https://www.selleckchem.com/products/bay-11-7085.html Transcription factor (TF)-based metabolite detection mainly depends on TF-regulated gene expression in cells. From TF activation to gene transcription and translation, the signal travels a relatively long way before it is received. Here, we propose a TF-splinting duplex DNA nanoswitch to detect metabolites. We show its feasibility using tryptophan repressor (TrpR) to detect l-tryptophan as a model. The assay has been optimized and characterized after obtaining a proof of concept, and the detection of l-tryptophan in complex biological samples is feasible. Unlike an equivalent gene expression approach, the whole process is a single-step, enzyme-free, and signal-on method. It can be completed within 20 min. This proposed TF-splinting duplex has the potential to be applied to the quick and convenient detection of other metabolites or even TFs.The label-free assay has drawn extensive attention because it does not require a labeling step and enables direct interaction and signal transduction between the sensing unit and target analytes. Herein, we demonstrate a proof-of-principle concept of a label-free and visualized nanoplasmonic strategy for silver ions sensing, where only Ti3C2 MXenes are employed by exploring their excellent adsorption affinity and reductive property toward metal ions. Ag+ was adsorbed onto the surface of Ti3C2 MXene nanosheets, followed by the Ti3C2 MXenes mediated in situ silver nanoparticles (Ag NPs) generation without adding any extra stabilizing or reducing agent. The excellent localized surface plasmon resonances at a particular wavelength provide Ag NPs the capability for colorimetric assay with a detection limit of 0.615 μM. With the assistance of a smartphone, RGB analysis exhibited visualized results consistent with the results measured on a UV-vis spectrometer, promising a budget, simple-operating on-site detection. Moreover, the detection of Ag+ in real samples was achieved with satis