In Vivo IVUS Image-Based Modeling for Human Coronary Plaque Assessment

用于人体冠状动脉斑块评估的体内 IVUS 基于图像的建模

• 批准号: 8018170
• 负责人: Dalin Tang
• 金额: $ 33.6万
• 依托单位: WORCESTER POLYTECHNIC INSTITUTE
• 依托单位国家: 美国
• 财政年份: 2004
• 资助国家: 美国
• 起止时间: 2004-09-01 至 2013-11-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8018170
• 关键词: Acute; American Heart Association; Angiography; Arterial Fatty Streak; Automation; Benchmarking; Blood flow; Cadaver; Cardiovascular Diseases; Cardiovascular system; Classification; Classification Scheme; Complement; Computer Simulation; Computer software; Coronary; Data; Data Analyses; Diagnosis; Diagnostic Procedure; Event; Future; Goals; Histology; Human; Hydrogels; Image; Image Analysis; Imaging technology; In Vitro; Lead; Lesion; Liquid substance; Magnetic Resonance Imaging; Measurement; Mechanics; Medicare; Methods; Modeling; Monitor; Morphology; Myocardial Infarction; Patients; Physicians; Prevention; Procedures; Property; Public Health; Research; Risk; Risk Factors; Rupture; Sampling; Scheme; Screening procedure; Series; Signal Transduction; Site; Stress; Stretching; Stroke; Structure; Syndrome; Techniques; Testing; Tissues; Ultrasonography; Validation; base; clinical application; commercialization; cost; imaging Segmentation; improved; in vivo; indexing; pressure; public health relevance; shear stress; simulation; success; three-dimensional modeling; tool; validation studies

DESCRIPTION (provided by applicant): The objective of this project is to combine anisotropic computational modeling with in vivo intravascular ultrasound (IVUS), angiography, ex vivo Magnetic Resonance Imaging (MRI), mechanical testing, and pathohistological analysis to analyze vulnerable atherosclerotic coronary plaques and identify critical blood flow and plaque stress/strain indicators for quantitative coronary plaque vulnerability assessment. The long term goals are: a) develop computational mechanical image analysis tools for more accurate plaque assessment and possible quantitative improvement to the current American Heart Association (AHA) plaque classification scheme; b) identify critical flow and stress/strain plaque vulnerability risk indicators which could be monitored for early prediction, diagnosis, treatment, and prevention of related cardiovascular diseases. The hypotheses are: (1) Critical plaque stress/strain conditions correlate closely with plaque vulnerability and may be used as indicators to further differentiate plaques within AHA advanced plaque classifications (types V- VIII) and provide more quantitative methods to assess plaque rupture risk; (2) Combination of in vivo IVUS imaging, pressure and flow measurements and 3D anisotropic multi-component models with fluid-structure interactions (FSI) and cyclic bending will improve the accuracy of mechanical analysis for coronary plaques and lead to more accurate in vivo plaque vulnerability assessment. This project has four specific aims. Aim 1: Develop and integrate in vivo IVUS imaging, flow and pressure measurements techniques, angiography, multi-contrast ex vivo MRI, histological analysis, and biaxial mechanical testing techniques to quantify plaque morphology, tissue components, curvature, intra-coronary flow and pressure conditions at the lesion site, and anisotropic vessel material properties. Aim 2: Develop 3D anisotropic multi-component FSI models for 100 human coronary plaques (50 in vivo IVUS, 50 ex vivo MRI) with cyclic bending and intra-coronary flow and pressure conditions (IVUS only) to obtain 3D flow shear stress and plaque stress/strain data; Aim 3: perform 3D mechanical image analysis for coronary plaques and identify correlations between critical stress/strain conditions (potential risk indicators) and plaque morphology and composition, vessel mechanical properties and blood flow pressure conditions (patient data). Computational models will be validated by both in vivo IVUS and in vitro experimental data. Aim 4: Introduce quantitative in vivo/ex vivo/histological plaque vulnerability assessment schemes and compare with AHA histology-based plaque classifications for possible quantitative improvements on AHA scheme and potential screening practice. Success of this project will lead to more accurate plaque vulnerability assessment and predictions for possible plaque rupture risk so that better decisions for treatment can be made leading to better public health and reduced costs of Medicare. Mechanical image analysis and software additions to enhance MRI/IVUS imaging technology for clinical applications are possible with future large-scale patient study validations. PUBLIC HEALTH RELEVANCE: Many cardiovascular events (such as heart attack and stroke) are caused by atherosclerotic plaque rupture which may happen without any warning signals. Success of this project will lead to more accurate in vivo coronary plaque vulnerability assessment and predictions for possible plaque rupture risk so that better and timely decisions for treatment can be made leading to better public health and reduced costs of Medicare. Commercialization of the research results is possible with the automation of model construction and data analysis procedures.

