Label-free nanopore sensors have emerged as a new generation technology of DNA
sequencing and have been widely used for single molecule analysis. Since the first α …

Long DNA molecules can self-entangle into knots. Experimental techniques for observing
such DNA knots (primarily gel electrophoresis) are limited to bulk methods and circular …

Flow-driven rotary motors such as windmills and water wheels drive functional processes in
human society. Although examples of such rotary motors also feature prominently in cell …

Nanopores enable label-free detection and analysis of single biomolecules. Here, we
investigate DNA translocations through a novel type of plasmonic nanopore based on a gold …

Despite the potential for nanopores to be a platform for high-bandwidth study of single-
molecule systems, ionic current measurements through nanopores have been limited in …

Nanopores are valuable single-molecule sensing tools that have been widely applied to the
detection of DNA, RNA, proteins, viruses, glycans, etc. The prominent sensing platform is …

Single‐molecule sensing technologies aim to detect and characterize single biomolecules,
but generally need labeling while the measurement times and throughput are severely …

DNA in cells is heavily covered with all types of proteins that regulate its genetic activity.
Detection of DNA-bound proteins is a challenge that is well suited to solid-state nanopores …

Graphene nanopores are receiving great attention due to their atomically thin membranes
and intrinsic electrical properties that appear greatly beneficial for biosensing and DNA …

While understanding translocation of DNA through a solid-state nanopore is vital for
exploiting its potential for sensing and sequencing at the single-molecule level, surprisingly …