Department of Biomedical Engineering, McGill University, Montreal, Quebec, Canada.
Department of Anesthesia, Division of Pediatric Anesthesia, McGill University Health Centre, Montreal, Quebec, Canada.
PLoS One. 2020 Sep 11;15(9):e0238402. doi: 10.1371/journal.pone.0238402. eCollection 2020.
Infants are at risk for potentially life-threatening postoperative apnea (POA). We developed an Automated Unsupervised Respiratory Event Analysis (AUREA) to classify breathing patterns obtained with dual belt respiratory inductance plethysmography and a reference using Expectation Maximization (EM). This work describes AUREA and evaluates its performance. AUREA computes six metrics and inputs them into a series of four binary k-means classifiers. Breathing patterns were characterized by normalized variance, nonperiodic power, instantaneous frequency and phase. Signals were classified sample by sample into one of 5 patterns: pause (PAU), movement (MVT), synchronous (SYB) and asynchronous (ASB) breathing, and unknown (UNK). MVT and UNK were combined as UNKNOWN. Twenty-one preprocessed records obtained from infants at risk for POA were analyzed. Performance was evaluated with a confusion matrix, overall accuracy, and pattern specific precision, recall, and F-score. Segments of identical patterns were evaluated for fragmentation and pattern matching with the EM reference. PAU exhibited very low normalized variance. MVT had high normalized nonperiodic power and low frequency. SYB and ASB had a median frequency of respectively, 0.76Hz and 0.71Hz, and a mode for phase of 4o and 100o. Overall accuracy was 0.80. AUREA confused patterns most often with UNKNOWN (25.5%). The pattern specific F-score was highest for SYB (0.88) and lowest for PAU (0.60). PAU had high precision (0.78) and low recall (0.49). Fragmentation was evident in pattern events <2s. In 75% of the EM pattern events >2s, 50% of the samples classified by AUREA had identical patterns. Frequency and phase for SYB and ASB were consistent with published values for synchronous and asynchronous breathing in infants. The low normalized variance in PAU, was consistent with published scoring rules for pediatric apnea. These findings support the use of AUREA to classify breathing patterns and warrant a future evaluation of clinically relevant respiratory events.
婴儿有发生术后潜在危及生命的呼吸暂停(POA)的风险。我们开发了一种自动无监督呼吸事件分析(AUREA),通过双带呼吸感应体积描记法和期望最大化(EM)参考来对呼吸模式进行分类。本研究描述了 AUREA 并评估了其性能。AUREA 计算了六个指标,并将其输入到一系列四个二进制 k-均值分类器中。呼吸模式的特征是归一化方差、非周期性功率、瞬时频率和相位。信号逐个样本分类为 5 种模式之一:暂停(PAU)、运动(MVT)、同步(SYB)和异步(ASB)呼吸,以及未知(UNK)。MVT 和 UNK 组合为UNKNOWN。从有发生 POA 风险的婴儿中获取了 21 个预处理记录进行分析。使用混淆矩阵、整体准确性和特定模式的精度、召回率和 F 分数来评估性能。通过 EM 参考评估了相同模式的片段的碎片化和模式匹配。PAU 表现出非常低的归一化方差。MVT 具有高的归一化非周期性功率和低频率。SYB 和 ASB 的中位数频率分别为 0.76Hz 和 0.71Hz,相位模式分别为 4o 和 100o。整体准确性为 0.80。AUREA 最常将模式与 UNKNOWN 混淆(25.5%)。SYB 的特定模式 F 分数最高(0.88),PAU 最低(0.60)。PAU 的精度高(0.78),召回率低(0.49)。在<2s 的模式事件中存在碎片化。在 75%的 EM 模式事件>2s 中,AUREA 分类的 50%样本具有相同的模式。SYB 和 ASB 的频率和相位与婴儿同步和异步呼吸的已发表值一致。PAU 中归一化方差低,与儿科呼吸暂停的已发表评分规则一致。这些发现支持使用 AUREA 对呼吸模式进行分类,并需要对临床相关呼吸事件进行进一步评估。