Imaging Brain Function in Real World Environments & Populations with Portable MRI

真实世界环境中的大脑功能成像

• 批准号: 8935941
• 负责人: MICHAEL GARWOOD
• 金额: $ 37.01万
• 依托单位: UNIVERSITY OF MINNESOTA
• 依托单位国家: 美国
• 财政年份: 2014
• 资助国家: 美国
• 起止时间: 2014-09-26 至 2017-05-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8935941
• 关键词: Applications Grants; Behavior; Behavioral; Bicycling; Binding; Brain; Brain imaging; Clinic; Cognitive; Confined Spaces; Developing Countries; Discipline; Disease; Elderly; Elements; Emergency Situation; Energy Supply; Engineering; Environment; Equipment; Feasibility Studies; Frequencies; Functional Magnetic Resonance Imaging; Funding; Generations; Goals; Head; Health; Helium; High Prevalence; High temperature of physical object; Hospitals; Human; Image; Imaging technology; Implant; Industry; Institution; Investigation; Laboratories; Liquid substance; Location; MRI Scans; Magnetic Resonance Imaging; Maintenance; Mathematics; Mechanics; Methodology; Methods; Motion; Movement; Natural Disasters; Neuroanatomy; Neurologic; Neurosciences; Neurosciences Research; New Territories; Nitrogen; Performance; Phase; Physically Handicapped; Physics; Play; Population; Population Heterogeneity; Population Study; Power Sources; Process; Reporting; Research Infrastructure; Role; Sampling; Shoulder; Site; Social Interaction; Soldier; Specific qualifier value; Sports; Students; System; Techniques; Technology; Temperature; Testing; Time; Traumatic Brain Injury; Tube; Variant; Veterans; War; Work; base; computer science; cost; design; experience; human subject; imaging modality; imaging system; magnetic field; meetings; multidisciplinary; neuroimaging; new technology; novel; portability; prevent; spatiotemporal; volunteer

 DESCRIPTION (provided by applicant): Functional magnetic resonance imaging (fMRI) continues to play a critical role in understanding the human brain. Yet current fMRI technology is far less than ideal for studying brain function due to the unnatural environment and restricting space of the magnet bore. Furthermore, fMRI cannot be performed on subjects who have metallic implants in their body (e.g., the elderly, soldiers and veterans), or who are impaired by certain physical disabilities as occurs in a variety of neurological and vestibular disorders. Finally, due to its expense and infrastructure requirements, MRI's predominant accessibility to wealthier institutions has resulted in a highly biased subject sampling and a shortage of studies in non-western environments and cultures. The general methodology used to obtain MR images today is essentially the same as that used approximately 4 decades ago. One major drawback of such methodology is that the tolerated magnetic field variation over the brain is limited to a small fraction of the magnet's field, B0. To overcome these limitations, a new MRI methodology has been conceived called STEREO, which stands for steering resonance over the object. By generating images with spatiotemporal-encoding, STEREO allows the B0 field to vary by a large amount, and for the first time, makes it possible to use a smaller, inherently less homogeneous magnet. In this project, the unique capabilities of STEREO will be exploited to demonstrate the feasibility of a portable, remotely supportable, head-only MRI scanner to permit imaging brain function in all populations and environments worldwide. To achieve this goal, this project will develop the STEREO methodology, in combination with new multi-coil gradient technology and new MRI spectrometer technology, to produce human brain images in a highly non-uniform B0. This project will also undertake a feasibility study of a new 1.5 T, high temperature superconducting magnet operating at liquid nitrogen temperature (77 K), to free the requirements for often unavailable liquid helium and/or a stable power supply for cryo-cooling. The overall objective of this grant proposal is to demonstrate the feasibility of critical new methods and technology required for this revolutionary MRI system to become a reality. A multidisciplinary team of leading experts from multiple institutions and industry will meet monthly to report and discuss progress, provide guidance, identify problems and decide corrective courses of action. Based on the experience gained in the process, our new generation MRI system will be specified and designed by the end of this 3-year project. This system will be built and tested with our next round of funding. Making this system available to neuroscientists will open exciting new territories of investigation into the human brain and human behavior, in a wide range of conditions and populations of subjects worldwide.

 描述（由申请人提供）：功能性磁共振成像（fMRI）在理解人脑方面继续发挥关键作用。然而，目前的功能磁共振成像技术是远远不够理想的研究大脑功能，由于不自然的环境和限制空间的磁铁孔。此外，不能对体内有金属植入物的受试者进行fMRI（例如，老年人、士兵和退伍军人），或因某些身体残疾而受损的人，如在各种神经和前庭疾病中发生的。最后，由于其费用和基础设施要求，MRI对富裕机构的主要可及性导致了受试者抽样的高度偏见以及非西方环境和文化研究的短缺。 今天用于获得MR图像的一般方法与大约40年前使用的方法基本相同。这种方法的一个主要缺点是大脑上的容许磁场变化限于磁体场B 0的一小部分。为了克服这些限制，人们构想了一种名为STEREO的新MRI方法，它代表在物体上引导共振。通过生成具有时空编码的图像，STEREO允许B 0场变化很大，并且第一次使得可以使用更小的、固有地更少的 均匀磁铁在该项目中，将利用STEREO的独特功能来证明便携式、可远程支持的、仅头部MRI扫描仪的可行性，以允许在全球所有人群和环境中对脑功能进行成像。为了实现这一目标，该项目将开发STEREO方法，结合新的多线圈梯度技术和新的MRI光谱仪技术，以高度不均匀的B 0生成人脑图像。该项目还将对一种在液氮温度（77 K）下运行的新的1.5 T高温超导磁体进行可行性研究，以消除对通常不可用的液氦和/或用于低温冷却的稳定电源的需求。这项资助提案的总体目标是证明这一革命性MRI系统成为现实所需的关键新方法和技术的可行性。来自多个机构和行业的领先专家组成的多学科团队将每月举行会议 报告和讨论进展情况，提供指导，发现问题并决定纠正行动方案。根据在此过程中获得的经验，我们的新一代MRI系统将在本3年项目结束时指定和设计。这个系统将在我们的下一轮资金中建立和测试。使这个系统提供给神经科学家将打开令人兴奋的新领域的调查人类大脑和人类行为，在广泛的条件和人群的主题世界各地。