Volume 14 , Issue 2 , PP: 53-69, 2024 | Cite this article as | XML | Html | PDF | Full Length Article
Vinitha V. 1 * , V. Parthasarathy 2 , R. Santhosh 3
Doi: https://doi.org/10.54216/JCIM.140204
Heart failure, a state marked by the heart's inefficiency in pumping blood adequately., can lead to serious health complications and reduced quality of life. Detecting heart failure early is crucial as it allows for timely intervention and management strategies to prevent progression and improve patient outcomes. The effectiveness of integrating ECG and AI for heart failure detection stems from AI's capacity to meticulously analyze extensive ECG datasets, facilitating the early identification of nuanced cardiac irregularities and enhancing diagnostic precision. While the current research lacks sufficient accuracy and is burdened by complexity issues. To overcome this issue, we proposed a novel Densely Connected Bi-directional Gated Recurrent Unit (Dense-BiGRU) model for accurate heart failure detection. In this work, we enhanced collected ECG signal in terms of performing multiple data pre-treatment including as denoising, powerline interference and normalization utilizing Collaborative Empirical Mode Decomposition (CEMD) algorithm, Adaptive Least Mean Square (Adaptive LMS) and min-max normalization method, respectively. Here, we utilized the LiteStream_Net layer for extracting appropriate feature from pre-processed signal. Finally, based on extracted features heart failure detection is implemented through introducing Dense-BiGRU algorithm. The proposed research is implemented using MATLAB simulation tools, and its validation is conducted through various simulation metrics including accuracy, recall, precision, F1-score, and AUC. The results of the implementation demonstrate that the proposed research surpasses existing state-of-the-art methodologies.
Heart failure detection , Dense-BiGRU (Densely connected bi-directional gated recurrent unit) , ECG signal , Classification , Data Pre-treatment
[1] Kataoka, H. (2021). Chloride in heart failure syndrome: its pathophysiologic role and therapeutic implication. Cardiology and Therapy, 10(2), 407-428.
[2] Rotz, S. J., Ryan, T. D., & Hayek, S. S. (2021). Cardiovascular disease and its management in children and adults undergoing hematopoietic stem cell transplantation. Journal of thrombosis and thrombolysis, 51, 854-869.
[3] Ambeth Kumar, V.D. (2017). Automation of Image Categorization with Most Relevant Negatives. Pattern Recognition and Image Analysis, 27(3), 371–379.
[4] Kumar, I., Kumar, A., Kumar, V.D.A. et al. (2022) Dense Tissue Pattern Characterization Using Deep Neural Network. Cogn Comput 14, 1728–1751.
[5] Shiraishi, Y., Kawana, M., Nakata, J., Sato, N., Fukuda, K., & Kohsaka, S. (2021). Time‐sensitive approach in the management of acute heart failure. ESC Heart Failure, 8(1), 204-221.
[6] Ambeth Kumar, V.D. Malathi,S. Ashok Kumar. (2015). Performance Improvement Using an Automation System for Segmentation of Multiple Parametric Features Based on Human Footprint. Journal of Electrical Engineering & Technology, 10(4), 1815-1821 , 2015.
[7] Ambeth Kumar, V.D. Vaishali,S. Shweta, B. (2015). Basic Study of the Human Foot. Biomedical and Pharmacology, 8(1), 435-444.
[8] Ardeti, V. A., Kolluru, V. R., Varghese, G. T., & Patjoshi, R. K. (2023). An overview on state-of-the-art electrocardiogram signal processing methods: Traditional to AI-based approaches. Expert Systems with Applications, 217, 119561.
[9] Saini, S. K., & Gupta, R. (2022). Artificial intelligence methods for analysis of electrocardiogram signals for cardiac abnormalities: State-of-the-art and future challenges. Artificial Intelligence Review, 55(2), 1519-1565.
[10] Murat, F., Yildirim, O., Talo, M., Demir, Y., Tan, R. S., Ciaccio, E. J., & Acharya, U. R. (2021). Exploring deep features and ECG attributes to detect cardiac rhythm classes. Knowledge-Based Systems, 232, 107473.
[11] Verrier, R. L., Nearing, B. D., & D’Avila, A. (2021). Spectrum of clinical applications of interlead ECG heterogeneity assessment: From myocardial ischemia detection to sudden cardiac death risk stratification. Annals of Noninvasive Electrocardiology, 26(6), e12894.
[12] Castiglione, V., Aimo, A., Vergaro, G., Saccaro, L., Passino, C., & Emdin, M. (2022). Biomarkers for the diagnosis and management of heart failure. Heart failure reviews, 1-19.
