TY - GEN
T1 - Optical manipulation of biological objects on azobenzene-containing systems
AU - Fabbri, Filippo
AU - Pinto, Sandra
AU - Lefebvre, Olivier
AU - Lahlil, Khalid
AU - Peretti, Jacques
AU - Smadja, Claire
AU - Randriamampita, Clotilde
AU - Lambert, Mireille
N1 - Publisher Copyright:
© 2022 IEEE.
PY - 2022/1/1
Y1 - 2022/1/1
N2 - Cells interact with a chemical and mechanical environment that influences their adaptive response and conditions the physiology and pathophysiology of the tissues. Much effort is being made to reconstruct simple systems in order to study the reciprocal influences of tissues and their environment, as well as to measure the consequences of environmental disturbances on cells. Specific tools are required for the in-vivo, real-time manipulation of the cellular environment's mechanical properties and for the measurement of the resulting local and collective cellular biomechanical responses. One innovative solution is the use of photoactive systems such as azobenzene-containing polymer materials (azopolymers), whose microstructure and mechanical optical and surface properties can be modulated in time and space by light. Here we show that azopolymer bio-substrates can be used to optically control and study the cellular response of mouse fibroblasts and to single out different classes of cellular responses that might specifically depend on the photo-induced mechanical modification of the environment surrounding the cellular focal adhesions.
AB - Cells interact with a chemical and mechanical environment that influences their adaptive response and conditions the physiology and pathophysiology of the tissues. Much effort is being made to reconstruct simple systems in order to study the reciprocal influences of tissues and their environment, as well as to measure the consequences of environmental disturbances on cells. Specific tools are required for the in-vivo, real-time manipulation of the cellular environment's mechanical properties and for the measurement of the resulting local and collective cellular biomechanical responses. One innovative solution is the use of photoactive systems such as azobenzene-containing polymer materials (azopolymers), whose microstructure and mechanical optical and surface properties can be modulated in time and space by light. Here we show that azopolymer bio-substrates can be used to optically control and study the cellular response of mouse fibroblasts and to single out different classes of cellular responses that might specifically depend on the photo-induced mechanical modification of the environment surrounding the cellular focal adhesions.
KW - azobenzene
KW - cells optical manipulation
KW - cellular adhesion
KW - cellular biomechanics
KW - matter transport
KW - multifunctional optical materials
KW - optical actuation
KW - optical tuning
KW - photo-softening
KW - photoactive polymers
KW - thin films
UR - https://www.scopus.com/pages/publications/85141163753
U2 - 10.1109/PN56061.2022.9908340
DO - 10.1109/PN56061.2022.9908340
M3 - Conference contribution
AN - SCOPUS:85141163753
T3 - 2022 Photonics North, PN 2022
BT - 2022 Photonics North, PN 2022
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2022 Photonics North, PN 2022
Y2 - 24 May 2022 through 26 May 2022
ER -