Hemodynamics, Uremia & Vascular Biology: Interactive Pathways for AVF Maturation

血流动力学、尿毒症

基本信息

批准号：
8635063
负责人：
PRABIR ROY-CHAUDHURY
金额：
--
依托单位：
CINCINNATI VA MEDICAL CENTER RESEARCH
依托单位国家：
美国
项目类别：
财政年份：
2013
资助国家：
美国
起止时间：
2013-10-01 至 2017-09-30
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/8635063
关键词：
Address Angioplasty Animal Model Animals Arteriovenous fistula Atherosclerosis Balloon Dilatation Bioinformatics Biological Biology Blood Vessels Blood flow Caliber Chronic Kidney Failure Clinical Comorbidity Complex Control Animal Control Groups Development Dialysis procedure Dilatation - action End stage renal failure Epidemic Event Exposure to Failure Family suidae Functional disorder Future Gene Expression Genes Genomics Grant Head Hemodialysis Histology Hyperplasia Inflammation Inflammatory Injury Intervention Kidney Failure Knowledge Light Link Magnetic Resonance Imaging Measures Modeling Outcome Oxidative Stress Pathway interactions Patients Phenotype RNA RNA Sequences Reverse Transcriptase Polymerase Chain Reaction Risk Factors Sampling Steno Stenosis Stress System Technology Thick Time Tissue Sample United States Uremia Vascular Diseases Vascular System Venous Veterans Work clinically relevant cost effective therapy endothelial dysfunction hemodynamics innovation knowledge base next generation sequencing novel prevent public health relevance response response to injury shear stress success

项目摘要

Although arteriovenous fistulae (AVFs) are widely considered to be the best form of dialysis vascular access they currently have very significant problems with maturation failure, which is an inability to achieve adequate venous dilatation and flow to support dialysis. At a radiological level AVF maturation failure is characterized by a perianastomotic venous segment stenosis, while at a histological and pathogenetic level it is due to a combination of neointimal hyperplasia and an absence of outward remodeling. At a mechanistic level, work performed by us during the current grant period has clearly demonstrated that differing hemodynamic profiles result in very different clinical (flow and diameter) and histological end points. We therefore believe that hemodynamic injury is the critical upstream event, which then results in a downstream cascade of events (the vascular biology response to injury). An important unknown, however, remains the potential impact of uremia within this cascade, especially in the context of being able to modulate the downstream biological response to upstream hemodynamic injury. The reason that uremia is likely to be important is that it is characterized by significant increases in oxidative stress, inflammation and endothelial dysfunction, all of which are key players in the downstream biological response to hemodynamic injury. In addition we, and others have been able to demonstrate the presence of neointimal hyperplasia within venous tissue samples taken at the time of dialysis vascular access creation (even before exposure to hemodynamic changes) suggesting that uremia per se (with its linkages to inflammation, oxidative stress and endothelial dysfunction), could be an important independent risk factor for venous stenosis/remodeling. The central hypothesis of the current proposal therefore is that AVF maturation is the end result of interactions between a wide spectrum of two prominent mechanistic pathways (upstream hemodynamic injury and uremia influenced downstream vascular biology). Put another way we want to explore how the presence or absence of uremia modulates the biological response to hemodynamic injury. We plan to address this central hypothesis through three Specific Aims. In Specific Aim 1, we will expand on the hypothesis that differential hemodynamic shear stress profiles (curved versus straight AVFs) initiate a sequence of differential biological (gene expression and cellular phenotyping) profiles, which then result in different morphometric (wall thickness) and clinical (flow and diameter) end points. This Specific Aim will also provide a historically concurrent comparator for the studies in Specific Aim 2. In Specific Aim 2, we will address the hypothesis that uremia per se can influence/modulate the biological response to hemodynamic injury, through a detailed comparison of the biological, morphometric and clinical end points described in Specific Aim 1 in the setting of a uremic pig model as compared to control animals (from Specific Aim 1). Finally in Specific Aim 3, we will combine the power of next generation sequencing technology (RNA Seq. analyses) with our unique animal model of uremia in order to look to the future, with regard to the identification of novel genes, pathways and mechanisms. This information could then be used to identify novel predictive markers for AVF maturation, or alternatively, as a knowledge base for the development of future biologically relevant therapies to prevent or treat AVF maturation failure. In summary, we believe that this proposal is significant because it focuses on an important clinical problem for which there are currently no effective therapies; it is unique in that it addresses head on the complex issue of uremia per se as a modulator of AVF maturation, and finally it is innovative in that it links advanced sequencing technology and bioinformatics to a clinically relevant uremic model.

尽管动静脉瘘 (AVF) 被广泛认为是透析血管通路的最佳形式他们目前存在非常严重的成熟失败问题，即无法达到足够的目标静脉扩张和流量以支持透析。在放射学水平上，AVF 成熟失败的特点是吻合口周围静脉段狭窄，而在组织学和病理学水平上，这是由于新内膜增生和缺乏外向重塑的组合。从机械层面看，工作我们在当前拨款期间进行的研究清楚地表明，不同的血流动力学特征导致非常不同的临床（流量和直径）和组织学终点。因此我们认为血流动力学损伤是关键的上游事件，然后导致下游级联事件（血管对损伤的生物学反应）。然而，一个重要的未知数仍然是尿毒症的潜在影响在这个级联中，特别是在能够调节下游生物反应的背景下上游血流动力学损伤。尿毒症可能很重要的原因是它的特征是氧化应激、炎症和内皮功能障碍显着增加，所有这些都是关键因素参与对血流动力学损伤的下游生物反应。此外，我们和其他人已经能够证明透析时采集的静脉组织样本中存在新内膜增生血管通路的建立（甚至在暴露于血流动力学变化之前）表明尿毒症本身（与它与炎症、氧化应激和内皮功能障碍的联系），可能是一个重要的独立因素静脉狭窄/重塑的危险因素。因此，当前提案的中心假设是 AVF 成熟是相互作用的最终结果广泛的两个主要机制途径（上游血流动力学损伤和尿毒症影响下游血管生物学）。换句话说，我们想探索存在或不存在如何尿毒症调节对血流动力学损伤的生物反应。我们计划解决这个中心假设通过三个具体目标。在具体目标 1 中，我们将扩展以下假设：微分血流动力学剪切应力分布（曲线与直接 AVF 相比）启动一系列差异生物学（基因表达和细胞表型）剖面，从而产生不同的形态（壁厚）和临床（流量和直径）终点。该具体目标还将为具体目标 2 中的研究提供历史上同时进行的比较。在具体目标 2 中，我们将讨论尿毒症本身可以影响/调节生物功能的假设。通过生物学、形态学和临床的详细比较，了解对血流动力学损伤的反应尿毒症猪模型与对照动物相比的具体目标 1 中描述的终点（来自具体目标 1）。最后，在具体目标 3 中，我们将结合下一代测序技术（RNA Seq. 分析）与我们独特的尿毒症动物模型，以便展望未来，在识别方面新的基因、途径和机制。然后，该信息可用于识别新颖的预测 AVF 成熟的标记，或者作为未来生物学发展的知识库预防或治疗 AVF 成熟失败的相关疗法。总之，我们认为该提案意义重大，因为它重点关注了一个重要的临床问题目前尚无有效的治疗方法；它的独特之处在于它解决了复杂的问题尿毒症本身作为 AVF 成熟的调节剂，最后它的创新之处在于它与先进的测序相联系技术和生物信息学应用于临床相关的尿毒症模型。