Difference between revisions of "Deep Learning for Cardiologist-level Myocardial Infarction Detection in Electrocardiograms"

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== Model Architecture ==
 
== Model Architecture ==
  
The dataset consists of 549 ECG records taken from 290 unique patients. Each ECG record has a mean length of over 100 seconds.
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The dataset, which was used to train, validate and test the neural network models, consists of 549 ECG records taken from 290 unique patients. Each ECG record has a mean length of over 100 seconds.
  
 
This Deep Neural Network model was created by modifying the ConvNetQuake model by adding 1D batch normalization layers.
 
This Deep Neural Network model was created by modifying the ConvNetQuake model by adding 1D batch normalization layers.

Revision as of 08:24, 10 November 2020

Presented by

Zihui (Betty) Qin, Wenqi (Maggie) Zhao, Muyuan Yang, Amartya (Marty) Mukherjee

Introduction

This paper presents an approach to the detection of heart disease, which is the leading cause of death worldwide, from ECG signals by fine-tuning the deep learning neural network, ConvNetQuake, in the area of scientific machine learning. A deep learning approach was used due to the model’s ability to be trained using multiple GPUs and terabyte-sized datasets. This, in turn, creates a model that is robust against noise. The purpose of this paper is to provide detailed analyses of the contributions of the ECG leads on identifying heart disease, to show the use of multiple channels in ConvNetQuake enhances prediction accuracy, and to show that feature engineering is not necessary for any of the training, validation, or testing processes. The benefits of translating knowledge between deep learning and it's real-world applications in health are also illustrated.

Previous Work and Motivation

The database used in previous works is the Physikalisch-Technische Bundesanstalt (PTB) database, which consists of ECG records. Previous papers used techniques, such as CNN, SVM, K-nearest neighbours, naïve Bayes classification, and ANN. From these instances, the paper observes several faults in the previous papers. The first being the issue that most papers use feature selection on the raw ECG data before training the model. Dabanloo, and Attarodi [30] used various techniques such as ANN, K-nearest neighbours, and Naïve Bayes. However, they extracted two features, the T-wave integral and the total integral, to aid in localizing and detecting heart disease. Sharma and Sunkaria [32] used SVM and K-nearest neighbours as their classifier, but extracted various features using stationary wavelet transforms to decompose the ECG signal into sub-bands. The second issue is that papers that do not use feature selection would arbitrarily pick ECG leads for classification without rationale. For example, Liu et al. [23] used a deep CNN that uses 3 seconds of ECG signal from lead II at a time as input. The decision for using lead II compared to the other leads was not explained.

The issue with feature selection is that it can be time-consuming and impractical with large volumes of data. The second issue with the arbitrary selection of leads is that it does not offer insight into why the lead was chosen and the contributions of each lead in the identification of heart disease. Thus, this paper addresses these two issues through implementing a deep learning model that does not rely on feature selection of ECG data and to quantify the contributions of each ECG and Frank lead in identifying heart disease.

Model Architecture

The dataset, which was used to train, validate and test the neural network models, consists of 549 ECG records taken from 290 unique patients. Each ECG record has a mean length of over 100 seconds.

This Deep Neural Network model was created by modifying the ConvNetQuake model by adding 1D batch normalization layers.

The input layer is a 10-second long ECG signal. There are 8 hidden layers in this model, each of which consists of a 1D convolution layer with the ReLu activation function followed by a batch normalization layer. The output layer is a one-dimensional layer that uses the Sigmoid activation function.

This model is trained by using batches of size 10. The learning rate is 10^-4. The ADAM optimizer is used. In training the model, the dataset is split into a train set, validation set and test set with ratios 80-10-10.

During the training process, the model was trained from scratch numerous times to avoid inserting unintended variation into the model by randomly initializing weights.

Result

The paper first uses quantification of accuracies for single channels with 20-fold cross-validation, resulting highest individual accuracies: v5, v6, vx, vz, and ii. The researcher further investigated the accuracies for pairs of top 5 highest individual channels using 20-fold cross-validation. The arrived at the conclusion of highest pairs accuracies to fed into a the neural network is lead v6 and lead vz. They then use 100-fold cross validation on v6 and vz pair of channels, then compare outliers based on top 20, top 50 and total 100 performing models, finding that standard deviation is non-trivial and there are few models performed very poorly.

Next, they discussed 2 factors effecting model performance evaluation: 1) Random train-val-test split might have effects of the performance of the model, but it can be improved by access with a larger data set and further discussion; and 2) random initialization of the weights of neural network shows little effects on the performance of the model performance evaluation, because of showing a high average results with a fixed train-val-test split.

Comparing with other models in other 12 papers, the model in this article has the highest accuracy, specificity, and precision. With concerns of patients' records effecting the training accuracy, they used 290 fold patient-wise split, resulting the same highest accuracy of the pair v6 and vz same as record-wise split. Even though the patient-wise split might result lower accuracy evaluation, however, it still maintain an high average of 97.83%.

Discussion & Conclusion

The paper introduced a new architecture for heart condition classification based on raw ECG signals using multiple leads. It outperformed the state-of-art model by a large margin of 1 percent. This study finds that out of the 15 ECG channels(12 conventional ECG leads and 3 Frank Leads), channel v6, vz and ii contain the most meaningful information for detecting myocardial infraction. Also, recent advances in machine learning can be leveraged to produce a model capable of classifying myocardial infraction with a cardiologist-level success rate. To further improve the performance of the models, access to larger labelled data set is needed. The PTB database is small so it is difficult to test the true robustness of the model with a relatively small test set. If a larger data set can be found to help correctly identify other heart conditions beyond myocardial infraction, the research group plans to share the deep learning models and develop an open source, computationally efficient app that can be readily used by cardiologists.

A detailed analysis of the relative importance of each of the standard 15 ECG channels indicates that deep learning can identify myocardial infraction by processing only ten seconds of raw ECG data from the v6, vz and ii leads and reaches cardiologist-level success rate. Deep learning algorithms may be readily used as commodity software. Neural network model that was originally designed to identify earthquakes may be re-designed and tuned to identify myocardial infraction. Feature engineering of ECG data is not required to identify myocardial infraction in the PTB database. This model only required ten seconds of raw ECG data to identify this heart condition with cardiologist-level performance. Access to larger database should be provided to deep learning researchers so they can work on detecting different types of heart conditions. Deep learning researchers and cardiology community can work together to develop deep learning algorithms that provides trustworthy, real-time information regarding heart conditions with minimal computational resources.