Evaluation of 3D C-Arm Fluoroscopy versus Diagnostic CT for Deep Brain Stimulation Stereotactic Registration and Post-Operative Lead Localization.

IF 1.9 4区 医学 Q3 NEUROIMAGING
Stereotactic and Functional Neurosurgery Pub Date : 2024-01-01 Epub Date: 2024-03-27 DOI:10.1159/000536017
James Manfield, Sean Martin, Alexander L Green, James J FitzGerald
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引用次数: 0

Abstract

Introduction: DBS efficacy depends on accuracy. CT-MRI fusion is established for both stereotactic registration and electrode placement verification. The desire to streamline DBS workflows, reduce operative time, and minimize patient transfers has increased interest in portable imaging modalities such as the Medtronic O-arm® and mobile CT. However, these remain expensive and bulky. 3D C-arm fluoroscopy (3DXT) units are a smaller and less costly alternative, albeit incompatible with traditional frame-based localization and without useful soft tissue resolution. We aimed to compare fusion of 3DXT and CT with pre-operative MRI to evaluate if 3DXT-MRI fusion alone is sufficient for accurate registration and reliable targeting verification. We further assess DBS targeting accuracy using a 3DXT workflow and compare radiation dosimetry between modalities.

Methods: Patients underwent robot-assisted DBS implantation using a workflow incorporating 3DXT which we describe. Two intra-operative 3DXT spins were performed for registration and accuracy verification followed by conventional CT post-operatively. Post-operative 3DXT and CT images were independently fused to the same pre-operative MRI sequence and co-ordinates generated for comparison. Registration accuracy was compared to 15 consecutive controls who underwent CT-based registration. Radial targeting accuracy was calculated and radiation dosimetry recorded.

Results: Data were obtained from 29 leads in 15 consecutive patients. 3DXT registration accuracy was significantly superior to CT with mean error 0.22 ± 0.03 mm (p < 0.0001). Mean Euclidean electrode tip position variation for CT to MRI versus 3DXT to MRI fusion was 0.62 ± 0.40 mm (range 0.0 mm-1.7 mm). In comparison, direct CT to 3DXT fusion showed electrode tip Euclidean variance of 0.23 ± 0.09 mm. Mean radial targeting accuracy assessed on 3DXT was 0.97 ± 0.54 mm versus 1.15 ± 0.55 mm on CT with differences insignificant (p = 0.30). Mean patient radiation doses were around 80% lower with 3DXT versus CT (p < 0.0001).

Discussion: Mobile 3D C-arm fluoroscopy can be safely incorporated into DBS workflows for both registration and lead verification. For registration, the limited field of view requires the use of frameless transient fiducials and is highly accurate. For lead position verification based on MRI co-registration, we estimate there is around a 0.4 mm discrepancy between lead position seen on 3DXT versus CT when corrected for brain shift. This is similar to that described in O-arm® or mobile CT series. For units where logistical or financial considerations preclude the acquisition of a cone beam CT or mobile CT scanner, our data support portable 3D C-arm fluoroscopy as an acceptable alternative with significantly lower radiation exposure.

三维 C 臂透视与诊断 CT 在脑深部刺激立体定向注册和术后导线定位方面的对比评估。
简介DBS 的疗效取决于准确性。CT-MRI 融合技术可用于立体定向注册和电极放置验证。由于希望简化 DBS 工作流程、缩短手术时间并尽量减少病人转运,人们对美敦力 O-arm® 和移动 CT 等便携式成像模式越来越感兴趣。然而,这些设备仍然昂贵而笨重。三维 C 臂透视(3DXT)装置是一种体积更小、成本更低的替代方案,尽管它与传统的基于框架的定位不兼容,也没有有用的软组织分辨率。我们的目的是比较 3DXT 和 CT 与术前核磁共振成像的融合,以评估 3DXT-MRI 融合是否足以实现准确配准和可靠的靶向验证。我们进一步评估了使用 3DXT 工作流程的 DBS 靶向准确性,并比较了两种模式的辐射剂量:方法:患者在机器人辅助下接受 DBS 植入术,使用我们介绍的 3DXT 工作流程。术中进行两次 3DXT 旋转,以进行注册和准确性验证,术后进行常规 CT 检查。术后 3DXT 和 CT 图像与术前相同的 MRI 序列独立融合,并生成坐标进行比较。将注册准确性与 15 个连续接受 CT 注册的对照组进行比较。计算径向定位精度并记录辐射剂量:结果:从 15 名连续患者的 29 个导联获得了数据。3DXT 登记的准确性明显优于 CT,平均误差为 0.22 ± 0.03 毫米(p < 0.0001)。CT 到 MRI 与 3DXT 到 MRI 融合的平均欧氏电极尖端位置差异为 0.62 ± 0.40 毫米(范围为 0.0 毫米-1.7 毫米)。相比之下,CT 与 3DXT 直接融合的电极尖端欧氏方差为 0.23 ± 0.09 毫米。3DXT 评估的平均径向定位精度为 0.97 ± 0.54 毫米,CT 为 1.15 ± 0.55 毫米,差异不显著(p = 0.30)。3DXT的平均患者辐射剂量比CT低约80%(p < 0.0001):讨论:移动式三维 C 臂透视可安全地纳入 DBS 工作流程,用于配准和导联验证。对于配准,有限的视野要求使用无框架的瞬时靶标,而且精度很高。对于基于核磁共振成像联合注册的导联位置验证,我们估计在校正脑偏移后,3DXT 与 CT 上看到的导联位置差异约为 0.4 毫米。这与 O-arm® 或移动 CT 系列所描述的情况类似。对于因后勤或经济因素而无法购置锥形束 CT 或移动 CT 扫描仪的单位,我们的数据支持便携式 3D C 臂透视,它是一种可接受的替代方法,而且辐射量明显更低。
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来源期刊
CiteScore
3.80
自引率
0.00%
发文量
33
审稿时长
3 months
期刊介绍: ''Stereotactic and Functional Neurosurgery'' provides a single source for the reader to keep abreast of developments in the most rapidly advancing subspecialty within neurosurgery. Technological advances in computer-assisted surgery, robotics, imaging and neurophysiology are being applied to clinical problems with ever-increasing rapidity in stereotaxis more than any other field, providing opportunities for new approaches to surgical and radiotherapeutic management of diseases of the brain, spinal cord, and spine. Issues feature advances in the use of deep-brain stimulation, imaging-guided techniques in stereotactic biopsy and craniotomy, stereotactic radiosurgery, and stereotactically implanted and guided radiotherapeutics and biologicals in the treatment of functional and movement disorders, brain tumors, and other diseases of the brain. Background information from basic science laboratories related to such clinical advances provides the reader with an overall perspective of this field. Proceedings and abstracts from many of the key international meetings furnish an overview of this specialty available nowhere else. ''Stereotactic and Functional Neurosurgery'' meets the information needs of both investigators and clinicians in this rapidly advancing field.
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