Influence of femtosecond laser pulse irradiation on the viability of cells at 1035, 517, and 345nm

Harzic, Ronan Le; Riemann, Iris; König, Karsten; Wüllner, Christian; Donitzky, Christof

doi:10.1063/1.2818107

Cited by 15 publications

(10 citation statements)

References 13 publications

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“…On the other hand, the pulse energy used in this paper (e.g., Fig. 5, ~0.15 nJ at the focus) is significantly below the nonlinear damage threshold for cultured cells [32,33], and approximately 50 to 100 times below the nonlinear ablative damage threshold [34,35]. Pulse energy much higher than the value used in this paper has been used in the past for in vivo 2photon imaging of the mouse brain [3,6].…”

Section: Discussionmentioning

confidence: 88%

Fiber-based tunable repetition rate source for deep tissue two-photon fluorescence microscopy

Charan

Wang

et al. 2018

Biomed. Opt. Express

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Deep tissue multiphoton imaging requires high peak power to enhance signal and low average power to prevent thermal damage. Both goals can be advantageously achieved through laser repetition rate tuning instead of simply adjusting the average power. We show that the ideal repetition rate for deep two-photon imaging in the mouse brain is between 1 and 10 MHz, and we present a fiber-based source with an arbitrarily tunable repetition rate within this range. The performance of the new source is compared to a mode-locked Ti:Sapphire (Ti:S) laser for imaging of mouse brain vasculature. At 2.5 MHz, the fiber source requires 5.1 times less average power to obtain the same signal as a standard Ti:S laser operating at 80 MHz.

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Section: Discussionmentioning

confidence: 88%

Fiber-based tunable repetition rate source for deep tissue two-photon fluorescence microscopy

Charan

Wang

et al. 2018

Biomed. Opt. Express

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“…[13]); a higher number indicates a better imaging throughput. It can be seen that for a medium repetition rate (100 kHz) and a tight focus (500 nm diameter), very high peak intensities (900 -2000 GW/cm 2 ) can be used [24]. This comes, however, at the cost of a very inefficient imaging process.…”

Section: Proliferation Assay On Hek Cellsmentioning

confidence: 99%

“…The likelihood of producing ROS, avalanche breakdown, or simply thermal damage increases if the system is already in an excited state. Consequently, a significant improvement in the illumination (dwell) [24] Abbreviations: CHO: Chinese hamster ovary [24]; AC: Adrenal chromaffin [9]; HEK: human embryo kidney [25].…”

Section: Proliferation Assay On Hek Cellsmentioning

confidence: 99%

Wide-field medium-repetition-rate multiphoton microscopy reduces photodamage of living cells

Macias-Romero

Zubkovs

Roke

2016

Biomed. Opt. Express

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Demands of higher spatial and temporal resolutions in linear and nonlinear imaging keep pushing the limits of optical microscopy. We showed recently that a multiphoton microscope with 200 kHz repetition rate and wide-field illumination has a 2-3 orders of magnitude improved throughput compared to a high repetition rate confocal scanning microscope. Here, we examine the photodamage mechanisms and thresholds in live cell imaging for both systems. We first analyze theoretically the temperature increase in an aqueous solution resulting from illuminating with different repetition rates (keeping the deposited energy and irradiated volume constant). The analysis is complemented with photobleaching experiments of a phenolsulfonphthalein (phenol red) solution. Combining medium repetition rates and wide-field illumination promotes thermal diffusivity, which leads to lower photodamage and allows for higher peak intensities. A three day proliferation assay is also performed on living cells to confirm these results: dwell times can be increased by a factor of 3×10(6) while still preserving cell proliferation. By comparing the proliferation data with the endogenous two-photon fluorescence decay, we propose to use the percentage of the remaining endogenous two-photon fluorescence after exposure as a simple in-situ viability test. These findings enable the possibility of long-term imaging and reduced photodamage.

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“…The opposite is the direction of the dependence on the pulse energy of the illumination fluence. At the same time, with 1.7 μJ of the pulse energy at the sample in our measurement, the fluence is less than 1 mJ/cm 2 , which is well below the known damaging thresholds for different kinds of live cells [17][18][19] and even more so in the case of the tissue samples, where maintaining the cell vivacity is not an issue. In fact, the mouse skin sample did not exhibit any signs of degradation even with ~50× higher fluence in the initial measurement for the maximum image size with only a 4× expanded laser beam and a 40× magnification illumination objective.…”

Section: Imaging Of Large Sample Areasmentioning

confidence: 56%

Optimization of wide-field second-harmonic generation microscopy for fast imaging of large sample areas in biological tissues

Dementjev¹,

Rudys²,

Karpicz³

et al. 2020

Lith. J. Phys.

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Second-harmonic generation (SHG) microscopy is a label-free imaging method that can be used to visualize the detailed arrangement of collagen structures in biological tissues. Here, we sought to optimize the speed of microscopic SHG image acquisition of macroscopic fixed tissue sample areas by employing the wide-field imaging with a high power and medium, 1 MHz pulse repetition frequency laser in combination with a mechanical sample scanning. Unlike in the conventional laser-scanning microscopy, the optimum of the wide-field acquisition entails an interplay between the size of the illuminated area and the intensity of the generated signal. We delineate quantitative procedures to set the image parameters for the maximum speed of the tiled image acquisition, and also describe the possible optimization of the laser parameters for further enhancement of the speed of acquisition.

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Influence of femtosecond laser pulse irradiation on the viability of cells at 1035, 517, and 345nm

Cited by 15 publications

References 13 publications

Fiber-based tunable repetition rate source for deep tissue two-photon fluorescence microscopy

Fiber-based tunable repetition rate source for deep tissue two-photon fluorescence microscopy

Wide-field medium-repetition-rate multiphoton microscopy reduces photodamage of living cells

Optimization of wide-field second-harmonic generation microscopy for fast imaging of large sample areas in biological tissues

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