Engineering the Surface of Ti 3 C 2 MXene Nanosheets for High Stability and Multimodal Anticancer Therapy

The surface of Ti C MXene nanosheets (TC NSs) was first modified with the antioxidants sodium ascorbate (SA) and dopamine (DA) (DSTC NS) to improve their stability in oxidative and hydration environments and thereby improve their bioapplications. This novel approach not only improved MXene stability...

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Veröffentlicht in:	Pharmaceutics 2022-01, Vol.14 (2)
Hauptverfasser:	Korupalli, Chiranjeevi, You, Kai-Long, Getachew, Girum, Rasal, Akash S, Dirersa, Worku Batu, Zakki Fahmi, Mochamad, Chang, Jia-Yaw
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container_title	Pharmaceutics
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creator	Korupalli, Chiranjeevi You, Kai-Long Getachew, Girum Rasal, Akash S Dirersa, Worku Batu Zakki Fahmi, Mochamad Chang, Jia-Yaw
description	The surface of Ti C MXene nanosheets (TC NSs) was first modified with the antioxidants sodium ascorbate (SA) and dopamine (DA) (DSTC NS) to improve their stability in oxidative and hydration environments and thereby improve their bioapplications. This novel approach not only improved MXene stability by arresting oxidation but also increased the available functional groups for further functionalization with various biomolecules. The DSTC NSs were then sequentially conjugated with enzyme glucose oxidase (GOx) and photosensitizer Ce6 to render the obtained CGDSTC NSs with glucose starvation and photodynamic therapeutic properties and thus attain high efficiency in killing cancer cells through the cooperative effect. The as-synthesized CGDSTC NSs demonstrated tremendous photothermal effect with conversion efficiency of 45.1% and photodynamic (ROS generation) properties upon irradiation with 808 and 671 nm lasers. Furthermore, it was observed that the enzymatic activity of CGDSTC NSs increased upon laser irradiation due to enhanced solution temperature. During in vitro studies, the CGDSTC NSs exhibited cytocompatability to HePG2 and HeLa cells under nonstimulus conditions. However, they elicited more than 90% cell-killing efficiency in the presence of glucose and laser irradiation via the cooperative effect between starvation therapy and phototherapy. These results indicate that CGDSTC NSs could be used as potential therapeutic agents to eradicate cancers with no or few adverse effects. This surface modification approach is also simple and facile to adopt in MXene-based research.
doi_str_mv	10.3390/pharmaceutics14020304
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title	Engineering the Surface of Ti 3 C 2 MXene Nanosheets for High Stability and Multimodal Anticancer Therapy
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