IEEE Trans Biomed Eng. 2017 Dec;64(12):2957-2967. doi: 10.1109/TBME.2017.2699972. Epub 2017 May 2.
We use a single-alveolar-compartment model to describe the partial pressure of carbon dioxide in exhaled breath, as recorded in time-based capnography. Respiratory parameters are estimated using this model, and then related to the clinical status of patients with obstructive lung disease.
Given appropriate assumptions, we derive an analytical solution of the model, describing the exhalation segment of the capnogram. This solution is parametrized by alveolar CO concentration, dead-space fraction, and the time constant associated with exhalation. These quantities are estimated from individual capnogram data on a breath-by-breath basis. The model is applied to analyzing datasets from normal (n = 24) and chronic obstructive pulmonary disease (COPD) (n = 22) subjects, as well as from patients undergoing methacholine challenge testing for asthma (n = 22).
A classifier based on linear discriminant analysis in logarithmic coordinates, using estimated dead-space fraction and exhalation time constant as features, and trained on data from five normal and five COPD subjects, yielded an area under the receiver operating characteristic curve (AUC) of 0.99 in classifying the remaining 36 subjects as normal or COPD. Bootstrapping with 50 replicas yielded a 95% confidence interval of AUCs from 0.96 to 1.00. For patients undergoing methacholine challenge testing, qualitatively meaningful trends were observed in the parameter variations over the course of the test.
A simple mechanistic model allows estimation of underlying respiratory parameters from the capnogram, and may be applied to diagnosis and monitoring of chronic and reversible obstructive lung disease.
我们使用单肺泡腔模型来描述时间型呼出气二氧化碳分压,记录在呼出气中。使用该模型估计呼吸参数,并将其与阻塞性肺疾病患者的临床状况相关联。
在适当的假设下,我们推导出模型的解析解,描述呼出气二氧化碳分压的呼气段。该解由肺泡 CO 浓度、死腔分数和与呼气相关的时间常数参数化。这些量是基于个体呼出气二氧化碳分压数据逐口气进行估计的。该模型应用于分析正常(n=24)和慢性阻塞性肺疾病(COPD)(n=22)受试者以及接受乙酰甲胆碱挑战测试的哮喘患者(n=22)的数据集。
基于对数坐标的线性判别分析的分类器,使用估计的死腔分数和呼气时间常数作为特征,并在来自五个正常和五个 COPD 受试者的数据上进行训练,对其余 36 个受试者进行正常或 COPD 的分类,其接收者操作特征曲线下的面积(AUC)为 0.99。50 个副本的自举产生了 AUC 的 95%置信区间为 0.96 至 1.00。对于接受乙酰甲胆碱挑战测试的患者,观察到参数变化在测试过程中呈现出有意义的趋势。
简单的机械模型允许从呼出气二氧化碳分压中估计潜在的呼吸参数,并可应用于慢性和可逆性阻塞性肺疾病的诊断和监测。
