IEEE Trans Biomed Eng. 2017 Dec;64(12):2836-2846. doi: 10.1109/TBME.2017.2675941. Epub 2017 Mar 3.
Respiratory inductance plethysmography (RIP) provides an unobtrusive method for measuring breathing characteristics. Accurately adjusted RIP provides reliable measurements of ventilation during rest and exercise if data are acquired via two elastic measuring bands surrounding the rib cage (RC) and abdomen (AB). Disadvantageously, the most accurate reported adjusted model for RIP in literature-least squares regression-requires simultaneous RIP and flowmeter (FM) data acquisition. An adjustment method without simultaneous measurement (reference-free) of RIP and FM would foster usability enormously.
In this paper, we develop generalizable, functional, and reference-free algorithms for RIP adjustment incorporating anthropometric data. Further, performance of only one-degree of freedom (RC or AB) instead of two (RC and AB) is investigated. We evaluate the algorithms with data from 193 healthy subjects who performed an incremental running test using three different datasets: training, reliability, and validation dataset. The regression equation is improved with machine learning techniques such as sequential forward feature selection and 10-fold cross validation.
Using the validation dataset, the best reference-free adjustment model is the combination of both bands with 84.69% breaths within 20% limits of equivalence compared to 43.63% breaths using the best comparable algorithm from literature. Using only one band, we obtain better results using the RC band alone.
Reference-free adjustment for RIP reveals tidal volume differences of up to 0.25 l when comparing to the best possible adjustment currently present which needs the simultaneous measurement of RIP and FM.
This demonstrates that RIP has the potential for usage in wide applications in ambulatory settings.
呼吸感应体积描记法(RIP)提供了一种非侵入性的测量呼吸特征的方法。如果通过环绕胸廓(RC)和腹部(AB)的两个弹性测量带获取数据,则经过精确调整的 RIP 可在休息和运动时提供可靠的通气测量。不利的是,文献中最准确的 RIP 调整模型(最小二乘回归)需要同时获取 RIP 和流量计(FM)数据。如果没有同时测量(无参考)RIP 和 FM,则可以极大地促进可用性。
在本文中,我们开发了可推广的、功能齐全的、无参考的 RIP 调整算法,该算法结合了人体测量学数据。此外,仅研究了一个自由度(RC 或 AB)而不是两个自由度(RC 和 AB)的情况。我们使用来自 193 名健康受试者的增量跑步测试数据评估了算法,这些数据来自三个不同的数据集:训练、可靠性和验证数据集。通过使用机器学习技术(如顺序前向特征选择和 10 折交叉验证),改进了回归方程。
使用验证数据集,最佳无参考调整模型是同时使用两个带的组合,与文献中最佳可比算法相比,84.69%的呼吸在 20%等效限制内,而仅使用一个带时,我们单独使用 RC 带获得了更好的结果。
与目前需要同时测量 RIP 和 FM 的最佳调整相比,RIP 的无参考调整显示潮气量差异最大可达 0.25l。
这表明 RIP 具有在广泛的动态环境应用中使用的潜力。
