用于分析脑脊液(CSF)分流阀的高分辨率放射学方法试点研究

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Martin P. Pichotka, Moritz Weigt, Mukesch J. Shah, Maximilian F. Russe, Thomas Stein, T. Billoud, Jürgen Beck, Jakob Straehle, Christopher L. Schlett, Dominik v. Elverfeldt, Marco Reisert
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引用次数: 0

摘要

目的尽管脑脊液(CSF)分流器具有挽救生命的功能,但其故障率很高,其中很大一部分故障归咎于调节阀。本试验研究旨在展示全面分析脑脊液分流瓣膜的放射学方法,既考虑到在优化设计中进行故障分析的潜力,也考虑到未来在临床活体应用中减少所需分流改造手术的数量。所提出的方法还可用于开发和支持故障 CSF 分流瓣膜的原位修复方法(如通过裂解或超声波)。此外,我们还研究了基于 CT 的方法,这些方法能够为此类诊断工具的训练提供准确的地面实况。使用模拟测试和训练数据,评估了机器学习诊断在识别和定位分流瓣内阻塞方面的性能,包括每像素灵敏度和特异性、Dice 相似系数以及无阻塞测试样本的假阳性率。作为补充,光子计数微型计算机断层扫描可以详细研究瓣膜阻塞机制,并为基于机器学习的诊断生成有效的基本事实。基于机器学习的瓣膜阻塞检测在模拟射线照片中显示出良好的结果,每像素灵敏度为 70%,每像素特异度为 90%,中位 Dice 系数为 0.8,在检测阈值为 0.5 时,假阳性率为 10%。结果表明,高分辨率对比度增强减影射线摄影(可能包括时间序列数据)与机器学习图像分析相结合,有可能极大地改善脑脊液分流瓣膜故障的诊断。考虑到测量的几何形状和放射剂量,所介绍的方法原则上适用于体内应用。需要开展进一步的研究,以便在真实世界的数据上验证这些结果,并完善所采用的方法。结合这些方法,可以对瓣膜故障机制进行全面分析,为改进脑脊液分流瓣膜的产品开发和临床诊断铺平道路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Pilot study on high-resolution radiological methods for the analysis of cerebrospinal fluid (CSF) shunt valves

Objectives

Despite their life-saving capabilities, cerebrospinal fluid (CSF) shunts exhibit high failure rates, with a large fraction of failures attributed to the regulating valve. Due to a lack of methods for the detailed analysis of valve malfunctions, failure mechanisms are not well understood, and valves often have to be surgically explanted on the mere suspicion of malfunction.

The presented pilot study aims to demonstrate radiological methods for comprehensive analysis of CSF shunt valves, considering both the potential for failure analysis in design optimization, and for future clinical in-vivo application to reduce the number of required shunt revision surgeries. The proposed method could also be utilized to develop and support in situ repair methods (e.g. by lysis or ultrasound) of malfunctioning CSF shunt valves.

Materials and methods

The primary methods described are contrast-enhanced radiographic time series of CSF shunt valves, taken in a favorable projection geometry at low radiation dose, and the machine-learning-based diagnosis of CSF shunt valve obstructions. Complimentarily, we investigate CT-based methods capable of providing accurate ground truth for the training of such diagnostic tools. Using simulated test and training data, the performance of the machine-learning diagnostics in identifying and localizing obstructions within a shunt valve is evaluated regarding per-pixel sensitivity and specificity, the Dice similarity coefficient, and the false positive rate in the case of obstruction free test samples.

Results

Contrast enhanced subtraction radiography allows high-resolution, time-resolved, low-dose analysis of fluid transport in CSF shunt valves. Complementarily, photon-counting micro-CT allows to investigate valve obstruction mechanisms in detail, and to generate valid ground truth for machine learning-based diagnostics.

Machine-learning-based detection of valve obstructions in simulated radiographies shows promising results, with a per-pixel sensitivity >70%, per-pixel specificity >90%, a median Dice coefficient >0.8 and <10% false positives at a detection threshold of 0.5.

Conclusions

This ex-vivo study demonstrates obstruction detection in cerebro-spinal fluid shunt valves, combining radiological methods with machine learning under conditions compatible to future in-vivo application.

Results indicate that high-resolution contrast-enhanced subtraction radiography, possibly including time-series data, combined with machine-learning image analysis, has the potential to strongly improve the diagnostics of CSF shunt valve failures. The presented method is in principle suitable for in-vivo application, considering both measurement geometry and radiological dose. Further research is needed to validate these results on real-world data and to refine the employed methods.

In combination, the presented methods enable comprehensive analysis of valve failure mechanisms, paving the way for improved product development and clinical diagnostics of CSF shunt valves.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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