Roy Ikink scite author profile

The fluid dynamic interaction of cavitation bubbles with adherent cells on a substrate is experimentally investigated. We find that the nonspherical collapse of bubbles near to the boundary is responsible for cell detachment. High-speed photography reveals that a wall bounded flow leads to the detachment of cells. Cells at the edge of the circular area of detachment are found to be permanently porated, whereas cells at some distance from the detachment area undergo viable cell membrane poration (sonoporation). The wall flow field leading to cell detachment is modeled with a self-similar solution for a wall jet, together with a kinetic ansatz of adhesive bond rupture. The self-similar solution for the delta-type wall jet compares very well with the full solution of the Navier-Stokes equation for a jet of finite thickness. Apart from annular sites of sonoporation we also find more homogenous patterns of molecule delivery with no cell detachment.

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Shock-Wave-Induced Jetting of Micron-Size Bubbles

Ohl

2003

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Free gas bubbles in water with radii between 7 and 55 m subjected to a shock wave exhibit a liquid jetting phenomenon with the jet pointing in the direction of the propagating shock wave. With increasing bubble radius, the length of the jet tip increases and a lower estimate of the averaged jet velocity increases linearly from 20 to 150 m=s. At a later stage, the jet breaks up and releases micronsize bubbles. In the course of shock wave permeabilization and transfection of biological cells, this observation suggests a microinjection mechanism when the cells are near bubbles exposed to a shock wave.

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Cell detachment method using shock-wave–induced cavitation

Junge

Ohl

Wolfrum

et al. 2003

Ultrasound in Medicine & Biology

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Shock induced jetting of micron sized bubbles

Ohl

Ikink

Lohse

et al. 2002

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Gas bubbles having a radius between 10 μm and 100 μm and rising freely in water when being subjected to a shock front exhibit a liquid jetting phenomenon. The jet points in the direction of the propagating shock wave. A linear relationship between the jet length and the bubble radius is found and a lower bound of the averaged velocity of the liquid jet can be estimated to be between 50 m/s and 300 m/s increasing linearly for larger bubbles. In a later stage the jet breaks up and releases micron sized bubbles. In the course of shock wave mediated cell permeabilization this observation suggests a microinjection mechanism responsible for cell transfection when minute gas bubbles are present and exposed together with cells to shock waves.

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Roy Ikink

Sonoporation from Jetting Cavitation Bubbles

Shock-Wave-Induced Jetting of Micron-Size Bubbles

Cell detachment method using shock-wave–induced cavitation

Shock induced jetting of micron sized bubbles

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