用于ECG电极的长期稳定性评估方法:以皮革电极为例

新型柔性电极采集心电(ECG)数据十分便利,但证实电极有效性时缺乏长期稳定性的评估数据,因此提出了一种多维度评价新型柔性电极长期稳定性的方法,包括外观形态、电极-皮肤接触阻抗、三种姿态下ECG采集质量三个方面;其中ECG采集质量的评估由改进的信噪比、设计的汉明距离(HD-RPS-2D)和其他四个常用指标进行量化。通过自制的新型猪皮革电极进行验证,结果表明:在144 h的佩戴过程中,猪皮革电极外观变化小,电极-皮肤接触阻抗在20~50 Hz范围内均低于标准电极,并且在所有测试频段内整体波动小;六个指标能够衡量ECG信号质量,采集ECG的指标值在三种姿态下均与标准电极高度相近,特别是坐姿、站姿状态下长期稳定。

基于双阶段特征提取网络的ECG降噪分类算法

临床采集到的标准12导联心电图常含有噪声,影响了心电信号分类结果的准确度,为此提出了一种基于双阶段特征提取网络的心电图(ECG)降噪分类算法。首先,在空间特征提取阶段,由深度耦合软阈值化去噪方法的残差收缩网络从输入的12导联标准心电信号中提取空间特征;其次,在时间特征提取阶段,由长短期记忆网络与注意力机制结合继续从心电信号中提取时间特征;最后,通过全连接网络层融合提取到的空间特征与时间特征,输出9个类别的概率预测分布。在CPSC2018数据集上与其他同类型先进分类算法进行了对比实验,验证所提算法的效果,实验结果表明:提出的分类算法在对9类ECG信号进行分类时平均F1分数达到0.854,在各项指标上表现更优。此外,实验证明所提算法在含噪数据中的表现也优于其他主流网络,充分证明了所提算法对于含噪心电信号的降噪分类性能,该算法也可应用于其他类似含噪声生理信号的分析和处理。

腔内ECG定位技术联合体外测量法在PICC中的应用

目的:探讨腔内心电图(ECG)定位技术联合体外测量法在经外周静脉穿刺的中心静脉导管(PICC)中的应用。方法:选取2021年1月—2023年1月阜宁县人民医院收治的100例行上肢PICC置管的患者作为研究对象。根据抛币法将其随机分为观察组和对照组,各50例。两组均进行PICC,对照组PICC应用体外测量法,观察组PICC应用腔内ECG定位技术联合体外测量法。比较两组一次性置管情况、导管相关并发症、置管满意度。结果:观察组置管准确率为98.00%,高于对照组的86.00%,置管过深率低于对照组,差异有统计学意义(P<0.05)。两组并发症发生率比较,差异无统计学意义(P>0.05)。观察组总满意度为100%,高于对照组的92.00%,差异有统计学意义(P<0.05)。结论:腔内ECG定位技术联合体外测量法可提高一次置管准确率,提高患者满意率。

面向ECG彩虹码的双输入改进VIT识别研究

基于海量ECG数据,辅助医生进行有效数据分析与诊断,提高效率并减少医疗资源消耗,实现ECG智能识别是当前一个重要研究方向。针对ECG智能识别单一图像、单一深度学习算法性能有限性问题,提出了一种面向ECG彩虹码的双输入改进VIT识别方法。首先,提出数学模型预测获取ECG标准周期,并以抽频方法挖掘ECG潜在特征,生成ECG彩虹码;然后,以卷积神经网络构建双输入特征提取模块,提取多种ECG图像局部特征进行融合,实现多维度ECG特征表示与融合,采用VIT编码模块对融合特征进行全局关注,实现基于多特征图像为输入的ECG识别。采用MIT-BIH数据库中的ECG进行实验,所提ECG识别方法获得99.41%的平均准确率,在现场采集的N类ECG中获得100%的准确率。实验结果表明,提出的图像变换方法能够有效可视化ECG特征,提出的识别方法能够有效实现ECG识别,与其他同类型方法相比获得了更优的性能。

