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. 2021 Dec 2;189(1):2.
doi: 10.1007/s00604-021-05117-0.

ZnSe nanodisks:Ti3C2 MXenes-modified electrode for nucleic acid liquid biopsy with photoelectrochemical strategy

Yuchan Meng #  1 Nana Qin #  1 Xu Hun  2
Affiliations

ZnSe nanodisks:Ti3C2 MXenes-modified electrode for nucleic acid liquid biopsy with photoelectrochemical strategy

Yuchan Meng et al. Mikrochim Acta. .

Abstract

ZnSe nanodisks:Ti3C2 MXene complex was prepared for the first time. Based on its remarkable photoelectrochemical performance, combined with the enzyme-free toehold-mediated strand displacement reaction, a photoelectrochemical biosensor for the detection of the non-small-cell cancer biomarker ctDNA KRAS G12D was developed. ZnSe nanodisks were in situ grown on Ti3C2 MXene surface by two-step hydrothermal method. The high conductivity and adjustable band gap of MXene significantly enhanced the photoelectric response of ZnSe. Subsequently, the photoelectrochemical biosensor was prepared by combining with the signal amplification function of p-aminophenol and the enzyme-free toehold-mediated strand displacement reaction on the modified ITO electrode surface. Under the optimized conditions, the linear detection range is 0.5 ~ 100.0 fM, and the detection limit is 0.2 fM, which realizes the sensitive detection of KRAS G12D. The photoelectrochemical biosensor constructed opens up a new pathway for the preparation of new Mxene-based composite materials and the research of photoelectrochemical biosensor. Nucleic acid liquid biopsy with ZnSe nanodisks:Ti3C2 MXene photoelectroactive modified electrode.

Keywords: Biomarker; MXene; Nanodisc; Non-small-cell lung cancer; Photoelectrochemical; Zinc selenide; ctDNA.

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References

    1. Wang H, Wu Y, Yuan X, Zeng G, Zhou J, Wang X, Chew JW (2018) Clay-inspired Mxene-based electrochemical devices and photo-electrocatalyst: state-of-the-art progresses and challenges. Adv Mater 30(12):1704561 - DOI
    1. Agresti A, Pazniak A, Pescetelli S, Di Vito A, Rossi D, Pecchia A, Auf der Maur M, Liedl A, Larciprete R, Kuznetsov DV, Saranin D, Di Carlo A (2019) Titanium-carbide Mxenes for work function and interface engineering in perovskite solar cells. Nat Mater 18(11):1228–1234 - DOI
    1. Huang K, Li C, Li H, Ren G, Wang L, Wang W, Meng X (2020) Photocatalytic applications of two-dimensional Ti3C2 Mxenes: a review. ACS Applied Nano Materials 3(10):9581–9603
    1. Ding M, Xiao R, Zhao C, Bukhvalov D, Chen Z, Xu H, Tang H, Xu J, Yang X (2021) Evidencing interfacial charge transfer in 2d Cds/2d Mxene Schottky heterojunctions toward high-efficiency photocatalytic hydrogen production. Solar RRL 5(2):2000414 - DOI
    1. Cui C, Cheng R, Zhang H, Zhang C, Ma Y, Shi C, Fan B, Wang H, Wang X (2020) Ultrastable Mxene@Pt/Swcnts’ nanocatalysts for hydrogen evolution reaction. Adv Func Mater 30(47):2000693 - DOI

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