Development of a Miniature Real-Time High-Resolution Endoscopic 3D Ultrasound System

微型实时高分辨率内窥镜3D超声系统的开发

• 批准号: RGPIN-2014-06237
• 负责人: Brown, Jeremy
• 金额: $ 1.82万
• 依托单位: Dalhousie University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2016
• 资助国家: 加拿大
• 起止时间: 2016-01-01 至 2017-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=612109
• 关键词: Development; Miniature; Real; Time; Resolution

The proposed research program is focused on developing high-frequency ultrasound technologies for use in high-resolution imaging applications. High-frequency ultrasound is a relatively new technology that uses micro-fabricated imaging probes that are capable of an order of magnitude higher resolution than conventional ultrasound systems currently used in diagnostic imaging. Specifically, the primary objective is to develop miniaturized (<3mm) imaging endoscopes and all of the associated electronic hardware and software that will enable this technology to be used as a tool for visualizing tissues from within the body, as opposed to the current equivalent technology that is limited to external topical applications. Potential applications of such a high resolution endoscope include laparoscopic, auditory, intracardiac, neural imaging, and many more. In conventional pulse-echo ultrasound, the resolution of the imaging system is proportional to the frequency of the ultrasound pulse generated by the transducer, however, higher frequency (higher resolution) comes at the price of lower penetration depth. Conventional low frequency large penetration ultrasound imaging systems are based on piezoelectric transducer arrays. By using a transducer array, which is made of many individually addressed piezoelectric elements, the effective curvature of the aperture can be changed electronically, resulting in a much better image quality. Use of an array also makes it possible to either multiplex a subset of elements across a much larger set of elements (linear array), or to steer the ultrasound beam to different angles from a fixed set of elements (phased array). Because phased arrays have the ability to steer the focused ultrasound beam, they can generate images with a large field-of-view from a much smaller form factor, and this makes them desirable for endoscopic applications as long as the diameter of the probe is not dominated by packaging of the electrical interconnects. This on-going research program has recently solved some of the challenges associated with developing miniature high frequency phased array endoscopes. These challenges include the micro-fabrication of the array elements and interconnecting these to a cabling system in a miniaturized form factor. Although the previously developed endoscope currently represents one of the most advanced ultrasound imaging arrays in the world, there are still a large number of research questions and challenges that need to be addressed before it can be realized as a useful diagnostic technology. The proposed research program will build upon these previous developments by designing, fabricating, and implementing first of a kind electronic hardware and software to allow the imaging endoscope to generate real-time high resolution images. The research program will also develop novel 2D micro-fabricated imaging arrays that will not only produce images of superior quality, but also real-time 3D volumes from an endoscope of identical miniaturized form factor. Currently no other imaging technology exists that combines such high resolution, with the miniature forward looking endoscopic form factor. The potential for this technology to revolutionize diagnostics in several different fields of medicine is very real. Not only could this be of great benefit to the Canadian health care system (and international) in terms of improving diagnostics and surgical guidance, but the technology also represents valuable IP that has many commercialization opportunities on both a local and national scale. This research program is also a very valuable training program for graduate students through a unique combination of high tech micro-fabrication training with conventional biomedical engineering methods.

拟议的研究计划的重点是开发用于高分辨率成像应用的高频超声技术。高频超声是一种相对较新的技术，它使用微制造的成像探头，其分辨率比目前用于诊断成像的传统超声系统高一个数量级。具体而言，主要目标是开发小型化（<3mm）成像内窥镜以及所有相关的电子硬件和软件，使该技术能够用作从体内可视化组织的工具，而不是目前仅限于外部局部应用的等同技术。这种高分辨率内窥镜的潜在应用包括腹腔镜、听觉、心内、神经成像等。在传统的脉冲回波超声中，成像系统的分辨率与换能器产生的超声脉冲的频率成比例，然而，较高的频率（较高的分辨率）是以较低的穿透深度为代价的。 传统的低频大穿透超声成像系统是基于压电换能器阵列的。通过使用由许多单独寻址的压电元件制成的换能器阵列，可以电子地改变孔径的有效曲率，从而产生更好的图像质量。阵列的使用还使得可以跨更大的元件集合（线性阵列）复用元件的子集，或者将超声波束从固定的元件集合（相控阵列）转向到不同的角度。因为相控阵列具有操纵聚焦超声波束的能力，所以它们可以从小得多的形状因子生成具有大视场的图像，并且这使得它们对于内窥镜应用是理想的，只要探针的直径不受电互连件的封装的支配。 这项正在进行的研究计划最近解决了与开发微型高频相控阵内窥镜相关的一些挑战。这些挑战包括阵列元件的微制造以及将这些阵列元件以小型化的形状因子互连到布线系统。虽然先前开发的内窥镜目前代表了世界上最先进的超声成像阵列之一，但在其成为有用的诊断技术之前，仍有大量的研究问题和挑战需要解决。拟议的研究计划将建立在这些以前的发展，通过设计，制造和实施第一种电子硬件和软件，使成像内窥镜生成实时高分辨率图像。该研究计划还将开发新型2D微加工成像阵列，不仅可以产生上级质量的图像，还可以从相同的小型化形状因子的内窥镜中产生实时3D体积。 目前还不存在将如此高的分辨率与微型前视内窥镜形状因子相结合的其他成像技术。这项技术在几个不同的医学领域彻底改变诊断的潜力是非常真实的。这不仅在改善诊断和手术指导方面对加拿大（和国际）医疗保健系统大有裨益，而且该技术也代表着宝贵的知识产权，在地方和国家范围内都有许多商业化机会。这项研究计划也是一个非常有价值的培训计划，研究生通过高科技微制造培训与传统的生物医学工程方法的独特结合。