Bioorthogonal catalysis via transition metal catalysts (TMCs) enables the generation of therapeutics locally through chemical reactions not accessible by biological systems. This localization can enhance the efficacy of anticancer treatment while minimizing off-target effects. The encapsulation of TMCs into nanomaterials generates “nanozymes” to activate imaging and therapeutic agents. Here, we report the use of cationic bioorthogonal nanozymes to create localized “drug factories” for cancer therapy in vivo. These nanozymes remained present at the tumor site at least seven days after a single injection due to the interactions between cationic surface ligands and negatively charged cell membranes and tissue components. The prodrug was then administered systemically, and the nanozymes continuously converted the non-toxic molecules into active drugs locally. This strategy substantially reduced the tumor growth in an aggressive breast cancer model, with significantly reduced liver damage compared to traditional chemotherapy.
Bioorthogonal nanozymes for breast cancer imaging and therapy / Z. Xianzhi, L. Yuanchang, D. Jeerapat, C. Laura J., S. Kristen N., J. Taewon, G. Ritabrita, S. Fedeli, G. Aarohi, H. Rui, H. Cristina-Maria, C. Roberto, P.K.D. Majhi, C. Yagiz Anil, L. Liang, J.J. D., V. Richard W., R. Vincent M.. - In: JOURNAL OF CONTROLLED RELEASE. - ISSN 1873-4995. - 357:(2023 May), pp. 31-39. [10.1016/j.jconrel.2023.03.032]
Bioorthogonal nanozymes for breast cancer imaging and therapy
S. Fedeli;
2023
Abstract
Bioorthogonal catalysis via transition metal catalysts (TMCs) enables the generation of therapeutics locally through chemical reactions not accessible by biological systems. This localization can enhance the efficacy of anticancer treatment while minimizing off-target effects. The encapsulation of TMCs into nanomaterials generates “nanozymes” to activate imaging and therapeutic agents. Here, we report the use of cationic bioorthogonal nanozymes to create localized “drug factories” for cancer therapy in vivo. These nanozymes remained present at the tumor site at least seven days after a single injection due to the interactions between cationic surface ligands and negatively charged cell membranes and tissue components. The prodrug was then administered systemically, and the nanozymes continuously converted the non-toxic molecules into active drugs locally. This strategy substantially reduced the tumor growth in an aggressive breast cancer model, with significantly reduced liver damage compared to traditional chemotherapy.
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