Mapping Shear Properties of Articular Cartilage Using Fast Confocal Microscopy
使用快速共焦显微镜绘制关节软骨的剪切特性
基本信息
- 批准号:7242668
- 负责人:
- 金额:$ 19.72万
- 依托单位:
- 依托单位国家:美国
- 项目类别:
- 财政年份:2007
- 资助国家:美国
- 起止时间:2007-04-01 至 2009-03-31
- 项目状态:已结题
- 来源:
- 关键词:AddressAffectArthritisArtsBase CompositionBehaviorBenchmarkingCartilageChargeCollagenComplexConfocal MicroscopyDataDegenerative polyarthritisDependenceDependencyDepthDevelopmentDiagnosisDiseaseEndopeptidasesEquilibriumExtracellular MatrixFrequenciesHeterogeneityImageImage AnalysisImplantIn SituInterstitial CollagenaseInvestigationJointsKnowledgeLeadMagnetic Resonance ImagingMapsMeasurementMechanicsMethodsMicroscopeMicroscopicMicroscopyMonitorNatural regenerationNormal tissue morphologyPeptide HydrolasesPrincipal InvestigatorPropertyProteoglycanRateResearch PersonnelRheumatoid ArthritisStressStructureTechniquesTechnologyTestingThree-Dimensional ImagingTissuesTrypsinUltrasonographyVariantVideo MicroscopyWorkarticular cartilagebasedesignfunctional mimicsknowledge basemacromoleculeprogramsrepairedresearch studyresponseshear stresstissue regenerationtool
项目摘要
DESCRIPTION (provided by applicant): The highly organized structure of the articular cartilage extracellular matrix gives rise to the complex mechanical behavior of the tissue. The destruction of this organized structure in diseases such as osteoarthritis compromises the function of the tissue, leading to loss of mobility in the joint. Efforts to replace cartilage lost to arthritis are limited by the ability to reconstruct the functional heterogeneity of healthy articular cartilage in tissue implants. A critical first step to the development of materials that mimic this functional heterogeneity is the characterization of how the micron scale tissue structure affects the macroscopic mechanical response. Recently, considerable advances have been made towards characterizing spatial variations in the equilibrium mechanical response of articular cartilage under compression. This proposal builds on this work and shows how to extend such measurements to address the heterogeneous dynamic response of articular cartilage tissue under shear. Moreover, recent technological advances in the manufacture of confocal microscopes are allowing for rapid in situ imaging of the three dimensional material structure. By combining this imaging capability with force measurement and image analysis tools it is now possible to make three dimensional correlation maps between the local tissue mechanical and structural responses and the applied macroscopic shear stress. The experiments proposed will take full advantage of these capabilities to investigate the effects of the applied strain rate, strain amplitude, and tissue compression on the material response at the macroscopic and microscopic levels. The detailed characterization of the cartilage shear properties obtained from these experiments will lead to a more thorough understanding of function in normal tissue, enable more effective diagnosis and monitoring of disease, and provide benchmarks and design input for efforts to replace or regenerate tissue. As such, these investigations are critical both for advancing the state of the art methods and technologies available to researchers and providing valuable information on the properties of this ubiquitous and important tissue.
描述(由申请人提供):关节软骨细胞外基质的高度组织化结构引起组织的复杂机械行为。在诸如骨关节炎的疾病中,这种组织结构的破坏损害了组织的功能,导致关节活动性的丧失。在组织植入物中重建健康关节软骨的功能异质性的能力限制了替换关节炎损失的软骨的努力。开发模拟这种功能异质性的材料的关键第一步是表征微米级组织结构如何影响宏观机械响应。最近,已经取得了相当大的进展,对压缩下的关节软骨的平衡力学响应的空间变化的特征。该建议建立在这项工作的基础上,并显示了如何扩展这些测量,以解决剪切下的关节软骨组织的异质动态响应。此外,最近在共焦显微镜制造中的技术进步允许三维材料结构的快速原位成像。通过将这种成像能力与力测量和图像分析工具相结合,现在可以在局部组织机械和结构响应与所施加的宏观剪切应力之间制作三维相关图。提出的实验将充分利用这些能力,调查所施加的应变率,应变振幅,和组织压缩的材料响应在宏观和微观水平上的影响。从这些实验中获得的软骨剪切特性的详细表征将导致对正常组织中的功能的更透彻的理解,能够更有效地诊断和监测疾病,并为替换或再生组织的努力提供基准和设计输入。因此,这些研究对于推进研究人员可用的最先进的方法和技术以及提供关于这种无处不在的重要组织的特性的有价值的信息都至关重要。
项目成果
期刊论文数量(0)
专著数量(0)
科研奖励数量(0)
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Itai Cohen其他文献
Itai Cohen的其他文献
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Mapping local strains in cartilage during injurious impact loading
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Mapping Shear Properties of Articular Cartilage Using Fast Confocal Microscopy
使用快速共焦显微镜绘制关节软骨的剪切特性
- 批准号:
7390685 - 财政年份:2007
- 资助金额:
$ 19.72万 - 项目类别:
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