It’s the most famous corkscrew in history. Now an electron microscope has captured the famous Watson-Crick double helix in all its glory, by imaging threads of DNA resting on a silicon bed of ...

At the end of the evaporation, DNA is then suspended between the micropillars and ready to be irradiated with the electron beam by the microscope.

DNA's double-helix structure is on display for the first time in this electron microscope photograph of a small bundle of DNA strands. Enzo Di Fabrizio ...

The first direct images of the DNA double helix have been taken using electron microscopy. In a study published in the journal NanoLetters, Enzo di Fabrizio, head of the Nanostructures Department ...

Three-dimensional model (based on electron microscopy data) of the double-ring structure loaded onto a DNA helix.

Enzo di Fabrizio and colleages from the University of Genoa, Italy, developed a technique to capture the famous double helix of DNA using a scanning electron microscope.

Scientists have developed a new method of imaging the building blocks of life. It involves an electron microscope and a bed of nails. DNA, we are taught early on, is colorful. The building block ...

During cell division, the familiar double-stranded DNA helix gets split into two single strands, and the cell's replication machinery moves along these single strands like a monorail, explains ...

At the end of the evaporation, DNA is then suspended between the micropillars and ready to be irradiated with the electron beam by the microscope.

DNA's double-helix structure is on display for the first time in this electron microscope photograph of a small bundle of DNA strands.

Using cryo-electron microscopy (cryo-EM), a team of structural and molecular biologists at Memorial Sloan Kettering Cancer Center (MSK) set out to investigate G4s — which have gained attention as ...