Researchers used DNA nanotechnology to build a synthetic membrane that mimics cell pores, enabling coordinated transport and ...

Living systems such as cells rely on membrane pores and channels to transport molecules, exchange signals, and organize ...

DNA nanotechnology exploits the predictable base-pairing and structural versatility of nucleic acids to engineer nanoscale architectures and dynamic devices. By programming strand sequences, ...

In the rapid and fast-growing world of nanotechnology, researchers are continually on the lookout for new building blocks to push innovation and discovery to scales much smaller than the tiniest speck ...

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 ...

Artificial DNA letters beyond A, T, G, C break a fundamental pairing rule to produce nanostructures with new shapes, far greater durability, and an unexpected ability to self-sort. But the four-letter ...

Chemists present two studies that open up new possibilities for biotechnological applications. LMU chemists present two studies that open up new possibilities for biotechnological applications. In the ...

The shape and morphology of a cell play a key role in the biological function. This corresponds to the principle of "form follows function," which is common in modern fields of design and architecture ...

LMU chemists present two studies that open up new possibilities for biotechnological applications. In the world of nanotechnology, the development of dynamic systems that respond to molecular signals ...

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 ...