Publications by authors named "A Kabla"
Dependence of acoustophoretic aggregation on the impedance of microchannel's walls.
Comput Methods Programs Biomed
November 2024
Background And Objectives: Acoustofluidic manipulation of particles and biological cells has been widely applied in various biomedical and engineering applications, including effective separation of cancer cell, point-of-care diagnosis, and cell patterning for tissue engineering. It is often implemented within a polydimethylsiloxane (PDMS) microchannel, where standing surface acoustic waves (SSAW) are generated by sending two counter-propagating ultrasonic waves on a piezoelectric substrate.
Methods: In this paper, we develop a full cross-sectional model of the acoustofluidic device using finite element method, simulating the wave excitation on the substrate and wave propagation in both the fluid and the microchannel wall.
To fulfil their function, epithelial tissues need to sustain mechanical stresses and avoid rupture. Although rupture is usually undesired, it is central to some developmental processes, for example, blastocoel formation. Nonetheless, little is known about tissue rupture because it is a multiscale phenomenon that necessitates comprehension of the interplay between mechanical forces and biological processes at the molecular and cellular scales.
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- Epithelial cells respond to sustained strains in two ways: typical stress relaxation and a unique tensioning process that increases stress levels.
- This tensioning response is influenced by the rate of strain, with more cells exhibiting this behavior as the strain rate increases.
- Actin remodeling plays a crucial role in this process, indicating that cell contractility helps epithelial cells adapt to environmental stress, acting as a protective mechanism.
Living cells are out of equilibrium active materials. Cell-generated forces are transmitted across the cytoskeleton network and to the extracellular environment. These active force interactions shape cellular mechanical behaviour, trigger mechano-sensing, regulate cell adaptation to the microenvironment and can affect disease outcomes.
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- The orientation of a cell's mitotic spindle during division is crucial for cell fate, tissue shape, and architecture, with divisions parallel to the epithelial plane supporting tissue growth, while perpendicular divisions may lead to stratification and potential metastasis.
- Although the molecular mechanisms regulating spindle orientation are well-understood, the impact of mechanical factors like tissue tension on this process is less explored, despite epithelia being subject to mechanical stress.
- Experimental findings indicate that reducing tissue tension leads to more divisions that are not aligned with the epithelial plane, whereas increasing tension helps restore proper division orientation, suggesting that proper spindle alignment requires a certain level of tension at the junctions between cells.