Dynamic Digital Radiography Pulmonary Function Testing

CHEST pulmonary Pub Date : 2024-09-01 DOI:10.1016/j.chpulm.2024.100052

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引用次数: 0

Abstract

Background

Common diagnostic tests for pulmonary disorders include chest radiography and pulmonary function tests (PFTs). Although essential, these tests only offer a static assessment. Chest dynamic digital radiography (DDR) integrates lung and diaphragm motion in one study with limited radiation exposure. DDR is relatively easy to obtain, but barriers to its clinical adoption include time-consuming manual analysis and unclear correlation with PFTs.

Research Question

Can a machine learning pipeline automate DDR analysis? What is the strength of the relationship between PFT measures and automated DDR-based lung area measurements?

Study Design and Methods

PFT and DDR studies were obtained in 55 participants. We developed an analysis pipeline using convolutional neural networks capable of quantifying lung areas in DDR images to generate DDR-based PFTs (dPFTs). PFT and dPFT measures were correlated in patients with normal, obstructive, and restrictive lung physiology.

Results

We observed statistically significant (P < 1 × 10^-6), strong correlations between dPFT areas and PFT volumes, including total lung capacity (r = 0.764), FEV₁ (r = 0.591), vital capacity (r = 0.763), and functional residual capacity (r = 0.756). Automated DDR and lung shape tracking revealed differences between normal, restrictive, and obstructive physiology using diaphragm curvature indices and strain analysis measurements. Linear regressions allowed for derivation of PFT values from dPFT measurements.

Interpretation

Statistically significant correlations found between dPFTs and PFTs suggest that dPFTs can act as a surrogate to PFTs when these are not available or unable to be performed. This study contributes to the potential integration of DDR as a reliable alternative to PFTs.

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动态数字射线肺功能测试：机器学习肺部研究替代方案

背景肺部疾病的常见诊断检查包括胸片和肺功能检查（PFT）。尽管这些检查必不可少，但它们只能提供静态评估。胸部动态数字放射摄影（DDR）将肺和膈肌的运动整合到一项研究中，且辐射量有限。DDR 相对容易获得，但其临床应用的障碍包括人工分析耗时以及与 PFT 的相关性不明确。PFT测量值与基于DDR的自动肺面积测量值之间的关系强度如何？我们利用卷积神经网络开发了一个分析管道，能够量化 DDR 图像中的肺面积，从而生成基于 DDR 的 PFT（dPFT）。结果我们观察到 dPFT 面积和 PFT 容积之间存在显著的统计学相关性（P < 1 × 10-6），包括总肺活量（r = 0.764）、FEV1（r = 0.591）、生命容量（r = 0.763）和功能残余容量（r = 0.756）。自动 DDR 和肺形状跟踪利用膈肌曲率指数和应变分析测量结果显示了正常、限制性和阻塞性生理机能之间的差异。通过线性回归，可以从 dPFT 测量值推导出 PFT 值。释义在 dPFT 和 PFT 之间发现的统计学意义上的显著相关性表明，在没有或无法进行 PFT 时，dPFT 可以作为 PFT 的替代物。这项研究有助于将 DDR 潜在整合为 PFT 的可靠替代方法。

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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CHEST pulmonary

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