Anatomical and functional imaging of the conventional outflow pathway

传统流出通道的解剖和功能成像

基本信息

批准号：
10752459
负责人：
Raymond Fang
金额：
$ 4.29万
依托单位：
NORTHWESTERN UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2023
资助国家：
美国
起止时间：
2023-09-01 至 2025-08-31
项目状态：
未结题

来源：
https://reporter.nih.gov/project-details/10752459
关键词：
3-Dimensional Anatomy Angiography Anterior Aqueous Humor Autopsy Behavior Biological Markers Biomedical Engineering Biophotonics Blindness Blood Vessels Blood flow Clinical Clinical Medicine Data Development Diameter Dimensions Distal Doctor of Philosophy Effectiveness Environment Eye Foundations Frequencies Functional Imaging Glaucoma Goals Height Heterogeneity Human Image Imaging technology Individual Intervention Investigation Light Machine Learning Maps Measurement Measures Mentors Methods Modeling Motion Mus Operating Rooms Optical Coherence Tomography Pathway interactions Pattern Pharmaceutical Preparations Phase Physicians Physiologic Intraocular Pressure Physiological Physiology Pilocarpine Predisposing Factor Procedures Property Publishing Research Research Personnel Resistance Resolution Rodent Sampling Scheme Structure Structure of sinus venosus of sclera Structure-Activity Relationship System Testing Three-Dimensional Imaging Tissues Trabecular meshwork structure Tracer Training Translating Treatment Effectiveness Variant Veins Visible Radiation Visualization Width Work anatomic imaging anterior chamber aqueous clinical care contrast imaging density design digital effective therapy eye chamber functional status glaucoma surgery graph theory imaging modality improved in vivo innovative technologies mathematical model mechanical properties meter minimally invasive non-invasive imaging optimal treatments pharmacologic pressure response retinal imaging technical report tool treatment strategy

项目摘要

Project Summary: Glaucoma is the leading cause of irreversible blindness worldwide. Currently, the only effective treatment for glaucoma is intraocular pressure (IOP) reduction. Physiologically, IOP is regulated by the aqueous outflow from the anterior chamber of the eye, with the vast majority leaving through the conventional outflow pathway. Despite the importance of the conventional outflow pathway, essential questions such as the relative contribution of the distal pathway to outflow resistance and the factors predisposing regions of the outflow pathway to be high and low flow remain unknown. Emerging imaging modalities such as optical coherence tomography, mainly used for retinal imaging, can provide anatomical and functional information that will elucidate the physiological behavior of the outflow pathway in vivo. Recent evidence using aqueous angiography shows that flow patterns in the outflow pathway can be used to increase the effectiveness of minimally invasive glaucoma surgery (MIGS). The PI is an MD/PhD trainee who proposes to utilize the ultrahigh (~1.3 microns in tissue) axial resolution of visible-light optical coherence tomography (vis-OCT) to noninvasively assess the physiology of the conventional outflow pathway in vivo. Using the information acquired for OCT, the goal is to develop noninvasive methods to assess regional flow patterns and improve MIGS. Vis-OCT is capable of generating three-dimensional volumetric information consisting of both anatomical and functional data. Additionally, the shorter wavelengths of light used by vis-OCT increase its axial resolution and provides increased sensitivity to slower blood flow and motion. Since increased resistance in any portion of the outflow pathway influences outflow, the high resolution of vis-OCT will be used to generate quantitative anatomical and functional measurements for all parts of the outflow pathway (trabecular meshwork, Schlemm’s canal, and distal vasculature). Thus, it is hypothesized that anatomical and functional information generated from imaging the outflow pathway in rodents can serve as biomarkers for understanding the flow patterns within the outflow pattern. To investigate this hypothesis, the PI proposes two aims: Aim 1 utilizes vis-OCT for anatomical imaging, measuring Schlemm canal volume and distal vasculature structure to make predictions to discover structural- function correlates related to regional outflow. Aim 2 focuses on the development of functional metrics, including the response of the pathway to pharmacological interventions and motion of the trabecular meshwork in response to intraocular pressure changes, to predict regional outflow. The training environment is well suited for this investigation, with the mentors' labs being experts in designing OCT systems and the co-mentors lab being experts in imaging aqueous outflow. This research leverages a diverse group of mentors with expertise in biophotonics, physiology, biomedical engineering, and clinical medicine. In addition to training the PI to become an independent researcher, the training plan shall also prepare the PI to become one of the physicians most knowledgeable in imaging and translating innovative technologies into clinical settings.

项目摘要：青光眼是目前全球唯一导致不可逆转失明的主要原因。青光眼的有效治疗方法是降低眼压 (IOP)。房水大部分从眼前房流出，大部分通过常规房水流出尽管传统的流出途径很重要，但仍存在一些基本问题，例如远端通路对流出阻力的相对贡献以及流出区域的诱发因素高流量和低流量的途径仍然未知。断层扫描主要用于视网膜成像，可以提供解剖和功能信息，以阐明最近使用水性血管造影的证据显示了体内流出途径的生理行为。流出路径中的流动模式可用于提高微创治疗的有效性青光眼手术 (MIGS) 是一名医学博士/博士生，他建议使用超高（~1.3 微米）。组织）可见光光学相干断层扫描（vis-OCT）的轴向分辨率，以无创地评估利用 OCT 获得的信息了解体内常规流出途径的生理学。开发非侵入性方法来评估区域血流模式并提高 MIGS 的能力。生成由解剖数据和功能数据组成的三维体积信息。此外，vis-OCT 使用的光波长较短，可提高其轴向分辨率并提供由于流出的任何部分的阻力增加，因此对较慢的血流和运动的敏感性增加。通路影响流出，vis-OCT 的高分辨率将用于生成定量的解剖学和流出通路所有部分（小梁网、施累姆氏管和远端）的功能测量因此，通过成像生成的解剖和功能信息被捕获。啮齿动物的流出路径可以作为了解流出物内流动模式的生物标志物为了研究这一假设，PI 提出了两个目标：目标 1 利用 vis-OCT 进行解剖成像，测量施累姆管体积和远端脉管系统结构以进行预测以发现结构- 与区域流出相关的功能目标 2 侧重于功能指标的制定，包括通路对药物干预的反应和小梁网的运动响应眼压变化，预测区域流出，非常适合训练环境。本次调查中，导师实验室是设计 OCT 系统的专家，共同导师实验室是这项研究利用了具有专业知识的多元化导师团队。生物光子学、生理学、生物医学工程和临床医学。作为一名独立研究员，培训计划还应让 PI 成为最有能力的医生之一。精通成像并将创新技术转化为临床环境。