NCS-FO: Collaborative Research: Fully-passive and wireless multi-channel neural recording for chronic in-vivo studies in animals

NCS-FO：合作研究：用于动物慢性体内研究的全被动无线多通道神经记录

• 批准号: 1734851
• 负责人: John Volakis
• 金额: $ 56.91万
• 依托单位: Ohio State University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2017
• 资助国家: 美国
• 起止时间: 2017-08-15 至 2017-11-30
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1734851&HistoricalAwards=false
• 关键词: NCS; FO; Collaborative; Research; Fully

This project focuses on the study of chronic in-vivo brain neuropotentials in free-moving animals acquired by wireless, fully-passive multi-channel recorders. Current clinical brain implants have limitations due to their intracranial wires, batteries, and heat caused by dense electronics. Recent work by the proposers introduced a new class of wireless and fully-passive neural implants. These implants were demonstrated to acquire in-vivo neural signal of 500 microVolts and in-vitro emulated neuropotentials as small as 20 microVolts. But these implants were limited to single-channel recording, prohibiting realistic in-depth brain studies. Herewith, we propose a bold and creative study to 1) Design and implement multi-channel, wireless and fully-passive brain implants; a passive approach is also proposed for implants, scalable to even 1000s of channels. 2) Enable chronic in-vivo recording and behavioral studies in free-moving animals. The proposed sensor system will provide, for the first time, a unique opportunity to study longitudinal brain dynamics. The impact of this research can be profound at many levels. Specifically, the success of this research may ultimately result in real and accessible multi-channel brain implant recorders to improve human well-being, especially for people suffering from chronic neurological disorders. Collectively, the recorded data can expose a very broad realm of the human's well-being. The utmost long-term aim is carefree, real-time and closed-loop diagnosis/treatment for several neurological disorders (tremors, Parkinson's, addictions, Alzheimer's, traumatic brain injury, epilepsy, etc.). A number of educational activities will be brought forward, including hands-on experiences to train students in a new area, summer camps, and a variety of outreach activities to attract women and minorities in engineering. This project is funded by Integrative Strategies for Understanding Neural and Cognitive Systems (NSF-NCS), a multidisciplinary program jointly supported by the Directorates for Computer and Information Science and Engineering (CISE), Education and Human Resources (EHR), Engineering (ENG), and Social, Behavioral, and Economic Sciences (SBE).This project proposes a bold and creative study for a new class of wireless fully-passive multi-channel neural recorders for safe and reliable neurosensing in free-moving animals. The key aspects of the proposed research are: 1) Design and implement multi-channel, wireless and fully-passive brain implants; Two different implants are proposed, with one scalable to 1000s of channels. 2) Enable chronic in-vivo recording and behavioral studies in free-moving animals. Of importance is that the proposed wireless and fully-passive biotelemetry sensor is expected to significantly enhance long-term reliability and safety of brain implants. This is due to 1) None to minimal heat dissipation by the implant, 2) Elimination of infections from intra-cranial wires, and 3) Avoidance of batteries within the skull. This game-changing research can lead to the first wireless and fully-passive chronic recording of brain signals using free-moving animal models (rats). Notably, the proposed neurosensors employ a unique microwave backscattering method to enable wireless battery-less operation. As a result, wires, cables and active electronic components are avoided. Multi-channel recording is implemented by integrating photo-selective and photo-sensitive switches to activated individual channels via a multi-band light source and corresponding filters for channel selection. Overall, the proposed sensor system will provide, a unique opportunity to study longitudinal brain dynamics for studying brain activity in the natural environment of animals. The proposed sensing system will also have significant impact on safety and reliability for long-term operation.

该项目的重点是研究通过无线、全被动多通道记录仪获得的自由移动动物的慢性在体脑神经电位。目前的临床脑植入物由于其颅内电线、电池和由密集电子器件引起的热量而具有局限性。提议者最近的工作介绍了一类新的无线和全被动神经植入物。这些植入物被证明可以获得500微伏的体内神经信号和小至20微伏的体外模拟神经电位。 但这些植入物仅限于单通道记录，无法进行现实的深入大脑研究。因此，我们提出了一个大胆的和创造性的研究1）设计和实现多通道，无线和全被动的大脑植入物;一个被动的方法也提出了植入物，可扩展到甚至1000个通道。2)在自由活动的动物中进行长期体内记录和行为研究。拟议的传感器系统将首次提供一个独特的机会来研究纵向脑动力学。这项研究的影响可以在许多层面上是深远的。具体来说，这项研究的成功可能最终导致真实的和可访问的多通道大脑植入记录器，以改善人类的福祉，特别是对患有慢性神经系统疾病的人。 总的来说，记录的数据可以揭示人类福祉的非常广泛的领域。最大的长期目标是对几种神经系统疾病（震颤、帕金森氏症、成瘾、阿尔茨海默氏症、创伤性脑损伤、癫痫等）进行无忧无虑的实时闭环诊断/治疗。将开展一些教育活动，包括在一个新领域培训学生的实践经验、夏令营和各种外联活动，以吸引妇女和少数民族从事工程学工作。该项目由理解神经和认知系统的综合战略（NSF-NCS）资助，这是一个由计算机和信息科学与工程（CISE），教育和人力资源（EHR），工程（ENG）和社会，行为，和经济科学（SBE）。该项目提出了一个大胆的和创造性的研究，为一类新的无线全被动多通道神经记录器的安全和可靠的神经传感在自由，移动的动物本研究的主要内容包括：1）设计并实现多通道、无线、全无源的脑植入体;提出了两种不同的脑植入体，其中一种可扩展到1000个通道。2)在自由活动的动物中进行长期体内记录和行为研究。重要的是，所提出的无线和全被动生物遥测传感器有望显着提高大脑植入物的长期可靠性和安全性。这是由于：1）植入物无散热至最低散热，2）消除颅内导线的感染，以及3）避免颅骨内的电池。这项改变游戏规则的研究可能会导致第一次使用自由移动的动物模型（大鼠）无线和完全被动地长期记录大脑信号。值得注意的是，所提出的神经传感器采用独特的微波反向散射方法来实现无线无电池操作。因此，避免了电线、电缆和有源电子部件。多通道记录是通过将光选择性和光敏开关集成到经由多波段光源和用于通道选择的相应滤波器激活的各个通道来实现的。总的来说，所提出的传感器系统将提供一个独特的机会，研究纵向脑动力学研究在自然环境中的动物的大脑活动。拟议的传感系统也将对长期运行的安全性和可靠性产生重大影响。