在图像导航支气管镜检查中使用片上磁感应进行三维位置跟踪

Manish Srivastava;Kilian O’Donoghue;Aleksandr Sidun;Herman Alexander Jaeger;Alessandro Ferro;Daragh Crowley;Christian van den Bosch;Marcus Kennedy;Daniel O’Hare;Pádraig Cantillon-Murphy
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引用次数: 0

摘要

本文介绍了一种结构紧凑、成本低廉的片上传感器和读出电路。该传感器可实现高分辨率 5 自由度(DoF)跟踪(x、y、z、偏航和俯仰)。在外部绕线传感器的帮助下,它还能实现高分辨率 6 自由度(DoF)跟踪(x、y、z、偏航、俯仰和滚动角)。该传感器利用低频磁场检测器械的位置和方向,是图像引导手术中使用 X 射线的可行替代方案。为了测量局部磁场,我们开发了一种能够感应磁场的高度微型片上磁传感器,它集成了片上磁传感器线圈、模拟前端、连续时间模数转换器(ADC)、LVDS 发送器、带隙基准和稳压器。微芯片采用 65 纳米 CMOS 技术制造,占地面积为 1.06 mm${}^{2}$,据我们所知,这是同类设计中最小的。5-DoF系统可在15厘米乘15厘米乘15厘米的兴趣体积(VOI)范围内以1.1毫米的精度精确导航。6-DoF 系统的导航精度为 0.8 毫米,在相同 VOI 内的角度误差为 1.1 度。这些结果是在台式表征中以 20 Hz 的更新率获得的。传感器原型在活体猪肺内的真实临床前体内环境中实现了精确的位置跟踪,据报告,最差情况下的注册精度为 5.8 毫米。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
3D Position Tracking Using On-Chip Magnetic Sensing in Image-Guided Navigation Bronchoscopy
This paper presents a compact and low-cost on-chip sensor and readout circuit. The sensor achieves high-resolution 5-degrees-of-freedom (DoF) tracking (x, y, z, yaw, and pitch). With the help of an external wire wound sensor, it can also achieve high-resolution 6-degrees-of-freedom (DoF) tracking (x, y, z, yaw, pitch, and roll angles). The sensor uses low-frequency magnetic fields to detect the position and orientation of instruments, providing a viable alternative to using X-rays in image-guided surgery. To measure the local magnetic field, a highly miniaturised on-chip magnetic sensor capable of sensing the magnetic field has been developed incorporating an on-chip magnetic sensor coil, analog-front end, continuous-time $\Delta\Sigma$ analog-to-digital converter (ADC), LVDS transmitter, bandgap reference, and voltage regulator. The microchip is fabricated using 65 nm CMOS technology and occupies an area of 1.06 mm ${}^{2}$ , the smallest reported among similar designs to the best of our knowledge. The 5-DoF system accurately navigates with a precision of 1.1 mm within the volume-of-interest (VOI) of 15 $\times$ 15 $\times$ 15 cm ${}^{3}$ . The 6-DoF system achieves a navigation accuracy of 0.8 mm and an angular error of 1.1 degrees in the same VOI. These results were obtained at a 20 Hz update rate in benchtop characterisation. The prototype sensor demonstrates accurate position tracking in real-life pre-clinical in-vivo settings within the porcine lung of a live swine, achieving a reported worst-case registration accuracy of 5.8 mm.
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