Concept of the raMVR SMOLM. Credit: Nature Photonics (2022). DOI: 10.1038/s41566-022-01116-6
A
new technology, inspired in part by the design of the James Webb Space
Telescope (JWST), uses mirror segments to sort and collect light on the
microscopic scale, and capture images of molecules with a new level of
resolution: position and orientation, each in three dimensions.
Details of this new system, developed by
Oumeng Zhang, a recent Ph.D. graduate from the lab of Matthew Lew, an associate
professor of electrical and systems engineering at the McKelvey School of
Engineering at Washington University in St. Louis, were published Dec. 5 in the
journal Nature Photonics.
Like the space telescope, the radially and azimuthally polarized multi-view
reflector (raMVR) microscope depends on gathering as much light as possible.
But instead of using that light to see things far away, it uses it to discern
different features of tiny, fluorescent molecules attached to proteins and cell
membranes.
"The setup is partially inspired by
telescopes," Zhang said. "It's a very similar setup. Instead of the
familiar honeycomb shape of the JWST, we use pyramid-shaped mirrors."
Currently, microscopes in this domain face challenges creating biological images. For one thing, such small amounts of light given off by the fluorescent molecules are sensitive to the slightest aberrations—including the murky environment inside a cell. Because of this, precise imaging relies more heavily on computer processing to sort out orientation after an image has been captured.
Credit:
Washington University in St. Louis
"Think of creating a color picture when all you have are gray-scale
camera sensors," Lew said. "You could try to recreate the color using
a computational tool, or you can directly measure it using a color sensor,
which uses various absorbing color filters on top of different pixels to detect
colors."
In a similar way, standard microscopes simply do not detect how molecules
are oriented. The raMVR microscope uses polarization optics called waveplates
along with its pyramid-shaped mirrors to separate light into eight channels,
each of which represents a different piece of the molecule's position and
orientation.
Notably, the raMVR microscope is not a small technology. But smaller isn't always
better.
"At the cutting edge of engineering physics, we often have to make tradeoffs to make our instruments compact," Lew said. "Here, we decided to take a different tack: How could we use every precious bit of light to make the most precise measurement possible? It's absolutely fun to think differently about the architecture of a microscope, and here, we think the newfound 6D imaging performance will enable new scientific discoveries in the near future."
Provided by Washington
University in St. Louis
by Brandie
Jefferson, Washington University in St. Louis
Source: Telescope-inspired microscope sees molecules in 6D (phys.org)
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