Microrobot-in-glass for dynamic motion analysis and wider in vitro applications

Hugo Salmon; Laurent Couraud; Christophe Roblin; Gilgueng Hwang

doi:10.1049/mnl.2019.0006

Microrobot-in-glass for dynamic motion analysis and wider in vitro applications

Hugo Salmon, Laurent Couraud, Christophe Roblin, Gilgueng Hwang

Research output: Contribution to journal › Article › peer-review

Abstract

Microrobots could become a key enabler in life science and medicine research as well as industrial applications. Although they provide high-performance tools for a wide range of applications, their environment and particularly surface forces induce significant challenge for their control. This work introduces an originally integrated microrobot in a permanently sealed glass microfluidic chip. Compared to conventional polymer chips, the glass substrate offers a smooth, stable, and inert surface. It also avoids the typical contamination and fast degradation of organosilicon polymers. In this environment, they demonstrate high-frequency hydrodynamics analysis and control. This strategy offers a high precision platform to study microrobot design and hydrodynamics as well as a transducer module for mapping surfaces and sensing interaction with physical environments.

Original language	English
Pages (from-to)	882-886
Number of pages	5
Journal	Micro and Nano Letters
Volume	14
Issue number	8
DOIs	https://doi.org/10.1049/mnl.2019.0006
Publication status	Published - 24 Jul 2019
Externally published	Yes

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abstract = "Microrobots could become a key enabler in life science and medicine research as well as industrial applications. Although they provide high-performance tools for a wide range of applications, their environment and particularly surface forces induce significant challenge for their control. This work introduces an originally integrated microrobot in a permanently sealed glass microfluidic chip. Compared to conventional polymer chips, the glass substrate offers a smooth, stable, and inert surface. It also avoids the typical contamination and fast degradation of organosilicon polymers. In this environment, they demonstrate high-frequency hydrodynamics analysis and control. This strategy offers a high precision platform to study microrobot design and hydrodynamics as well as a transducer module for mapping surfaces and sensing interaction with physical environments.",

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AU - Couraud, Laurent

AU - Roblin, Christophe

AU - Hwang, Gilgueng

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AB - Microrobots could become a key enabler in life science and medicine research as well as industrial applications. Although they provide high-performance tools for a wide range of applications, their environment and particularly surface forces induce significant challenge for their control. This work introduces an originally integrated microrobot in a permanently sealed glass microfluidic chip. Compared to conventional polymer chips, the glass substrate offers a smooth, stable, and inert surface. It also avoids the typical contamination and fast degradation of organosilicon polymers. In this environment, they demonstrate high-frequency hydrodynamics analysis and control. This strategy offers a high precision platform to study microrobot design and hydrodynamics as well as a transducer module for mapping surfaces and sensing interaction with physical environments.

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Microrobot-in-glass for dynamic motion analysis and wider in vitro applications

Abstract

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