A new discovery could lead to Star Trek-like biosensor devices that could flag the barest presence of a specific virus, antibody, or protein marker for cancer in blood—or sniff out airborne chemical warfare agents while they’re still far below toxic levels.
The discovery follows years of work by Stephen Arnold, professor of applied physics at New York University, who in 1995 discovered that an optical fiber could excite what he termed Whispering Gallery Mode (WGM) in polymer micro-beads less than one-third the diameter of a human hair.
Further discoveries and patents led to WGM biosensors capable of gauging the mass of viruses, proteins, and other nanoparticles by sending them into spacecraft-like orbit around the micro-bead, thanks to a photonic “tractor beam” caused by the resonating light.
Watch the video below to see it in action:
Arnold and collaborators then devised a way to make these WGM biosensors sensitive enough to identify even the smallest individual bio-particles from the RNA virus MS2 to single molecules down to 6 zepto-grams (6×10-21 grams), below the mass of all known cancer markers. Many companies, including Genalyte, employ WGM biosensors in diagnostic products that can perform dozens of bioassays in minutes.
Now, Arnold and his team at the Tandon School of Engineering’s MicroParticle PhotoPhysics Laboratory for BioPhotonics (MP3L) at NYU are the first to find a way to determine the density of charges on an area of a WGM micro-bead’s surface, as well as the charge of an ensnared nanoparticle or virus, by measuring how light frequency fluctuates as the tiny particle follows its wobbly course around the sphere. This discovery could allow researchers and manufacturers not just to identify nanoparticles, but to manipulate them.
The WGM biosensor, which Arnold named for the famous Whispering Gallery in the dome of St. Paul’s Cathedral in London, is a device the size of a small smartphone comprising a tunable laser guided down a specially treated fiber optic filament with a detector at the far end of the filament measuring the light’s intensity and resonance.
A tiny silica bead next to the filament diverts a portion of the light beam, which begins to resonate within the bead the way sound resonates under the dome of the church gallery for which the phenomenon is named.
While the WGM biosensor’s ability to identify individual nanoparticles led to highly sensitive measuring capabilities, Arnold’s latest discovery could make possible biosensors tailored to very specific applications, from wearable sensors for soldiers and rescuers designed to detect extremely low concentrations of a suspected airborne nerve agent, to ways of increasing the efficiency of nanoparticle drug uptake and redistribution.
“Charge controls the ability to transport particles that are interacting with cells and other objects that possess electric fields,” he says. “By determining the charge of a virus, for example, you can understand how it can be transported to the cell surface. You need to understand this mechanism in order to engineer a WGM micro-bead that has a specific antigen at a specific region of its surface so that the biosensor can attract specific pathogens or other biomolecules.”
Arnold and the MP3L team were able to extract the electrostatic force between the orbiting nanoparticle and the surface of the glass bead through experiments based on the observation that the nano-orbital phenomenon requires a near balance between the electrostatic force and the known optical tractor beam force, just as a weighing scale balances the force of a spring against your body’s weight.
“The difference in the strength of the force being measured is extraordinarily small,” says Arnold, who explains that the measured electrostatic force involved in keeping a nanoparticle in orbit was only 0.00000000000003 (3×10-14) pounds. “With this force in hand both the charge on the nanoparticle and the microcavity charge density could be calculated through a series of experiments.”
The team next plans to use the discovery to develop technology for “photonic printing,” the ability to quickly create numerous task-specific WGM biosensors, with specific molecules attached to specific areas of the micro-bead.
The researchers report their findings in the journal Applied Physics Letters. Funding for this research came from the National Science Foundation and the Air Force Office of Scientific Research.