Highly sensitive protein detection via covalently linked aptamer to MoS(2) and exonuclease-assisted amplification strategy

Molybdenum disulfide (MoS(2)) has shown highly attractive superiority as a platform for sensing. However, DNA physisorption on the surface of MoS(2) was susceptible to nonspecific probe displacement and false-positive signals. To solve these problems, we have developed a novel MoS(2)–aptamer nanosheet biosensor for detecting thrombin using a covalently linked aptamer to the MoS(2) nanosheet. Ten percent Tween 80 was used to prevent thrombin from nonspecific binding and to rapidly form thiol-DNA/gold nanoparticle (AuNP) conjugates. Furthermore, an MoS(2) and exonuclease coassisted signal amplification strategy was developed to improve the detection limit for thrombin. We used the hybridization of the aptamer molecules and the matched strand with a 5′ terminal thiol to immobilize the aptamer molecules on the surface of AuNPs in AuNPs@MoS(2) nanocomposites. Exonuclease digested the single-strand aptamer and released the thrombin, which was then detected in the next recycle. With the coassisted amplification strategy, a 6 fM detection limit was achieved, showing that this method has higher sensitivity than most reported methods for thrombin detection. The results presented in this work show that this method of covalently attaching the aptamer and using the coassisted amplification is a promising technique for the detection of protein in medical diagnostics.