2016
DOI: 10.1038/lsa.2016.196
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Ultrafast laser-scanning time-stretch imaging at visible wavelengths

Abstract: Optical time-stretch imaging enables the continuous capture of non-repetitive events in real time at a line-scan rate of tens of MHz—a distinct advantage for the ultrafast dynamics monitoring and high-throughput screening that are widely needed in biological microscopy. However, its potential is limited by the technical challenge of achieving significant pulse stretching (that is, high temporal dispersion) and low optical loss, which are the critical factors influencing imaging quality, in the visible spectrum… Show more

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Cited by 146 publications
(103 citation statements)
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“…We also note that this spinning-disc assay platform can be compatible with not only bright-field and quantitative phase imaging, but also fluorescence imaging. For instance, a recent demonstration of ultrafast all-optical laser-scanning fluorescence imaging at a line-scan rate of > 1 MHz, based on a concept of free-space angular-chirp-enhanced delay (FACED) [27], could be a viable option to be combined with the current high-speed spinning assay platform to enrich fluorescence-image-based single-cell analysis, such as CTC detection with multi-color fluorescence staining [28].…”
Section: Resultsmentioning
confidence: 99%
“…We also note that this spinning-disc assay platform can be compatible with not only bright-field and quantitative phase imaging, but also fluorescence imaging. For instance, a recent demonstration of ultrafast all-optical laser-scanning fluorescence imaging at a line-scan rate of > 1 MHz, based on a concept of free-space angular-chirp-enhanced delay (FACED) [27], could be a viable option to be combined with the current high-speed spinning assay platform to enrich fluorescence-image-based single-cell analysis, such as CTC detection with multi-color fluorescence staining [28].…”
Section: Resultsmentioning
confidence: 99%
“…A relay lens system and an objective lens (×40, numerical aperture (NA) = 0.66) are configured as an inverted microscope and are used to project the virtual sources onto the sample plane—resembling the ultrafast laser line‐scanning action, that is, pulses from different virtual sources arrive at the sample plane at different time points. The temporal delay between adjacent virtual sources is given by τ ≈ 2 S / c , where S is the mirror separation and c is the speed of light in free space . Without mechanical beam steering, the line‐scan rate is governed by the laser repetition rate (20 MHz).…”
Section: Methodsmentioning
confidence: 99%
“…The pixel size along y axis ( Δy ), that is, the microfluidic flow axis, are defined based on the microfluidic flow speed ( v ) and the repetition interval of the pulsed laser ( Δt ), that is, Δy = vΔt . As the temporal delay between adjacent virtual sources results in the modulation of the captured waveform , modulation peaks are detected and their amplitudes are assigned as the image pixel brightness. The extracted 2D image is normalized by the line scan background to form a bright‐field (BF) image in which the image contrast originates from light absorption and scattering of the cell.…”
Section: Methodsmentioning
confidence: 99%
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“…A new pulse‐stretching technique, termed free‐space angular‐chirp‐enhanced delay (FACED), was used to attain superior image quality . With the assistant of FACED technique, megahertz fluorescence and visible‐bandwidth time‐stretch microscopy was realized . Polarization‐division multiplexing technique was used to increase the spatial resolution .…”
Section: Introductionmentioning
confidence: 99%