Table 6.
Comparison of existing algorithms for detection of shockable rhythms.
| Reference | Brief approach | Dataset used | Accuracy reported |
|---|---|---|---|
| Figuera et al. (2016) | An ML-algorithms with built-in feature selection capabilities were used to determine the optimal feature subsets for classification. Patient-wise bootstrap techniques were used to evaluate algorithm performance on public database | Validated on the VFDB and the CUDB datasets | Sensitivity = 96.6%, Specificity = 98.8% |
| Kwon et al. (2018) | The authors proposed an embedded microcontroller where an ECG sensor is used to capture, filter and process data, run a real-time VF detection algorithms developed a VF detection algorithm, via Time Delay (TD), based on phase space reconstruction. | Open access MIT-BIH dataset | Sensitivity = 96.56%, Specificity = 81.53% |
| Krasteva et al. (2020) | A deep convolutional network was proposed and studied on Holter ECG recordings for detection of shockable and non-shockable rhythms. The impact of various network hyper-parameter tuning was reported | The data used in the study contains a wide variety of non-shockable and shockable rhythms from two sources: public Holter ECG databases from continuously monitored patients with ventricular arrhythmias, and OHCA databases recorded by AEDs from patients in cardiac arrest. | For analysis on short windows (2 s): Sensitivity 97.6% =, Specificity = 98.7%. For analysis on long windows (5 s) : Sensitivity = 99.6 % Specificity = 99.4 % |
| Jeon et al. (2020) | A deep architecture comprising convolutional layers and recurrent networks for classification of ECG beats. Furthermore, a lightweight model is proposed with fused RNN for speeding up the prediction time on central processing units (CPUs) | The authors used 48 ECGs from the open access MIT-BIH Arrhythmia Database, and 76 ECGs were collected with S-Patch devices developed by Samsung SDS | For the baseline model: Sensitivity = 99.86%, Specificity = 98.31% for the light-weight model: Sensitivity = 99.92%, Specificity = 99.11% |
| Our proposed approach | A CNN-LSTM architecture is proposed for classification of VF, VT and other rhythms from ECG | The approach is evaluated on CUDB and VFDB datasets | Detection rate of shockable rhythms (VF and VT) on CUDB: very small windows (2 s) Sensitivity = 96.10%, Specificity = 98.34% for large windows (8 s) Sensitivity = 99.21%, Specificity = 99.68% Detection rate of shockable rhythms (VF and VT) on VFDB: very small windows (2 s) Sensitivity = 94.68%, Specificity = 92.77% for large windows (8 s) Sensitivity = 98.56%, Specificity = 99.08% |