Relation of changes in peak expiratory flow (PEF) and forced expiratory volume in 1 s (FEV1) during bronchoconstriction

IF 1.3 4区医学 Q4 PHYSIOLOGY

Clinical Physiology and Functional Imaging Pub Date : 2024-06-22 DOI:10.1111/cpf.12898

Leon L. Csonka, Antti Tikkakoski, Liisa Vuotari, Jussi Karjalainen, Lauri Lehtimäki

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Abstract

Diagnosis of asthma can be confirmed based on variability in peak expiratory flow (PEF) or changes in forced expiratory volume in 1 s (FEV₁) measured with spirometry. Our aim was to use methacholine challenge as a model of induced airway obstruction to assess how well relative changes in PEF reflect airway obstruction in comparison to relative changes in FEV₁. We retrospectively studied 878 patients who completed a methacholine challenge test. To assess congruency along with differences between relative changes in FEV₁ and PEF during airway obstruction, a regression analysis was performed, and a Bland & Altman plot was constructed. ROC analysis, sensitivity, specificity, positive and negative predictive values and κ-coefficient were used to analyze how decrease in PEF predicts decrease of 10% or 15% in FEV₁. The relative change in PEF was on average less than the relative change in FEV₁. In the ROC analysis areas under the curve were 0.844 and 0.893 for PEF decrease to predict a 10% and 15% decrease in FEV₁, respectively. The agreement between changes in PEF and FEV₁ varied from fair to moderate. Airway obstruction detected by change in PEF was false in about 40% of cases when compared to change in FEV₁. Change in PEF is not a very accurate measure of airway obstruction when compared to change in FEV₁. Replacing peak flow metre with a handheld spirometer might improve diagnostic accuracy of home monitoring in asthma.

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支气管收缩时呼气流量峰值（PEF）和 1 秒用力呼气容积（FEV1）变化的关系。

哮喘的诊断可根据呼气流量峰值（PEF）的变化或肺活量测定法测得的 1 秒内用力呼气容积（FEV1）的变化来确定。我们的目的是将甲氨胆碱挑战作为诱发气道阻塞的模型，以评估 PEF 的相对变化与 FEV1 的相对变化相比，能在多大程度上反映气道阻塞。我们对 878 名完成了甲喹啉挑战测试的患者进行了回顾性研究。为了评估气道阻塞期间 FEV1 和 PEF 相对变化的一致性和差异，我们进行了回归分析，并绘制了布兰德和阿尔特曼图。利用 ROC 分析、灵敏度、特异性、阳性和阴性预测值以及 κ 系数来分析 PEF 下降如何预测 FEV1 下降 10%或 15%。PEF 的相对变化平均小于 FEV1 的相对变化。在 ROC 分析中，预测 FEV1 下降 10% 和 15% 的 PEF 下降曲线下面积分别为 0.844 和 0.893。PEF 和 FEV1 变化之间的一致性从一般到中等不等。与 FEV1 的变化相比，通过 PEF 的变化检测到的气道阻塞约有 40% 是错误的。与 FEV1 的变化相比，PEF 的变化并不能非常准确地测量气道阻塞。用手持式肺活量计取代峰值流量计可能会提高哮喘家庭监测的诊断准确性。

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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来源期刊

Clinical Physiology and Functional Imaging 医学-生理学

CiteScore

3.40

自引率

5.60%

发文量

审稿时长

6-12 weeks

期刊介绍： Clinical Physiology and Functional Imaging publishes reports on clinical and experimental research pertinent to human physiology in health and disease. The scope of the Journal is very broad, covering all aspects of the regulatory system in the cardiovascular, renal and pulmonary systems with special emphasis on methodological aspects. The focus for the journal is, however, work that has potential clinical relevance. The Journal also features review articles on recent front-line research within these fields of interest. Covered by the major abstracting services including Current Contents and Science Citation Index, Clinical Physiology and Functional Imaging plays an important role in providing effective and productive communication among clinical physiologists world-wide.