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Biomimetic Surface for Neural Implants

用于神经植入的仿生表面

基本信息

批准号：
8761947
负责人：
XINYAN Tracy CUI
金额：
$ 61.73万
依托单位：
UNIVERSITY OF PITTSBURGH AT PITTSBURGH
依托单位国家：
美国
项目类别：
财政年份：
2008
资助国家：
美国
起止时间：
2008-08-15 至 2019-06-30
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/8761947
关键词：
Acute Address Animals Attenuated Autopsy Binding Biochemical Biocompatible Materials Biological Biomimetics Blood Vessels Brain Cell Adhesion Molecules Characteristics Chronic Cicatrix Clinical Clinical effectiveness Cochlear Implants Coupled Custom Deep Brain Stimulation Development Devices Dyes Electrodes Epilepsy Extravasation Failure Floor Goals Growth Inhibitors Health Histology Human Image Immunohistochemistry Implant Inflammation Knowledge Lead Life Light Link Longevity Macaca mulatta Mental Depression Metric Microarray Analysis Microelectrodes Microglia Microscopy Modeling Modification Molecular Morphology Motor Cortex Movement Mus Names Nerve Degeneration Neural Cell Adhesion Molecule L1 Neurites Neurons Noise Ocular Prosthesis Parkinson Disease Performance Primates Process Rattus Reaction Research Signal Transduction Speed Stem cell transplant Surface Technology Testing Therapeutic Time Tissues Transgenic Animals Translating Transplantation Visual Cortex Work base brain machine interface brain tissue calcium indicator clinical application density design electric impedance expiration functional restoration implantable device improved in vivo mind control molecular dynamics nervous system disorder neural growth neuronal growth novel novel strategies promoter public health relevance relating to nervous system repaired response scaffold success surface coating tool two-photon

项目摘要

DESCRIPTION (provided by applicant): R01:Biomimetic Surface for Neural Implant PI: Tracy Cui Implantable microelectrode arrays for neural recording and stimulation have demonstrated tremendous research and clinical potential. Studies of brain tissue response to neural electrode arrays have revealed localized microglia activation, followed by astrocytic scarring and neural degeneration. These reactions are thought to contribute to the low yield and chronic failure of neural recording, although direct links have not been soundly established. Past studies characterizing the CNS response to implants have used postmortem histology at discrete time points. This approach suffers from a large degree of variability and fails to capture the dynamic molecular, cellular and vascular changes of the host. To address this issue, we have developed an experimental set-up to directly image the electrode-tissue interface in live animals using 2-photon microscopy in conjunction with electrical recording. Our previous work indicates that by coating the surface of neural probes with neural adhesion molecules, neuronal density around the device can be promoted while glial reaction attenuated. Meanwhile, neural recording quality is drastically improved. We hypothesize that promoting neuronal growth and health, and/or inhibiting microglia activation will lead to recording improvement. The specific objectives of thi project are to investigate the biological mechanisms of the coating's effect on recording and to evaluate the clinical potential of biomimetic coating in a brain machine interface (BMI) model. First, the acute neuronal and microglia responses to coated probes will be characterized in transgenic animals using two photon imaging and electrical recording for two weeks. Real time tissue characteristics (such as neuronal and neurite density, microglia density and morphology, vasculature change and BBB leakage) will be correlated to recording metrics(such as unit yield, SNR, amplitude of signal and noise as well as impedance). Several biomolecules that promote or inhibit neuronal growth or microglia activation will be immobilized on the Blackrock arrays to test our hypothesis. Secondly, the long-term benefit of the coatings on recording will be determine by testing the optimum coating conditions in rats for 6 months. Explants will be taken monthly to examine the coating longevity, while immunohistochemistry and microarray analysis of the tissue at the interface will be performed to characterize the cellular and molecular change over time. Thirdly, to assess the potential of biomimetic coating for clinical application, coated electrodes will be tested in rhesus monkeys in a brain-machine-interface (BMI) model. Recording metrics such as SNR, signal amplitude, unit yield and stability will be quantified over 2 years and compared to uncoated arrays. A novel functional metric will be developed to assess functionality of the recorded signals. BMI performance will be evaluated based on speed and accuracy. This proposal combines the cutting edge real-time imaging, effective biomaterial strategies and state of the art brain machine interface technology to understand the interactions between neural implants and host tissue. The findings will guide the development of seamless neural interface devices for BMI, visual and auditory prosthesis, deep brain stimulation for Parkinson's disease, depression and epilepsy, to name a few. The knowledge will also benefit other brain implants from biochemical sensing and therapeutic delivery to scaffold and stem cell transplant for treating neurological disorders.

描述（由申请人提供）：R 01：用于神经植入物的仿生表面PI：Tracy Cui用于神经记录和刺激的植入式微电极阵列已显示出巨大的研究和临床潜力。脑组织对神经电极阵列反应的研究揭示了局部小胶质细胞激活，随后出现星形胶质细胞疤痕和神经变性。这些反应被认为是导致神经记录的低产量和慢性失败的原因，尽管直接联系还没有完全建立。过去表征CNS对植入物反应的研究使用了离散时间点的尸检组织学。这种方法具有很大程度的可变性，并且不能捕获宿主的动态分子、细胞和血管变化。为了解决这个问题，我们已经开发了一个实验装置，直接成像的电极组织界面在活的动物使用2光子显微镜结合电记录。我们的前期工作表明，通过在神经探针表面涂覆神经粘附分子，可以提高器件周围的神经元密度，同时减弱胶质反应。与此同时，神经记录质量得到了极大的改善。我们假设，促进神经元的生长和健康，和/或抑制小胶质细胞激活将导致记录的改善。本项目的具体目标是研究涂层对记录影响的生物学机制，并评估仿生涂层在脑机接口（BMI）模型中的临床潜力。首先，将在转基因动物中使用双光子成像和电记录两周来表征对包被探针的急性神经元和小胶质细胞反应。将真实的时间组织特征（例如神经元和神经突密度、小胶质细胞密度和形态、脉管系统变化和BBB泄漏）与记录度量（例如单位产量、SNR、信号和噪声的幅度以及阻抗）相关联。几种促进或抑制神经元生长或小胶质细胞活化的生物分子将被固定在Blackrock阵列上以测试我们的假设。其次，将通过在大鼠中测试最佳涂层条件6个月来确定涂层对记录的长期益处。每月取出一次，以检查涂层寿命，同时对界面处的组织进行免疫组织化学和微阵列分析，以表征细胞和分子随时间的变化。第三，为了评估仿生涂层的临床应用潜力，电极将在恒河猴脑机接口（BMI）模型中进行测试。将在2年内量化记录指标，如SNR、信号幅度、单位产量和稳定性，并与未涂层阵列进行比较。将开发一种新的功能度量来评估记录信号的功能。 BMI性能将根据速度和准确性进行评估。该提案结合了尖端的实时成像，有效的生物材料策略和最先进的脑机接口技术，以了解神经植入物和宿主组织之间的相互作用。这些发现将指导BMI，视觉和听觉假体，帕金森病，抑郁症和癫痫症的深部脑刺激的无缝神经接口设备的开发。这些知识也将使其他脑植入物受益，从生化传感和治疗输送到支架和干细胞移植，用于治疗神经系统疾病。