Your search keyword '"Almanza, G."' showing total 2 results

1. Effect of the shear rate and residence time on the lysis of AC16 human cardiomyocyte cells via surface acoustic waves.

Author

Almanza, G., Trujillo, R. M., Sanchez-Saldaña, D., Rosand, Ø., Høydal, M., Fernandino, M., and Dorao, C. A.

Subjects

*ACOUSTIC surface waves, *ACOUSTIC streaming, *LYSIS, *DENSITY

Abstract

The efficient breakage of one cell or a concentration of cells for releasing intracellular material such as DNA, without damaging it, is the first step for several diagnostics or treatment processes. As the cell membrane is easy to bend but resistant to stretching, the exposure of the cell to a shear rate during a short period of time can be sufficient to damage the membrane and facilitate the extraction of DNA. However, how to induce high shear stresses on cells in small microliter volumes samples has remained an elusive problem. Surface acoustic waves operating at high frequencies can induce acoustic streaming leading to shear rates sufficient to cell lysis. Lysis induced by acoustic streaming in sessile droplets has been investigated in the past from the lysis efficiency point of view. However, the effects of the velocity field and shear rate induced by acoustic streaming on the lysis process remain unexplored. Here, we study the lysis of AC16 human cardiomyocytes in microliter droplets under the effect of the shear rate induced by acoustic streaming. It is identified that for a given shear rate, the extracted DNA is also affected by the actuation period which can be attributed to a cycling process that leads to an accumulation of damage on the cell membrane. [ABSTRACT FROM AUTHOR]

Published

2023

2. In-droplet cell lysis of AC16 human cardiomyocyte cells via surface acoustic waves.

Author

Trujillo, R. M., Almanza, G., Sanchez-Saldaña, D., Rosand, Ø., Høydal, M., Fernandino, M., and Dorao, C. A.

Subjects

*ACOUSTIC surface waves, *LYSIS, *ACOUSTIC streaming, *ACOUSTIC wave propagation, *CELL size, *CELL survival

Abstract

Although several lysis methods are available, biomedical applications are pushing the demand for miniaturised systems and thus for new ways to lyse cells in small volumes. In this work, we demonstrate in-droplet cell lysis of AC16 human cardiomyocyte cells in 20 μL droplets using high frequency surface acoustic waves. The acoustic streaming leads to high shear flow creating porous or breaking the cell membrane and releasing intracellular material. Contrary to previous work where the lysis efficiency is measured by a cell-permeant dye that can be used to determine cell viability, here we propose to quantify the DNA extracted from the cells as a measure of the lysis efficiency. This reagent-free method provides a valuable cell lysis alternative for many biological and biomedical applications, particularly for the development of point-of-care platforms. [ABSTRACT FROM AUTHOR]

Published

2023