Detection of low-frequency mutations in clinical samples by increasing mutation abundance via the excision of wild-type sequences.

The efficiency of DNA-enrichment techniques is often insufficient to detect mutations that occur at low frequencies. Here we report a DNA-excision method for the detection of low-frequency mutations in genomic DNA and in circulating cell-free DNA at single-nucleotide resolution. The method is based on a competitive DNA-binding-and-digestion mechanism, effected by deoxyribonuclease I (DNase) guided by single-stranded phosphorothioated DNA (sgDNase), for the removal of wild-type DNA strands.

Dynamics of base pairs with low stability in RNA by solid-state nuclear magnetic resonance exchange spectroscopy.

Base pairs are fundamental building blocks of RNA. The base pairs of low stability are often critical in RNA functions. Here, we develop a solid-state NMR-based water-RNA exchange spectroscopy (WaterREXSY) to characterize RNA in solid.

A multifunctional nanoprobe for targeting tumors and mitochondria with singlet oxygen generation and monitoring mitochondrion pH changes in cancer cells by ratiometric fluorescence imaging.

Mitochondria are the main sites of cell metabolism. Even minor pH changes may lead to mitochondrial dysfunction and promote cell apoptosis. Mitochondrion-targeting photosensitizers can produce singlet oxygen in the mitochondria.

Unique Approach To Develop Carbon Dot-Based Nanohybrid Near-Infrared Ratiometric Fluorescent Sensor for the Detection of Mercury Ions.

The ratiometric fluorescence assay, which can eliminate the external effects, has attracted great attention. In this work, a carbon dot (CD)-based nanohybrid dual-emission system was simply prepared by a unique approach of solvothermal treating corn bract and used as a ratiometric fluorescent sensor for Hg detection. Under a single excitation, the obtained nanohybrid sensor had two emission bands around 470 and 678 nm, which may originate from the intrinsic structure of CDs and chlorophyll-derived porphyrins, respectively.

Sulfur and nitrogen binary doped carbon dots derived from ammonium thiocyanate for selective probing doxycycline in living cells and multicolor cell imaging.

A novel sulfur and nitrogen binary doped carbon dots (S,N-CDs) was synthesized by one-step manner through the hydrothermal treatment of citric acid (CA) and ammonium thiocyanate, and the procedures for biomedical applications, including probing doxycycline in living cells and multicolor cell imaging were developed. The obtained S,N-CDs are stable in aqueous solution, possess a very high quantum yield (QY, 74.15%) and good photostability.

Green preparation of fluorescent carbon dots from lychee seeds and their application for the selective detection of methylene blue and imaging in living cells.

A green approach was developed for the preparation of fluorescent carbon dots (CDs) by using lychee seeds as precursors. The preparation of CDs was performed by simple pyrolysis. The quantum yield of as-prepared CDs was 10.