The understanding of cell manipulation, for example in microinjection, requires an accurate model of the cells. Motivated by this important requirement, a 3D particlebased mechanical model is derived for simulating the deformation of the fish egg membrane and the corresponding cellular forces during microrobotic cell injection. The model is formulated based on the kinematic and dynamic of spring- damper configuration with multi-particle joints considering the visco-elastic fluidic properties. It simulates the indentation force feedback as well as cell visual deformation during microinjection. A preliminary simulation study is conducted with different parameter configurations. The results indicate that the proposed particle-based model is able to provide similar deformation profiles as observed from a real microinjection experiment of the zebrafish embryo published in the literature. As a generic modelling approach is adopted, the proposed model also has the potential in applications with different types of manipulation such as micropipette cell aspiration.
History
Event
IEEE Systems, Man and Cybernetics. Conference (2013 : Manchester, England)
Pagination
2219 - 2224
Publisher
IEEE
Location
Manchester, England
Place of publication
Piscataway, N.J.
Start date
2013-10-13
End date
2013-10-16
Language
eng
Publication classification
E1 Full written paper - refereed
Copyright notice
2013, IEEE
Title of proceedings
SMC 2013 : Proceedings of the 2013 IEEE International Conference on Systems, Man and Cybernetics