In-situ activation of biomimetic single-site bioorthogonal nanozyme for tumor-specific combination therapy
Copper-catalyzed click chemistry offers creative strategies for activation of therapeutics without disrupting biological processes. Despite tremendous efforts, current copper catalysts face fundamental challenges in achieving high efficiency, atom economy, and tissue-specific selectivity. Herein, we...
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sg-ntu-dr.10356-1806462024-10-16T02:15:21Z In-situ activation of biomimetic single-site bioorthogonal nanozyme for tumor-specific combination therapy Ma, Mengmeng Yuan, Wei Zhong, Wenbin Cheng, Yu Yao, Haochen Zhao, Yanli School of Chemistry, Chemical Engineering and Biotechnology Medicine, Health and Life Sciences Click chemistry Cell-specific therapy Copper-catalyzed click chemistry offers creative strategies for activation of therapeutics without disrupting biological processes. Despite tremendous efforts, current copper catalysts face fundamental challenges in achieving high efficiency, atom economy, and tissue-specific selectivity. Herein, we develop a facile "mix-and-match synthetic strategy" to fabricate a biomimetic single-site copper-bipyridine-based cerium metal-organic framework (Cu/Ce-MOF@M) for efficient and tumor cell-specific bioorthogonal catalysis. This elegant methodology achieves isolated single-Cu-site within the MOF architecture, resulting in exceptionally high catalytic performance. Cu/Ce-MOF@M favors a 32.1-fold higher catalytic activity than the widely used MOF-supported copper nanoparticles at single-particle level, as first evidenced by single-molecule fluorescence microscopy. Furthermore, with cancer cell-membrane camouflage, Cu/Ce-MOF@M demonstrates preferential tropism for its parent cells. Simultaneously, the single-site CuII species within Cu/Ce-MOF@M are reduced by upregulated glutathione in cancerous cells to CuI for catalyzing the click reaction, enabling homotypic cancer cell-activated in situ drug synthesis. Additionally, Cu/Ce-MOF@M exhibits oxidase and peroxidase mimicking activities, further enhancing catalytic cancer therapy. This study guides the reasonable design of highly active heterogeneous transition-metal catalysts for targeted bioorthogonal reactions. National Research Foundation (NRF) Financial support was provided by the National Research Foundation Singapore under Its Competitive Research Programme (NRF-CRP26-2021-0002). 2024-10-16T02:15:21Z 2024-10-16T02:15:21Z 2025 Journal Article Ma, M., Yuan, W., Zhong, W., Cheng, Y., Yao, H. & Zhao, Y. (2025). In-situ activation of biomimetic single-site bioorthogonal nanozyme for tumor-specific combination therapy. Biomaterials, 312, 122755-. https://dx.doi.org/10.1016/j.biomaterials.2024.122755 0142-9612 https://hdl.handle.net/10356/180646 10.1016/j.biomaterials.2024.122755 39151270 2-s2.0-85201186235 312 122755 en NRF-CRP26-2021-0002 Biomaterials © 2024 Elsevier Ltd. All rights are reserved, including those for text and data mining, AI training, and similar technologies. |
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Medicine, Health and Life Sciences Click chemistry Cell-specific therapy |
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Medicine, Health and Life Sciences Click chemistry Cell-specific therapy Ma, Mengmeng Yuan, Wei Zhong, Wenbin Cheng, Yu Yao, Haochen Zhao, Yanli In-situ activation of biomimetic single-site bioorthogonal nanozyme for tumor-specific combination therapy |
| description |
Copper-catalyzed click chemistry offers creative strategies for activation of therapeutics without disrupting biological processes. Despite tremendous efforts, current copper catalysts face fundamental challenges in achieving high efficiency, atom economy, and tissue-specific selectivity. Herein, we develop a facile "mix-and-match synthetic strategy" to fabricate a biomimetic single-site copper-bipyridine-based cerium metal-organic framework (Cu/Ce-MOF@M) for efficient and tumor cell-specific bioorthogonal catalysis. This elegant methodology achieves isolated single-Cu-site within the MOF architecture, resulting in exceptionally high catalytic performance. Cu/Ce-MOF@M favors a 32.1-fold higher catalytic activity than the widely used MOF-supported copper nanoparticles at single-particle level, as first evidenced by single-molecule fluorescence microscopy. Furthermore, with cancer cell-membrane camouflage, Cu/Ce-MOF@M demonstrates preferential tropism for its parent cells. Simultaneously, the single-site CuII species within Cu/Ce-MOF@M are reduced by upregulated glutathione in cancerous cells to CuI for catalyzing the click reaction, enabling homotypic cancer cell-activated in situ drug synthesis. Additionally, Cu/Ce-MOF@M exhibits oxidase and peroxidase mimicking activities, further enhancing catalytic cancer therapy. This study guides the reasonable design of highly active heterogeneous transition-metal catalysts for targeted bioorthogonal reactions. |
| author2 |
School of Chemistry, Chemical Engineering and Biotechnology |
| author_facet |
School of Chemistry, Chemical Engineering and Biotechnology Ma, Mengmeng Yuan, Wei Zhong, Wenbin Cheng, Yu Yao, Haochen Zhao, Yanli |
| format |
Article |
| author |
Ma, Mengmeng Yuan, Wei Zhong, Wenbin Cheng, Yu Yao, Haochen Zhao, Yanli |
| author_sort |
Ma, Mengmeng |
| title |
In-situ activation of biomimetic single-site bioorthogonal nanozyme for tumor-specific combination therapy |
| title_short |
In-situ activation of biomimetic single-site bioorthogonal nanozyme for tumor-specific combination therapy |
| title_full |
In-situ activation of biomimetic single-site bioorthogonal nanozyme for tumor-specific combination therapy |
| title_fullStr |
In-situ activation of biomimetic single-site bioorthogonal nanozyme for tumor-specific combination therapy |
| title_full_unstemmed |
In-situ activation of biomimetic single-site bioorthogonal nanozyme for tumor-specific combination therapy |
| title_sort |
in-situ activation of biomimetic single-site bioorthogonal nanozyme for tumor-specific combination therapy |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/180646 |
| _version_ |
1814777716337016832 |