Catalase‐Mimetic Artificial Biocatalysts with Ru Catalytic Centers for ROS Elimination and Stem‐Cell Protection

Sun, Yimin; Mu, Shengdong; Xing, Zhenyu; Guo, Jiusi; Wu, Zihe; Yu, Fanyuan; Bai, Mingru; Han, Xianglong; Cheng, Chong; Ye, Ling

doi:10.1002/adma.202206208

Cited by 52 publications

(35 citation statements)

References 57 publications

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“…In recent years, given the enormous benefits of antioxidase-like biocatalysts, such as efficient biocatalytic activity to preserve redox balance, low antigenicity, high stability after administration, and large-scale production, , there has been dramatically increased interest in designing biocatalysts via diverse transition metal compounds and metal nanoparticles that can mimic the function of natural antioxidases, including catalase (CAT), glutathione peroxidase (GPx), and superoxide dismutase (SOD). − Despite thrilling progress in discovering catalytic ROS-scavenging materials, , the development of ultrafast and broad-spectrum antioxidase-like catalytic structures is still a grand challenge. They are mostly based on metal compounds, such as Co 3 O 4 , MnO 2 , CeO 2 , , and Pt-doped CeO 2 , due to their high biodegradability and good biocompatibility.…”

Section: Introductionmentioning

confidence: 99%

Amorphizing Metal Selenides-Based ROS Biocatalysts at Surface Nanolayer toward Ultrafast Inflammatory Diabetic Wound Healing

Deng

Gao

et al. 2023

ACS Nano

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The microenvironments with high reactive-oxygen-species (ROS) levels, inflammatory responses, and oxidative-stress effects in diabetic ulcer wounds, leading to poor proliferation and differentiation of stem cells, severely inhibit their efficient healing. Here, to overcome the unbalanced multielectron reactions in ROS catalysis, we develop a cobalt selenide-based biocatalyst with an amorphous Ru@CoSe nanolayer for ultrafast and broadspectrum catalytic ROS-elimination. Owing to the enriched electrons and more unoccupied orbitals of Ru atoms, the amorphous Ru@CoSe nanolayer-equipped biocatalyst displays excellent catalase-like kinetics (maximal reaction velocity, 23.05 μM s −1 ; turnover number, 2.00 s −1 ), which exceeds most of the currently reported metal compounds. The theoretical studies show that Ru atoms act as "regulators" to tune the electronic state of the Co sites and modulate the interaction of oxygen intermediates, thus improving the reversible redox properties of active sites. Consequently, the Ru@CoSe can efficiently rescue the proliferation of mesenchymal stem cells and maintain their angiogenic potential in the oxidative stress environment. In vivo experiments reveal the superior ROS-elimination ability of Ru@CoSe on the inflammatory diabetic wound. This study offers an effective nanomedicine for catalytic ROS-scavenging and ultrafast healing of inflammatory wounds and also provides a strategy to design biocatalytic metal compounds via bringing amorphous catalytic structures.

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Section: Introductionmentioning

confidence: 99%

Amorphizing Metal Selenides-Based ROS Biocatalysts at Surface Nanolayer toward Ultrafast Inflammatory Diabetic Wound Healing

Deng

Gao

et al. 2023

ACS Nano

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“…[ 8,9 ] In recent years, thrilling innovations to engineer artificial biocatalysts with diverse metal coordination environments that can mimic the function of natural enzymes have been promoted by the spectacularly increasing demands in enzyme‐like nanomedicines. [ 10–16 ] Nevertheless, most of the current studies on catalytic biotherapeutics focus on the synthesis, characterization, and biological applications of ROS‐production materials. [ 17–26 ] The developments of ROS‐scavenging biocatalysts are very slow and challenging.…”

Section: Introductionmentioning

confidence: 99%

Antioxidase‐Like Nanobiocatalysts with Ultrafast and Reversible Redox‐Centers to Secure Stem Cells and Periodontal Tissues

Guo

Xing

Liu

et al. 2023

Adv Funct Materials

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Exploration of efficient antioxidase-like reactive oxygen nanobiocatalysts (ROBCs) is a major challenge in combating oxidative stress-related diseases. Herein, the molecularly well-defined Ru-porphyrin-networks (Ru-Por-Net)-based ROBCs with ultrafast and reversible redox-centers for catalytic elimination of reactive oxygen species (ROS) are reported. Owing to the large π-conjugated networks, Ru-N coordination structures, and unique electronic and redox properties of atomic Ru sites, the Ru-Por-Net-based ROBCs exhibit exceptional catalytic ROS-scavenging activities. It is considerably more efficient than recently reported state-of-the-art anti-ROS biocatalysts. Notably, a new nucleophilic attack pathway to eliminate H 2 O 2 and produce O 2 is proposed via theoretical calculations, and the desorption of the OO* process is identified as the rate-determining step of atomic Ru centers. Cellular studies reveal that the new ROBCs can efficiently secure the survival, adhesion, spreading, and differentiation of the stem cells in high-ROS-level microenvironments. In vivo rat periodontitis treatments further demonstrate their superior anti-ROS therapeutic effects. This study provides significant insights into the crucial functions of Ru-N coordinated porphyrin-networks in catalytic ROS-scavenging and offers a new strategy to engineer high-performance antioxidase-like nanobiocatalysts for stem cell-based therapies and inflammatory diseases.

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“…Here, by taking the advantages of semiconducting and biocompatible barium titanate (BaTiO 3 , BTO) [52][53][54] and superior catalytic activities of Ru species in multielectron reactions, [55][56][57][58][59] we report synthesizing a new BTO-supported Ru clusterzymes (namely RuNC/BTO) via a facile method for ultrasound-amplified biocatalytic tumor nanotherapies. The morphology and chemical/electronic structures of the RuNC/ BTO are analyzed, and our data prove that RuNC/BTO consists of abundant surface-decorated Ru nanoclusters via RuO coordination.…”

Section: Introductionmentioning

confidence: 99%

Semiconducting Titanate Supported Ruthenium Clusterzymes for Ultrasound‐Amplified Biocatalytic Tumor Nanotherapies

Zhu

Deng

Yuan

et al. 2023

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Catalase‐Mimetic Artificial Biocatalysts with Ru Catalytic Centers for ROS Elimination and Stem‐Cell Protection

Cited by 52 publications

References 57 publications

Amorphizing Metal Selenides-Based ROS Biocatalysts at Surface Nanolayer toward Ultrafast Inflammatory Diabetic Wound Healing

Amorphizing Metal Selenides-Based ROS Biocatalysts at Surface Nanolayer toward Ultrafast Inflammatory Diabetic Wound Healing

Antioxidase‐Like Nanobiocatalysts with Ultrafast and Reversible Redox‐Centers to Secure Stem Cells and Periodontal Tissues

Semiconducting Titanate Supported Ruthenium Clusterzymes for Ultrasound‐Amplified Biocatalytic Tumor Nanotherapies

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