Yinjun Tang
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Explore the profile of Yinjun Tang including associated specialties, affiliations and a list of published articles.
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13
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11
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Recent Articles
1.
Liu M, Xu W, Tang Y, Wu Y, Gu W, Du D, et al.
Angew Chem Int Ed Engl
. 2025 Feb;
:e202424070.
PMID: 39937141
Nanozymes with atomically dispersed metal sites (ADzymes), especially single-atom nanozymes, have attracted widespread attention in recent years due to their unique advantages in mimicking the active sites of natural enzymes....
2.
Wen Y, Xu W, Jiang W, Yang W, Liu M, Wu Y, et al.
Small
. 2025 Jan;
e2411402.
PMID: 39871718
The severe environmental and human health hazards posed by organophosphorus compounds underscore the pressing need for advancements in their degradation and detection. However, practical implementation is impeded by prolonged degradation...
3.
Chen Y, Wu Y, Xu W, Tang Y, Cai Y, Yu X, et al.
Anal Chem
. 2024 Sep;
PMID: 39270057
Nanozymes, possessing nanomaterial properties and catalytic activities, offer great opportunities to design sensitive analytical detection systems. However, the low interference resistance of nanozymes poses a significant limitation on the precise...
4.
Tang Y, Liu X, Qi P, Cai Y, Wang H, Qin Y, et al.
ACS Nano
. 2024 Sep;
18(37):25685-25694.
PMID: 39223090
Phosphates within tumors function as key biomolecules, playing a significant role in sustaining the viability of tumors. To disturb the homeostasis of cancer cells, regulating phosphate within the organism proves...
5.
Cai Y, Wu Y, Tang Y, Xu W, Chen Y, Su R, et al.
Small
. 2024 Aug;
20(46):e2403354.
PMID: 39101616
Defect engineering is an effective strategy to enhance the enzyme-like activity of nanozymes. However, previous efforts have primarily focused on introducing defects via de novo synthesis and post-synthetic treatment, overlooking...
6.
Tang Y, Liu X, Qi P, Xu W, Wu Y, Cai Y, et al.
Nano Lett
. 2024 Jul;
24(32):9974-9982.
PMID: 39083237
Various applications related to glucose catalysis have led to the development of functional nanozymes with glucose oxidase (GOX)-like activity. However, the unsatisfactory catalytic activity of nanozymes is a major challenge...
7.
Wei X, Lin Y, Wu Z, Qiu Y, Tang Y, Eguchi M, et al.
Angew Chem Int Ed Engl
. 2024 May;
63(31):e202405571.
PMID: 38757486
The rational design of efficient catalysts for uric acid (UA) electrooxidation, as well as the establishment of structure-activity relationships, remains a critical bottleneck in the field of electrochemical sensing. To...
8.
Wen Y, Xu W, Wu Y, Tang Y, Liu M, Sha M, et al.
Talanta
. 2024 Apr;
275:126112.
PMID: 38677169
The development of nanomaterials with multi-enzyme-like activity is crucial for addressing challenges in multi-enzyme-based biosensing systems, including cross-talk between different enzymes and the complexities and costs associated with detection. In...
9.
Lei M, Ding X, Liu J, Tang Y, Chen H, Zhou Y, et al.
Anal Chem
. 2024 Apr;
96(15):6072-6078.
PMID: 38577757
The urgent need for sensitive and accurate assays to monitor acetylcholinesterase (AChE) activity and organophosphorus pesticides (OPs) arises from the imperative to safeguard human health and protect the ecosystem. Due...
10.
Fang Q, Wang H, Wei X, Tang Y, Luo X, Xu W, et al.
Adv Healthc Mater
. 2023 Jun;
12(27):e2301073.
PMID: 37285868
Developing functional nanomaterials for nonenzymatic glucose electrochemical sensing platforms is vital and challenging from the perspective of pathology and physiology. Accurate identification of active sites and thorough investigation of catalytic...