Volume 14 , Issue 1 , PP: 59-76, 2025 | Cite this article as | XML | Html | PDF | Full Length Article
Radhika .B 1 * , Noor Fathima 2 , Leelavathi .V .V 3 , Ambika .N .A 4 , Pratibha .S 5 , Asma Banu .S 6
Doi: https://doi.org/10.54216/JISIoT.140105
The recent progress in the Internet of Things (IoT), Artificial Intelligence (AI), and cloud computing has revolutionized the traditional healthcare system, upgrading it into a smart healthcare system. Medical services can be enhanced by integrating essential technology such as IoT and AI. The integration of IoT and AI presents several prospects within the healthcare industry. In this research, a novel hybrid Deep Learning (DL) model called Binary Butterfly Optimization Algorithm with Stacked Non-symmetric Deep Auto-Encoder (BBOA-SNDAE) for HD (HD) prediction based on the Medical IoT technology. The key aim of the work is to categorize and predict HD utilizing clinical data with the BBOA-SDNAE model. Initially, the model is trained using the Cleveland and Statlog datasets. The input data is preprocessed and standardized utilizing the Min-Max normalization. After preprocessing, the selection of features is performed utilizing the BBOA to choose the best optimal features for improved classification. Based on the selected features, the classification is performed using the SNDAE technique. The research model was assessed based on accuracy, sensitivity, precision, specificity, NPV, and F-measure. The model attained 99.62% accuracy, 99.45% precision, 99.32% NPV, 99.56% sensitivity, 99.45% specificity, and 99.38% f-measure using the HD dataset, and the model attained 98.84% accuracy, 98.73% precision, 98.34% NPV, 98.62% sensitivity, 98.21% specificity, and 98.27% f-measure using the sensor data. The results of the research model were compared with the current model for validation, where the research model outperformed all the compared models.
Medical IoT , HD Prediction , AI , Deep Learning, BBOA, SNDAE
[1] M. S. H. Talpur, A. A. Abro, M. Ebrahim, I. A. Kandhro, S. Manickam, S. U. Arfeen, A. Dandoush, and M. Uddin, “Illuminating Healthcare Managements: A Comprehensive Review of IoT-Enabled Chronic Diseases Monitoring,” IEEE Access, vol. 12, pp. 48189-48209, 2024.
[2] K. M. Zobair, L. Houghton, D. Tjondronegoro, L. Sanzogni, M. Z. Islam, T. Sarker, and M. J. Islam, “Systematic reviews of Internet of medical things for cardio vascular diseases preventions among Australian first nation,” Heliyon, vol. 9, e22420, 2023.
[3] 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.
[4] P. Mishra and G. Singh, “Internet of Medical Things Healthcare for Sustainable Smart Cities: Current Status and Future Prospect,” Applied Sciences, vol. 13, 8869, 2023.
[5] M. Dadkhah, M. Mehraen, F. Rahamnia, F. Rahiminia, and K. Kimiaffar, “Use of internet of things for chronic diseases managements: an overview,” Journal of Medical Signals & Sensors, vol. 11, no. 2, pp. 138-157, 2021.
[6] N. Akhtar, S. Rehman, H. Saddia, and Y. Perwaj, “A holistic analysis of Medical Internet of Things (MIoT),” Journal of Information and Computational Sciences, vol. 11, no. 4, pp. 209-222, 2021.
[7] 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
[8] F. Qureshi and S. Krishna, “Wearable Hardware Designs for the Internet of Medical Things (IoMT),” Sensors, vol. 18, 3812, 2018.
[9] Z. Ashfaq, A. Rafey, R. Mumtaj, S. M. H. Zaiddi, H. Salim, S. A. R. Zaidei, S. Mumtaj, and A. Haqque, “A review of enabling technologies for Internet of Medical Things (IoMT) Ecosystems,” Ain Shams Engineering Journal, vol. 13, 101660, 2022.
[10] Hemamalini, Selvamani, and Visvam Devadoss Ambeth Kumar. (2022). Outlier Based Skimpy Regularization Fuzzy Clustering Algorithm for Diabetic Retinopathy Image Segmentation. Symmetry, 14(12), 2512.
[11] F. A. Turjman, M. H. Nawaaz, and U. D. Ulausar, “Intelligences in the Internet of Medical Things era: A systematic reviews of current and future trend,” Computer Communication, vol. 150, pp. 644-660, 2020.
[12] C. Huang, J. Wang, S. Wang, and Y. Zhang, “Internet of medical things: A systematic review,” Neurocomputing, vol. 557, 126719, 2023.
