Item request has been placed!
×
Item request cannot be made.
×
Processing Request
COMPUTATIONAL STUDY OF GEOMETRIC EFFECTS OF BOTTOM WALL MICROGROOVES ON CELL DOCKING INSIDE MICROFLUIDIC DEVICES.
Item request has been placed!
×
Item request cannot be made.
×
Processing Request
- Author(s): AHANDOUST, SINA1 (AUTHOR) ; SAADATMAND, MARYAM2 (AUTHOR)
- Source:
Journal of Mechanics in Medicine & Biology. Mar2021, Vol. 21 Issue 2, pN.PAG-N.PAG. 20p.
- Subject Terms:
- Additional Information
- Abstract:
Cells docking inside microfluidic devices is effective in studying cell biology, cell-based biosensing, as well as drug screening. Furthermore, single cell and regularly cells docking inside the microstructure of microfluidic systems are advantageous in different analyses of single cells exposed to equal drug concentration and mechanical stimulus. In this study, we investigated bottom wall microgrooves with semicircular and rectangular geometries with different sizes which are suitable for single cell docking along the length of the microgroove in x -direction and numerous cells docking regularly in one line inside the microgroove in a 3D microchannel. We used computational fluid dynamics to analyze the fluid recirculation area inside different microgrooves. The height of recirculation area in the bottom of microgroove could affect the cell's attachment, and also materials delivery to attached cells, so the height of recirculation area may have optimum value. In addition, we analyzed the fluid drag force on cell movement toward the microgroove. This parameter was proportional to the fluid velocities in x and y directions in different microgrooves geometries. In different microgrooves' geometries the fluid velocity in y -direction did not change, but the fluid velocity in x -direction decreased inside the microgroove. Therefore, the cell movement time inside the microgroove increased, and also the drag force in y -direction could push the cells toward the bottom due to the lower drag force in x -direction. The percentages of negative shear stress and average shear stress on the adhered cell surface were also calculated. The lower average shear stress, and negative shear stress around 50% on the cell surface were against cell detachment from the substrate. The results indicated that at the constant fluid inlet velocity and microchannel height, microgroove geometry and ratio of cell size to the microgroove size play pivotal roles in the cell initial adhesion to the substrate as well as the cell detachment. [ABSTRACT FROM AUTHOR]
- Abstract:
Copyright of Journal of Mechanics in Medicine & Biology is the property of World Scientific Publishing Company and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)
No Comments.