基于单通道ECG信号与INFO-ABCLogitBoost模型的睡眠分期

为了减少对传统多导睡眠图(PSG)系统的依赖,基于单通道心电图(ECG)信号,设计了一种简单高效的睡眠分析算法.采用最大重叠离散小波变换(MODWT)对原始信号进行多分辨分析,再进一步提取峰值信息;根据峰值位置的一阶偏差,提取多维度的心率变异性(HRV)特征.为了进一步筛选与不同睡眠阶段具有强关联性的HRV特征,提出基于ReliefF算法与Gini指数的特征提取方法.在此基础上,采用INFO-ABCLogitBoost方法挖掘HRV与不同睡眠阶段之间的关联性,从而实现睡眠阶段的精细分类.在实际公开数据集上的实验结果表明,所提出的模型在睡眠分期任务中,总体精度为83.67%,准确率为82.59%,Kappa系数为77.94%,F1-Score为82.97%.相比于睡眠分期任务中的常规模型,所提方法展现出更加高效便捷的睡眠质量评估性能,有助于实现家庭或移动医疗场景下的睡眠监测.

基于深度学习的ECG信号分类与诊断

心电图(ECG)信号描绘了心脏的电活动,提供了有关心脏状态的重要信息。ECG信号分类可用于临床预测、诊断、评估的成果,对于心脏病的自动诊断非常重要。但是基于机器学习的ECG信号分类研究也存在一些如模型复杂度与临床数据实时传输和及时更新等未能解决的问题。因此,笔者首先对近10年来基于机器学习的ECG信号分类从波形形态分类、疾病诊断分类和纯粹的机器学习分类研究进行了回顾与综述,总结出了目前的研究遇到的困境,最后对未来面临的问题进行展望。深入学习模型在现实应用中仍存在一些挑战,未来的研究将进一步探索在芯片中实现机器学习模型的便携性和成本效益的硬件解决方案。此外,机器学习算法应寻求最佳的计算开销平衡,并重视在现实世界环境中的应用。在未来研究中,ECG应多进行临床试验,以评估机器学习模型在处理实际生物医学信号时的有效性和可行性,同时构造性价比高的深度学习模型,以帮助医学专家进行精确和及时的预测和诊断。

以BP神经网络为工具的短时ECG信号情感分类

针对目前生理信号情感识别领域采用的生理信号种类太多或使用的生信号长度较长的问题,本文使用BP神经网络对单一、短时ECG信号进行情感识别分类,并对识别时间进行了估计。通过诱发被试喜、怒、哀、惧和平静5种基本情感状态,采集到ECG生理信号,处理后利用神经网络建立模型。实验结果表明,本文方法得到的情感分类的平均识别率为89.14%,且生理信号进行特征提取和识别分类的时间总和小于0.15s,有效地降低了对生理信号种类和窗口长度的依赖。

Electroencephalogram findings in 10 patients with post-stroke epilepsy:A retrospective study

BACKGROUND Post-stroke epilepsy is a common and easily overlooked complication of acute cerebrovascular disease.Long-term seizures can seriously affect the prognosis and quality of life of patients.Electroencephalogram(EEG)is the simplest way to diagnose epilepsy,and plays an important role in predicting seizures and guiding medication.AIM To explore the EEG characteristics of patients with post-stroke epilepsy and improve the detection rate of inter-seizure epileptiform discharges.METHODS From January 2017 to June 2020,10 patients with post-stroke epilepsy in our hospital were included.The clinical,imaging,and EEG characteristics were collected.The stroke location,seizure type,and ictal and interictal EEG manifestations of the patients with post-stroke epilepsy were then retrospectively analyzed.RESULTS In all 10 patients,epileptiform waves occurred in the side opposite to the stroke lesion during the interictal stage;these manifested as sharp wave,sharp-wave complex,or spike discharges in the anterior head lead of the side opposite to the lesion.CONCLUSION In EEG,epileptiform waves can occur in the side opposite to the stroke lesion in patients with post-stroke epilepsy.

