CSHL 2022 Molecular Mechanisms of Neuronal Connectivity Conference

CSHL 2022神经元连接分子机制会议

• 批准号: 10469150
• 负责人: DAVID J. STEWART
• 金额: $ 1万
• 依托单位: COLD SPRING HARBOR LABORATORY
• 依托单位国家: 美国
• 财政年份: 2022
• 资助国家: 美国
• 起止时间: 2022-08-15 至 2023-07-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/10469150
• 关键词: Anatomy; Animal Model; Area; Axon; Biochemistry; Biological Models; Brain; Cells; Cellular biology; Collaborations; Communication; Computational Biology; Consultations; Data; Defect; Dendrites; Development; Discipline; Electrophysiology (science); Ensure; Environment; Equilibrium; European; Faculty; Fostering; Foundations; Functional Imaging; Gender; Genetic; Goals; Health; Human; Incentives; Industrialization; Industry; International; Interview; Invertebrates; Laboratories; Length of Stay; Mediation; Molecular; Molecular Biology; Morphogenesis; Natural regeneration; Nerve Degeneration; Nerve Regeneration; Nervous system structure; Neuroglia; Neuronal Plasticity; Neurons; Neurosciences; Oral; Participant; Positioning Attribute; Postdoctoral Fellow; Primates; Process; Published Comment; Publishing; Research; Research Institute; Research Personnel; Resolution; Schedule; Scientist; Series; Synapses; System; Thinking; Woman; Work; axon guidance; axon injury; axon regeneration; base; career; career development; career networking; clinically relevant; graduate student; human stem cells; insight; interest; laboratory facility; lectures; meetings; nervous system disorder; neural circuit; neuron regeneration; neuronal circuitry; neurophysiology; new technology; optical imaging; parity; posters; programs; relating to nervous system; repaired; structural biology; success; symposium; synaptogenesis; transcriptomics; unpublished works; Anatomy; Animal Model; Area; Axon; Biochemistry; Biological Models; Brain; Cells; Cellular biology; Collaborations; Communication; Computational Biology; Consultations; Data; Defect; Dendrites; Development; Discipline; Electrophysiology (science); Ensure; Environment; Equilibrium; European; Faculty; Fostering; Foundations; Functional Imaging; Gender; Genetic; Goals; Health; Human; Incentives; Industrialization; Industry; International; Interview; Invertebrates; Laboratories; Length of Stay; Mediation; Molecular; Molecular Biology; Morphogenesis; Natural regeneration; Nerve Degeneration; Nerve Regeneration; Nervous system structure; Neuroglia; Neuronal Plasticity; Neurons; Neurosciences; Oral; Participant; Positioning Attribute; Postdoctoral Fellow; Primates; Process; Published Comment; Publishing; Research; Research Institute; Research Personnel; Resolution; Schedule; Scientist; Series; Synapses; System; Thinking; Woman; Work; axon guidance; axon injury; axon regeneration; base; career; career development; career networking; clinically relevant; graduate student; human stem cells; insight; interest; laboratory facility; lectures; meetings; nervous system disorder; neural circuit; neuron regeneration; neuronal circuitry; neurophysiology; new technology; optical imaging; parity; posters; programs; relating to nervous system; repaired; structural biology; success; symposium; synaptogenesis; transcriptomics; unpublished works

ABSTRACT Molecular Mechanisms of Neuronal Connectivity September 13 – 17, 2022 The proposed meeting to be held at Cold Spring Harbor Laboratory on “Molecular Mechanisms of Neuronal Connectivity” in September 2022 will assemble leaders in the field, junior faculty, postdoctoral fellows and graduate students to discuss new, cutting-edge developments in the areas defined in the meeting title. This proposal seeks support for the thirteenth of a biennial series of meetings held at Cold Spring Harbor Laboratory that has emerged as the premiere meeting in the world for this field. Topics to be discussed for the 2022 meeting will include: programs of circuit wiring, axon targeting, axon regeneration, synapse assembly, synapses in neural circuits, glial control of neuronal circuitry and neuronal repair. The planned sessions and invited session chairs will emphasize new technologies and adverse experimental approaches. Approaches include cell biology, biochemistry, genetics, structural biology, computational biology and electrophysiology. Importantly, the meeting brings together research from multiple systems, including various vertebrate and invertebrate model organisms, primates and human stem cells for investigating neural connectivity and function. Given the diverse approaches currently employed in this field, communication among international researchers is essential to advance research and understanding of fundamental mechanisms that regulate wiring of the nervous system and how these mechanisms may relate to the causes and potential cures for neurological disease. Oral presentations will be selected by the session chairs in consultation with the organizers. Each session will be chaired by two leading scientists in the field and the session chairs will give presentations on their cutting-edge research. Selected speakers primarily include graduate students, postdoctoral fellows and junior faculty. Three special lectures will be presented to provide essential background critical to stimulating discussion between scientists working on related but distinct areas. There will also be three poster sessions where a majority of participants can present their work. The meeting will be of moderate size, and we expect 250-350 neuroscientists in attendance.

抽象的 神经元连通性的分子机制 9月13日至17日，2022年 拟议的会议将在冷泉港实验室举行，以“神经元的分子机制 连通性” 2022年9月将组建领导者，初级教职员工，博士后研究员和 研究生讨论会议标题中定义的领域的新的，尖端的发展。这 提案寻求支持在冷春港举行的两年一度的一系列会议的第十三次支持 实验室已成为该领域的世界首映会议。要讨论的主题 2022会议将包括：电路接线，轴突靶向程序，轴突再生，突触组件， 神经元电路的突触，神经元电路的神经胶质控制和神经元修复。计划的会议和 受邀的会议椅将强调新技术和不良实验方法。方法 包括细胞生物学，生物化学，遗传学，结构生物学，计算生物学和电生理学。 重要的是，会议汇集了来自多个系统的研究，包括各种脊椎动物和 无脊椎动物模型生物，主要和人类干细胞用于研究神经连通性和 功能。鉴于目前在该领域采取的不同方法，国际之间的沟通 研究人员对于提高研究和了解规范基本机制的研究和理解至关重要 神经系统的接线以及这些机制如何与原因和潜在治疗方法有关 神经疾病。会议主席将与 组织者。每个会议将由该领域的两位主要科学家主持，会议主席将提供 关于其前沿研究的演讲。选定的演讲者主要包括研究生 博士后研究员和初级教师。将介绍三个特殊讲座以提供必需品 背景对于刺激从事相关但不同领域的科学家之间的讨论至关重要。那里 也将是三个海报会议，大多数参与者可以展示他们的作品。会议将是 中等大小，我们预计有250-350名神经科学家出席。