THREE-AXIS OCULAR MOTOR CONTROL BY THE CEREBELLUM

小脑的三轴眼运动控制

• 批准号: 6178733
• 负责人: MARK F. WALKER
• 金额: $ 12.35万
• 依托单位: JOHNS HOPKINS UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 1999
• 资助国家: 美国
• 起止时间: 1999-09-30 至 2004-09-29
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/6178733
• 关键词: Primates; binocular vision; biological signal transduction; brain disorders; cerebellum; clinical research; computer data analysis; eye disorder diagnosis; eye movement disorders; eye movements; human subject; neuromuscular system; neuroregulation; smooth pursuit eye movement; statistics /biometry; video recording system; visual stimulus

The goal of this career development proposal is to provide the educational and research training necessary for a career in ocular motor neuro-ophthalmology, with an emphasis on the role of the cerebellum in the three-axis (horizontal, vertical, and torsional) control of eye movements. The research plan involves a combination of experimental and modeling approaches with parallel studies in human cerebellar patients and non-human primates. Additional training components include formal instruction in statistics and data analysis, control system approaches to the ocular motor system, mentoring in neural modeling techniques, and additional instruction in clinical neuro-ophthalmology and strabismus. Although much has been learned about the cerebellar control of horizontal and vertical eye movements, studies of the cerebellar control of torsion are much more limited. The experiments in this proposal take advantage of recent advances in three-axis techniques to investigate the vestibulocerebellar, and particularly the floccular, contribution to eye torsion. Using a three-axis magnetic search coil technique, recordings will be made in human cerebellar patients and in primates before and after surgical floccular lesions. Experiments will address the control of three-axis eye velocity during eye movements evoked by visual (pursuit and optokinetic) and vestibular (low- and high-frequency) stimulation. The control of static torsion and binocular alignment will also be investigated. Later experiments will focus on the cerebellar contribution to the linear VOR and on the effects of lesions in other cerebellar regions on three-axis eye movement behavior. These experiments should provide a greater understanding of the pathophysiology of vestibulocerebellar lesions, as well the three-axis representation of visual and eye movement signals in the cerebellum. They also complement other recent studies dealing with peripheral mechanisms of torsion control. Finally, they may lead to a greater insight into the role of the cerebellum in compensating for lesions elsewhere in the ocular motor system, such as superior oblique pareses and other causes of strabismus. This might lead to better treatment for these disorders.

该职业发展计划的目标是提供必要的教育和研究培训，以眼运动神经眼科学的职业生涯，重点是小脑在眼球运动的三轴（水平，垂直和扭转）控制中的作用。 该研究计划包括实验和建模方法的结合，以及对人类小脑患者和非人类灵长类动物的平行研究。 其他培训内容包括统计和数据分析的正式指导，眼运动系统的控制系统方法，神经建模技术的指导，以及临床神经眼科学和斜视的其他指导。虽然已经了解了很多关于小脑控制水平和垂直眼球运动的研究，但小脑控制扭转的研究要有限得多。 在这个建议中的实验利用三轴技术的最新进展，以调查前庭小脑，特别是絮状，眼睛扭转的贡献。 使用三轴磁探测线圈技术，记录将在人类小脑患者和灵长类动物手术前和手术后絮状病变。 实验将解决在视觉（追踪和视动）和前庭（低频和高频）刺激诱发的眼球运动过程中三轴眼球速度的控制。 静态扭转和双目对准的控制也将进行研究。 以后的实验将集中于小脑对线性VOR的贡献，以及小脑其他区域病变对三轴眼球运动行为的影响。这些实验应该提供了一个更好的理解的病理生理前庭小脑病变，以及在小脑的视觉和眼球运动信号的三轴表示。 他们还补充了其他最近的研究处理扭转控制的外周机制。 最后，他们可能导致更深入地了解小脑在补偿眼运动系统其他部位病变中的作用，如上级斜肌麻痹和其他斜视原因。 这可能会导致更好的治疗这些疾病。