Advanced Assessment of Hepatic Inflammation and Fibrosis with MR Elastography

利用 MR 弹性成像对肝脏炎症和纤维化进行高级评估

• 批准号: 8645160
• 负责人: Meng Yin
• 金额: $ 35.22万
• 依托单位: MAYO CLINIC ROCHESTER
• 依托单位国家: 美国
• 财政年份: 2014
• 资助国家: 美国
• 起止时间: 2014-05-01 至 2018-04-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8645160
• 关键词: 3-Dimensional; Accounting; Acute; Adopted; Animals; Behavior; Biological; Biopsy; Cells; Clinical; Data; Databases; Dependency; Development; Diagnosis; Diffuse; Disease; Disease Progression; Elasticity; Elements; Equation; Evaluation; Fibrosis; Freezing; Frequencies; Goals; Hepatic; Hepatology; Histologic; Histology; Imaging technology; Inflammation; Intercellular Fluid; Isotropy; Liquid substance; Liver; Liver Fibrosis; Liver diseases; Measures; Mechanics; Methods; Modeling; Monitor; Mus; Natural History; Pathologic; Patients; Phase; Predictive Value; Process; Property; Solid; Soy Bean Curd; Techniques; Testing; Time; Tissues; Translating; Viscosity; chronic liver disease; clinical Diagnosis; clinically relevant; disease diagnosis; early onset; elastography; experience; human study; human subject; in vivo; in vivo Model; mouse model; non-alcoholic fatty liver; nonalcoholic steatohepatitis; pressure; public health relevance; response; soft tissue; success; theories; tool; viscoelasticity

DESCRIPTION (provided by applicant): Mechanical properties are promising surrogates for monitoring and characterizing various pathophysiologic conditions of cells and tissues. For example, we have pioneered the development of liver MR elastography (MRE), a noninvasive imaging technology for measuring liver stiffness, which is beginning to see widespread clinical use for assessing hepatic fibrosis as an alternative to biopsy. Despite this progress, there is a need to further develop hepatic MRE so that it can have the precision necessary to track disease progression and response to therapy. Several intrinsic pathologic conditions of the liver (e.g., inflammation) compromise the positive predictive value of liver stiffness for characterizing hepatic fibrosis alone. These factors cause similar amounts of stiffness augmentation but have different pathophysiological origins and correspond to different architectural changes. Therefore, the major goal of this proposal is to develop advanced hepatic MRE techniques, including poroviscoelastic (PVE) mechanical models, capable of differentiating inflammation and fibrosis while considering the effects of steatosis in the liver tissue. Our basic assumption is that liver tissue can reasonably be modeled using biphasic PVE theory consisting of an intrinsically isotropic incompressible viscoelastic solid matrix phase and an incompressible saturated fluid phase. The hypothesis is that analysis of time-harmonic hepatic MRE data based on such a PVE model will enable the separation of the steatosis- and fibrosis-related solid matrix mechanical responses from that of the inflammation-related pore fluid behavior. In Aim 1, we will implement a PVE analysis method to determine PVE parameters and evaluate the key assumptions of the model in phantom studies. In Aim 2, we will use an acute hepatic inflammation mouse model to evaluate the potential for a PVE model to differentiate and quantify inflammation extent by testing whether noninvasively calculated PVE pore pressure significantly correlates with invasively measured interstitial fluid pressure (IFP), indicating tha it could be used as a surrogate for histology-proven inflammation extent. In Aim 3, we will further evaluate the potential for PVE hepatic MRE to differentiate and quantify coexisting inflammation and fibrosis in mouse models with chronic liver disease (NAFLD/NASH mouse model). We hypothesize that significant correlations can be found among MRE-assessed PVE parameters (elasticity, viscosity & pore pressure) and hepatic histology (fibrosis, steatosis & inflammation). In Aim 4, we will perform a translational human study using existing patient data to determine if there is at least one or a combination of several PVE parameters that can distinguish and quantify progressive steatosis, early onset and ongoing inflammation and subsequently developed hepatic fibrosis in the liver. The success of this proposed study will maximize the clinically relevant information provided by hepatic MRE to substantially advance our understanding and ability to diagnose disease progress in the broad pathophysiologic spectrum of chronic liver diseases.

描述(申请人提供)：机械性能是监测和表征细胞和组织的各种病理生理条件的有前途的替代物。例如，我们率先开发了肝脏磁共振弹性成像(MRE)，这是一种测量肝脏硬度的非侵入性成像技术，开始广泛用于评估肝纤维化作为活检的替代方案。尽管取得了这些进展，但仍有必要进一步发展肝脏MRE，以便它能够具有跟踪疾病进展和治疗反应所需的精确度。肝脏固有的几种病理状态(如炎症)影响了肝脏僵硬的阳性预测值 单单是肝纤维化。这些因素导致的僵硬增加的量相似，但具有不同的病理生理起源，并对应于不同的结构变化。因此，这项建议的主要目标是发展先进的肝脏MRE技术，包括多孔粘弹性(PVE)力学模型，能够区分炎症和纤维化，同时考虑肝组织脂肪变性的影响。我们的基本假设是，肝组织可以用由本征各向同性不可压缩粘弹性固体基质相和不可压缩饱和流体相组成的两相PVE理论来合理地建模。假设基于这样的PVE模型对时间调和的肝脏MRE数据的分析将使脂肪变性和纤维化相关的固体基质机械反应与炎症相关的孔道流体行为分离。在目标1中，我们将实施PVE分析方法来确定PVE参数，并在模型研究中评估模型的关键假设。在目标2中，我们将使用急性肝炎小鼠模型来评估PVE模型区分和量化炎症程度的可能性，方法是测试无创性计算的PVE孔压与侵入性测量的间质流体压力(IFP)是否显著相关，表明它可以作为组织学证实的炎症程度的替代。在目标3中，我们将进一步评估PVE肝脏MRE在区分和量化慢性肝病小鼠模型(NAFLD/NASH小鼠模型)共存的炎症和纤维化方面的潜力。我们假设MRE评估的PVE参数(弹性、粘度和孔压)与肝组织学(纤维化、脂肪变性和炎症)之间存在显著的相关性。 在目标4中，我们将使用现有的患者数据进行一项翻译的人体研究，以确定是否至少有一个或几个PVE参数的组合可以区分和量化进行性脂肪变性、早期发病和持续的炎症以及随后发生的肝脏纤维化。这项拟议研究的成功将最大限度地增加肝脏MRE提供的临床相关信息，大大提高我们对慢性肝病广泛的病理生理谱中的疾病进展的理解和诊断能力。