Tensor Scale-based Methods for Assessment of Trabecular Bone Quality

基于张量尺度的骨小梁质量评估方法

• 批准号: 7659272
• 负责人: PUNAM K. SAHA
• 金额: $ 39万
• 依托单位: UNIVERSITY OF IOWA
• 依托单位国家: 美国
• 财政年份: 2009
• 资助国家: 美国
• 起止时间: 2009-06-18 至 2013-05-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7659272
• 关键词: Address; Algorithms; Anisotropy; Architecture; Biomechanics; Bone Density; Bone Diseases; Bone remodeling; Classification; Clinical; Clinical Research; Competence; Complex; Computing Methodologies; Data; Deterioration; Diagnosis; Disease; Disease Progression; Disease regression; Distal; Early Diagnosis; Equilibrium; Experimental Designs; Femur; Fracture; Funding; Goals; Histologic; Human; Image; Image Analysis; Imaging Techniques; Individual; Joints; Laboratories; Laws; Magnetic Resonance Imaging; Measures; Mechanics; Meta-Analysis; Methods; Modeling; Monitor; Noise; Osteogenesis; Osteoporosis; Patients; Performance; Peripheral; Property; Public Health; Radial; Relative (related person); Reproducibility; Research; Research Personnel; Resolution; Risk; Role; Scanning; Shapes; Signal Transduction; Simulate; Site; Skeleton; Specimen; Staging; Stress; Structure; Technology; Testing; Therapeutic Effect; Thick; Three-Dimensional Image; United States National Institutes of Health; Variant; Woman; X-Ray Computed Tomography; base; bone; bone imaging; bone loss; bone mass; bone quality; bone strength; conventional therapy; design; detector; experience; human subject; improved; in vivo; indexing; long bone; men; osteoporosis with pathological fracture; public health relevance; research study; response; retinal rods; spine bone structure; substantia spongiosa

DESCRIPTION (provided by applicant): Trabecular bone (TB) is a complex quasi-random network of interconnected struts and plates. TB constantly remodels to adapt dynamically to the stresses to which it is subjected (Wolff's Law). In osteoporosis, this dynamic equilibrium between bone formation and resorption is perturbed, leading to bone loss and structural deterioration, both increasing fracture risk. Most osteoporotic fractures occur at sites rich in TB (vertebrae, radius, proximal femur). Bone's mechanical competence can only be partly explained by variations in bone mineral density (BMD), which led to the notion of bone quality, chief among which is architecture as a determinant of TB strength. Recent advances in CT and MRI now allow imaging of TB in vivo. However, the limited SNR precludes voxel sizes much smaller than TB thickness, therefore resulting in images that are inherently fuzzy. Therefore, most conventional histomorphometric approaches to TB structure assessment are not applicable to in vivo resolution regime. This proposal introduces a new morphometric index called tensor scale (t-scale) to measure quality of TB micro architecture via in vivo imaging and designs experimental plans to evaluate reproducibility and sensitivity of t-scale-based TB architectural measures. Also, we will examine their strengths to detect TB architectural changes in response to disease or treatment progression. The fundamental principle of t-scale is to fit an ellipsoid to a local structure. The unique property of t-scale is that the ellipsoid's shape, orientation and size simultaneously determine the topology (plates vs. rods), orientation and scale of trabeculae. Our major goals in this project are - (1) to develop the methodology for computing t-scale-based architectural measures from TB images, (2) to evaluate the sensitivity and reproducibility of t-scale-based measures, (3) to examine t-scale measures' ability to predict experimental biomechanical parameters of TB specimens and (4) to examine the sensitivity of t-scale measures to detect the effects of osteoporotic TB loss and antiresorptive treatment via in vivo MRI. The proposed method will (1) obviate the need for binarization, (2) characterize topology, orientation and scale without the need for skeletonization and (3) detect early TB architectural changes in response to treatment or disease progression. The central hypothesis is that the new parameters are more sensitive to detecting remodeling effects and more reproducible than conventional measures. Sensitivity and reproducibility of the new method will be evaluated using synthetic TB networks, micro-CT and ex vivo MR imaging of TB cores from cadaveric distal radii along with experimental biomechanical data, MR images of intact specimens and of human subjects, and finally, patient data from clinical studies previously funded by the NIH. Our objective is to apply t-scale based analysis methods to longitudinal and cross-sectional imaging studies for assessing bone quality. PUBLIC HEALTH RELEVANCE: This project will develop an advanced technology for trabecular bone (TB) quality assessment via in vivo imaging which will enable early detection of TB micro-architectural changes in response to treatment or bone disease including osteoporosis. Osteoporosis is a major public health threat and in the U.S. only, 10 million individuals (eight million are women and two million are men) are estimated to already have the disease and almost 34 million more are estimated to have low bone mass, placing them at increased risk for osteoporosis. The technology proposed in the project will be helpful to diagnose patients at early stage of the disease and routinely monitor their disease status or effects of therapeutic treatments.

