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thesis defence : Maxime Fauconnier
On The November 19, 2021
at 9.30 a.m.
At LaBTaU laboratory, 151, cours Albert Thomas - 69424 LYON Cedex 03 - France
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81292735@t.plcm.vc
Video Conference ID: 127 038 791 2
Alternative VTC instructions
or via Teams
Join on your computer or mobile app
Click here to join the PhD Defense
Join with a video conferencing device
81292735@t.plcm.vc
Video Conference ID: 127 038 791 2
Alternative VTC instructions
Characterisation of the membrane deformation of a biological cell induced by cavitation microbubbles, for the improvement of the sonoporation phenomenon
We will be pleased to welcome Hélène Delanoë-Ayari (University of Lyon), Bertrand Dubus (University of Lille), Valeria Garbin (University of Delft) and Michiel Postema (University of Tampere) as members of the jury.
On the menu of the day, there will be oscillating non-spherical micro-bubbles and micro-flow, but also mechanical interaction with biological cells.
The presentation will be given in English, and you can already find the abstract on the link below: click
Abstract:
It is widely accepted that, ultrasound contrast agents used as acoustic resonators help in enhancing the delivery of genes and drugs into biological cells. Employed as mechanical transducers, their energy allows to locally permeabilize cell membranes through a process called sonoporation. Because of its stochastic, complex and rapidly-evolving behaviour, the motion of thousands of oscillating microbubbles interacting with as many cells is a phenomenon hard to capture and predict. This is why several experimental studies investigate sonoporation either post-ultrasound exposure especially by flow cytometry measurement and scanning electron microscopy either during ultrasound exposure with the internalization of fluorescent dyes or by patch-clamp techniques that allow the monitoring of abnormal changes in the transmembrane current. In such works where the microbubbles are clearly identified as main actor in the sonoporation, their time-resolved dynamics is left to the side, while it might actually play an important role. Two distinct mechanisms caused by the bubble oscillation may be responsible for sonoporation. First, the direct deformation of the cell by the oscillating bubble, occurring at the acoustic time scale, may create pores in the membrane, when sufficiently stretched. Second, due to a nonlinear response at high pressure, the surrounding fluid may be subject to microstreaming, occurring at a slower time scale, which is likely to generate shear stresses on the cell membrane. In order to enhance these two acoustofluidics mechanisms and hopefully the cell sonoporation, large-amplitude bubble oscillations are required. However, because violent bubble oscillations – possibly their collapse – can lead to cells death instead of cells poration, reaching high-amplitude oscillations of stable microbubbles is crucial. Such large dynamics involve the appearance of nonspherical bubble deformations. With the view to study these nonspherical bubble shape modes, their physics and their possible action on a nearby biological cell, this thesis work presents an experimental work in three stages. First, the oscillatory dynamics of a single bubble attached to a wall is studied, in particular through the conditions for the emergence of its nonspherical modes. Second, the appearance of microstreaming induced by such a nonspherical bubble is analyzed on the basis of a quantitative description of its interface. Lastly, this knowledge acquired on an oscillating bubble is transposed to the configuration of a bubble-cell pair. The bubble-induced mechanical effects that apply on the cell are assessed at both the acoustic and the fluidic time scales.
On the menu of the day, there will be oscillating non-spherical micro-bubbles and micro-flow, but also mechanical interaction with biological cells.
The presentation will be given in English, and you can already find the abstract on the link below: click
Abstract:
It is widely accepted that, ultrasound contrast agents used as acoustic resonators help in enhancing the delivery of genes and drugs into biological cells. Employed as mechanical transducers, their energy allows to locally permeabilize cell membranes through a process called sonoporation. Because of its stochastic, complex and rapidly-evolving behaviour, the motion of thousands of oscillating microbubbles interacting with as many cells is a phenomenon hard to capture and predict. This is why several experimental studies investigate sonoporation either post-ultrasound exposure especially by flow cytometry measurement and scanning electron microscopy either during ultrasound exposure with the internalization of fluorescent dyes or by patch-clamp techniques that allow the monitoring of abnormal changes in the transmembrane current. In such works where the microbubbles are clearly identified as main actor in the sonoporation, their time-resolved dynamics is left to the side, while it might actually play an important role. Two distinct mechanisms caused by the bubble oscillation may be responsible for sonoporation. First, the direct deformation of the cell by the oscillating bubble, occurring at the acoustic time scale, may create pores in the membrane, when sufficiently stretched. Second, due to a nonlinear response at high pressure, the surrounding fluid may be subject to microstreaming, occurring at a slower time scale, which is likely to generate shear stresses on the cell membrane. In order to enhance these two acoustofluidics mechanisms and hopefully the cell sonoporation, large-amplitude bubble oscillations are required. However, because violent bubble oscillations – possibly their collapse – can lead to cells death instead of cells poration, reaching high-amplitude oscillations of stable microbubbles is crucial. Such large dynamics involve the appearance of nonspherical bubble deformations. With the view to study these nonspherical bubble shape modes, their physics and their possible action on a nearby biological cell, this thesis work presents an experimental work in three stages. First, the oscillatory dynamics of a single bubble attached to a wall is studied, in particular through the conditions for the emergence of its nonspherical modes. Second, the appearance of microstreaming induced by such a nonspherical bubble is analyzed on the basis of a quantitative description of its interface. Lastly, this knowledge acquired on an oscillating bubble is transposed to the configuration of a bubble-cell pair. The bubble-induced mechanical effects that apply on the cell are assessed at both the acoustic and the fluidic time scales.
