Construction of Nanozyme‐Hydrogel for Enhanced Capture and Elimination of Bacteria

Sang, Yanjuan; Li, Wei; Líu, Hao; Lu, Zongqing; Wang, Huan; Liu, Zhengwei; Ren, Jinsong; Qu, Xiaogang

doi:10.1002/adfm.201900518

“…To the best of our knowledge,t he complex protein scaffold is responsible for the high selectivity and efficiency of natural enzymes.However,nanozymes are intrinsically deficient in their fine structure and thus lack the finesse of enzyme-catalyzed reactions,t hereby resulting in unsatisfactory selectivity and activity.I na ddition, the atomic composition and structural complexity of nanomaterials endow ad iverse range of nanozyme catalytic mechanisms.F or example,m any transitionmetal-based nanozymes,such as Fe 3 O 4 , MnO 2 ,V 2 O 5 ,M oS 2 ,a nd so on, with intrinsic peroxidase,o xidase,c atalase,a nd superoxide dismutase activity,h ave been discovered. [4,[19][20][21][22][23] TheF enton or Fenton-like reactions are widely used to explain the catalytic mechanism of peroxidase mimics.T he generated COH can be used for the degradation of organic pollutants and in the treatment of cancer, as well as in biosensing applications. [24] Another catalytic mechanism of peroxidase mimics,w hich occurs in Prussian blue and its cyanometalate structural analogues,i st he electron transfer effects.…”

Section: Introductionmentioning

confidence: 99%

When Nanozymes Meet Single‐Atom Catalysis

Jiao

¹

,

Yan

²

,

Wu

³

et al. 2019

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Nanomaterials with enzyme‐like activities, coined nanozymes, have been researched widely as they offer unparalleled advantages in terms of low cost, superior activity, and high stability. The complex structure and composition of nanozymes has led to extensive investigation of their catalytic sites at an atomic scale, and to an in‐depth understanding of the biocatalysis occurring. Single‐atom catalysts (SACs), characterized by atomically dispersed active sites, have provided opportunities for mimicking metalloprotease and for bridging the gap between natural enzymes and nanozymes. In this Minireview, we illustrate the unique properties of nanozymes and we discuss recent advances in the synthesis, characterization, and applications of SACs. Subsequently, we outline the impressive progress made in single‐atom nanozymes and we discuss their applications in sensing, degradation of organic pollutants, and in therapeutic roles. Finally, we present the major challenges and opportunities remaining for a successful marriage of nanozymes and SACs.

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“…因此, 在杀菌的同时破坏生物膜或抑制生物膜的再生是促进伤口愈合和抗伤口感染的重要策略. Yan和Liu课题组 [56] 合成了一图 7 AMP NRs介导热疗的作用机理 [45] (网络版彩图) Figure 7 Schematic illustration of AMP NRs mediated PTT [45] (color online) (网络版彩图) Figure 8 Design and antibacterial mechanism of the 2D MOF/GOx hybrid nanocatalyst as a benign and self-activated cascade reagenta [52] (color online) 图 9 MoS 2 纳米水凝胶的合成过程及其在抗菌和促进伤口愈合中的作用机理 [58] (网络版彩图) Figure 9 Synthesis of MoS 2 nanohydrogel and its mechanism in antibacterial and wound healing [58] (color online) [61] (网络版彩图) Figure 10 Mechanisms of dextran-coated iron oxide nanoparticles in the treatment of dental caries [61] (color online) 以MOF-AuNPs纳米杂化物为放射增敏平台, 并在其内包载阿霉素, 实现了放图 11 基于PtFe@Fe 3 O 4 纳米酶的光增强肿瘤催化治疗原理 [66] (网络版彩图) Figure 11 Schematic of the photo-enhanced tumor catalytic therapy based on the PtFe@Fe 3 O 4 nanozyme [66] (color online)…”

Section: 虽然抗生素的发明能够杀伤部分细菌但细菌具有变mentioning

confidence: 99%

Nanozymes: a new choice for disease treatment

Hou¹,

Zhang²,

Yan³

2020

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“…In addition, the atomic composition and structural complexity of nanomaterials endow a diverse range of nanozyme catalytic mechanisms. For example, many transition‐metal‐based nanozymes, such as Fe 3 O 4 , MnO 2 , V 2 O 5 , MoS 2 , and so on, with intrinsic peroxidase, oxidase, catalase, and superoxide dismutase activity, have been discovered . The Fenton or Fenton‐like reactions are widely used to explain the catalytic mechanism of peroxidase mimics.…”

Section: Introductionmentioning

confidence: 99%

When Nanozymes Meet Single‐Atom Catalysis

Jiao

¹

,

Yan

²

,

Wu

³

et al. 2019

View full text Add to dashboard Cite

Nanomaterials with enzyme‐like activities, coined nanozymes, have been researched widely as they offer unparalleled advantages in terms of low cost, superior activity, and high stability. The complex structure and composition of nanozymes has led to extensive investigation of their catalytic sites at an atomic scale, and to an in‐depth understanding of the biocatalysis occurring. Single‐atom catalysts (SACs), characterized by atomically dispersed active sites, have provided opportunities for mimicking metalloprotease and for bridging the gap between natural enzymes and nanozymes. In this Minireview, we illustrate the unique properties of nanozymes and we discuss recent advances in the synthesis, characterization, and applications of SACs. Subsequently, we outline the impressive progress made in single‐atom nanozymes and we discuss their applications in sensing, degradation of organic pollutants, and in therapeutic roles. Finally, we present the major challenges and opportunities remaining for a successful marriage of nanozymes and SACs.

show abstract

Construction of Nanozyme‐Hydrogel for Enhanced Capture and Elimination of Bacteria

Cited by 248 publications

References 52 publications

When Nanozymes Meet Single‐Atom Catalysis

When Nanozymes Meet Single‐Atom Catalysis

Nanozymes: a new choice for disease treatment

When Nanozymes Meet Single‐Atom Catalysis

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