DPSS yellow‐green 561‐nm lasers for improved fluorochrome detection by flow cytometry

Telford, William G.; Murga, Matilde; Hawley, Teresa S.; Hawley, Robert G.; Packard, Beverly Z.; Komoriya, Akira; Haas, Fred J. L. M.; Hubert, Charles

doi:10.1002/cyto.a.20182

Cited by 69 publications

(36 citation statements)

References 17 publications

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“…This property allows the study of single cell characteristics within an otherwise homogeneous cell population. Furthermore, to our knowledge, this is the first study to make use of the newly available 561-nm laser lines for flow cytometry (43,44). This laser line, with an excitation close to the optimum for many low molecular markers in the yellowred range ("fruit basket" (45)), holds promise to be applied in multicolor studies in the future.…”

Section: Discussionmentioning

confidence: 99%

Systems Biological Analysis of Epidermal Growth Factor Receptor Internalization Dynamics for Altered Receptor Levels

Schmidt-Glenewinkel

Reinz

Eils

et al. 2009

Journal of Biological Chemistry

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Epidermal growth factor (EGF) receptor (EGFR) overexpression is a hallmark of many cancers. EGFR endocytosis is a critical step in signal attenuation, raising the question of how receptor expression levels affect the internalization process. Here we combined quantitative experimental and mathematical modeling approaches to investigate the role of the EGFR expression level on the rate of receptor internalization. Using tetramethylrhodamine-labeled EGF, we established assays for quantifying EGF-triggered EGFR internalization by both high resolution confocal microscopy and flow cytometry. We determined that the flow cytometry approach was more sensitive for examining large populations of cells. Mathematical modeling was used to investigate the relationship between EGF internalization kinetics, EGFR expression, and internalization machinery. We predicted that the standard parameter used to assess internalization kinetics, the temporal evolution r(t) of the ratio of internalized versus surface-located ligand⅐receptor complexes, does not describe a straight line, as proposed previously. Instead, a convex or concave curve occurs depending on whether initial receptor numbers or internalization adaptors are limiting the uptake reaction, respectively. To test model predictions, we measured EGF-EGFR binding and internalization in cells expressing different levels of green fluorescent protein-EGFR. As expected, surface binding of rhodaminelabeled EGF increased with green fluorescent protein-EGFR expression level. Unexpectedly, internalization of ligand⅐ receptor complexes increased linearly with increasing receptor expression level, suggesting that receptors and not internalization adaptors were limiting the uptake in our experimental model. Finally, determining the ratio of internalized versus surface-located ligand⅐receptor complexes for this cell line confirmed that it follows a convex curve, supporting our model predictions.

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Section: Discussionmentioning

confidence: 99%

Systems Biological Analysis of Epidermal Growth Factor Receptor Internalization Dynamics for Altered Receptor Levels

Schmidt-Glenewinkel

Reinz

Eils

et al. 2009

Journal of Biological Chemistry

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“…Indeed, higher signal-to-noise ratios can be achieved for some important fluorophores when excited with light at 562 nm compared to the more commonly available green lasers at 532 nm 6 . Significant effort has been going into developing high power lasers at wavelengths in the yellow and orange spectral region, but this remains technically challenging.…”

Section: Introductionmentioning

confidence: 99%

1.9 W yellow, CW, high-brightness light from a high efficiency semiconductor laser-based system

Hansen¹,

Christensen

Noordegraaf³

et al. 2017

SPIE Proceedings

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Semiconductor lasers are ideal sources for efficient electrical-to-optical power conversion and for many applications where their small size and potential for low cost are required to meet market demands. Yellow lasers find use in a variety of bio-related applications, such as photocoagulation, imaging, flow cytometry, and cancer treatment. However, direct generation of yellow light from semiconductors with sufficient beam quality and power has so far eluded researchers. Meanwhile, tapered semiconductor lasers at near-infrared wavelengths have recently become able to provide neardiffraction-limited, single frequency operation with output powers up to 8 W near 1120 nm.We present a 1.9 W single frequency laser system at 562 nm, based on single pass cascaded frequency doubling of such a tapered laser diode. The laser diode is a monolithic device consisting of two sections: a ridge waveguide with a distributed Bragg reflector, and a tapered amplifier. Using single-pass cascaded frequency doubling in two periodically poled lithium niobate crystals, 1.93 W of diffraction-limited light at 562 nm is generated from 5.8 W continuous-wave infrared light. When turned on from cold, the laser system reaches full power in just 60 seconds. An advantage of using a single pass configuration, rather than an external cavity configuration, is increased stability towards external perturbations. For example, stability to fluctuating case temperature over a 30 K temperature span has been demonstrated. The combination of high stability, compactness and watt-level power range means this technology is of great interest for a wide range of biological and biomedical applications.

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“…Compact, turn-key sources of picosecond radiation at 560 nm are in great demand for many fluorescence-based imaging techniques, including stimulated emission depletion microscopy (STED) [1], semiconductor characterization and biochemical analysis [2]. Pulsed semiconductor laser diodes operating at this wavelength have recently become commercially available but they suffer from limited average output power with an elliptical output beam and low degree of polarization.…”

Section: Introductionmentioning

confidence: 99%

Fiber-integrated frequency-doubling of a picosecond Raman laser to 560 nm

Runcorn¹,

Legg²,

Murray³

et al. 2015

Opt. Express

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Abstract:We report the development of a fiber-integrated picosecond source at 560 nm by second harmonic generation of a Raman fiber laser. A picosecond ytterbium master oscillator power fiber amplifier is used to pulse-pump a Raman amplifier, which is seeded by a continuous wave distributed feedback laser diode operating at 1120 nm. The pulse train generated at 1120 nm is frequency-doubled in a fiber-coupled periodicallypoled lithium niobate crystal module, producing 450 mW of average power at 560 nm with a pulse duration of 150 ps at a repetition rate of 47.5 MHz. The near diffraction-limited (M 2 = 1.02) collimated output beam is ideal for super-resolution microscopy applications.

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DPSS yellow‐green 561‐nm lasers for improved fluorochrome detection by flow cytometry

Cited by 69 publications

References 17 publications

Systems Biological Analysis of Epidermal Growth Factor Receptor Internalization Dynamics for Altered Receptor Levels

Systems Biological Analysis of Epidermal Growth Factor Receptor Internalization Dynamics for Altered Receptor Levels

1.9 W yellow, CW, high-brightness light from a high efficiency semiconductor laser-based system

Fiber-integrated frequency-doubling of a picosecond Raman laser to 560 nm

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