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SURGICAL

A Contactless and Biocompatible Approach for 3D Active Microrobotic Targeted Drug Delivery

Federico Ongaro, Dennis Niehoff, Sumit Mohanty, Sarthak Misra

Year
2019
Citations
28
Access
Open access

Abstract

As robotic tools are becoming a fundamental part of present day surgical interventions, microrobotic surgery is steadily approaching clinically-relevant scenarios. In particular, minimally invasive microrobotic targeted drug deliveries are reaching the grasp of the current state-of-the-art technology. However, clinically-relevant issues, such as lack of biocompatibility and dexterity, complicate the clinical application of the results obtained in controlled environments. Consequently, in this work we present a proof-of-concept fully contactless and biocompatible approach for active targeted delivery of a drug-model. In order to achieve full biocompatiblity and contacless actuation, magnetic fields are used for motion control, ultrasound is used for imaging, and induction heating is used for active drug-model release. The presented system is validated in a three-dimensional phantom of human vessels, performing ten trials that mimic targeted drug delivery using a drug-coated microrobot. The system is capable of closed-loop motion control with average velocity and positioning error of 0.3 mm/s and 0.4 mm, respectively. Overall, our findings suggest that the presented approach could augment the current capabilities of microrobotic tools, helping the development of clinically-relevant approaches for active in-vivo targeted drug delivery.

Keywords

Drug deliveryImaging phantomTargeted drug deliveryBiocompatible materialBiomedical engineeringComputer scienceNanoroboticsNanotechnologyMedical physicsMedicine

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