在实验室实验中表征的医疗设备光纤传感的形状精度。

Shape accuracy of fiber optic sensing for medical devices characterized in bench experiments.

作者信息

Megens Mischa, Leistikow Merel D, van Dusschoten Anneke, van der Mark Martin B, Horikx Jeroen J L, van Putten Elbert G, Hooft Gert W 't

机构信息

In-body Systems group, Philips Research, 5656 AE, Eindhoven, The Netherlands.

FORS Venture, Philips - Image Guided Therapy, 5684 PC, Best, The Netherlands.

出版信息

Med Phys. 2021 Jul;48(7):3936-3947. doi: 10.1002/mp.14881. Epub 2021 Jun 28.

DOI:10.1002/mp.14881

PMID:33843097

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9291042/

Abstract

PURPOSE

Fiber Optic RealShape (FORS) is a new technology that visualizes the full three-dimensional shape of medical devices, such as catheters and guidewires, using an optical fiber embedded in the device. This three-dimensional shape provides guidance to clinicians during minimally invasive procedures, and enables intuitive navigation. The objective of this paper is to assess the accuracy of the FORS technology, as implemented in the current state-of-the-art Philips FORS system. The FORS system provides the shape of the entire device, including tip location and orientation. We consider all three aspects.

METHODS

In bench experiments, we determined the accuracy of the location and orientation of the tip by displacing and rotating the fiber end, while allowing the rest of the fiber to change shape freely. To test the accuracy of the full shape, we have placed the fiber in a groove, which was accurately machined in a thick, stiff metal "path plate." We then compared the reconstructed shape with the known shape of the groove.

RESULTS

The tip location is found with submillimeter accuracy, and the orientation is sensed with milliradian accuracy. The shape of a fiber in the path plate faithfully follows the known shape of the groove, with typical deviation less than 0.5 mm in the plane of the plate. Out of plane accuracy, perhaps slightly less relevant clinically, is more challenging, due to the influence of twist; yet even out of the plane, the deviation is only submillimeter.

CONCLUSION

The technology achieves submillimeter precision and provides full three-dimensional shape, surpassing the reported precision of other navigation and tracking technologies, and therefore may potentially alleviate the need for fluoroscopy.

摘要

目的

光纤真实形状（FORS）是一项新技术，它利用嵌入医疗设备（如导管和导丝）中的光纤来呈现其完整的三维形状。这种三维形状在微创手术过程中为临床医生提供指导，并实现直观导航。本文的目的是评估当前最先进的飞利浦FORS系统所采用的FORS技术的准确性。FORS系统可提供整个设备的形状，包括尖端位置和方向。我们对这三个方面都进行了考量。

方法

在实验台上进行的实验中，我们通过移动和旋转光纤末端来确定尖端位置和方向的准确性，同时让光纤的其余部分自由变形。为了测试完整形状的准确性，我们将光纤放置在一个精确加工在厚而硬的金属“路径板”中的凹槽中。然后，我们将重建的形状与凹槽的已知形状进行比较。

结果

尖端位置的定位精度达到亚毫米级，方向感测精度达到毫弧度级。路径板中光纤的形状忠实地遵循凹槽的已知形状，在板平面内的典型偏差小于0.5毫米。平面外精度在临床上可能相关性稍低，由于扭转的影响，其测量更具挑战性；然而即使在平面外，偏差也仅为亚毫米级。

结论

该技术实现了亚毫米级精度，并提供完整的三维形状，超越了其他导航和跟踪技术所报告的精度，因此可能潜在地减少对荧光透视的需求。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d322/9291042/5978c70f162d/MP-48-3936-g010.jpg

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在实验室实验中表征的医疗设备光纤传感的形状精度。

Shape accuracy of fiber optic sensing for medical devices characterized in bench experiments.

作者信息

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSION

目的

方法

结果

结论

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