Real-Time Teleoperation of Magnetic Force-Driven Microrobots With 3D Haptic Force Feedback for Micro-Navigation and Micro-Transportation

Abstract

Untethered mobile microrobots controlled by an external magnetic gradient field can be employed as advanced biomedical applications inside the human body such as cell therapy, micromanipulation, and noninvasive surgery. Haptic technology and telecommunication, on the other hand, can extend the potentials of untethered microrobot applications. In those applications, users can communicate with the robot operating system remotely to manipulate microrobots with haptic feedback. Haptic sensations artificially constructed by the wirelessly communicated information can assist human operators to experience forces while controlling the microrobots. The proposed system is composed of a haptic device and a magnetic tweezer system, both of which are integrated through a teleoperation technique based on network communication. Users can control the microrobots remotely and feel the haptic interactions with the remote environment in real-time. The 3D haptic environment is reconstructed dynamically by a model-free haptic rendering algorithm using a 2D planar image input of the microscope. The interaction between microrobots and environmental objects is haptically rendered as 3D objects to achieve spatial haptic operation with obstacle avoidance. Moreover, path generation and path guidance forces provide virtual interaction for human users to manipulate the microrobot by following the near-optimal path in path-following tasks. The potential applications of the presented system are medical remote treatment in different sites, remote drug delivery by avoiding physically penetrating through the skin, remotely-controlled cell manipulations, and biopsy without a biopsy needle.