Comprehensive MRI Guidance of Focused Ultrasound Neurosurgery

聚焦超声神经外科综合MRI指导

基本信息

批准号：
10442602
负责人：
CRAIG H MEYER
金额：
$ 54.83万
依托单位：
UNIVERSITY OF VIRGINIA
依托单位国家：
美国
项目类别：
财政年份：
2020
资助国家：
美国
起止时间：
2020-09-01 至 2024-05-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/10442602
关键词：
3-Dimensional Ablation Acoustics Adverse event Animal Experiments Animal Model Animals Area Brain Brain Neoplasms Brain region Clinical Clinical Research Dangerousness Deep Brain Stimulation Development Diffusion Diffusion Magnetic Resonance Imaging Disease Dose Eating Effectiveness Engineering Environment Essential Tremor Excision Feedback Focused Ultrasound Focused Ultrasound Therapy Frequencies Future Goals Heating Hemorrhage Histology Hot Spot Image Infection International Lead Lesion Location Magnetic Resonance Imaging Medical Medicare Mental Depression Methods Modeling Monitor Movement Disorders Multicenter Trials Neurologic Operative Surgical Procedures Pain Parkinson Disease Patient Care Patients Performance Persons Physiologic pulse Pilot Projects Population Prevalence Procedures Protons Refractory Research Research Project Grants Risk Safety Social Interaction Sonication Spatial Distribution Symptoms System Techniques Technology Temperature Testing Therapeutic Thermometry Time Tissues Treatment Efficacy Tremor Ultrasonic Transducer Ultrasonography Universities Virginia Wait Time Work Writing adverse event risk cranium design experience experimental study high risk imaging modality improved innovation minimally invasive neurosurgery overtreatment pre-clinical programs rapid technique real time monitoring reduce symptoms simulation soft tissue sound ultrasound volunteer

项目摘要

PROJECT SUMMARY/ABSTRACT Essential tremor (ET) is a debilitating, common movement disorder, with prevalence as high as 4% of the population. ET is often disabling, with reduced ability to write, eat, or drink. People with the disorder often curtail their social interactions because of embarrassment and are at risk for depression. There are medical therapies that can reduce symptoms, but many patients have tremor that is not responsive to medical treatment. Deep brain stimulation can work well, but many patients are not candidates for surgery or would prefer a non-surgical option. MR-guided Focused Ultrasound (MRgFUS) is a minimally invasive method of treating ET that works in patients who are refractory to medical therapy. Focused ultrasound (FUS) delivers acoustic energy that focally heats lesions to ablative temperatures of greater than 60C. The combination of FUS with MRI guidance (MRgFUS) enables precisely localized tissue ablation, monitored by real-time MR thermometry. Transcranial MRgFUS has been used to treat ET with signiﬁcant and durable reduction in symptoms. Through our clinical experience, we have identiﬁed several critical areas where improved treatment monitoring could dramatically increase safety and effectiveness. The overall goal of this project is to provide comprehensive MRI feedback for transcranial focused ultrasound to improve the safety, efﬁciency and efﬁcacy of treatment. Our speciﬁc aims are the following: Aim 1: Develop real-time volumetric thermometry techniques to monitor thermal treatment. MRgFUS treatments are currently monitored using a 2D pulse sequence for temperature mapping. During ablation, the treatment can only be monitored in a plane, and the location of peak temperature rise can occur outside of the plane. In this aim, we will develop new methods for real-time volumetric MR thermometry and validate these techniques in pre-clinical and volunteer studies. Aim 2: Develop methods to monitor unintended heating of the brain and skull. The skull absorbs energy from the applied ultrasound, which results in heating of the skull and the nearby soft tissue, including the brain. There is currently no direct monitoring of this heating, and the required wait time between sonications is only estimated using simple models. In this aim, we will develop new, rapid, 3D ultrashort-echo-time methods for monitoring skull temperature changes combined with whole-brain volumetric thermometry and test these methods in studies of patients undergoing FUS treatment for ET. Aim 3: Develop real-time treatment monitoring techniques to give early assessment of viability. Critical MR moni- toring functions include visualizing the lesion as it is created. We hypothesize that diffusion-weighted imaging can capture clinically useful lesion contrast at early time points. In this aim, we will develop and validate new methods for diffusion imaging in the challenging environment of a FUS transducer and test these methods in studies of patients. This research will fundamentally improve the treatment of essential tremor using MRgFUS, thereby advancing a tech- nology that can have a signiﬁcant impact on the treatment of these patients.

项目概要/摘要特发性震颤 (ET) 是一种使人衰弱的常见运动障碍，患病率高达 4%。 ET 通常会导致残疾，导致书写、饮食或饮水能力下降。患有这种疾病的人通常会减少社交互动。因为尴尬而有患抑郁症的风险，有一些药物疗法可以减轻症状，但是许多患有震颤的患者对药物治疗没有反应，但深部脑刺激可以起到很好的效果。患者不适合手术或更喜欢非手术选择。 MR 引导聚焦超声 (MRgFUS) 是一种治疗 ET 的微创方法，适用于以下患者：聚焦超声 (FUS) 提供声能，将病灶集中加热至消融。 FUS 与 MRI 引导 (MRgFUS) 的结合可实现超过 60°C 的精确定位。通过实时 MR 测温监测的组织消融已被用于治疗 ET。并持久减轻症状。通过我们的临床经验，我们已经确定了可以改进治疗监测的几个关键领域该项目的总体目标是提供全面的 MRI 反馈。经颅聚焦超声以提高治疗的安全性、效率和功效。下列的：目标 1：开发实时体积测温技术来监测 MRgFUS 治疗。目前使用 2D 脉冲序列进行温度测绘监测。在消融过程中，只能进行治疗。在飞机内进行监测，并且峰值温升的位置可能发生在飞机外。为此，我们将开发一种方法。实时体积磁共振测温的新方法，并在临床前和志愿者研究中验证这些技术。目标 2：开发监测大脑和颅骨意外发热的方法颅骨从大脑中吸收能量。应用超声波，导致头骨和附近的软组织（包括大脑）加热，目前还没有。直接监测这种加热，并且仅使用简单的模型来估计超声处理之间所需的等待时间。为了实现这一目标，我们将开发新的、快速的 3D 超短回波时间方法来监测头骨温度变化并在接受 FUS 治疗 ET 的患者的研究中测试这些方法。目标 3：开发实时治疗监测技术，对关键 MR 监测进行早期评估。扭转功能包括在病变形成时对其进行可视化，我们勇敢地认为弥散加权成像可以捕捉到它。在早期时间点进行临床上有用的病变对比，我们将开发和验证新的扩散方法。在 FUS 传感器的挑战性环境中进行成像，并在患者研究中测试这些方法。这项研究将从根本上改善使用 MRgFUS 治疗原发性震颤的方法，从而推进技术的发展。可以对这些患者的治疗产生重大影响的科学。