Single-atom Ni-N4 provides a robust cellular NO sensor

Zhou, Min; Jiang, Ying; Guo, Wang; Wu, Wenjie; Chen, Wenxing; Yu, Ping; Lin, Yuqing; Mao, Junjie; Mao, Lanqun

doi:10.1038/s41467-020-17018-6

Cited by 168 publications

(155 citation statements)

References 48 publications

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“…SACs have sparked tremendous interest as emerging fields owing to their high atom utilization efficiency [ 206,207 ] Whereas, few studies focused on the applications of SACs in biosensing. [ 208–211 ] In a very recent study, Zhu and co‐workers elaborately designed a new type of photoelectrochemical (PEC) biosensing by coupling DNA with SACs, where single‐atom Pt was anchored on the surface of hollow CdS (HCdS‐Pt 1 ) with multienzyme‐encapsulated DNA flowers (DFs) consisted of horseradish peroxidase (HRP) and glucose oxidase (GOx) to enhance selectivity and sensitivity. HRP&GOx‐DFs enriched by target exosome will bio‐etch HCdS‐Pt 1 , which had been used in in situ sensing of exosomes released by the HepG2 cells.…”

Section: Applications Of Single‐atom Catalystsmentioning

confidence: 99%

“…Besides the widely reported application in these fields described above, SACs have also attracted intensive research interest in both experimental investigations and theoretical calculations, [ 222–225 ] such as water–gas shift (WGS) reaction, [ 210–212,226–228 ] CO oxidation, [ 34,229–231 ] methane conversion, etc. [ 232–235 ]…”

Section: Applications Of Single‐atom Catalystsmentioning

confidence: 99%

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Synthesis Strategies, Catalytic Applications, and Performance Regulation of Single‐Atom Catalysts

Jung

et al. 2021

Adv Funct Materials

140

106

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The recent dramatic increase in research on isolated metal atoms has received extensive scientific interest in the new frontier of single‐atom catalysis. As newly advanced materials in catalysis, single‐atom catalysts (SACs) have received enormous interest from the perspectives of both scientific research and industrial applications due to their remarkable activity. In addition, other catalytic properties of single metal atoms, including stability and selectivity, can be further improved by tuning their electronic/geometric structures and modulating the metal–support interactions. SACs usually consist of dispersed atoms and appropriate support materials, which are employed to anchor, confine, and/or coordinate with isolated metal atoms. Therefore, the nature of single metal sites allows acquiring a maximum atom utilization approaching 100%, which is of significance, particularly for the development of noble‐metal‐based catalysts. In order to systematically understand the structure–property relationships and the underlying catalytic mechanisms relationship of SACs, the representative scientific research efforts in their synthesis strategies, catalytic applications, and performance regulation are discussed here. Typical single‐atom catalysis processes and the corresponding mechanisms in electrochemistry, photochemistry, organic synthesis, and biomedicine are also summarized. Finally, the challenges and prospects for the development of single‐atom catalysis and SACs are highlighted.

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Section: Applications Of Single‐atom Catalystsmentioning

confidence: 99%

Section: Applications Of Single‐atom Catalystsmentioning

confidence: 99%

Synthesis Strategies, Catalytic Applications, and Performance Regulation of Single‐Atom Catalysts

Jung

et al. 2021

Adv Funct Materials

140

106

View full text Add to dashboard Cite

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“…Recently, using nickel single‐atom based electrocatalyst (Figure 3A), Zhou et al. have demonstrated for the first time the SACs facilities NO oxidation and its successful application in real‐time selective NO sensing in live cellular environment (Figure 3B) [27] . Though SACs show great electrocatalytic properties to some of the physiologically relevant chemicals compared to nanocatalysts, the SACs based biosensors have surprisingly been less exploited, probably because of the challenges in controlling over the catalytic activities and biocompatibility of SACs in complexed biosystems.…”

Section: Selective Detection By Using Electrocatalysts To Modulate the Interfacial Electron Transfermentioning

confidence: 99%

Selectively Probing Neurochemicals in Living Animals with Electrochemical Systems

Jia

Jiang

2021

ChemNanoMat

Self Cite

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Neurochemicals are essential molecules presented in the central nervous system that are primarily involved in neural activity and signaling. Neurochemical abnormalities resulted from genetic or environmental changes can lead to several behavioral and neurological disorders, including Alzheimer's and Parkinson's diseases. It is therefore imperative to employ detection systems of the optimal selectivity and spatio‐temporal resolution to ascertain the specific molecular basis particular to the pathological process. Electrochemical systems featuring excellent temporal‐spatial resolution and designable electrode interface are arguably the most versatile and widely used approaches for sensing of neurochemicals in living brain environment. Nevertheless, there are still many challenges that must be addressed to enable highly selective, sensitive, and stable in vivo electrochemical sensors and facilitate their development for emerging applications ranging from early diagnosis of brain diseases to designing potential curative treatments. Here, we provide a brief overview of the application of electrochemical sensors and biosensors in the analysis of neurochemicals in living animals. In particular, we highlight recent advances in modulating the physicochemical properties of electrode that can lead to in vivo sensors with exceptional selectivity. In addition, future trends of highly selective in vivo electrochemical systems are prospected.

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“…Mao and co‐workers reported a flexible sensor based on a Ni single atom catalyst, which can monitor the release of nitrogen monoxide in cells in real time under the stimulation of drugs and stretching ( Figure ). [ 75 ] Using SiO 2 spheres as templates and controlling the weight percentage of dopamine hydrochloride, Ni(acac) 2 and pyrolysis temperature, Ni atoms were successfully anchored to N‐doped hollow carbon spheres (Ni SACs/N–C). Ni atoms are coordinated by N atoms to form Ni–N 4 , providing a good electrical conductivity in the large surface area support.…”

Section: Atomically Controlled Nanoarchitectonicsmentioning

confidence: 99%

Atomic Nanoarchitectonics for Catalysis

Chen

Sciortino

Ariga

2020

Adv Materials Inter

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Useful materials and energies from given materials including petroleum, minerals, biomass, and solar lights are obtained through various conversions. In most cases, efficient and specific conversions are supported by catalysts. Especially, nanotechnological structural analyses and regulation are important subjects in research approaches for advanced catalysts. Catalyst fabrication and functions based on atomic‐ and nanoscale‐level nanoarchitectonics approach are introduced in this progress report. Some of them are categorized as a hot subject: single atom catalysts. In order to show generalities and possibilities of catalyst designs by nanolevel structural regulations, several nanoarchitected catalysts are first exemplified. In the following sections, hot topics on atomically controlled catalysts designs are discussed with classification of i) site‐arrangement nanoarchitectonics, ii) multiatom arrangement nanoarchitectonics, and iii) hierarchical nanoarchitectonics.

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Single-atom Ni-N4 provides a robust cellular NO sensor

Cited by 168 publications

References 48 publications

Synthesis Strategies, Catalytic Applications, and Performance Regulation of Single‐Atom Catalysts

Synthesis Strategies, Catalytic Applications, and Performance Regulation of Single‐Atom Catalysts

Selectively Probing Neurochemicals in Living Animals with Electrochemical Systems

Atomic Nanoarchitectonics for Catalysis

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