Plasma Mediated off-Resonance Plasmonic Enhanced Ultrafast Laser-Induced Nanocavitation

Boulais, Étienne; Lachaine, R.; Meunier, Michel

doi:10.1021/nl302200w

Cited by 173 publications

(225 citation statements)

References 55 publications

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“…However, the best rule is to avoid such distorted signals because they may lead to misinterpretation of the bubble parameters. 58 In all three considered cases (single NB, single NB with misaligned probe beam, and multiple NBs), the durations of the bubble-specific signals could be linked to the maximal diameter of the NB (or the largest NB as in Figure 2(b-I)), while their amplitudes differed significantly and, therefore, their use as NB metrics may lead to artifacts. 59 The third method of NB detection employs the pressure waves generated during the bubble expansion and collapse 23,26 ( Figure 1(c)).…”

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confidence: 87%

“…If such absorbance emerges (due to plasma formation or any non-linear modification of the optical properties of the media), the method may characterize an NB incorrectly. 58,59 In another method, the beam is pointed off the detector aperture and produces a low base level at the detector. In this case, only the light scattered by an NB will reach the detector and will increase its output signal, also producing a time-response with a bubble-specific shape.…”

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confidence: 99%

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Experimental techniques for imaging and measuring transient vapor nanobubbles

Lukianova‐Hleb

Lapotko

2012

Applied Physics Letters

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Imaging and measuring transient vapor bubbles at nanoscale pose certain experimental challenges due to their reduced dimensions and lifetimes, especially in a single event experiment. Here, we analyze three techniques that employ optical scattering and acoustic detection in identifying and quantifying individual photothermally induced vapor nanobubbles (NBs) at a wide range of excitation energies. In optically transparent media, the best quantitative detection can be achieved by measuring the duration of the optical scattering time-response, while in an opaque media, the amplitude of the acoustic time-response well describes NBs in the absence of stress waves. Transient thermal evaporation and the generation of vapor bubbles are one of the basic processes accompanying non-stationary high-temperature heat-and mass-transfer in liquids. The science and the methods for the detection of inertial vapor bubbles of various origins were well developed for macro-and micro-sized bubbles and mainly employ their ability to emit pressure and to scatter the incident light. Recent developments in nanoscience reduced the spatial and temporal scale of vapor bubbles to nanometers and nanoseconds. [7][8][9][10]23,[27][28][29][30][31][32][33] Unlike their larger analogs, vapor nanobubbles (NBs) require much higher sensitivity and resolution of the detection methods for their imaging, quantification, and identification among other phenomena, such as transient heating and the generation of stress waves. Here, we analyze several experimental techniques for the imaging and quantitative analysis of transient vapor nanobubbles as single events and we troubleshoot some related errors. Due to the multiple biomedical applications of NBs and related phenomena, [34][35][36][37][38] it should be noted that we consider the transient events, but not the materials (particles) that are often also called nanobubbles.39, 40 We also do not consider the cavitation of preexisting bubbles that is well studied elsewhere. 41 While NBs may have various sources of energy (the heating of liquid above the boiling threshold, local rarefaction, and plasma discharge), we employed an experimental model of a single NB in water. Such a model provides maximal precision, control, and reproducibility in NB generation through the localized transient photothermal heating of liquid above the evaporation point. This was achieved through the optical excitation of individual 60 nm gold nanospheres in water with single short laser pulses (70 ps and 532 nm) at specific fluences above the NB generation threshold. We used the plasmonic conversion of optical energy into heat to control the maximal diameter and lifetime of the NBs through the fluence of a single laser pulse, as described in detail previously. [8][9][10]33 This experimental model includes an internal metal nanoparticle (NP) that acts as the source of the bubble energy during bubble generation and prevents the development of extreme temperatures and sonoluminescence at the collapse stage, 8,42 unlike "classical" bu...

