Collaborative Research: Development of Preclinical X-ray Phase-Contrast Tomography for 3D Imaging of Engineered Tissues

合作研究：开发用于工程组织 3D 成像的临床前 X 射线相衬断层扫描

• 批准号: 1263994
• 负责人: Abhinav Bhushan
• 金额: $ 27.5万
• 依托单位: Illinois Institute of Technology
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2013
• 资助国家: 美国
• 起止时间: 2013-10-01 至 2018-09-30
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1263994&HistoricalAwards=false
• 关键词: Collaborative; Research; Development; Preclinical; ray

1263988/1263994 Anastasio/BreyThe field X-ray imaging is being revolutionized by the development of techniques based on phase-contrast (PC), which have shown great promise for soft tissue imaging. The principal advantage is that X-ray PC imaging methods are sensitive to alternative physical properties of tissues, and can differentiate tissues that have very similar or even identical X-ray absorption properties. The broadobjective of this research program is to develop and comprehensively evaluate X-ray PC imaging and tomography for use in the evaluation and monitoring of engineered tissues. The specific research objects of the project are to: (1) Investigate non-traditional mechanisms of X-ray contrast produced by model-engineered tissues and determine conditions for optimal imaging of polymer and tissue structuresex vivo and in culture conditions; (2) Optimize grating-based PC imager designs and image reconstruction algorithms for volumetric imaging of engineered tissues; and (3) Evaluate a benchtop PC imager for 3D in vivo evaluation of engineered tissues in small animal models. The intellectual merit of the proposed research arises from the development and refinement of hardware designs and image formation algorithms for a new X-ray imaging modality and their application to the important problem of characterizing and monitoring engineered tissues. Novel X-ray contrast mechanisms that can effectively characterize engineered tissues will be systematically investigated. Model polymer scaffolds and engineered tissues will be used in the evaluation and optimization of these imaging systems in order to ensure broad relevance to many areas of tissue engineering, regenerative medicine and biomaterials. To accomplish this research, a combination of physics and fundamental principles of biomedical engineering and imaging science are employed by our collaborative research team.There are several broad impacts of the project that will yield important benefits to both biomedical science and society. The successful completion of this project will establish X-ray PC imaging as a highly effective tool for characterizing the 3D structure of engineered tissues and will have a transformative impact on the field of tissue engineering. The acceleration of tissue engineering research will have a significant impact on human health by leading to new therapeutic approaches for the treatment of defects resulting from disease, trauma or congenital defects. The integration of this research with the proposed educational activities will help attract students to the increasingly important fields of biomedical engineering, biomedical imaging and tissue engineering and enhance greatly their educationalopportunities.

1263988/1263994 Anastasio/Brey基于相衬（PC）的技术的发展正在彻底改变现场X射线成像，该技术在软组织成像方面表现出巨大的前景。主要优点是X射线PC成像方法对组织的替代物理性质敏感，并且可以区分具有非常相似或甚至相同的X射线吸收性质的组织。本研究计划的主要目的是开发和全面评估X射线PC成像和断层扫描技术，用于工程组织的评估和监测。本项目的具体研究目标是：（1）研究模型工程组织产生X射线对比度的非传统机制，确定离体和培养条件下聚合物和组织结构的最佳成像条件：（2）优化基于光栅的PC成像器设计和图像重建算法，用于工程组织的体积成像;和（3）评估台式PC成像仪，用于小动物模型中工程组织的3D体内评估。所提出的研究的智力价值产生于硬件设计和图像形成算法的开发和改进，用于新的X射线成像模式及其应用于表征和监测工程组织的重要问题。新的X射线对比机制，可以有效地表征工程组织将进行系统的研究。模型聚合物支架和工程组织将用于这些成像系统的评估和优化，以确保与组织工程，再生医学和生物材料的许多领域的广泛相关性。为了完成这项研究，我们的合作研究团队采用了物理学和生物医学工程和成像科学的基本原理相结合的方法。该项目具有多个广泛的影响，将为生物医学科学和社会带来重要利益。该项目的成功完成将使X射线PC成像成为表征工程组织3D结构的高效工具，并将对组织工程领域产生变革性影响。组织工程研究的加速将对人类健康产生重大影响，因为它将为治疗由疾病、创伤或先天性缺陷引起的缺陷带来新的治疗方法。这项研究与拟议的教育活动的整合将有助于吸引学生到生物医学工程，生物医学成像和组织工程等日益重要的领域，并大大提高他们的教育机会。