Manipulation of ROS‐Responsiveness of Dextran with Thioether Side Chains

Reactive oxygen species (ROS) ‐responsive polymers based on thioether are widely used for drug delivery platforms for inflammation. However, the responsiveness of polymers containing thioether is not tunable toward acute and chronic inflammation, respectively. Here, two kinds of thioether molecules...

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Veröffentlicht in:	Macromolecular chemistry and physics 2022-09, Vol.223 (18), p.n/a
Hauptverfasser:	Xia, Yu, Chen, Runhai, Ke, Yue, Xiang, Zehong, Ma, Zhifang, Shi, Qiang, Ataullakhanov, Fazly I., Panteleev, Mikhail
Format:	Artikel
Sprache:	eng
Schlagworte:	Biocompatibility dextran Dextrans Grafting Hydrogen peroxide Hydroxyl groups Inflammation Molecular structure Nanoparticles NMR Nuclear magnetic resonance Oxidation Polymers reactive oxygen species ROS responsiveness thioether Toxicity
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container_title	Macromolecular chemistry and physics
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creator	Xia, Yu Chen, Runhai Ke, Yue Xiang, Zehong Ma, Zhifang Shi, Qiang Ataullakhanov, Fazly I. Panteleev, Mikhail
description	Reactive oxygen species (ROS) ‐responsive polymers based on thioether are widely used for drug delivery platforms for inflammation. However, the responsiveness of polymers containing thioether is not tunable toward acute and chronic inflammation, respectively. Here, two kinds of thioether molecules are grafted onto the hydroxyl groups of dextran in a simple and efficient manner. The grafted dextrans possess similar macromolecular structure and molecular weight and easily form nanoparticles. Cytotoxicity experiments confirm the good biocompatibility and antioxidant properties of the nanoparticles. The grafted dextran responds to typical ROS molecules in the order of ClO−, KO2, and H2O2. As for H2O2, the grafted dextran with ester group responds much faster than that of the carbonate group, with the former responding six times faster than the latter, which provides opportunities for the treatment of acute and chronic inflammation, respectively. It is demonstrated that the ester group near the thioether renders the oxidation reaction easier than that of carbonate groups because of its lower energy barrier, which is directly confirmed by an in situ nuclear magnetic resonance (NMR) investigation of the reaction between model molecules and H2O2 and theoretical computational simulations. In conclusion, the ROS responsiveness of grafted dextran can be tunable and the grafted dextran exhibits the potential application in inflammation‐involved disease. To investigate the influencing factors affecting the reactive oxygen species (ROS) responsiveness of thioether‐containing polymers, two different grafted dextran—grafted dextran with ester‐linked side chain (ESD) and grafted dextran with carbonate‐linked side chain (CSD)—are synthesized respectively. The results show that the ROS responsiveness of grafted dextran is tunable substantially with thioether structure in the side chains through qualitative and quantitative analysis.
doi_str_mv	10.1002/macp.202200106
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However, the responsiveness of polymers containing thioether is not tunable toward acute and chronic inflammation, respectively. Here, two kinds of thioether molecules are grafted onto the hydroxyl groups of dextran in a simple and efficient manner. The grafted dextrans possess similar macromolecular structure and molecular weight and easily form nanoparticles. Cytotoxicity experiments confirm the good biocompatibility and antioxidant properties of the nanoparticles. The grafted dextran responds to typical ROS molecules in the order of ClO−, KO2, and H2O2. As for H2O2, the grafted dextran with ester group responds much faster than that of the carbonate group, with the former responding six times faster than the latter, which provides opportunities for the treatment of acute and chronic inflammation, respectively. It is demonstrated that the ester group near the thioether renders the oxidation reaction easier than that of carbonate groups because of its lower energy barrier, which is directly confirmed by an in situ nuclear magnetic resonance (NMR) investigation of the reaction between model molecules and H2O2 and theoretical computational simulations. In conclusion, the ROS responsiveness of grafted dextran can be tunable and the grafted dextran exhibits the potential application in inflammation‐involved disease. To investigate the influencing factors affecting the reactive oxygen species (ROS) responsiveness of thioether‐containing polymers, two different grafted dextran—grafted dextran with ester‐linked side chain (ESD) and grafted dextran with carbonate‐linked side chain (CSD)—are synthesized respectively. 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It is demonstrated that the ester group near the thioether renders the oxidation reaction easier than that of carbonate groups because of its lower energy barrier, which is directly confirmed by an in situ nuclear magnetic resonance (NMR) investigation of the reaction between model molecules and H2O2 and theoretical computational simulations. In conclusion, the ROS responsiveness of grafted dextran can be tunable and the grafted dextran exhibits the potential application in inflammation‐involved disease. To investigate the influencing factors affecting the reactive oxygen species (ROS) responsiveness of thioether‐containing polymers, two different grafted dextran—grafted dextran with ester‐linked side chain (ESD) and grafted dextran with carbonate‐linked side chain (CSD)—are synthesized respectively. 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However, the responsiveness of polymers containing thioether is not tunable toward acute and chronic inflammation, respectively. Here, two kinds of thioether molecules are grafted onto the hydroxyl groups of dextran in a simple and efficient manner. The grafted dextrans possess similar macromolecular structure and molecular weight and easily form nanoparticles. Cytotoxicity experiments confirm the good biocompatibility and antioxidant properties of the nanoparticles. The grafted dextran responds to typical ROS molecules in the order of ClO−, KO2, and H2O2. As for H2O2, the grafted dextran with ester group responds much faster than that of the carbonate group, with the former responding six times faster than the latter, which provides opportunities for the treatment of acute and chronic inflammation, respectively. It is demonstrated that the ester group near the thioether renders the oxidation reaction easier than that of carbonate groups because of its lower energy barrier, which is directly confirmed by an in situ nuclear magnetic resonance (NMR) investigation of the reaction between model molecules and H2O2 and theoretical computational simulations. In conclusion, the ROS responsiveness of grafted dextran can be tunable and the grafted dextran exhibits the potential application in inflammation‐involved disease. To investigate the influencing factors affecting the reactive oxygen species (ROS) responsiveness of thioether‐containing polymers, two different grafted dextran—grafted dextran with ester‐linked side chain (ESD) and grafted dextran with carbonate‐linked side chain (CSD)—are synthesized respectively. 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subjects	Biocompatibility dextran Dextrans Grafting Hydrogen peroxide Hydroxyl groups Inflammation Molecular structure Nanoparticles NMR Nuclear magnetic resonance Oxidation Polymers reactive oxygen species ROS responsiveness thioether Toxicity
title	Manipulation of ROS‐Responsiveness of Dextran with Thioether Side Chains
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