Electron microscopy is one of the current gold standards for viewing nanoscale objects. This technology uses a beam of electrons to outline the shape and structure of nanoscale objects. Other optical imaging–based techniques are used as well, but all of them are relatively bulky, require time for the preparation and analysis of samples, and have a limited field of view — typically smaller than 0.2 square millimeters — which can make viewing particles in a sparse population, such as low concentrations of viruses, challenging.
To overcome these issues, the UCLA team, led by Aydogan Ozcan, an associate professor of electrical engineering and bioengineering, developed the new optical microscopy platform by using nanoscale lenses that stick to the objects that need to be imaged. This lets users see single viruses and other objects in a relatively inexpensive way and allows for the processing of a high volume of samples.
"This work demonstrates a high-throughput and cost-effective technique to detect sub–100-nanometer particles or viruses over very large sample areas," said Ozcan, who is also a member of the California NanoSystems Institute and holds a faculty appointment in the department of surgery at the David Geffen School of Medicine at UCLA. "It is enabled by a unique combination of surface chemistry and computational imaging."
The team also included lead authors Onur Mudanyali and Euan McLeod, both UCLA postdoctoral scholars in the Ozcan BioPhotonics Research Laboratory; Wei Luo, Alon Greenbaum and Ahmet F. Coskun, UCLA graduate-student members of Ozcan's lab; and Yves Hennequin and Cedric P. Allier, collaborators from CEA-Leti, a research institute based in France.
At scales smaller than 100 nanometers, optical microscopy becomes a challenge because of its weak light-signal levels. Using a special liquid composition, nanoscale lenses, which are typically thinner than 200 nanometers, self-assemble around objects on a glass substrate.
The researchers have used the new technique to create images of single polystyrene nanoparticles, as well as adenoviruses and H1N1 influenza viral particles.
The research is published online in the journal Nature Photonics.
The Ozcan BioPhotonics Lab is funded by an Army Research Office Young Investigator Award, a Presidential Early Career Award for Scientists and Engineers (PECASE), a National Science Foundation CAREER Award, an Office of Naval Research Young Investigator Award and a National Institutes of Health Director's New Innovator Award.