期刊
ANALYTICAL CHEMISTRY
卷 93, 期 10, 页码 4506-4512出版社
AMER CHEMICAL SOC
DOI: 10.1021/acs.analchem.0c04861
关键词
-
资金
- National Natural Science Foundation of China [21904032, 22076041]
The integration of magnetic separation and DNA walker amplification has resulted in a robust and sensitive single-particle electrochemical biosensor. This method effectively captures and separates targets from complex samples, avoiding interference and aggregation, leading to cyclic amplification and greatly enhanced detection sensitivity. The ultrasensitive detection of HIV DNA in complex systems demonstrates promising potential for real sample applications and the development of new single-entity biosensors.
Single-particle electrochemical collision has gained great achievements in fundamental research, but it is challenging to use in practice on account of its low collision frequency and the interference of the complex matrix in actual samples. Here, magnetic separation and DNA walker amplification were integrated to build a robust and sensitive single-particle electrochemical biosensor. Magnetic nanobeads (MBs) can specifically capture and separate targets from complex samples, which not only ensures the anti-interference capability of this method but also avoids the aggregation of platinum nanoparticles (Pt NPs) caused by numerous coexisting substances. A low amount of targets can lead to the release of more Pt NPs and the generation of more collision current transients, realizing cyclic amplification. Compared with simple hybridization, a DNA walker can improve the collision frequency by about 3-fold, greatly enhancing detection sensitivity, and a relationship between collision frequency and target concentration is used to realize quantification. The biosensor realized an ultrasensitive detection of 4.86 fM human immunodeficiency virus DNA (HIV-DNA), which is 1-4 orders of magnitude lower than that of traditional methods. The successful HIV-DNA detection in complex systems (serum and urine) demonstrated a great promising application in real samples and in the development of new single-entity biosensors.
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