Artifacts Can Be Deceiving: The Actual Location of Deep Brain Stimulation Electrodes Differs from the Artifact Seen on Magnetic Resonance Images.

IF 1.9 4区 医学 Q3 NEUROIMAGING
Noa B Nuzov, Bhumi Bhusal, Kaylee R Henry, Fuchang Jiang, Jasmine Vu, Joshua M Rosenow, Julie G Pilitsis, Behzad Elahi, Laleh Golestanirad
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引用次数: 1

Abstract

Introduction: Deep brain stimulation (DBS) is a common treatment for a variety of neurological and psychiatric disorders. Recent studies have highlighted the role of neuroimaging in localizing the position of electrode contacts relative to target brain areas in order to optimize DBS programming. Among different imaging methods, postoperative magnetic resonance imaging (MRI) has been widely used for DBS electrode localization; however, the geometrical distortion induced by the lead limits its accuracy. In this work, we investigated to what degree the difference between the actual location of the lead's tip and the location of the tip estimated from the MRI artifact varies depending on the MRI sequence parameters such as acquisition plane and phase encoding direction, as well as the lead's extracranial configuration. Accordingly, an imaging technique to increase the accuracy of lead localization was devised and discussed.

Methods: We designed and constructed an anthropomorphic phantom with an implanted DBS system following 18 clinically relevant configurations. The phantom was scanned at a Siemens 1.5 Tesla Aera scanner using a T1MPRAGE sequence optimized for clinical use and a T1TSE sequence optimized for research purposes. We varied slice acquisition plane and phase encoding direction and calculated the distance between the caudal tip of the DBS lead MRI artifact and the actual tip of the lead, as estimated from MRI reference markers.

Results: Imaging parameters and lead configuration substantially altered the difference in the depth of the lead within its MRI artifact on the scale of several millimeters - with a difference as large as 4.99 mm. The actual tip of the DBS lead was found to be consistently more rostral than the tip estimated from the MR image artifact. The smallest difference between the tip of the DBS lead and the tip of the MRI artifact using the clinically relevant sequence (i.e., T1MPRAGE) was found with the sagittal acquisition plane and anterior-posterior phase encoding direction.

Discussion/conclusion: The actual tip of an implanted DBS lead is located up to several millimeters rostral to the tip of the lead's artifact on postoperative MR images. This distance depends on the MRI sequence parameters and the DBS system's extracranial trajectory. MRI parameters may be altered to improve this localization.

伪影可能具有欺骗性:脑深部刺激电极的实际位置与磁共振图像上看到的伪影不同。
脑深部电刺激(DBS)是一种常见的治疗多种神经和精神疾病。最近的研究强调了神经成像在定位电极接触相对于目标脑区的位置以优化DBS编程中的作用。在不同的成像方法中,术后磁共振成像(MRI)被广泛用于DBS电极定位;然而,引线引起的几何畸变限制了其精度。在这项工作中,我们研究了导联尖端的实际位置与从MRI伪影中估计的尖端位置之间的差异在多大程度上取决于MRI序列参数(如采集平面和相位编码方向)以及导联的颅外结构。据此,设计并讨论了一种提高铅定位精度的成像技术。方法:根据18种临床相关配置,设计并构建了植入DBS系统的拟人假体。在Siemens 1.5 Tesla Aera扫描仪上扫描幻体,使用为临床使用优化的T1MPRAGE序列和为研究目的优化的T1TSE序列。我们改变了切片采集平面和相位编码方向,并计算了DBS导联MRI伪影的尾端与实际导联尖端之间的距离,这是根据MRI参考标记估计的。结果:成像参数和引线结构实质上改变了其MRI伪影中引线深度的差异,其差异在几毫米的范围内-差异可达4.99毫米。DBS导联的实际尖端被发现始终比MR图像伪影估计的尖端更吻侧。DBS导联尖端与使用临床相关序列(即T1MPRAGE)的MRI伪影尖端在矢状采集平面和前后相位编码方向上的差异最小。讨论/结论:在术后MR图像上,植入DBS导联的实际尖端位于导联伪影尖端的吻侧几毫米处。这个距离取决于MRI序列参数和DBS系统的颅外轨迹。可以改变MRI参数来改善这种定位。
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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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