A Wireless Implanted Device for Brain Monitoring in Support of Addiction Research

用于支持成瘾研究的大脑监测无线植入设备

• 批准号: 7682922
• 负责人: PAUL A GARRIS
• 金额: $ 14.98万
• 依托单位: CASE WESTERN RESERVE UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2008
• 资助国家: 美国
• 起止时间: 2008-09-01 至 2010-08-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7682922
• 关键词: Address; Amphetamines; Analytical Chemistry; Animal Model; Animals; Arts; Award; Basic Science; Behavior; Brain; Calibration; Chemicals; Cocaine; Collaborations; Complex; Computers; Consumption; Data; Development; Device or Instrument Development; Devices; Dimensions; Dopamine; Dose; Drug Addiction; Drug Controls; Electric Stimulation; Electrical Engineering; Electrophysiology (science); Engineering; Equipment; Flow Injection Analysis; Foundations; Goals; Head; Illinois; Immunity; Implant; In Vitro; Investigation; Laboratory Animals; Link; Measurement; Microelectrodes; Monitor; Morphologic artifacts; Movement; Neurobiology; Neurotransmitters; Noise; Pharmaceutical Preparations; Psychological reinforcement; Public Health; Rattus; Research; Resolution; Role; Scanning; Scheme; Scientist; Semiconductors; Signal Transduction; Source; Staging; Stimulus; Techniques; Technology; Telemetry; Testing; Transgenic Mice; Universities; Weight; Wireless Technology; addiction; awake; carbon fiber; digital; electrical measurement; implantable device; innovation; instrument; instrumentation; meetings; metal oxide; microsystems; miniaturize; mouse model; neuromechanism; neuroregulation; next generation; postsynaptic; programs; psychostimulant; public health relevance; relating to nervous system; transmission process

DESCRIPTION (provided by applicant): In this Cutting-Edge Basic Research Award (CEBRA) proposal, an electrical engineer/computer scientist (PI Mohseni) and a neurobiologist/analytical chemist (PI Garris) will collaborate to develop an ultra-small, implantable device for wireless neural monitoring and stimulation in awake animals. This device will advance the investigation of biologic mechanisms of drug addiction by extending recent innovations in fast-scan cyclic voltammetry (FSCV) at a carbon-fiber microelectrode (CFM). By virtue of chemically selective recording with sub-second temporal resolution at a micron-sized probe, FSCV at a CFM is recognized as state-of-the-art for neurotransmitter monitoring. In the last decade, great strides have been made applying FSCV at a CFM to ambulatory rats for studying the role of phasic dopaminergic transmission in goal-directed behaviors, particularly with regard to cocaine reinforcement, and combining chemical and electrical measurements at the same probe for quantifying postsynaptic effects of brain dopamine dynamics. By extending the already attractive analytical attributes of FSCV at a CFM on several fronts, we firmly believe that the device proposed here meets criteria for the CEBRA program. Proposed developments include: (1) replacing the hardwired connection with a digital telemetry link; (2) replacing the external stimulus generator with an on-chip component; (3) significantly reducing overall dimensions, weight, and power consumption; (4) supporting multiple, independently configurable channels for FSCV, electrophysiology, and combined measurements. Collectively, these advances address concerns related to the current use of "large" head-mounted devices as well as tethering animals to equipment, which may alter behavior, act as a noise source, and preclude measurements in smaller, but valuable animal models such as transgenic mice. Moreover, multiple data channels afford the enticing prospect of marrying two powerful technologies for neural monitoring, FSCV at a CFM and multielectrode array single-unit recording, to assess complex circuit-level control of drug-related behavior on an integrative level. The three specific aims are to: (1) using very-large-scale-integration techniques in standard complementary-metal-oxide-semiconductor technology, develop a 16-channel device supporting voltammetry, electrophysiology, and combined measurements, as well as electrical stimulation; (2) test and characterize the device on several levels, including benchtop engineering assessment, in vitro calibration with flow injection analysis, and anesthetized and awake rats; (3) showcase device features in two pilot applications, FSCV dopamine measurements in the awake rat during high-dose administration of the psychostimulant amphetamine and single-unit recording with microwire bundles chronically implanted in a transgenic mouse model. By developing the first wireless integrated circuit supporting chemical and electrical sensing and electrical stimulation, this CEBRA proposal will address key limitations of existing instrumentation for FSCV at a CFM and advance this already powerful neural monitoring technique. PUBLIC HEALTH RELEVANCE: This project will develop a miniaturized wireless device supporting chemical and electrical recording as well as electrical stimulation in the brain of small laboratory animals. This device will advance basic science research investigating neural mechanisms of drug addiction.

描述（由申请人提供）：在这项尖端基础研究奖（CEBRA）提案中，电气工程师/计算机科学家（PI Mohseni）和神经生物学家/分析化学家（PI Garris）将合作开发一种超小型植入式设备，用于清醒动物的无线神经监测和刺激。该装置将通过在碳纤维微电极（CFM）上扩展快速扫描循环伏安法（FSCV）的最新创新来推进对药物成瘾生物机制的研究。凭借在微米级探针上以亚秒级时间分辨率进行化学选择性记录，CFM上的FSCV被认为是神经递质监测的最新技术。在过去的十年中，已经取得了很大的进步，应用FSCV在CFM的动态大鼠研究阶段性多巴胺能传递的作用，在目标导向的行为，特别是关于可卡因的强化，并结合化学和电测量在同一探针定量脑多巴胺动力学的突触后效应。通过扩展已经有吸引力的分析属性FSCV在CFM在几个方面，我们坚信，这里提出的设备符合标准的CEBRA计划。拟议的发展包括：（1）用数字遥测链路取代硬连线连接;（2）用片上组件取代外部刺激发生器;（3）显著降低整体尺寸、重量和功耗;（4）支持多个可独立配置的通道，用于FSCV、电生理学和组合测量。总的来说，这些进展解决了与当前使用“大型”头戴式设备以及将动物拴在设备上相关的问题，这些设备可能会改变行为，充当噪声源，并妨碍在较小但有价值的动物模型（如转基因小鼠）中进行测量。此外，多个数据通道提供了诱人的前景，结合两个强大的神经监测技术，FSCV在CFM和多电极阵列单单元记录，评估复杂的电路级控制的药物相关行为的综合水平。三个具体目标是：（1）在标准互补金属氧化物半导体技术中使用超大规模集成技术，开发支持伏安法、电生理学和组合测量以及电刺激的16通道设备;（2）在多个水平上测试和表征装置，包括台式工程评估，利用流动注射分析的体外校准，以及麻醉和清醒大鼠;（3）在两个试点应用中展示了设备功能，在高剂量精神兴奋剂安非他明给药期间清醒大鼠的FSCV多巴胺测量和在转基因小鼠模型中长期植入微线束的单单位记录。通过开发第一个支持化学和电学传感以及电刺激的无线集成电路，CEBRA的提案将解决CFM中FSCV现有仪器的关键限制，并推进这种已经强大的神经监测技术。 公共卫生关系：该项目将开发一种小型化无线设备，支持化学和电记录以及小型实验室动物大脑的电刺激。这一装置将推进基础科学研究，研究药物成瘾的神经机制。