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Low-Power Nanotweezers May Benefit Cell Studies

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URBANA-CHAMPAIGN, Ill., Oct. 1, 2012 — Low-power optical tweezers can trap, manipulate and analyze nanoparticles — including delicate biological samples — new work demonstrates.

University of Illinois at Urbana-Champaign engineers showed that near-field optical forces can be enhanced even further by exploiting the high-peak powers associated with a femtosecond optical source, and without making alterations in the fabrication process.

“We used an average power of 50 microwatts to trap, manipulate and probe nanoparticles,” said Kimani Toussaint Jr., assistant professor of mechanical science and engineering. “This is 100 times less power than what you would get from a standard laser pointer.”

The experimental setup schematic showing laser source, microscope, and imaging detector and spectrometer.
The experimental setup schematic showing laser source, microscope, and imaging detector and spectrometer. Inset illustrates the two different sample configurations that were explored; the red arrows correspond to the input polarization directions, and the black arrows depict the propagation vector. Courtesy of the University of Illinois.

It is already known that plasmonic nanoantennas enhance local fields by several orders of magnitude, and the UIUC group previously showed that these structures can be used with a regular continuous-wave laser source to make very good optical tweezers.

“This is exciting because, for the first time, we’re showing that, the near-field optical forces can be enhanced even further, without doing anything extra in terms of fabrication, but rather simply by exploiting the high-peak powers associated with using a femtosecond optical source,” Toussaint said.

Their system is suitable for biological (lab-on-a-chip) applications such as cell manipulation because it runs at average power levels roughly three orders of magnitude lower than the estimated optical damage threshold for biological structures, Toussaint said.

“This system offers increased local diagnostic capabilities by permitting the probing of the nonlinear optical response of trapped specimens, enabling studies of in vitro fluorescent-tagged cells, or viruses using a single line for trapping and probing rather than two or more laser lines,” he said.

This image shows experimentally collected spectra from the trapped fluorescent microbead-BNA system (inverted orientation) with horizontal and vertical polarization (parallel and perpendicular to the bowtie axis, respectively).
This image shows experimentally collected spectra from the trapped fluorescent microbead-BNA system (inverted orientation) with horizontal and vertical polarization (parallel and perpendicular to the bowtie axis, respectively). The reference is taken from a microbead trapped away from the arrays in the inverted orientation. The inset image depicts the dramatic fluorescence enhancement when the particle is moved onto the array (indicated by the yellow outline). The scale bar is 5 µm. Courtesy of K. Toussaint, University of Illinois.


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In their paper, which appeared Sept. 17 in Scientific Reports, the investigators discuss how the trapping strength of gold bow-tie nanoantenna arrays (BNAs) is greatly improved using a femtosecond-pulsed laser beam. They also describe using a femtosecond source to perform optical trapping with plasmonic nanotweezers.

“We present strong evidence that a [femtosecond] source could actually augment the near-field optical forces produced by the BNAs, and most likely, other nanoantenna systems, as well. To our knowledge, this has never been demonstrated,” said Brian Roxworthy, a graduate student in Toussaint’s PROBE (Photonics Research of Bio/nano Environments) lab group. Demonstrating controlled particle fusing, he added, could pave the way to the creation of novel nanostructures; it could also lead to improved local magnetic field response, which will be essential for magnetic plasmonics.

The paper also demonstrated trap stiffness improvement of up to 5 times as compared to traditional optical tweezers using a femtosecond source, and up to 2 times as compared to continuous-wave nanotweezers. They also showed successful trapping and tweezing of spherical dielectric, metal, fluorescent and nonfluorescent particles varying between 80 nm and 1.2 µm in diameter; silver nanoparticle fusing to BNAs; approximately 3.5 times enhancement of the second-harmonic signal for the combined nanoparticle-BNA system as compared to bare BNAs; and improvement of two-photon fluorescent signal received from trapped microparticles as compared to the response without BNAs.

For more information, visit: www.engineering.illinois.edu

Published: October 2012
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.
optical tweezers
Optical tweezers refer to a scientific instrument that uses the pressure of laser light to trap and manipulate microscopic objects, such as particles or biological cells, in three dimensions. This technique relies on the momentum transfer of photons from the laser beam to the trapped objects, creating a stable trapping potential. Optical tweezers are widely used in physics, biology, and nanotechnology for studying and manipulating tiny structures at the microscale and nanoscale levels. Key...
photonics
The technology of generating and harnessing light and other forms of radiant energy whose quantum unit is the photon. The science includes light emission, transmission, deflection, amplification and detection by optical components and instruments, lasers and other light sources, fiber optics, electro-optical instrumentation, related hardware and electronics, and sophisticated systems. The range of applications of photonics extends from energy generation to detection to communications and...
probe
Acronym for profile resolution obtained by excitation. In its simplest form, probe involves the overlap of two counter-propagating laser pulses of appropriate wavelength, such that one pulse selectively populates a given excited state of the species of interest while the other measures the increase in absorption due to the increase in the degree of excitation.
Americaspulsed lasersBasic ScienceBiophotonicsBNAsBrian Roxworthydelicate biological samplesfemtosecond optical sourcefluorescent particlesgold bow tie nanoantenna arraysImagingin vitro fluorescent-tagged cellsKimani Toussaint Jr.lab-on-a-chip applicationsLasersMicroscopynanonanoparticle analysisnanoparticlesoptical nanotweezersoptical tweezersOpticsparticle manipulationparticle trappingphotonicsPhotonics Research of Bio/nano Environmentsplasmonic nanotweezersprobeResearch & TechnologySensors & DetectorsspectroscopyUniversity of Illinois at Urbana-Champaign

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