[13] 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
[14] B. Pradhan, S. Bhatacharyya, and K. Paul, “IoT-based application in health care device,” Journal of Healthcare Engineering, vol. 2021, pp. 1-18, 2021.
[15] Ambeth Kumar, V.D. Vaishali,S. Shweta, B. (2015). Basic Study of the Human Foot. Biomedical and Pharmacology, 8(1), 435-444.
[16] S. Krishnamoorthy, A. Duaa, and S. Guptha, “Roles of emerging technologies in futures IoT-driven Healthcare 4.0 technologies: A survey, current challenge and future direction,” Journal of Ambient Intelligences and Humanized Computing, vol. 14, pp. 361-407, 2023.
[17] 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
[18] 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
[19] Shivam Grover, Kshitij Sidana, Vanita Jain, “Egocentric Performance Capture: A Review”, Fusion: Practice and Applications, Volume 2, Issue 2 , PP: 64-73, 2020.
[20] 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
[21] 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.
[22] S. Subramani, N. Varshiney, M. V. Aanand, M. E. M. Soudaggar, L. A. A. Keriadis, T. K. Upadhyyay et al., “Cardiovascular Disease Predictions by Machine Learning Incorporations with Deep Learning,” Frontiers in Medicine, 10, 1150933, 2023.
[23] S. Bebortta, S. S. Tripathi, S. Basher, and C. L. Chowdary, “FedEHR: A Federated Learning Approach toward the Predictions of Heart Disease in IoT-Based Electronics Health Record,” Diagnostics, vol. 13, 3166, 2023.
[24] A. Khanna, P. Selvaraaj, D. Guptha, T. H. Shikh, P. K. Pareak, and V. Sankar, “Internet of things and deep learning enabled health care diseases diagnosis using biomedicals electrocardiogram signal,” Expert Systems, vol. 40, no. 4, e12864, 2023.
[25] M. Umer, S. Sadhiq, H. Karamiti, W. Karamiti, R. Majed, and M. Napi, “IoT Based Smart Monitoring of Patient with Acute Heart Failures,” Sensors, vol. 22, 2431, 2022.
[26] A. A. Nancy, D. Ravindhran, P. M. D. R. Vincent, K. Srinivaasan, and D. G. Reigna, “IoT-Cloud-Based Smart Healthcare Monitoring Systems for Heart Diseases Predictions via Deep Learning,” Electronics, vol. 11, 2292, 2022.
[27] A. F. Subahi, O. I. Khaalaf, Y. Alotabi, R. Natrajan, N. Mahaadev, and T. Ramesh, “Modified Self-Adaptive Bayesian Algorithms for Smart Heart Diseases Predictions in IoT Systems,” Sustainability, vol. 14, 14208, 2022.
[28] S. Dami and M. Yahaghizadah, “Predicting cardiovascular event with deep learning approaches in the contexts of the internet of things,” Neural Computing and Application, vol. 33, pp. 7979–7996, 2021.
[29] S. Iranpak, A. Shahbarami, and H. Shakari, “Remote patients monitoring and classifying using the internet of thing platforms combined with cloud computing,” Journal of Big Data, vol. 8, 120, pp. 1-22, 2021.
[30] L. Tan, K. Yui, A. K. Basheer, X. Chang, F. Min, L. Zhaou, and X. Zhu, “Towards real-time and efficient cardiovascular monitoring for COVID-19 patient by 5G-enabled wearables medical device: a deep learning approach,” Neural Computing and Application, vol. 35, pp. 13921–13934, 2023.
[31] Z. A. Makhadmeh and A. Tollba, “Utilizing IoT Wearables Medical Devices for Heart Diseases Predictions using Higher Orders Boltzmann Models: A Classification Approach,” Measurement, vol. 147, 106815, 2019.
[32] S. N. Makhadmeh, M. A. A. Betar, A. K. Abaasi, M. A. Awadalah, I. A. Dousah, Z. A. A. Alyaseri et al., “Recent advance in butterfly optimizations algorithms, its version and application,” Archives of Computational Method in Engineering, vol. 30, pp. 1399-1420, 2023.
[33] S. Arora and P. Aanand, “Binary butterfly optimizations approaches for features selections,” Expert Systems with Application, vol. 116, pp. 147-160, 2019.
[34] Q. Ke, “Research on threats detections in cyber security based on machines learning,” In Journal of Physics: Conferences Series, vol. 2113, 012074, 2021.
[35] D. Nehra, V. Managat, and K. Kumaar, “A deep learning approach for networks intrusions detections using non-symmetrical auto-encoders,” Intelligent Computing and Communications System, pp. 371-382, 2021.