A new quantitative real-time PCR method to measure human miRNAs using the PROMER technology.

MicroRNAs (miRNAs) are small, non-coding RNA molecules that play a crucial role in regulating gene expression. Dysregulation of miRNAs is associated with various human diseases, including cancer. Accurate quantification of miRNAs in bodily fluids or tissue biopsy samples is essential for their use as biomarkers in tumor diagnosis, yet current methods remain suboptimal.

PROMER technology: A new real-time PCR tool enabling multiplex detection of point mutation with high specificity and sensitivity.

Real-time polymerase chain reaction (real-time PCR) is a powerful tool for the precise quantification of nucleic acids in various applications. In cancer management, the monitoring of circulating tumor DNA (ctDNA) from liquid biopsies can provide valuable information for precision care, including treatment selection and monitoring, prognosis, and early detection. However, the rare and heterogeneous nature of ctDNA has made its precise detection and quantification challenging, particularly for ctDNA containing hotspot mutations.

Selective and sensitive ratiometric detection of Hg(II) ions using a simple amino acid based sensor.

Synthesis of a novel pyrene derivative sensor (Py-Met) based on amino acid and its fluorescent behavior for Hg(II) in water was investigated. Upon Hg(II) binding, the Py-Met-bearing sulfonamide group exhibited a considerable excimer emission at 480 nm along with a decrease of monomer emission at 383 nm. Py-Met allows a selective and sensitive ratiometric detection of Hg(II) without any interference from other metal ions.

A methionine-based turn-on chemical sensor for selectively monitoring Hg2+ ions in 100% aqueous solution.

Dansyl-labeled methionine is synthesized by solid-phase synthesis, and found to be a highly sensitive and selective sensor for Hg(2+). The sensor sensitively detects Hg(2+) ions in aqueous solution by a turn-on response; however, the sensor detects Hg(2+) ions by a turn-off response in organic and mixed aqueous-organic solutions. We investigated the binding stoichiometry, binding constant, and binding mode of the sensor under various solvent conditions.