<i>In vitro</i> methods to study bubble-cell interactions: Fundamentals and therapeutic applications

Lajoinie, Guillaume; Cock, Ine De; Coussios, Constantin C.; Lentacker, Ine; Gac, Séverine Le; Stride, Eleanor; Versluis, Michel

doi:10.1063/1.4940429

Cited by 49 publications

(63 citation statements)

References 200 publications

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“…The OptiCell TM (Nunc, Thermo Fisher Scientific, Wiesbaden, Germany) has been extensively used for both microbubble characterization and drug delivery studies [3]. Since the OptiCell is no longer being manufactured, the CLINIcell R (MABIO, Tourcoing, France) is an interesting alternative imaging and cell culture chamber.…”

Section: Introductionmentioning

confidence: 99%

Acoustic Characterization of the CLINIcell for Ultrasound Contrast Agent Studies

Beekers

Rooij

Steen

et al. 2019

IEEE Trans. Ultrason., Ferroelect., Freq. Contr.

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Section: Introductionmentioning

confidence: 99%

Acoustic Characterization of the CLINIcell for Ultrasound Contrast Agent Studies

Beekers

Rooij

Steen

et al. 2019

IEEE Trans. Ultrason., Ferroelect., Freq. Contr.

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“…To achieve these aims, we rely on well-known analytical models that reproduce the observed fluid flow in very good approximation. Our results show that flow measurements can be used as diagnostics for the bubble dynamics which could additionally lead to optimization of the energy delivered to the system in real applications (Fernandez Rivas et al 2010;Verhaagen 2012;Lajoinie et al 2016). The precise determination of the different bubble oscillation regimes (linear, nonlinear, bubble emission) could allow for considerable energy savings, and a significant enhancement in control and reliability of processes.…”

mentioning

confidence: 99%

Streaming flow by oscillating bubbles: quantitative diagnostics via particle tracking velocimetry

et al. 2017

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Oscillating microbubbles can be used as microscopic agents. Using external acoustic fields they are able to set the surrounding fluid into motion, erode surfaces and even to carry particles attached to their interfaces. Although the acoustic streaming flow that the bubble generates in its vicinity has been often observed, it has never been measured and quantitatively compared with the available theoretical models. The scarcity of quantitative data is partially due to the strong three-dimensional character of bubble-induced streaming flows, which demands advanced velocimetry techniques. In this work, we present quantitative measurements of the flow generated by single and pairs of acoustically excited sessile microbubbles using a three-dimensional particle tracking technique. Using this novel experimental approach we are able to obtain the bubble's resonant oscillating frequency, study the boundaries of the linear oscillation regime, give predictions on the flow strength and the shear in the surrounding surface and study the flow and the stability of a two-bubble system. Our results show that velocimetry techniques are a suitable tool to make diagnostics on the dynamics of acoustically excited microbubbles.

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“…[26][27][28] Zhou et al showed that the impact of the microbubble on the membrane permeability decreased dramatically with increasing distance between the cell and the bubble. [26][27][28] Zhou et al showed that the impact of the microbubble on the membrane permeability decreased dramatically with increasing distance between the cell and the bubble.…”

Section: Introductionmentioning

confidence: 99%

Sonoporation of Cells by a Parallel Stable Cavitation Microbubble Array

et al. 2019

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Sonoporation is a targeted drug delivery technique that employs cavitation microbubbles to generate transient pores in the cell membrane, allowing foreign substances to enter cells by passing through the pores. Due to the broad size distribution of microbubbles, cavitation events appear to be a random process, making it difficult to achieve controllable and efficient sonoporation. In this work a technique is reported using a microfluidic device that enables in parallel modulation of membrane permeability by an oscillating microbubble array. Multirectangular channels of uniform size are created at the sidewall to generate an array of monodispersed microbubbles, which oscillate with almost the same amplitude and resonant frequency, ensuring homogeneous sonoporation with high efficacy. Stable harmonic and high harmonic signals emitted by individual oscillating microbubbles are detected by a laser Doppler vibrometer, which indicates stable cavitation occurred. Under the influence of the acoustic radiation forces induced by the oscillating microbubble, single cells can be trapped at an oscillating microbubble surface. The sonoporation of single cells is directly influenced by the individual oscillating microbubble. The parallel sonoporation of multiple cells is achieved with an efficiency of 96.6 ± 1.74% at an acoustic pressure as low as 41.7 kPa.

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In vitro methods to study bubble-cell interactions: Fundamentals and therapeutic applications

Cited by 49 publications

References 200 publications

Acoustic Characterization of the CLINIcell for Ultrasound Contrast Agent Studies

Acoustic Characterization of the CLINIcell for Ultrasound Contrast Agent Studies

Streaming flow by oscillating bubbles: quantitative diagnostics via particle tracking velocimetry

Sonoporation of Cells by a Parallel Stable Cavitation Microbubble Array

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