描述(申请人提供)：本项目的目标是将各向异性计算模型与体内血管内超声(IVUS)、血管造影术、体外磁共振成像(MRI)、机械测试和病理组织学分析相结合，以分析易受动脉粥样硬化影响的冠状动脉斑块，并确定用于定量评估冠状动脉斑块脆弱性的关键血流和斑块应力/应变指标。长期目标是：a)开发计算机机械图像分析工具，以便更准确地评估斑块，并可能对当前的美国心脏协会(AHA)斑块分类方案进行量化改进；b)识别关键血流和应力/应变斑块易损性风险指标，这些指标可被监测，用于相关心血管疾病的早期预测、诊断、治疗和预防。这些假设是：(1)临界斑块应力/应变状况与斑块脆弱性密切相关，可用作AHA高级斑块分类(类型V-VIII型)中进一步区分斑块的指标，并提供更多定量方法来评估斑块破裂风险；(2)体内IVUS成像、压力和血流测量与具有流体-结构相互作用(FSI)和循环弯曲的3D各向异性多组分模型相结合，将提高冠状动脉斑块力学分析的准确性，导致更准确的体内斑块脆弱性评估。这个项目有四个具体目标。目的1：开发和集成体内IVUS成像、流量和压力测量技术、血管造影术、多对比体外MRI、组织学分析和双轴机械测试技术，以量化斑块的形态、组织成分、曲率、病变部位的冠状动脉内血流和压力状况以及各向异性血管材料特性。目的2：建立100个冠状动脉斑块(50个在体IVUS，50个体外MRI)循环弯曲和冠状动脉内血流和压力状态(仅限IVUS)的三维各向异性多组分FSI模型，以获得3D血流剪应力和斑块应力/应变数据；目标3：对冠状动脉斑块进行三维力学图像分析，确定临界应力/应变条件(潜在风险指标)与斑块形态和组成、血管机械特性和血流压力条件(患者数据)之间的关系。计算模型将通过体内IVUS和体外实验数据进行验证。目的：介绍体内/体外/组织学斑块易损性定量评估方案，并与基于AHA组织学的斑块分类进行比较，以期对AHA方案和潜在的筛查实践进行量化改进。该项目的成功将导致更准确的斑块脆弱性评估和对可能的斑块破裂风险的预测，从而做出更好的治疗决定，从而改善公共健康并降低医疗保险的成本。随着未来大规模患者研究的验证，可能会增加机械图像分析和软件，以增强临床应用的MRI/IVUS成像技术。 公共卫生相关性：许多心血管事件(如心脏病发作和中风)是由动脉粥样硬化斑块破裂引起的，可能在没有任何警告信号的情况下发生。该项目的成功将导致更准确的在体冠状动脉斑块脆弱性评估和对可能的斑块破裂风险的预测，以便做出更好和及时的治疗决定，从而改善公共健康并降低医疗保险的成本。随着模型构建和数据分析程序的自动化，研究成果的商业化是可能的。