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Superbright nanocrystals advance biosensing

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Superbright, photostable and background-free nanocrystals called SuperDots – three orders of magnitude brighter than quantum dots – enable a new approach to highly advanced biosensing technologies using optical fibers. When combined with a unique optical fiber that allows light to interact with nanoscale volumes of liquid, SuperDots allow a single nanoparticle to be detected from a distance.

The implications for nanoscale applications such as biodetection and bioimaging are significant, according to the researchers who developed the technique. “Up until now, measuring a single nanoparticle would have required placing it inside a very bulky and expensive microscope,” said professor Tanya Monro, director of the University of Adelaide’s Institute for Photonics and Advanced Sensing (IPAS) and a member of the team that made the discovery with colleagues from Macquarie University in Sydney and Peking University in China. “For the first time, we’ve been able to detect a single nanoparticle at one end of an optical fiber from the other end. That opens up all sorts of possibilities in sensing.”


The microstructured optical fiber has been employed as a nanoliter-volume spectroscope to analyze the optical properties of nanocrystals. Courtesy of Matthew Henderson.


Nanocrystals can be doped with sensitizer ions that absorb infrared radiation, then transfer their excitation to activator ions that then emit visible light. The more dopants that are added, the higher the emission brightness – but only up to a point. At a certain relatively low threshold, activator ions are maxed out, and brightness begins to diminish.

The team found that high levels of infrared radiation combined with higher activator concentrations in excess of the threshold led to significantly enhanced luminescence signals by up to a factor of 70, an improvement of three orders of magnitude over quantum dots.

These single nanocrystals were bright and sensitive enough to be detected remotely using an optical fiber, or to be seen with the naked eye through an automated scanning microscope, so they could provide high-contrast biolabels to track individual cells or sense single molecules.

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The special optical fiber engineered at IPAS also proved useful in understanding the properties of nanoparticles.

“Material scientists have faced a huge challenge in increasing the brightness of nanocrystals,” said Dr. Dayong Jin of Macquarie’s Advanced Cytometry Laboratories. “Using these optical fibers, however, we have been given unprecedented insight into the light emissions. Now, thousands of emitters can be incorporated into a single SuperDot, creating a far brighter and more easily detectable nanocrystal.”

“Using optical fibers, we can get to many places, such as inside the living human brain, next to a developing embryo or within an artery – locations that are inaccessible to conventional measurement tools,” Monro said. “This advance ultimately paves the way to breakthroughs in medical treatment. For example, measuring a cell’s reaction in real time to a cancer drug means doctors could tell at the time treatment is being delivered whether or not a person is responding to the therapy.”


SuperDots enable the microstructured optical fiber to detect and track the movement of a single nanocrystal remotely. Courtesy of Dr. Mathieu Juan.


Under infrared illumination, SuperDots selectively produce bright blue, red and infrared light with 1000 times more sensitivity than existing materials.

“Neither the glass of the optical fiber nor other background biological molecules respond to infrared, so that removed the background signal issue. By exciting these SuperDots, we were able to lower the detection limit to the ultimate level: a single nanoparticle,” Jin said.

The work appears in Nature Nanotechnology (doi: 10.1038/nnano.2013.171). Macquarie is working with industry partners Minomic International Ltd. and Patrys Ltd. to develop uses for SuperDots in cancer diagnostic kits. The university is now seeking other industrial partners with the capacity to jointly develop solutions outside of these fields.

Published: November 2013
Glossary
nano
An SI prefix meaning one billionth (10-9). Nano can also be used to indicate the study of atoms, molecules and other structures and particles on the nanometer scale. Nano-optics (also referred to as nanophotonics), for example, is the study of how light and light-matter interactions behave on the nanometer scale. See nanophotonics.
AdelaideBIOBiophotonicsBioScancancerDayong JindetectionfiberIMSInstitute for Photonics and Advanced SensingIPASMacquarieMinomicnanonanocrystalNewsOPTOPatrysphotostableResearch & Technologysensingsingle moleculeSuperDotTanya MonroDispmaterials and chemicalsLEDs

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