Stroke Electroencephalogram Data Synthesizing through Progressive Efficient Self-Attention Generative Adversarial Network

Early and timely diagnosis of stroke is critical for effective treatment,and the electroencephalogram(EEG)offers a low-cost,non-invasive solution.However,the shortage of high-quality patient EEG data often hampers the accuracy of diagnostic classification methods based on deep learning.To address this issue,our study designed a deep data amplification model named Progressive Conditional Generative Adversarial Network with Efficient Approximating Self Attention(PCGAN-EASA),which incrementally improves the quality of generated EEG features.This network can yield full-scale,fine-grained EEG features from the low-scale,coarse ones.Specially,to overcome the limitations of traditional generative models that fail to generate features tailored to individual patient characteristics,we developed an encoder with an effective approximating self-attention mechanism.This encoder not only automatically extracts relevant features across different patients but also reduces the computational resource consumption.Furthermore,the adversarial loss and reconstruction loss functions were redesigned to better align with the training characteristics of the network and the spatial correlations among electrodes.Extensive experimental results demonstrate that PCGAN-EASA provides the highest generation quality and the lowest computational resource usage compared to several existing approaches.Additionally,it significantly improves the accuracy of subsequent stroke classification tasks.

Emotion Detection Using ECG Signals and a Lightweight CNN Model

Emotion recognition is a growing field that has numerous applications in smart healthcare systems and Human-Computer Interaction(HCI).However,physical methods of emotion recognition such as facial expressions,voice,and text data,do not always indicate true emotions,as users can falsify them.Among the physiological methods of emotion detection,Electrocardiogram(ECG)is a reliable and efficient way of detecting emotions.ECG-enabled smart bands have proven effective in collecting emotional data in uncontrolled environments.Researchers use deep machine learning techniques for emotion recognition using ECG signals,but there is a need to develop efficient models by tuning the hyperparameters.Furthermore,most researchers focus on detecting emotions in individual settings,but there is a need to extend this research to group settings aswell since most of the emotions are experienced in groups.In this study,we have developed a novel lightweight one dimensional(1D)Convolutional Neural Network(CNN)model by reducing the number of convolution,max pooling,and classification layers.This optimization has led to more efficient emotion classification using ECG.We tested the proposed model’s performance using ECG data from the AMIGOS(A Dataset for Affect,Personality and Mood Research on Individuals andGroups)dataset for both individual and group settings.The results showed that themodel achieved an accuracy of 82.21%and 85.62%for valence and arousal classification,respectively,in individual settings.In group settings,the accuracy was even higher,at 99.56%and 99.68%for valence and arousal classification,respectively.By reducing the number of layers,the lightweight CNNmodel can process data more quickly and with less complexity in the hardware,making it suitable for the implementation on the mobile phone devices to detect emotions with improved accuracy and speed.

Deep Learning-Based ECG Classification for Arterial Fibrillation Detection

The application of deep learning techniques in the medical field,specifically for Atrial Fibrillation(AFib)detection through Electrocardiogram(ECG)signals,has witnessed significant interest.Accurate and timely diagnosis increases the patient’s chances of recovery.However,issues like overfitting and inconsistent accuracy across datasets remain challenges.In a quest to address these challenges,a study presents two prominent deep learning architectures,ResNet-50 and DenseNet-121,to evaluate their effectiveness in AFib detection.The aim was to create a robust detection mechanism that consistently performs well.Metrics such as loss,accuracy,precision,sensitivity,and Area Under the Curve(AUC)were utilized for evaluation.The findings revealed that ResNet-50 surpassed DenseNet-121 in all evaluated categories.It demonstrated lower loss rate 0.0315 and 0.0305 superior accuracy of 98.77%and 98.88%,precision of 98.78%and 98.89%and sensitivity of 98.76%and 98.86%for training and validation,hinting at its advanced capability for AFib detection.These insights offer a substantial contribution to the existing literature on deep learning applications for AFib detection from ECG signals.The comparative performance data assists future researchers in selecting suitable deep-learning architectures for AFib detection.Moreover,the outcomes of this study are anticipated to stimulate the development of more advanced and efficient ECG-based AFib detection methodologies,for more accurate and early detection of AFib,thereby fostering improved patient care and outcomes.

