CRCNS: Crossbeam Transcranial Ultrasound Technology to Stimulate the Deep Brain

CRCNS：交叉束经颅超声技术刺激深部大脑

基本信息

批准号：
10397709
负责人：
Kim Butts-Pauly
金额：
$ 20.68万
依托单位：
STANFORD UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2021
资助国家：
美国
起止时间：
2021-09-10 至 2024-05-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/10397709
关键词：
Addictive Behavior Animal Model Animals Behavior Biological Brain Clinical Computer Models Computer software Deep Brain Stimulation Development Drug Addiction Drug Withdrawal Symptoms Effectiveness Electroencephalography Elements Ensure Evoked Potentials Exhibits Family suidae Feedback Financial compensation Functional Magnetic Resonance Imaging Goals Health Hippocampus (Brain)Human Image Institution Instruction Magnetic Resonance Imaging Mediating Memory Modality Modeling Mus Neurologic Neurosciences Nucleus Accumbens Pharmaceutical Preparations Phase Principal Investigator Public Health Rattus Relapse Research Resolution Resources Rodent Science Slice Spottings Stretching Structure Structure of paraventricular nucleus of thalamus System Technology Tissues Transducers Ultrasonography Validation Withdrawal Symptom Work addiction bone clinical application cranium experimental study image guided imaging modality improved nervous system disorder neural circuit neuroregulation nonhuman primate novel relating to nervous system response

项目摘要

SUMMARY Numerous neuroscience and clinical applications exist for a noninvasive neuromodulation technology that can reach deep in the brain with high resolution. One compelling clinical application is the treatment of drug addiction, a major public health challenge in the US. In humans, the neural targets for treatment are 1-4 mm3, and thus a critical goal is to stimulate deep in the brain with higher resolutions than currently available with any noninvasive stimulation modality. The goal of this research is the development and experimental validation of computational models for optimization of high resolution deep brain transcranial ultrasound stimulation (TUS) for neuroscience and clinical application. Noninvasive transcranial ultrasound stimulation has been shown to be safe and spatially specific in various animal models. However, current systems are not optimized for high resolution TUS of the deep brain. Computational modeling suggests we can optimize TUS with phased array systems that can be driven in pairs while oriented at 90° to each other and focused to the same point, called “crossbeam.” This improves the stimulation resolution by more than an order of magnitude. In addition, our modeling suggests that we can selectively stimulate neural tissue using a “pinch” or “stretch.” In this project, we will perform a biological validation of crossbeam’s improved effectiveness due to the neural tissue’s sensitivity to “pinch” or “stretch.” Our validated modeling will be used to refine a crossbeam neurostimulation strategy involving optimized array probes. This will allow not only choice of focal depth, but also compensation of phase aberrations resulting from the propagation through the skull bone. The optimized hardware and the developed computational models will be integrated with imaging guidance and validated in skull phantom experiments. RELEVANCE (See instructions): We are developing the technology for improving health through the noninvasive treatment of neurological disorders such as addiction.

概括无创神经调节技术存在大量神经科学和临床应用，可以以高分辨率到达大脑深处，一种引人注目的临床应用是药物治疗。成瘾是美国的一项重大公共卫生挑战。对于人类来说，治疗的神经目标是 1-4。 mm3，因此一个关键目标是以比目前更高的分辨率刺激大脑深处这项研究的目标是开发和实验。高分辨率深脑经颅超声优化计算模型的验证用于神经科学和临床应用的无创经颅超声刺激（TUS）。已被证明在各种动物模型中是安全的和空间特异性的，然而，当前的系统是安全的。未针对深部大脑的高分辨率 TUS 进行优化计算模型表明我们可以进行优化。具有相控阵系统的 TUS，可以成对驱动，同时彼此成 90° 定向并聚焦到同一点，称为“横梁”。这将刺激分辨率提高了一个数量级以上此外，我们的模型表明我们可以使用a选择性地刺激神经组织。 “捏”或“拉伸”。在这个项目中，我们将对横梁的改进进行生物学验证。由于神经组织对“收缩”或“拉伸”的敏感性，我们验证的模型将是有效的。用于完善涉及优化阵列探针的横梁神经刺激策略。不仅可以选择焦深，还可以补偿传播引起的相位像差通过颅骨，优化的硬件和开发的计算模型将被集成。具有成像引导并在头骨模型实验中得到验证。相关性（参见说明）：我们正在开发通过神经系统疾病的无创治疗来改善健康的技术诸如成瘾之类的疾病。