Neuroprotective strategies for retinopathy and cognition in diabetes

糖尿病视网膜病变和认知的神经保护策略

• 批准号: 9901366
• 负责人: RACHAEL STEWART ALLEN
• 金额: --
• 依托单位: VETERANS HEALTH ADMINISTRATION
• 依托单位国家: 美国
• 财政年份: 2019
• 资助国家: 美国
• 起止时间: 2019-04-01 至 2024-03-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/9901366
• 关键词: 3,4-Dihydroxyphenylacetic Acid; Acute Lung Injury; Adult; Age; Age-Years; Animal Model; Animals; Appearance; Area; Award; Blindness; Blood Vessels; Blood capillaries; Brain; Caring; Cerebrum; Clinical; Clinical Research; Clinical Trials; Cognition; Cognitive deficits; Complications of Diabetes Mellitus; Corpus striatum structure; Development; Diabetes Mellitus; Diabetic Retinopathy; Disease; Disease Progression; Dopamine; Dopamine Agonists; Dose; Electroretinography; Endocytosis; Environment; Enzyme-Linked Immunosorbent Assay; Exhibits; Extravasation; Fat-Restricted Diet; Foundations; Functional disorder; Future; Goals; Healthcare Systems; High Fat Diet; High Pressure Liquid Chromatography; Histology; Human; Hyperemia; Hyperglycemia; Impaired cognition; Insulin Resistance; Insulin-Dependent Diabetes Mellitus; Irritable Bowel Syndrome; KDR gene; Kidney; Lead; Levodopa; Link; Malignant Neoplasms; Measures; Medical Records; Memory Loss; Mental Depression; Modeling; Motivation; Motor; Neuronal Dysfunction; Neurons; Non-Insulin-Dependent Diabetes Mellitus; Outcome Study; Pathology; Pathway interactions; Patients; Pericytes; Pharmaceutical Preparations; Population; Prevalence; Prevention; Rattus; Recording of previous events; Research; Research Personnel; Retina; Retinal Diseases; Rodent; Rodent Model; Role; Scientist; Signs and Symptoms; Streptozocin; Structure; System; Time; Tissues; Training; Translating; Translations; Treatment Efficacy; Type 2 diabetic; Vascular Diseases; Vascular Endothelial Growth Factors; Veterans; Visual; angiogenesis; brain dysfunction; brain health; brain tissue; career development; clinical application; clinical translation; clinically relevant; clinically translatable; cognitive change; diabetic; diabetic patient; diabetic rat; interest; large datasets; motor deficit; motor disorder; neovascularization; patient population; pre-clinical; prevent; restoration; retinal damage; side effect

Over 25 million U.S. citizens (8.3% of the population) have diabetes, including 20% of veterans in the VA system. With the worldwide prevalence of diabetes predicted to rise 35% by 2025, diabetic complications impose an ever-increasing burden on healthcare systems. One of the most common complications, diabetic retinopathy (DR), is the leading cause of blindness in working age adults. In addition, early neuronal dysfunction in diabetic retinopathy occurs prior to clinically diagnosable pathology, and early DR is likely intimately related to other diabetic complications, for example, cognitive decline and structural changes in the brain. The continued rise in the number of diabetic patients and the complexity of their care underscores the urgent need to identify clinically translatable treatments to target complications prior to obvious signs and symptoms. While diabetes is not commonly thought of as a disease of dopamine disruption, dopamine has been implicated in several diabetic complications, including diabetic retinopathy. Our approach is to identify whether dopamine deficiency is a common mechanism for cerebral and retinal deficits in Type II diabetes and to use this information to develop dopamine treatments for long term clinical translation that would delay disease progression. In this study, we will use the high fat diet + low dose STZ rat model of Type II diabetes because approximately 90% of diabetic patients in the VA system have Type II diabetes. We hypothesize that: 1) dopamine disruption underlies both retinal and cerebral complications in diabetes, and 2) dopamine- targeted treatments will result in reduced retinal, cognitive, and motor dysfunction and reduced vascular pathology in the brain and retina. In the first specific aim, we will identify in Type II diabetic rats the temporal appearance of retinal dysfunction (electroretinogram, optokinetic tracking), cognitive dysfunction (y-maze), motor dysfunction (rotarod), retinal vascular dysfunction (functional hyperemia), and later stage vascular pathology (acellular capillaries and pericyte loss), as well as retinal and brain levels of dopamine and DOPAC (HPLC). After determining the time course of these deficits, in the second specific aim, we will implement L- DOPA treatment to reduce dopamine deficiency in diabetic rats. We will determine whether rats receiving treatment exhibit reduced dopamine deficiency and reduced retinal, cognitive, and motor dysfunction. In our third specific aim, we will use a retrospective chart review in a large dataset to determine whether diabetic patients taking levodopa or dopamine agonists exhibit delayed onset and progression of DR compared with diabetic patients not taking dopamine-related drugs. The expected outcome of this study is that L-DOPA treatment given at the earliest signs of retinopathy in a rodent model of Type II diabetes will provide protection against diabetic damage in the brain and retina and that L-DOPA/dopamine agonists will provide similar protection against DR in patients. Our rodent research can lead to the identification of a similar window for preclinical retinopathy treatment in diabetic patients, which would allow for greater treatment efficacy and prevention of future complications. If treatments that target dopamine protect against retinal and cerebral complications in diabetes, these findings would motivate the development of a human clinical trial. Overall, the motivation for this study is the need for a better understanding of the role of dopamine in diabetic retinopathy and other diabetic complications with the long-term goal of developing dopamine-targeted treatments that delay or prevent vision loss and cerebral deficits in our Veterans and others with diabetes. The Atlanta VA has a large population of diabetic patients and already performs clinical diabetes research, making a long term clinical study on dopamine treatment in diabetes a natural fit for the Center’s goals and interests. This research will also provide valuable training to the applicant, which will enable her to become a successful and productive independent investigator in the field of the diabetic brain and retina within the VA research environment.

