Scientists are exploring DNA-based robots, tiny molecular machines that could one day navigate the body, deliver targeted therapies, and even build nanoscale technologies.

Tunable DNA hairpin springs stretch millions of protein copies under piconewton tension, enabling bulk biochemical discovery of binding partners invisible to single-molecule techniques.

DNA origami paves a way to position quantum emitters on chips. Here’s how scientists are making it possible. Conceptual view of chip-based quantum systems arranged in precise patterns. One of the ...

The COVID-19 pandemic brought messenger RNA (mRNA) vaccines to the forefront of global health care. After their clinical ...

RNA vaccines saved millions of lives during COVID-19 but have limitations like waning immunity and complex production. Scientists are now testing a new platform called DoriVac, which uses folded DNA ...

Researchers have demonstrated a new way to precisely place quantum light sources on chips ...

DNA, the blueprint of life, is best known for its fundamental role as genetic material—storing and transmitting biological information through the precise sequence of its bases. For decades, this ...

Researchers use DNA nanotechnology to build layered lattice structures that produce new interference patterns with unique physical properties and nanoscale control. (Nanowerk News) Researchers are ...

DNA Moiré Superlattices are the focus of a study now published in Nature Nanotechnology. “Unlike conventional methods that rely on mechanical stacking and twisting of two-dimensional materials, our ...

Researchers study how DNA nanopores (DNPs) interact with low-curvature supported lipid bilayers over time. Using QCM-D, the study tracks diffusion, aggregation, and incorporation of DNPs, highlighting ...

The Martin A. Fisher School of Physics at Brandeis University has long held an international reputation for excellence in research, offering its graduate students opportunities to work with top ...