Efficient ECG classification based on Chi-square distance for arrhythmia detection

This study introduces a new classifier tailored to address the limitations inherent in conventional classifiers such as K-nearest neighbor(KNN),random forest(RF),decision tree(DT),and support vector machine(SVM)for arrhythmia detection.The proposed classifier leverages the Chi-square distance as a primary metric,providing a specialized and original approach for precise arrhythmia detection.To optimize feature selection and refine the classifier’s performance,particle swarm optimization(PSO)is integrated with the Chi-square distance as a fitness function.This synergistic integration enhances the classifier’s capabilities,resulting in a substantial improvement in accuracy for arrhythmia detection.Experimental results demonstrate the efficacy of the proposed method,achieving a noteworthy accuracy rate of 98% with PSO,higher than 89% achieved without any previous optimization.The classifier outperforms machine learning(ML)and deep learning(DL)techniques,underscoring its reliability and superiority in the realm of arrhythmia classification.The promising results render it an effective method to support both academic and medical communities,offering an advanced and precise solution for arrhythmia detection in electrocardiogram(ECG)data.

基于ECG和PPG特征的情绪识别研究

心理健康是我们身体健康的重要组成部分,也是我们拥有幸福生活的基础。现代社会的高压力和快节奏生活使人们越来越容易感到焦虑、抑郁和情绪不稳定,通过合理的健康情绪检测方法有益于帮助医护对患者进行情绪监督调理。基于现有的心电图(ECG)和脉搏波(PPG)两种穿戴式监测情绪的方法,使用WESAD数据集,分别验证了心电信号的心率和心率特异性对中性、压力、愉悦和冥想四种情绪状态的重要性,并基于Sklearn库的分类器,使用交叉验证方法评估和比较它们的性能。实验结果显示,ExtraTrees分类模型在情感状态分类中表现最佳,ECG在分类器中具有更优秀的表现。

基于卷积神经网络的ECG心律失常分类研究

基于心电信号进行心律失常自动检测和分类识别研究,辅助临床医生进行心血管相关疾病诊断。采用MIT-BIH数据库作为数据源,对该数据库心电数据进行小波分解与重构去噪后,构建卷积神经网络模型,结合Adam优化器,并优化丢弃值、训练步数和批大小三个超参数来优化模型,使用准确率、灵敏性和正预测率三个指标评价模型性能。实验结果表明,模型实现心律失常五分类的整体准确率大于99%,与现有模型性能相比,准确率提升1.2%。

全面解读IA ECG广色域测试版ICC文件

七色分色技术已发展多年,欧美印刷机构和协会相继投人研发和制定更新相关标准体系,当前色彩校准技术手段等条件正走向成熟,本文对IAECG广色域测试版ICC文件进行全面解读。

缓慢型心房颤动(Af)伴发长R-R间期在静态心电图(ECG)中发生率及意义

探讨ECG(静态心电图)在缓慢型Af(心房颤动)伴发长R-R间期中的应用意义。方法 截选2021年03月至2022年03月54例ECG提示缓慢型心房颤动患者,按照有无伴随相关症状(头晕、黑朦、晕厥等),分为甲组33例(有相关症状)和乙组21例(无相关症状);按照年龄,分为老年组30例(≥80岁)和非老年组24例(<80岁);比较各组伴发长R-R间期发生率。结果 本试验中,甲、乙组伴发长R-R间期发生率差异明显,甲组发生率显著更高(P<0.05)。老年组、非老年组伴发长R-R间期发生率差异明显,老年组发生率显著更高(P<0.05)。结论 缓慢型心房颤动行静态心电图检查,能够准确诊断患者有无伴发长R-R间期;针对老年患者和伴随头晕、黑朦、晕厥等症状患者,应加强其静态心电图检查,以便更好诊断、鉴别其病情,促使患者尽早接受专业治疗和干预,保证其生命安全与预后质量。

