Adam Schonewille;Changyan He;Cameron Forbrigger;Nancy Wu;James Drake;Thomas Looi;Eric Diller
{"title":"Electromagnets Under the Table: An Unobtrusive Magnetic Navigation System for Microsurgery","authors":"Adam Schonewille;Changyan He;Cameron Forbrigger;Nancy Wu;James Drake;Thomas Looi;Eric Diller","doi":"10.1109/TMRB.2024.3421249","DOIUrl":null,"url":null,"abstract":"Miniature magnetic tools have the potential to enable minimally invasive surgical techniques to be applied to space-restricted surgical procedures in areas such as neurosurgery. However, typical magnetic navigation systems, which create the magnetic fields to drive such tools, either cannot generate large enough fields, or surround the patient in a way that obstructs surgeon access to the patient. This paper introduces the design of a magnetic navigation system with eight electromagnets arranged completely under the operating table, to endow the system with maximal workspace accessibility, which allows the patient to lie down on the top surface of the system without any constraints. The found geometric layout of the electromagnets maximizes the field strength and uniformity over a reasonable neurosurgical operating volume. The system can generate non-uniform magnetic fields up to 38 mT along the x and y axes and 47 mT along the z axis at a working distance of 120 mm away from the actuation system workbench, deep enough to deploy magnetic microsurgical tools in the brain. The forces which can be exerted on millimeter-scale magnets used in prototype neurosurgical tools are validated experimentally. Due to its large workspace, this system could be used to control milli-robots in a variety of surgical applications.","PeriodicalId":73318,"journal":{"name":"IEEE transactions on medical robotics and bionics","volume":"6 3","pages":"980-991"},"PeriodicalIF":3.4000,"publicationDate":"2024-07-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"IEEE transactions on medical robotics and bionics","FirstCategoryId":"1085","ListUrlMain":"https://ieeexplore.ieee.org/document/10578059/","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"ENGINEERING, BIOMEDICAL","Score":null,"Total":0}
引用次数: 0
Abstract
Miniature magnetic tools have the potential to enable minimally invasive surgical techniques to be applied to space-restricted surgical procedures in areas such as neurosurgery. However, typical magnetic navigation systems, which create the magnetic fields to drive such tools, either cannot generate large enough fields, or surround the patient in a way that obstructs surgeon access to the patient. This paper introduces the design of a magnetic navigation system with eight electromagnets arranged completely under the operating table, to endow the system with maximal workspace accessibility, which allows the patient to lie down on the top surface of the system without any constraints. The found geometric layout of the electromagnets maximizes the field strength and uniformity over a reasonable neurosurgical operating volume. The system can generate non-uniform magnetic fields up to 38 mT along the x and y axes and 47 mT along the z axis at a working distance of 120 mm away from the actuation system workbench, deep enough to deploy magnetic microsurgical tools in the brain. The forces which can be exerted on millimeter-scale magnets used in prototype neurosurgical tools are validated experimentally. Due to its large workspace, this system could be used to control milli-robots in a variety of surgical applications.
微型磁性工具有可能使微创外科技术应用于神经外科等空间受限的外科手术领域。然而,用于产生磁场以驱动此类工具的典型磁导航系统要么不能产生足够大的磁场,要么将病人包围起来,阻碍外科医生接近病人。本文介绍了一种磁导航系统的设计,它有八个电磁铁,完全布置在手术台下方,赋予系统最大的工作空间可达性,使病人可以不受任何限制地躺在系统的上表面。所发现的电磁铁几何布局可在合理的神经外科手术空间内最大限度地提高磁场强度和均匀性。该系统可在距离执行系统工作台 120 毫米的工作距离内产生沿 x 轴和 y 轴高达 38 mT、沿 z 轴高达 47 mT 的非均匀磁场,其深度足以在大脑中部署磁性显微外科工具。实验验证了神经外科工具原型中使用的毫米级磁铁所能承受的力。由于工作空间大,该系统可用于控制各种外科应用中的微型机器人。