| Literature DB >> 30312145 |
Sungwoong Jeon1,2, Ali Kafash Hoshiar1,2, Kangho Kim1,2, Seungmin Lee1,2, Eunhee Kim1,2, Sunkey Lee1,2, Jin-Young Kim1,2, Bradley J Nelson2,3, Hyo-Jeong Cha4, Byung-Ju Yi4, Hongsoo Choi1,2.
Abstract
Magnetically actuated soft robots may improve the treatment of disseminated intravascular coagulation. Significant progress has been made in the development of soft robotic systems that steer catheters. A more challenging task, however, is the development of systems that steer sub-millimeter-diameter guidewires during intravascular treatments; a novel microrobotic approach is required for steering. In this article, we develop a novel, magnetically actuated, soft microrobotic system, increasing the steerability of a conventional guidewire. The soft microrobot is attached to the tip of the guidewire, and it is magnetically steered by changing the direction and intensity of an external magnetic field. The microrobot is fabricated via replica molding and features a soft body made of polydimethylsiloxane, two permanent magnets, and a microspring. We developed a mathematical model mapping deformation of the soft microrobot using a feed-forward approach toward steering. Then, we used the model to steer a guidewire. The angulation of the microrobot can be controlled from 21.1° to 132.7° by using a magnetic field of an intensity of 15 mT. Steerability was confirmed by two-dimensional in vitro tracking. Finally, a guidewire with the soft microrobot was tested by using a three-dimensional (3D) phantom of the coronary artery to verify steerability in 3D space.Entities:
Keywords: guidewire; intravascular treatments; magnetic steering; percutaneous coronary intervention (PCI); soft microrobot; steerability
Year: 2018 PMID: 30312145 PMCID: PMC6386781 DOI: 10.1089/soro.2018.0019
Source DB: PubMed Journal: Soft Robot ISSN: 2169-5172 Impact factor: 8.071