TY - GEN
T1 - Vectorial control of cell movement by the design of microelasticity distribution of biomaterial surface
AU - Kidoaki, Satoru
AU - Matsuda, Takehisa
PY - 2008
Y1 - 2008
N2 - The understanding and realization of directional cell movement towards a harder region of a cell culture substrate surface, so-called mechanotaxis, may provide a solid basis for a functional artificial extracellular matrix, enabling manipulation and elucidation of cell motility. The photolithographic surface microelasticity patterning method was developed for fabricating a cell-adhesive hydrogel with a microelasticity-gradient (MEG) surface using photocurable styrenated gelatin to investigate the condition of surface elasticity to induce mechanotaxis as a basis for such substrate-elasticity-dependent control of cell motility. Patterned MEG gels consisting of different absolute surface elasticities, elasticity jumps and sharpness of elasticity were prepared by regulating the photoirradiation power, periods and positions. Surface elasticity and its two-dimensional distribution were characterized by microindentation tests using atomic force microscopy (AFM). From the analyses of trajectories of 3T3 cell movement on each prepared MEG gel, three critical criteria of the elasticity jump and the absolute elasticity to induce mechanotaxis were identified: 1) a high elasticity ratio between the hard region and the soft one, 2) elasticity of the softer region to provide medium motility, and 3) sharpness of the elasticity boundary. Design of these conditions was found to be necessary for fabricating an artificial extracellular matrix to control or manipulate vectorial cell movement.
AB - The understanding and realization of directional cell movement towards a harder region of a cell culture substrate surface, so-called mechanotaxis, may provide a solid basis for a functional artificial extracellular matrix, enabling manipulation and elucidation of cell motility. The photolithographic surface microelasticity patterning method was developed for fabricating a cell-adhesive hydrogel with a microelasticity-gradient (MEG) surface using photocurable styrenated gelatin to investigate the condition of surface elasticity to induce mechanotaxis as a basis for such substrate-elasticity-dependent control of cell motility. Patterned MEG gels consisting of different absolute surface elasticities, elasticity jumps and sharpness of elasticity were prepared by regulating the photoirradiation power, periods and positions. Surface elasticity and its two-dimensional distribution were characterized by microindentation tests using atomic force microscopy (AFM). From the analyses of trajectories of 3T3 cell movement on each prepared MEG gel, three critical criteria of the elasticity jump and the absolute elasticity to induce mechanotaxis were identified: 1) a high elasticity ratio between the hard region and the soft one, 2) elasticity of the softer region to provide medium motility, and 3) sharpness of the elasticity boundary. Design of these conditions was found to be necessary for fabricating an artificial extracellular matrix to control or manipulate vectorial cell movement.
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U2 - 10.1109/MHS.2008.4752498
DO - 10.1109/MHS.2008.4752498
M3 - Conference contribution
AN - SCOPUS:62449266645
SN - 9781424429196
T3 - 2008 International Symposium on Micro-NanoMechatronics and Human Science, MHS 2008
SP - 469
EP - 474
BT - 2008 International Symposium on Micro-NanoMechatronics and Human Science, MHS 2008, with Symposium on "COE for Education and Research of Micro-Nano Mechatronics"
T2 - 2008 International Symposium on Micro-NanoMechatronics and Human Science, MHS 2008, with Symposium on "COE for Education and Research of Micro-Nano Mechatronics", Symposium on "System Cell Engineering by Multi-scale Manipulation"
Y2 - 6 November 2008 through 9 November 2008
ER -