Development of novel tests to quantify objective spine function

开发新的测试来量化客观脊柱功能

• 批准号: RGPIN-2018-05211
• 负责人: Kawchuk, Gregory
• 金额: $ 2.84万
• 依托单位: University of Alberta
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=713543
• 关键词: Development; novel; tests; quantify; objective

BACKGROUND: If functional tests like electrocardiography were unavailable, the impact on heart patients would be disastrous. Unfortunately, this situation exists in the spine - few objective tests are available to quantify mechanical spine function. As such, my research program will address, then solve, significant engineering challenges to create a suite of novel measures of objective spine function. MY RESEARCH PROGRAM: Objective 1: My prior DG work has shown spine vibration creates a “fingerprint” that reveals tissue status. Unfortunately, this invasive approach limits clinical application. This objective will validate ultra-fast ultrasound as a non-invasive way to quantify 3D vertebral displacements during vibration. A range of vibrations (chirp) will be applied non-invasively in anesthetized pigs. The vertebral displacement response will be measured simultaneously by ultra-fast ultrasound (test signal) and a triaxial accelerometer implanted surgically (criterion signal). The test signal will then be validated against the criterion signal. Objective 2: In prior DG work, we have shown that indentation stiffness is a clinically significant measure of spine function. By understanding how individual spinal tissues contribute indentation stiffness, clinicians can specifically target underlying causes of back pain. This objective will identify how spinal tissues contribute to bulk force-displacement (FD) data obtained via rolling indentation by adapting this technique for concurrent MRI and fluoroscopic imaging. The resulting FD data will be input into a computer model to identify how/when specific tissues contribute to a FD curve. Objective 3: We have recently used cineMRI to visualize intra-articular events associated with joint sounds, yet more sophisticated imaging is needed to ascertain their relation to joint health status. This objective will identify intra-articular parameters (biomarkers) of joint sounds that define functional versus dysfunctional joints. To do this, we will combine new MRI techniques to visualize joint sounds in larger volumes with ultra-fast ultrasound capable of imaging rates of over 1,000 Hz. LONG-TERM OBJECTIVES: The long-term objective of my research program is to develop novel ways to measure objective spine function toward reducing morbidity, disability and cost burdens for Canadians. Knowledge generated here will provide an engineering foundation from which to address the clinical significance of these measures and their underlying mechanisms. ENVIRONMENT, TRAINING AND KNOWLEDGE TRANSFER: This research program is founded on established multidisciplinary collaborations having a productive history of publication, training, and funding. These elements continue to produce sought-after HQPs as evidenced by mentoring recognition, student awards won and successful career placements in science, engineering and health care.

背景：如果没有心电图等功能检查，对心脏病患者的影响将是灾难性的。不幸的是，这种情况存在于脊柱中-很少有客观的测试可以量化脊柱的机械功能。因此，我的研究计划将解决重大的工程挑战，以创建一套客观脊柱功能的新措施。 我的研究目标：目标1：我之前的DG工作表明脊柱振动会产生一个“指纹”，揭示组织状态。不幸的是，这种侵入性方法限制了临床应用。该目标将验证超快超声作为一种非侵入性方式来量化振动过程中的3D椎骨位移。将在麻醉猪中无创地施加一系列振动（啁啾）。将通过超快超声（测试信号）和手术植入的三轴加速度计（标准信号）同时测量椎体位移响应。然后，将根据标准信号验证测试信号。目的2：在先前的DG工作中，我们已经证明压痕刚度是脊柱功能的临床重要指标。通过了解个体脊柱组织如何贡献压痕刚度，临床医生可以专门针对背痛的根本原因。该目标将确定脊柱组织如何通过调整该技术用于同步MRI和荧光镜成像，对通过滚动压痕获得的体积力-位移（FD）数据做出贡献。将得到的FD数据输入计算机模型，以确定特定组织如何/何时对FD曲线有贡献。目标3：我们最近使用cineMRI来可视化与关节音相关的关节内事件，但需要更复杂的成像来确定它们与关节健康状况的关系。该目标将确定关节音的关节内参数（生物标志物），这些参数定义了功能性关节与功能障碍性关节。为此，我们将结合联合收割机新的磁共振成像技术，以更大的体积与超快速超声能够成像速率超过1,000赫兹可视化关节的声音。 长期替代品：我的研究计划的长期目标是开发新的方法来衡量客观脊柱功能，以减少加拿大人的发病率，残疾和成本负担。这里产生的知识将提供一个工程基础，从解决这些措施的临床意义及其潜在的机制。 环境，培训和知识转移：该研究计划建立在已建立的多学科合作基础上，具有丰富的出版，培训和资助历史。这些因素继续产生受欢迎的HQP，如指导认可，学生获奖和科学，工程和医疗保健方面的成功职业安置所证明。