描述（由申请方提供）：小梁骨（TB）是一种由相互连接的支柱和接骨板组成的复杂准随机网络。肺结核不断重塑，以动态地适应它所受到的压力（沃尔夫定律）。在骨质疏松症中，骨形成和再吸收之间的这种动态平衡被扰乱，导致骨丢失和结构恶化，两者都增加了骨折的风险。大多数骨质疏松性骨折发生在结核菌丰富的部位（椎骨、桡骨、股骨近端）。骨的机械能力只能部分由骨矿物质密度（BMD）的变化来解释，这导致了骨质量的概念，其中主要是结构作为TB强度的决定因素。CT和MRI的最新进展现在允许体内TB成像。然而，有限的SNR排除了远小于TB厚度的体素尺寸，因此导致图像固有地模糊。因此，大多数传统的TB结构评估的组织形态学方法不适用于体内分辨率方案。该提案引入了一种新的形态测量指标，称为张量尺度（t-scale），通过体内成像来测量TB微结构的质量，并设计了实验计划来评估基于t-scale的TB结构测量的再现性和灵敏度。此外，我们还将检查它们在检测结核病结构变化方面的优势，以应对疾病或治疗进展。t尺度的基本原理是将椭球体拟合到局部结构。t尺度的独特性质是椭圆体的形状、方向和大小同时决定了小梁的拓扑结构（板与杆）、方向和尺度。我们在这个项目中的主要目标是：（1）开发从TB图像计算基于t尺度的建筑测量的方法，（2）评估基于t尺度的测量的灵敏度和再现性，（3）检验t尺度测量预测TB标本的实验生物力学参数的能力;（4）检验t尺度测量的灵敏度，通过体内MRI检测肺结核丢失和抗吸收治疗的效果的量表测量。所提出的方法将（1）消除对二值化的需要，（2）表征拓扑、方向和尺度而不需要二值化，以及（3）检测响应于治疗或疾病进展的早期TB结构变化。中心假设是，新的参数是更敏感的检测重塑效果和更可重复的比传统的措施。新方法的灵敏度和可重复性将使用合成TB网络，来自尸体桡骨远端的TB核心的micro-CT和离体MR成像沿着实验生物力学数据，完整标本和人类受试者的MR图像，最后，来自NIH先前资助的临床研究的患者数据进行评估。我们的目标是应用t-尺度为基础的分析方法，纵向和横截面成像研究评估骨质量。公共卫生相关性：该项目将开发一种先进的技术，通过体内成像进行骨小梁（TB）质量评估，这将能够早期检测TB微结构变化，以应对治疗或骨骼疾病，包括骨质疏松症。骨质疏松症是一个主要的公共健康威胁，仅在美国，估计有1000万人（800万女性和200万男性）已经患有这种疾病，估计还有近3400万人骨质疏松，使他们患骨质疏松症的风险增加。该项目提出的技术将有助于在疾病的早期阶段诊断患者，并定期监测其疾病状态或治疗效果。