基于卷积神经网络与ECG信息的多模态疲劳驾驶检测研究

为解决驾驶员疲劳驾驶引发的交通事故问题,本研究致力于设计一款高精度、及时预警的疲劳驾驶检测与预警装置。文章提出了一种基于卷积神经网络与ECG信息的多模态疲劳驾驶检测方法:首先,通过训练数据集获取模型文件,并将其与预设行为进行对比,得出预警结果;接着,结合ECG信号对驾驶员的驾驶状态进行进一步分析,输出最终结果并触发预警。实验结果表明,该方法能够准确识别驾驶员的疲劳状态并及时发出预警,最高检测正确率达到了99%,验证了方法的可行性。

基于定量脑电图及经颅多普勒的多模脑功能监测评估急性高血压性脑出血血肿扩大及预后的价值

目的评估定量脑电图(QEEG)和经颅多普勒(TCD)的多模脑功能监测在预测急性高血压性脑出血患者血肿扩大及预后的价值。方法回顾性分析2019年10月至2022年10月120例急性高血压性脑出血患者的临床资料。所有患者在入院24 h内接受QEEG和TCD检查,并根据血肿是否扩大将患者分为血肿扩大组(79例)和血肿稳定组(41例)。通过对比两组间QEEG和TCD的参数差异,探究这些监测指标与血肿扩大及患者预后之间的关联。结果血肿扩大组的患者年龄较高,且吸烟比例也较高,血肿扩大组患者的初始神经功能损伤更严重,血肿扩大组在脑出血后不同时间点的DAR和DTABR值均高于续血肿稳定组(P<0.05)。相关性分析显示DAR、DTABR和P1与血肿扩大呈正相关,其中DAR和DTABR的相关性尤其强(r值分别为0.774和0.738,P<0.05),P1的相关性相对较弱(r=0.213,P<0.05)。ROC曲线分析显示DAR、DTABR和P1参数在预测血肿扩大方面具有高灵敏度和特异度,DAR的AUC值高达0.970。随访期间,血肿稳定组的MRS评分在所有时间点上优于血肿扩大组(P<0.05)。结论QEEG和TCD有助于早期识别高风险患者,从而实施更有针对性的治疗措施,改善患者的临床结果。

基于互信息与自适应图卷积的运动想象脑电信号识别

针对运动想象脑电信号非线性特征提取困难、难以有效捕获脑电通道间功能连接关系的问题,提出一种基于互信息和自适应图卷积的运动想象脑电信号分类识别方法。首先,对原始运动想象脑电信号进行子频带划分,提取频域信息;然后,采用互信息神经估计方法构建邻接矩阵,获取脑电信号的非线性关系;最后,设计一种结合CBAM的自适应图卷积网络捕获各通道间的动态关联强度,实现空频特征提取。在BCICompetitionⅣ2a和BCICompetitionⅢ3a数据集上,分别达到83.14%和88.19%的平均准确率,结果表明本文方法能有效获得脑电通道间功能连接关系,为运动想象脑电信号解码提供新思路。

基于参数优化变分模态分解的信号降噪方法

针对心电信号中肌电干扰噪声难以去除的问题,提出一种基于参数优化变分模态分解(VMD)的信号降噪方法。通过设计动态边界策略和反向种群生成方式,对白鲸优化(BWO)算法进行改进;采用改进白鲸优化算法对VMD参数自适应寻优,确定分解层数K与惩罚因子α;对含噪心电信号进行分解,得到k个本征模态函数(IMF)分量,同时采用相关系数法进行有效模态和含噪模态识别;对噪声主导的模态分量采用小波阈值降噪,并重构信号主导模态与降噪后模态。对仿真信号与含真实肌电干扰的心电信号进行降噪处理,实验结果表明,所提方法去噪效果优于小波阈值去噪法、EMD法、EMD-小波阈值去噪法,真实含噪的心电信号经该方法去噪后自相关系数可达0.91以上。