy, but it is often limited by systemic toxicity, nonspecificity, and adaptive development of parallel energy supplies. Herein, we introduce a concept of cascaded catalytic nanomedicine by c...

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Veröffentlicht in:ACS nano 2019-08, Vol.13 (8), p.8890-8902
Hauptverfasser: Ma, Yinchu, Zhao, Yangyang, Bejjanki, Naveen Kumar, Tang, Xinfeng, Jiang, Wei, Dou, Jiaxiang, Khan, Malik Ihsanullah, Wang, Qin, Xia, Jinxing, Liu, Hang, You, Ye-Zi, Zhang, Guoqing, Wang, Yucai, Wang, Jun
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container_end_page 8902
container_issue 8
container_start_page 8890
container_title ACS nano
container_volume 13
creator Ma, Yinchu
Zhao, Yangyang
Bejjanki, Naveen Kumar
Tang, Xinfeng
Jiang, Wei
Dou, Jiaxiang
Khan, Malik Ihsanullah
Wang, Qin
Xia, Jinxing
Liu, Hang
You, Ye-Zi
Zhang, Guoqing
Wang, Yucai
Wang, Jun
description Intratumoral glucose depletion-induced cancer starvation represents an important strategy for anticancer therapy, but it is often limited by systemic toxicity, nonspecificity, and adaptive development of parallel energy supplies. Herein, we introduce a concept of cascaded catalytic nanomedicine by combining targeted tumor starvation and deoxygenation-activated chemotherapy for an efficient cancer treatment with reduced systemic toxicity. Briefly, nanoclustered cascaded enzymes were synthesized by covalently cross-linking glucose oxidase (GOx) and catalase (CAT) via a pH-responsive polymer. The release of the enzymes can be first triggered by the mildly acidic tumor microenvironment and then be self-accelerated by the subsequent generation of gluconic acid. Once released, GOx can rapidly deplete glucose and molecular oxygen in tumor cells while the toxic side product, i.e., H2O2, can be readily decomposed by CAT for site-specific and low-toxicity tumor starvation. Furthermore, the enzymatic cascades also created a local hypoxia with the oxygen consumption and reductase-activated prodrugs for an additional chemotherapy. The current report represents a promising combinatorial approach using cascaded catalytic nanomedicine to reach concurrent selectivity and efficiency of cancer therapeutics.
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title Nanoclustered Cascaded Enzymes for Targeted Tumor Starvation and Deoxygenation-Activated Chemotherapy without Systemic Toxicity
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