Olivier Cartiaux, Xavier Banse, Laurent Paul, Bernard G Francq, Carl-Éric Aubin, Pierre-Louis Docquier
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引用次数: 65
Abstract
Background: Resection of bone tumors within the pelvis requires good cutting accuracy to achieve satisfactory safe margins. Manually controlled bone cutting can result in serious errors, especially due to the complex three-dimensional geometry, limited visibility, and restricted working space of the pelvic bone. This experimental study investigated cutting accuracy during navigated and non-navigated simulated bone tumor cutting in the pelvis.
Methods: A periacetabular tumor resection was simulated using a pelvic bone model. Twenty-three operators (10 senior and 13 junior surgeons) were asked to perform the tumor cutting, initially according to a freehand procedure and later with the aid of a navigation system. Before cutting, each operator used preoperative planning software to define four target planes around the tumor with a 10-mm desired safe margin. After cutting, the location and flatness of the cut planes were measured, as well as the achieved surgical margins and the time required for each cutting procedure.
Results: The location of the cut planes with respect to the target planes was significantly improved by using the navigated cutting procedure, averaging 2.8 mm as compared to 11.2 mm for the freehand cutting procedure (p < 0.001). There was no intralesional tumor cutting when using the navigation system. The maximum difference between the achieved margins and the 10-mm desired safe margin was 6.5 mm with the navigated cutting process (compared to 13 mm with the freehand cutting process).
Conclusions: Cutting accuracy during simulated bone cuts of the pelvis can be significantly improved by using a freehand process assisted by a navigation system. When fully validated with complementary in vivo studies, the planning and navigation-guided technologies that have been developed for the present study may improve bone cutting accuracy during pelvic tumor resection by providing clinically acceptable margins.
背景:骨盆内骨肿瘤切除需要良好的切割精度以获得满意的安全切缘。人工控制的骨切割会导致严重的错误,特别是由于骨盆骨的三维几何形状复杂,能见度有限,工作空间有限。本实验研究探讨了导航和非导航模拟骨盆骨肿瘤切割的准确性。方法:采用骨盆骨模型模拟髋臼周围肿瘤切除术。23名外科医生(10名高级外科医生和13名初级外科医生)被要求进行肿瘤切割,最初根据徒手手术,后来在导航系统的帮助下进行。在切割之前,每位手术人员使用术前规划软件确定肿瘤周围的四个靶平面,期望的安全裕度为10mm。切割后,测量切割平面的位置和平整度,以及达到的手术切缘和每次切割所需的时间。结果:使用导航切割程序,切割平面相对于靶平面的位置显着改善,平均2.8 mm,而徒手切割程序为11.2 mm (p结论:在模拟骨盆骨切割过程中,使用导航系统辅助的徒手过程可以显着提高切割精度。当补充的体内研究充分验证后,为本研究开发的计划和导航引导技术可以通过提供临床可接受的边缘来提高骨盆肿瘤切除术时的骨切割准确性。
期刊介绍:
The scope of Computer Aided Surgery encompasses all fields within surgery, as well as biomedical imaging and instrumentation, and digital technology employed as an adjunct to imaging in diagnosis, therapeutics, and surgery. Topics featured include frameless as well as conventional stereotaxic procedures, surgery guided by ultrasound, image guided focal irradiation, robotic surgery, and other therapeutic interventions that are performed with the use of digital imaging technology.
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