Living systems such as cells rely on membrane pores and channels to transport molecules, exchange signals, and organize biochemical reactions. These functions emerge from dynamic interactions between ...

Scientists are pioneering new methods for designing and assembling DNA nanostructures, enhancing their potential for applications in medicine, materials science and data storage. (Nanowerk News) ...

Scientists from the RNA Institute at the University of Albany (UAlbany) have developed new methods for designing and assembling DNA nanostructures that enhance their potential for use in various ...

Newly developed DNA nanostructures can form flexible, fluid, and stimuli-responsive condensates without relying on chemical cross-linking, report researchers from the Institute of Science Tokyo and ...

To assemble these minuscule structures, researchers first create a scaffold: a long piece of single-stranded DNA with a carefully designed sequence of bases. Then they add hundreds of shorter DNA ...

DNA nanostructures assembled in ionic liquids instead of magnesium become stable in biological conditions and bind cancer-cell markers with higher precision. (Nanowerk News) DNA nanostructures are ...

Using 'DNA origami' scientists have built innovative nanostructures that pave the way for advanced robotics that can deliver targeted drugs -- plus they made a tiny map of Australia and mini dinosaurs ...

DNA nanostructures are exciting new biomedical tools with myriad potential in treatment, diagnosis and disease prevention. Made of folded DNA, these nanostructures are highly programmable and have ...

A recent article in Small describes a modular platform for assembling protein-DNA composites using covalent, site-specific conjugation. This method enables the formation of stable structures with ...

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A new study combines RNA origami and glass nanopores to achieve a 18-nucleotide resolution for diagnosing repeat expansion disorders like ALS.