超过2500万美国公民(占总人口的8.3%)患有糖尿病，其中包括退伍军人中的20% 系统。到2025年，全球糖尿病患病率预计将上升35%，糖尿病并发症 给医疗系统带来越来越大的负担。糖尿病是最常见的并发症之一 视网膜病变(DR)是导致工作年龄成年人失明的主要原因。此外，早期神经元 糖尿病视网膜病变的功能障碍发生在临床可诊断的病理之前，早期DR是可能的。 与其他糖尿病并发症密切相关，例如，认知能力下降和大脑结构改变 大脑。糖尿病患者数量的持续增加及其护理的复杂性突显了 迫切需要确定临床上可转化的治疗方法，以在出现明显症状和 症状。虽然糖尿病通常不被认为是一种多巴胺紊乱的疾病，但多巴胺 与几种糖尿病并发症有牵连，包括糖尿病视网膜病变。我们的方法是找出 多巴胺缺乏是否是II型糖尿病患者大脑和视网膜缺陷的常见机制 利用这些信息来开发用于长期临床翻译的多巴胺疗法，这将延迟 疾病的发展。在本研究中，我们将使用高脂饮食+小剂量STZ建立II型糖尿病大鼠模型 因为VA系统中大约90%的糖尿病患者患有II型糖尿病。我们假设 这是：1)多巴胺紊乱是糖尿病视网膜和脑部并发症的基础，2)多巴胺- 有针对性的治疗将减少视网膜、认知和运动功能障碍，并减少血管 大脑和视网膜的病理学。在第一个特定目标中，我们将识别II型糖尿病大鼠的颞叶 出现视网膜功能障碍(视网膜电图、视动跟踪)、认知功能障碍(y-迷宫)、 运动功能障碍(Rotarod)、视网膜血管功能障碍(功能性充血)和晚期血管 病理学(无细胞毛细血管和周细胞丢失)以及视网膜和大脑中多巴胺和DOPAC的水平 (高效液相色谱)。在确定了这些赤字的时间进程后，在第二个具体目标中，我们将落实L-- 多巴治疗减少糖尿病大鼠的多巴胺缺乏。我们将确定老鼠是否会收到 治疗减少了多巴胺缺乏，减少了视网膜、认知和运动功能障碍。在我们的 第三个具体目标是，我们将使用大型数据集中的回溯性图表回顾来确定糖尿病患者 与服用左旋多巴或多巴胺激动剂的患者相比，服用左旋多巴或多巴胺激动剂的患者表现出延迟的DR的发病和进展 不服用多巴胺相关药物的糖尿病患者。本研究的预期结果是，L-多巴 在II型糖尿病啮齿动物模型中最早出现视网膜病变迹象的治疗将提供保护 抗糖尿病对大脑和视网膜的损害，L-多巴/多巴胺激动剂将提供类似的 保护患者免受DR的侵害。我们对啮齿动物的研究可以导致识别出类似的窗口 糖尿病患者的临床前视网膜病变治疗，这将允许更好的治疗效果和 预防未来的并发症。如果针对多巴胺的治疗可以预防视网膜和脑部疾病 在糖尿病并发症方面，这些发现将推动人类临床试验的发展。总体而言， 这项研究的动机是需要更好地了解多巴胺在糖尿病视网膜病变中的作用。 和其他糖尿病并发症，长期目标是开发多巴胺靶向治疗， 延缓或预防退伍军人和其他糖尿病患者的视力丧失和脑缺陷。亚特兰大退伍军人事务部 大量的糖尿病患者，已经进行了糖尿病的临床研究，使长期 多巴胺治疗糖尿病的临床研究自然符合该中心的目标和兴趣.这项研究 还将为申请者提供有价值的培训，这将使她成为一名成功和多产的 在退伍军人事务部的研究环境中，从事糖尿病脑和视网膜领域的独立研究员。