[13] Chung, C. T., Lee, S., King, E., Liu, T., Armoundas, A. A., Bazoukis, G., & Tse, G. (2022). Clinical significance, challenges and limitations in using artificial intelligence for electrocardiography-based diagnosis. International journal of arrhythmia, 23(1), 24.
[14] Ambeth Kumar, V.D. Ramakrishnan,M. (2013). Temple and Maternity Ward Security using FPRS. Journal of Electrical Engineering & Technology, 8(3), 633-637.
[15] Kumar, V.D.A., Sharmila, S., Kumar, A. et al. (2023). A novel solution for finding postpartum haemorrhage using fuzzy neural techniques. Neural Comput & Applic. 35(33), 23683–23696
[16] Gupta, V., Mittal, M., & Mittal, V. (2021). Chaos theory and ARTFA: emerging tools for interpreting ECG signals to diagnose cardiac arrhythmias. Wireless Personal Communications, 118(4), 3615-3646.
[17] Liu, X., Wang, H., Li, Z., & Qin, L. (2021). Deep learning in ECG diagnosis: A review. Knowledge-Based Systems, 227, 107187.
[18] Sathya Preiya, V., and V. D. Ambeth Kumar. (2023). Deep Learning-Based Classification and Feature Extraction for Predicting Pathogenesis of Foot Ulcers in Patients with Diabetes. Diagnostics 13(12), 1983.
[19] Balakrishnan, Chitra, and V. D. Ambeth Kumar. (2023). IoT-Enabled Classification of Echocardiogram Images for Cardiovascular Disease Risk Prediction with Pre-Trained Recurrent Convolutional Neural Networks. Diagnostics 13(4), 775
[20] Hemamalini, Selvamani, and Visvam Devadoss Ambeth Kumar. (2022). Outlier Based Skimpy Regularization Fuzzy Clustering Algorithm for Diabetic Retinopathy Image Segmentation. Symmetry, 14(12), 2512
[21] Kavitha, D., Gnaneswar, G., Dinesh, R., Sai, Y.R., & Suraj, R. (2021). Heart Disease Prediction using Hybrid machine Learning Model. 2021 6th International Conference on Inventive Computation Technologies (ICICT), 1329-1333.
[22] Mohamed Suhail, M., & Abdul Razak, T. (2022). Cardiac disease detection from ECG signal using discrete wavelet transform with machine learning method. Diabetes research and clinical practice, 109852 .
[23] Akçin, E., İşleyen, K.S., Özcan, E., Hameed, A.A., Alimovski, E., & Jamil, A. (2021). A Hybrid Feature Extraction Method for Heart Disease Classification using ECG Signals. 2021 Innovations in Intelligent Systems and Applications Conference (ASYU), 1-6.
[24] Hossain, A.I., Sikder, S., Das, A., & Dey, A. (2021). Applying Machine Learning Classifiers on ECG Dataset for Predicting Heart Disease. 2021 International Conference on Automation, Control and Mechatronics for Industry 4.0 (ACMI), 1-6.
[25] El Hamdaoui, H., Boujraf, S., Chaoui, N.E., Alami, B., & Maaroufi, M. (2021). Improving Heart Disease Prediction Using Random Forest and AdaBoost Algorithms. International Journal of Online and Biomedical Engineering (iJOE).
[26] Piyush K. Pareek, Pixel Level Image Fusion in Moving objection Detection and Tracking with Machine Learning “,Fusion: Practice and Applications, Volume 2 , Issue 1 , PP: 42-60, 2020
[27] Shivam Grover, Kshitij Sidana, Vanita Jain, “Egocentric Performance Capture: A Review”, Fusion: Practice and Applications, Volume 2, Issue 2 , PP: 64-73, 2020.
[28] Abdel Nasser H. Zaied, Mahmoud Ismail and Salwa El- Sayed, A Survey on Meta-heuristic Algorithms for Global Optimization Problems, Journal of Intelligent Systems and Internet of Things, Volume 1 , Issue 1 , PP: 48-60, 2020
[29] Mahmoud H.Alnamoly, Ahmed M. Alzohairy, Ibrahim M. El-Henawy, “A survey on gel images analysis software tools, Journal of Intelligent Systems and Internet of Things, Volume 1 , Issue 1 , PP: 40-47, 2021.
[30] Sherubha, “Graph Based Event Measurement for Analyzing Distributed Anomalies in Sensor Networks”, Sådhanå(Springer), 45:212, https://doi.org/10.1007/s12046-020-01451-w