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confidence: 87%

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confidence: 99%

Experimental techniques for imaging and measuring transient vapor nanobubbles

Lukianova‐Hleb

Lapotko

2012

Applied Physics Letters

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“…The interactions, which lead to membrane permeabilization, are based on heating of the particle or nanocavitation due to the near-field enhancement. 6,7 The main disadvantage of all techniques is the incubation with the gold nanoparticles. First, it is time-consuming, which limits the high-throughput applicability in routine usage.…”

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confidence: 99%

Immobilization of gold nanoparticles on cell culture surfaces for safe and enhanced gold nanoparticle-mediated laser transfection

et al. 2014

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“…We have shown that the LIB of trapped polystyrene nanoparticles significantly reduced the energy required for cavitation [6,7]. This leads to the permeabilization of cell membranes and transfection of cells in a targeted area in the absence of a lysis zone of cells.Gold nanoparticle clusters have played a key role in this field, through antibody binding and sequestration with subsequent irradiation by nanosecond or femtosecond laser pulses [8][9][10]. A unique interaction of gold nanoparticles with light, known as surface plasmon resonance, can lead to strong absorption of light for heat generation.…”

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confidence: 99%

“…Gold nanoparticle clusters have played a key role in this field, through antibody binding and sequestration with subsequent irradiation by nanosecond or femtosecond laser pulses [8][9][10]. A unique interaction of gold nanoparticles with light, known as surface plasmon resonance, can lead to strong absorption of light for heat generation.…”

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confidence: 99%

Laser-induced breakdown of an optically trapped gold nanoparticle for single cell transfection

et al. 2013

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The cell selective introduction of therapeutic agents remains a challenging problem. Here we demonstrate spatially controlled cavitation instigated by laser-induced breakdown of an optically trapped single gold nanoparticle of diameter 100 nm. The energy breakdown threshold of the gold nanoparticle with a single nanosecond laser pulse at 532 nm is three orders of magnitude lower than water, which leads to nanocavitation allowing single cell transfection. We quantify the shear stress to cells from the expanding bubble and optimize the pressure to be in the range of 1-10 kPa for transfection. The transfection of genes and injection of therapeutic agents into individual mammalian cells are among the most important research tools in modern molecular biology [1]. The use of acoustic bubbles in the proximity of cells oscillated by ultrasonic irradiation (insonation) can lead to enhanced membrane permeabilization of cells, and is known as sonoporation. Acoustic streaming, shock waves, and liquid microjets associated with the dynamics of cavitation bubble are implicated in gene and drug delivery into cells [2]. This approach, however, often leads to nonuniform and sporadic molecular uptake that lacks cell selectivity and suffers from a significant loss of cell viability. Recently a suite of optical methods in the domain of cavitation-based therapies has provided the potential of sterility, reconfigurability, and single cell selectivity [3]. Laser-induced breakdown (LIB) of a liquid medium containing cells, has demonstrated cell lysis, necrosis or membrane permeabilization, with the outcome dependent upon the hydrodynamic shear stress to cells caused by the expanding bubble [4]. However, the relatively high energy deposition required for this process resulted in a much larger cavitation bubble (typically >200 μm in diameter) compared to the typical cell size that effectively reduces cell viability and has been detrimental to allow its wider usage.More spatially controlled cavitation may be achieved by optically trapping particles for subsequent LIB instead of the surrounding liquid [5]. Optical tweezers allow the positioning of individual nanoparticles or microparticles at a desired location within the buffer medium. Therefore, using this tool for LIB offers additional degrees of freedom-the particle material, its size, and the LIB position relative to cells or tissues. We have shown that the LIB of trapped polystyrene nanoparticles significantly reduced the energy required for cavitation [6,7]. This leads to the permeabilization of cell membranes and transfection of cells in a targeted area in the absence of a lysis zone of cells.Gold nanoparticle clusters have played a key role in this field, through antibody binding and sequestration with subsequent irradiation by nanosecond or femtosecond laser pulses [8][9][10]. A unique interaction of gold nanoparticles with light, known as surface plasmon resonance, can lead to strong absorption of light for heat generation. However, the introduction of gold nanoparticles in the c...

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Plasma Mediated off-Resonance Plasmonic Enhanced Ultrafast Laser-Induced Nanocavitation

Cited by 173 publications

References 55 publications

Experimental techniques for imaging and measuring transient vapor nanobubbles

Experimental techniques for imaging and measuring transient vapor nanobubbles

Immobilization of gold nanoparticles on cell culture surfaces for safe and enhanced gold nanoparticle-mediated laser transfection

Laser-induced breakdown of an optically trapped gold nanoparticle for single cell transfection

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