内窥镜终身系统架构:探究过去诊断未来的技术。

IF 2.3 4区 社会学 Q1 SOCIAL SCIENCES, INTERDISCIPLINARY Systems Pub Date : 2022-10-01 Epub Date: 2022-10-14 DOI:10.3390/systems10050189
Craig M Browning, Robert Cloutier, Thomas C Rich, Silas J Leavesley
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引用次数: 0

摘要

系统工程捕捉客户的愿望和需求,在任何物理开发之前,从整体目标到微小细节构思系统。虽然许多系统项目往往大型而复杂(如云基础设施、长期太空旅行穿梭机、导弹防御系统),但系统工程也可应用于较小而复杂的系统。在这里,我们感兴趣的系统是内窥镜,它是一种标准的生物医学检查设备,用于腹腔镜手术、上下消化道检查和上呼吸道检查。内窥镜检查通常用于识别癌前组织和癌变组织,因此对内窥镜系统的要求是能够在正常组织和肿瘤(早期异常组织生长)区域之间提供高对比度的图像。在本手稿中,我们回顾了内窥镜迄今为止的所有技术进步,并从理论上提出了该系统的下一个版本,以提供更好的检测能力。利用系统结构和系统思维,将内窥镜技术分解成不同类别,以便直观地了解从最初到目前最先进的系统在整个生命周期中的改进情况。这次审查的结果被用来确定子系统和组件的趋势,以估计不同子系统的理论最大性能以及进一步发展的领域。子系统分析表明,未来的内窥镜系统将侧重于更复杂的成像和更高的计算要求,以提供更好的对比度,从而对早期异常组织生长进行更准确的光学诊断。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Endoscopy Lifetime Systems Architecture: Scoping Out the Past to Diagnose the Future Technology.

Systems engineering captures the desires and needs of the customer to conceptualize a system from the overall goal down to the small details prior to any physical development. While many systems projects tend to be large and complicated (i.e., cloud-based infrastructure, long-term space travel shuttles, missile defense systems), systems engineering can also be applied to smaller, complex systems. Here, the system of interest is the endoscope, a standard biomedical screening device used in laparoscopic surgery, screening of upper and lower gastrointestinal tracts, and inspection of the upper airway. Often, endoscopic inspection is used to identify pre-cancerous and cancerous tissues, and hence, a requirement for endoscopic systems is the ability to provide images with high contrast between areas of normal tissue and neoplasia (early-stage abnormal tissue growth). For this manuscript, the endoscope was reviewed for all the technological advancements thus far to theorize what the next version of the system could be in order to provide improved detection capabilities. Endoscopic technology was decomposed into categories, using systems architecture and systems thinking, to visualize the improvements throughout the system's lifetime from the original to current state-of-the-art. Results from this review were used to identify trends in subsystems and components to estimate the theoretical performance maxima for different subsystems as well as areas for further development. The subsystem analysis indicated that future endoscope systems will focus on more complex imaging and higher computational requirements that will provide improved contrast in order to have higher accuracy in optical diagnoses of early, abnormal tissue growth.

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来源期刊
Systems
Systems Decision Sciences-Information Systems and Management
CiteScore
2.80
自引率
15.80%
发文量
204
审稿时长
11 weeks
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