Femtosecond laser axotomy for in vivo nerve regeneration studies in C elegans

飞秒激光轴切术用于线虫体内神经再生研究

• 批准号: 7487005
• 负责人: ADELA BEN-YAKAR
• 金额: $ 41.17万
• 依托单位: UNIVERSITY OF TEXAS AT AUSTIN
• 依托单位国家: 美国
• 财政年份: 2007
• 资助国家: 美国
• 起止时间: 2007-09-01 至 2011-07-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7487005
• 关键词: Ablation; Address; Affect; Animal Model; Animals; Apoptosis; Area; Axon; Axotomy; Behavior; Behavioral; Biological; Caenorhabditis elegans; Cells; Chemical Synapse; Chromosome Pairing; Complex; Condition; Development; Dimensions; Disease; Distal; Doctor of Philosophy; Electron Microscopy; Elements; Engineering; Essential Genes; Event; Exposure to; Fluorescence; Frequencies; Genes; Genetic; Goals; Growth; Heating; Hour; Human; Huntington Disease; Image; Individual; Injury; Institution; Investigation; Ion Channel; Label; Laser Surgery; Lasers; Lesion; Light; Localized; Measurement; Measures; Mediating; Medicine; Membrane; Microscopy; Microtomy; Modeling; Molecular; Morphology; Motor Neurons; Mus; Muscle; Names; Natural regeneration; Nature; Necrosis; Nematoda; Nerve; Nerve Regeneration; Nervous system structure; Neuraxis; Neurites; Neurobiology; Neurodegenerative Disorders; Neurons; Neurotoxins; Numbers; Operative Surgical Procedures; Optics; Organism; Paralysed; Parkinson Disease; Patients; Phagocytosis; Photobleaching; Physiologic pulse; Plasma; Principal Investigator; Probability; Process; Property; Pulse taking; Recovery; Recovery of Function; Research; Research Personnel; Resolution; Role; Side; Signal Transduction; Site; Spinal cord injury; Staging; Stress; Synapses; Synaptic Vesicles; System; Techniques; Texas; Time; Tissues; Transmission Electron Microscopy; Trauma; Ultrasonics; Ultrasonography; Universities; Vesicle; Zebrafish; austin; axon regeneration; college; design; developmental neurobiology; fascinate; fluorescence imaging; genetic analysis; in vivo; insight; laser scissor; mutant; nanoscale; nanosurgery; nervous system development; nervous system disorder; neuronal cell body; novel; physical process; positional cloning; presynaptic; prevent; programs; radius bone structure; research study; size; submicron; tool

DESCRIPTION (provided by applicant): Spinal cord injuries with consequent paralysis affect more than 250,000 people in the US and several million worldwide. The biological causes that prevent axonal regeneration to occur in the central nervous system (CMS) are still elusive. The lack of experimental techniques suited to address these questions in simple genetic model organisms has delayed the pace of the discoveries in this field. Recently, we have demonstrated that laser surgery can be used as a precise cutting tool to severe individual neurons in the nematode Caenorhabditis elegans. In the operated animals, the cut axons spontaneously regenerated with a complete recovery of the neuronal and behavioral function. Our first goal is to investigate in great detail the properties of femtosecond laser ablation of tissue and control its precision for severing axons inside C. elegans with minimal interference to the regeneration processes. The broad goal of this proposal is to understand the molecular mechanisms and the events that regulate axonal regeneration. We propose specifically to proceed as follow: 1. Determine the extent of tissue damage caused by the laser surgery and set optimal conditions for large scale screens. 2. Characterize and understand the dynamic events happening on the membrane at both sides of the severed axon. 3. Discover the genes and conditions that are essential for the regeneration process to occur. Hundred of thousands of people each year in the US and in the world are affected by paralisys caused by injuries or internal traumas of the nerves. The lacking ability of nerves in the Central Nervous System to regenerate is the main reason of the minimal recovery of the patients. The studies presented in this proposal will provide new insights into the fascinating process of nerve regeneration and hopefully offer new avenues for therapies.

描述（由申请人提供）：脊髓损伤导致瘫痪影响美国超过25万人，全球数百万人。 阻止轴突再生发生在中枢神经系统（CMS）的生物学原因仍然是难以捉摸的。 由于缺乏适合在简单遗传模式生物中解决这些问题的实验技术，延迟了这一领域的发现步伐。 最近，我们已经证明，激光手术可以作为一种精确的切割工具，严重的线虫秀丽隐杆线虫个别神经元。 在手术动物中，切断的轴突自发再生，神经元和行为功能完全恢复。 我们的第一个目标是详细研究飞秒激光消融组织的特性，并控制其切割C内轴突的精度。对再生过程的干扰最小。 这项建议的主要目标是了解调节轴突再生的分子机制和事件。 我们具体建议如下：1.确定激光手术造成的组织损伤程度，并为大规模屏幕设置最佳条件。 2.描述和理解在切断的轴突两侧的膜上发生的动态事件。 3.发现再生过程发生所必需的基因和条件。 在美国和世界上，每年有数十万人受到神经损伤或内部创伤引起的疼痛的影响。 中枢神经系统的神经缺乏再生能力是患者恢复最小的主要原因。 该提案中提出的研究将为神经再生的迷人过程提供新的见解，并有望为治疗提供新的途径。