Physiology of Inflammatory Arthritis in High Resolution

高分辨率炎症性关节炎的生理学

• 批准号: 8025132
• 负责人: XUEDING WANG
• 金额: $ 58.14万
• 依托单位: UNIVERSITY OF MICHIGAN AT ANN ARBOR
• 依托单位国家: 美国
• 财政年份: 2011
• 资助国家: 美国
• 起止时间: 2011-09-06 至 2016-06-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8025132
• 关键词: Acute; Affect; Animals; Antirheumatic Agents; Arthritis; Biochemical; Biological Markers; Blood; Blood Volume; Bone Tissue; Cadaver; Chronic; Clinical; Clinical Management; Collaborations; Contrast Media; Development; Devices; Diagnosis; Digit structure; Disease; Early identification; Elements; Functional disorder; Gadolinium; Genetic; Goals; Gold; Human; Hyperemia; Hypoxia; Image; Imaging technology; Inflammatory; Intervention; Joints; Lasers; Lead; Length; Magnetic Resonance Imaging; Malignant Neoplasms; Maps; Medical; Modality; Modeling; Molecular; Monitor; Onset of illness; Optics; Organ; Patients; Performance; Peripheral; Pharmacologic Substance; Physicians; Physiological; Physiology; Property; Protocols documentation; Rattus; Real-Time Systems; Research; Research Personnel; Resolution; Resources; Rheumatoid Arthritis; Scanning; Sensitivity and Specificity; Signal Transduction; Specimen; Speed; Structure; Swelling; Synovial Membrane; Synovitis; System; Techniques; Technology; Therapeutic; Three-Dimensional Imaging; Time; Tissues; Transducers; Treatment Efficacy; Ultrasonic Transducer; Ultrasonics; Ultrasonography; United States National Institutes of Health; Validation; arthropathies; base; bone; clinical practice; cost; cost effective; design; gadolinium oxide; hemodynamics; imaging modality; improved; in vivo; innovation; instrument; interest; nanoparticle; novel; research study; response; soft tissue; spectroscopic imaging; technology development; tomography; uptake; volunteer

DESCRIPTION (provided by applicant): Development and application of new imaging technologies for the discovery of biomarkers of inflammatory arthritic disease onset, progression, and response to therapy are of broad interest and are common goals of physicians, medical researchers and scientific entities such as the NIH. Presenting high resolution optical information in soft tissues with imaging depth up to several centimeters, innovative spectroscopic photoacoustic tomography (SPAT) offers significant benefits to the diagnosis and treatment of inflammatory arthritis, particularly in combination with more established ultrasound imaging (US). SPAT, in addition to capturing peripheral bone and soft tissue images, has the unique capability to quantify tissue hemodynamic properties including regional blood oxygenation and blood volume, both abnormal in synovial tissue associated with inflammatory arthritis. Therefore, findings from SPAT should lead to creation of new direct and sensitive tissue-specific biomarkers, and may have revolutionary impact on clinical management of arthritis. Based on our past validation in animals and human cadaver joints, this physiological imaging modality will be adapted to human inflammatory arthritis for the first time in the proposed research. Through collaboration with the NIH Ultrasonic Transducer Resource Center, we will develop a specially designed SPAT and US dual-modality system employing the state-of-the-art ultrasonic imaging and transducer development technologies. This system will enable simultaneous SPAT and US imaging of human peripheral joints in real-time. Moreover, it can present physicians with both optical and ultrasonic contrast as well as tissue physiological information. Through the experiments on normal volunteers and rheumatoid arthritis patients, we will examine the performance of SPAT and US in imaging the articular tissue structures of peripheral joints and their ability in visualizing morphological biomarkers of rheumatoid arthritis. More interestingly, we will explore the potential of SPAT in assessing new physiological biomarkers of synovitis including hyperemia and hypoxia. We expect that, with sensitivity and specificity comparable to MRI but without using a contrast agent, this cost-effective imaging may provide unique opportunities for arthritis, including pre-diagnosis, identification of initial natural disease sequelae and progression, along with monitoring of non-pharmaceutical and pharmaceutical based interventions. PUBLIC HEALTH RELEVANCE: The objective of this research is to adapt innovative functional photoacoustic imaging integrated with state-of-the-art ultrasound technologies to human inflammatory arthritis, and to find novel physiological biomarkers of arthritic disease onset, progression, and response to therapy that could be evaluated with the revolutionary dual-modality imaging modality.

描述（由申请人提供）：用于发现炎性关节炎疾病发作、进展和对治疗的反应的生物标志物的新成像技术的开发和应用受到广泛关注，并且是医生、医学研究人员和科学实体（如NIH）的共同目标。创新的光谱光声断层扫描（SPAT）在软组织中呈现高分辨率光学信息，成像深度可达几厘米，为炎症性关节炎的诊断和治疗提供了显著优势，特别是与更成熟的超声成像（US）相结合。SPAT除了捕获外周骨和软组织图像外，还具有量化组织血液动力学特性的独特能力，包括局部血氧和血容量，这两种特性在与炎症性关节炎相关的滑膜组织中均异常。因此，SPAT的发现将导致新的直接和敏感的组织特异性生物标志物的产生，并可能对关节炎的临床治疗产生革命性的影响。基于我们过去在动物和人类尸体关节中的验证，这种生理成像模式将在拟议的研究中首次适用于人类炎症性关节炎。通过与NIH超声传感器资源中心合作，我们将采用最先进的超声成像和传感器开发技术开发专门设计的SPAT和US双模态系统。该系统将能够同时SPAT和US成像的人外周关节的实时。此外，它可以向医生提供光学和超声对比度以及组织生理信息。通过对正常志愿者和类风湿关节炎患者的实验，我们将检查SPAT和US在外周关节关节组织结构成像中的性能以及它们在可视化类风湿关节炎的形态学生物标志物方面的能力。更有趣的是，我们将探索SPAT在评估滑膜炎新的生理生物标志物（包括充血和缺氧）方面的潜力。我们预期，由于灵敏度和特异性与MRI相当，但不使用造影剂，这种具有成本效益的成像可能为关节炎提供独特的机会，包括预诊断，识别最初的自然疾病后遗症和进展，沿着非药物和药物干预的监测。 公共卫生关系：本研究的目的是将创新的功能性光声成像与最先进的超声技术相结合，以适应人类炎症性关节炎，并找到关节炎疾病发作，进展和治疗反应的新生理生物标志物，这些生物标志物可以用革命性的双模态成像模式进行评估。