Your search keyword '"tortuous microchannel devices"' showing total 4 results

1. Effect of Geometric Curvature on Collective Cell Migration in Tortuous Microchannel Devices

Author

Mazlee Bin Mazalan, Mohamad Anis Bin Ramlan, Jennifer Hyunjong Shin, and Toshiro Ohashi

Subjects

collective cell migration, tortuous microchannel devices, engineered tissue-scaffold, Mechanical engineering and machinery, TJ1-1570

Abstract

Collective cell migration is an essential phenomenon in many naturally occurring pathophysiological processes, as well as in tissue engineering applications. Cells in tissues and organs are known to sense chemical and mechanical signals from the microenvironment and collectively respond to these signals. For the last few decades, the effects of chemical signals such as growth factors and therapeutic agents on collective cell behaviors in the context of tissue engineering have been extensively studied, whereas those of the mechanical cues have only recently been investigated. The mechanical signals can be presented to the constituent cells in different forms, including topography, substrate stiffness, and geometrical constraint. With the recent advancement in microfabrication technology, researchers have gained the ability to manipulate the geometrical constraints by creating 3D structures to mimic the tissue microenvironment. In this study, we simulate the pore curvature as presented to the cells within 3D-engineered tissue-scaffolds by developing a device that features tortuous microchannels with geometric variations. We show that both cells at the front and rear respond to the varying radii of curvature and channel amplitude by altering the collective migratory behavior, including cell velocity, morphology, and turning angle. These findings provide insights into adaptive migration modes of collective cells to better understand the underlying mechanism of cell migration for optimization of the engineered tissue-scaffold design.

Published

2020

2. Effect of Geometric Curvature on Collective Cell Migration in Tortuous Microchannel Devices

Author

Bin Mazalan, Mazlee, Bin Ramlan, Mohamad Anis, Shin, Jennifer Hyunjong, 1000030270812, Ohashi, Toshiro, Bin Mazalan, Mazlee, Bin Ramlan, Mohamad Anis, Shin, Jennifer Hyunjong, 1000030270812, and Ohashi, Toshiro

Abstract

Collective cell migration is an essential phenomenon in many naturally occurring pathophysiological processes, as well as in tissue engineering applications. Cells in tissues and organs are known to sense chemical and mechanical signals from the microenvironment and collectively respond to these signals. For the last few decades, the effects of chemical signals such as growth factors and therapeutic agents on collective cell behaviors in the context of tissue engineering have been extensively studied, whereas those of the mechanical cues have only recently been investigated. The mechanical signals can be presented to the constituent cells in different forms, including topography, substrate stiffness, and geometrical constraint. With the recent advancement in microfabrication technology, researchers have gained the ability to manipulate the geometrical constraints by creating 3D structures to mimic the tissue microenvironment. In this study, we simulate the pore curvature as presented to the cells within 3D-engineered tissue-scaffolds by developing a device that features tortuous microchannels with geometric variations. We show that both cells at the front and rear respond to the varying radii of curvature and channel amplitude by altering the collective migratory behavior, including cell velocity, morphology, and turning angle. These findings provide insights into adaptive migration modes of collective cells to better understand the underlying mechanism of cell migration for optimization of the engineered tissue-scaffold design.

Published

2020

3. Effect of Geometric Curvature on Collective Cell Migration in Tortuous Microchannel Devices

Author

Mohamad Anis Bin Ramlan, Toshiro Ohashi, Mazlee Mazalan, and Jennifer Hyunjong Shin

Subjects

lcsh:Mechanical engineering and machinery, Constraint (computer-aided design), Context (language use), 02 engineering and technology, Curvature, Article, 03 medical and health sciences, Tissue engineering, lcsh:TJ1-1570, Electrical and Electronic Engineering, 030304 developmental biology, Physics, 0303 health sciences, Microchannel, collective cell migration, Mechanical Engineering, Collective cell migration, Cell migration, engineered tissue-scaffold, 021001 nanoscience & nanotechnology, tortuous microchannel devices, Control and Systems Engineering, 0210 nano-technology, Biological system, Microfabrication

Abstract

Collective cell migration is an essential phenomenon in many naturally occurring pathophysiological processes, as well as in tissue engineering applications. Cells in tissues and organs are known to sense chemical and mechanical signals from the microenvironment and collectively respond to these signals. For the last few decades, the effects of chemical signals such as growth factors and therapeutic agents on collective cell behaviors in the context of tissue engineering have been extensively studied, whereas those of the mechanical cues have only recently been investigated. The mechanical signals can be presented to the constituent cells in different forms, including topography, substrate stiffness, and geometrical constraint. With the recent advancement in microfabrication technology, researchers have gained the ability to manipulate the geometrical constraints by creating 3D structures to mimic the tissue microenvironment. In this study, we simulate the pore curvature as presented to the cells within 3D-engineered tissue-scaffolds by developing a device that features tortuous microchannels with geometric variations. We show that both cells at the front and rear respond to the varying radii of curvature and channel amplitude by altering the collective migratory behavior, including cell velocity, morphology, and turning angle. These findings provide insights into adaptive migration modes of collective cells to better understand the underlying mechanism of cell migration for optimization of the engineered tissue-scaffold design.

Published

2020

4. Effect of Geometric Curvature on Collective Cell Migration in Tortuous Microchannel Devices.

Author

Mazalan, Mazlee Bin, Ramlan, Mohamad Anis Bin, Shin, Jennifer Hyunjong, and Ohashi, Toshiro

Subjects

*CELL migration, *TISSUE scaffolds, *CURVATURE, *COLLECTIVE behavior, *TISSUE engineering, *CHEMICAL detectors

Abstract

Collective cell migration is an essential phenomenon in many naturally occurring pathophysiological processes, as well as in tissue engineering applications. Cells in tissues and organs are known to sense chemical and mechanical signals from the microenvironment and collectively respond to these signals. For the last few decades, the effects of chemical signals such as growth factors and therapeutic agents on collective cell behaviors in the context of tissue engineering have been extensively studied, whereas those of the mechanical cues have only recently been investigated. The mechanical signals can be presented to the constituent cells in different forms, including topography, substrate stiffness, and geometrical constraint. With the recent advancement in microfabrication technology, researchers have gained the ability to manipulate the geometrical constraints by creating 3D structures to mimic the tissue microenvironment. In this study, we simulate the pore curvature as presented to the cells within 3D-engineered tissue-scaffolds by developing a device that features tortuous microchannels with geometric variations. We show that both cells at the front and rear respond to the varying radii of curvature and channel amplitude by altering the collective migratory behavior, including cell velocity, morphology, and turning angle. These findings provide insights into adaptive migration modes of collective cells to better understand the underlying mechanism of cell migration for optimization of the engineered tissue-scaffold design. [ABSTRACT FROM AUTHOR]

Published

2020