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Nanoparticle Induced Circuit Excitation

纳米颗粒感应电路激励

基本信息

批准号：
8656131
负责人：
JEFFREY M FRIEDMAN
金额：
$ 38.37万
依托单位：
ROCKEFELLER UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2011
资助国家：
美国
起止时间：
2011-09-26 至 2016-04-30
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/8656131
关键词：
Action Potentials Address Animals Antibodies Apoptosis Autologous Transplantation Basic Science Behavior Binding Biology Biotin Brain Calcium Cell physiology Cell surface Cells Clinical Communities Complex Coupled Cultured Cells DNA Structure Data Desire for food Diabetic mouse Disadvantaged Distant Electromagnetic Fields Endocrine Energy Metabolism Ensure Epitopes Exposure to Feeding behaviors Fiber Optics Foundations Frequencies Gene Expression Gene Expression Regulation Glucagon Glucose Glycocalyx Goals Gold Heating Hippocampus (Brain)Hormones Human Hypothalamic structure Image In Vitro Individual Injection of therapeutic agent Insulin Internal Ribosome Entry Site Investigation Ion Channel Lead Life Light Luciferases Membrane Membrane Potentials Metals Methodology Methods Mitochondria Modeling Monitor Neurons Nude Mice Operative Surgical Procedures Optical Methods Organism Peripheral Physiological Physiological Processes Physiology Plasma Play Population Process Proteins Protocols documentation Relative (related person)Reporter Response Elements Rewards Rhodopsin Role Safety Slice Staging Streptavidin Structure of nucleus infundibularis hypothalami System TRPV1 gene Techniques Technology Temperature Testing Time Transgenic Mice base blood glucose regulation cell type cellular engineering combinatorial diabetic dopaminergic neuron ferrous oxide glucose metabolism implantation in vivo induced pluripotent stem cell insulin secretion iron oxide mouse model nanoparticle new technology novel strategies particle patch clamp promoter radiofrequency relating to nervous system research study response tool tumor

项目摘要

DESCRIPTION (provided by applicant): A set of experiments is proposed to validate and further develop a new nanoparticle based technology, Nanoparticle induced Circuit excitation (NICE), for modulating the activity of cells remotely and non-invasively. A fundamental goal of biology is to understand the role of each cell type in a complex organism. The definitive test of cell function is to selectively turn on or off the activity of a single cell type in a living animal and examine the effect on physiological function. Recent tools, such as light activated ion channels such as channel rhodopsin, have pioneered the external control of membrane potential in genetically defined cells and established a new means for investigation by neuroscientists. However, these optical methods have practical disadvantages limiting their application including the need for surgical implantation of invasive fiber optics; the inability to stimulate cells in multiple anatomical regions simultaneously; and the difficulty of modulating multiple cell types in parallel. We address this challenge by using nanoparticles to activate defined cell populations remotely with radiowaves. Ferrous oxide coated with streptavidin is used to decorate cells, which express a biotin acceptor protein under the control of cell specific promoters. These same cells are engineered to also express TRPV1, a single component, temperature-sensitive ion channel that can detect small changes in temperature within the physiological range and by conformational change allow graded calcium entry. Exposing the metal coated cells to a defined electromagnetic field increases the local temperature and activates TRPV1 channels resulting in a Ca2+ current and cell activation. We have preliminary data that confirms the efficacy of this method in vitro and now propose to extend our studies to further validate the technology in vitro and to modulate in vivo functions such as hormone release and neural activity. We will also establish a means for combinatorial activation of different cells using a modified TRPV1 and nanoparticles fabricated from other metals that can be excited at different wavelengths. We will use this tool to examine the roles of specific peripheral and CNS cell populations in energy metabolism. We propose to develop this method in three stages: 1) Validate the safety and utility of NICE in vitro and refine the methodology by decorating different cell types with distinct particles tuned to different wavelengths to activate ensembles of different cell populations in various combinations. 2) Establish the ability of NICE to modify hormone release to regulate glucose metabolism in diabetic animals in vivo. 3) Show that NICE can be used to stimulate action potentials in electrically excitable cells to modify behavior and use NICE to investigate the role of specific hypothalamic populations in (NPY and POMC) to control appetite. In time, NICE may be adapted for clinical uses, e.g: induced pluripotent stem cells engineered to express NICE constructs may act as autografts to enable external control of cell function. These applications are distant but not inconceivable and the studies proposed may form the foundation for the clinical use of nanoparticles.

描述(申请人提供)：为了验证和进一步开发一种新的基于纳米颗粒的技术，纳米颗粒感应电路激发(NICE)，用于远程和非侵入性地调节细胞的活动，提出了一组实验。生物学的一个基本目标是了解每种细胞类型在复杂有机体中的作用。细胞功能的决定性测试是有选择地开启或关闭活着的动物中单一细胞类型的活动，并检查其对生理功能的影响。最近的工具，如光激活离子通道，如视紫红质，开创了对遗传细胞膜电位的外部控制，并为神经科学家的研究建立了一种新的手段。然而，这些光学方法的实际缺点限制了它们的应用，包括需要外科手术植入侵入性光纤；无法同时刺激多个解剖区域的细胞；以及难以并行调节多种细胞类型。我们通过使用纳米颗粒通过无线电波远程激活确定的细胞群来应对这一挑战。用包被链霉亲和素的氧化亚铁修饰细胞，在细胞特异性启动子的控制下表达生物素受体蛋白。这些细胞也被设计成表达TRPV1，这是一种单一成分的温度敏感离子通道，可以检测生理范围内温度的微小变化，并通过构象变化允许分级钙离子进入。将金属涂层细胞暴露在规定的电磁场中会增加局部温度，并激活TRPV1通道，导致钙电流和细胞激活。我们有初步数据证实了这种方法在体外的有效性，现在建议扩大我们的研究，以进一步在体外验证这项技术，并调节体内的功能，如激素释放和神经活动。我们还将建立一种方法，使用改进的TRPV1和由其他金属制成的纳米颗粒来组合激活不同的细胞，这些纳米颗粒可以在不同的波长下被激发。我们将使用这个工具来研究特定的外周和中枢神经系统细胞群在能量代谢中的作用。我们建议分三个阶段发展这一方法：1)在体外验证NICE的安全性和实用性，并通过用不同波长的不同颗粒装饰不同类型的细胞来激活不同组合中不同细胞群的集合来改进方法。2)建立NICE调节体内糖尿病动物糖代谢的激素释放能力。3)证明NICE可以用来刺激电兴奋细胞的动作电位以改变行为，并用NICE研究特定的下丘脑群(NPY和POMC)在控制食欲中的作用。随着时间的推移，NICE可能会被用于临床，例如：表达NICE结构的诱导多能干细胞可以作为自体移植细胞，从而实现细胞功能的外部控制。这些应用是遥远的，但并非不可想象，所提出的研究可能为纳米颗粒的临床应用奠定基础。