X-Ray Imaging in the Simulated Microgravity Environment of Parabolic Flight.

IF 0.9 4区 医学 Q4 BIOPHYSICS Aerospace medicine and human performance Pub Date : 2023-10-01 DOI:10.3357/AMHP.6286.2023
David Lerner, Michael Pohlen, Adam Wang, Jeanne Walter, Michael Cairnie, Sheyna Gifford
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Abstract

INTRODUCTION: The advancement of human spaceflight has made urgent the need to develop medical imaging technology to ensure a high level of in-flight care. To date, only ultrasound has been used in spaceflight. Radiography has multiple advantages over ultrasound, including lower operator dependence, more rapid acquisition, typically higher spatial resolution, and characterization of tissue with acoustic impedance precluding ultrasound. This proof-of-concept work demonstrates for the first time the feasibility of performing human radiographs in microgravity.METHODS: Radiographs of a phantom and human subject's hand, knee, chest, cervical spine, and pelvis were obtained aboard a parabolic flight in microgravity and simulated lunar gravity with various subject and operator positions. Control radiographs were acquired with the same system on the ground. These radiographs were performed with a Food and Drug Administration-approved ultra-portable, wireless, battery-powered, digital x-ray system.RESULTS: The radiographs of the phantom acquired in reduced gravity were qualitatively and quantitatively compared to the ground controls and found to exhibit similar diagnostic adequacy. There was no statistically significant difference in contrast resolution or spatial resolution with a spatial resolution across all imaging environments up to the Nyquist frequency of 3.6 line-pairs/mm and an average contrast-to-noise ratio of 2.44.DISCUSSION: As mass, power, and volume limitations lessen over the coming decades and the miniaturization of imaging equipment continues, in-flight implementation of nonsonographic modalities will become practical. Given the demonstrated ease of use and satisfactory image quality, portable radiography is ready to be the new frontier of space medical imaging.Lerner D, Pohlen M, Wang A, Walter J, Cairnie M, Gifford S. X-ray imaging in the simulated microgravity environment of parabolic flight. Aerosp Med Hum Perform. 2023; 94(10):786-791.

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抛物线飞行模拟微重力环境中的X射线成像。
简介:载人航天的发展迫切需要发展医学成像技术,以确保高水平的飞行护理。到目前为止,只有超声波被用于太空飞行。射线照相术比超声具有多个优点,包括较低的操作者依赖性、更快速的采集、通常更高的空间分辨率,以及用声阻抗来表征组织,从而排除超声。这项概念验证工作首次证明了在微重力条件下进行人体射线照相的可行性。方法:在微重力和模拟月球重力的抛物线飞行中,在不同的受试者和操作员位置上,获得人体模型和受试者的手、膝盖、胸部、颈椎和骨盆的射线照片。对照射线照片是用地面上的同一系统采集的。这些射线照片是用美国食品药品监督管理局批准的超便携式、无线、电池供电的数字x射线系统进行的。结果:在失重状态下获得的体模的射线照片与地面对照进行了定性和定量比较,发现显示出类似的诊断充分性。在奈奎斯特频率高达3.6的所有成像环境中,对比度分辨率或空间分辨率与空间分辨率没有统计学上的显著差异 线对/mm和2.44的平均对比噪声比。讨论:随着未来几十年质量、功率和体积限制的减少,成像设备的小型化不断发展,非单色模式的飞行实现将变得可行。鉴于便携式射线照相术的易用性和令人满意的图像质量,它有望成为空间医学成像的新前沿。Lerner D,Pohlen M,Wang A,Walter J,Cairnie M,Gifford S.抛物飞行模拟微重力环境下的X射线成像。Aerosp Med Hum表演。2023年;94(10):786-791。
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来源期刊
Aerospace medicine and human performance
Aerospace medicine and human performance PUBLIC, ENVIRONMENTAL & OCCUPATIONAL HEALTH -MEDICINE, GENERAL & INTERNAL
CiteScore
1.10
自引率
22.20%
发文量
272
期刊介绍: The peer-reviewed monthly journal, Aerospace Medicine and Human Performance (AMHP), formerly Aviation, Space, and Environmental Medicine, provides contact with physicians, life scientists, bioengineers, and medical specialists working in both basic medical research and in its clinical applications. It is the most used and cited journal in its field. It is distributed to more than 80 nations.
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