Cardiovascular diseases are the most common cause of death worldwide over the last few decades in the developed as well as underdeveloped and developing countries. Early detection of cardiac diseases and continuous supervision of clinicians can reduce the mortality rate. However, accurate detection of heart diseases in all cases and consultation of a patient for 24 hours by a doctor is not available since it requires more sapience, time and expertise. In this?study, a tentative design of a cloud-based heart disease prediction system had been proposed to detect impending heart disease using Machine learning techniques. For the accurate detection of the heart disease, an efficient machine learning technique should be used which had been derived from a distinctive analysis among several machine learning algorithms in a Java Based Open Access Data Mining Platform, WEKA. The proposed algorithm was validated using two widely used open-access database, where 10-fold cross-validation is applied in order to analyze the performance of heart disease detection. An accuracy level of 97.53% accuracy was found from the SVM algorithm along with sensitivity and specificity of 97.50% and 94.94%respectively. Moreover, to monitor the heart disease patient round-the-clock by his/her caretaker/doctor, a real-time patient monitoring system was developed and presented using Arduino, capable of sensing some real-time parameters such as body temperature, blood pressure, humidity, heartbeat. The developed system can transmit the recorded data to a central server which are updated every 10 seconds. As a result, the doctors can visualize the patient’s real-time sensor data by using the application and start live video streaming if instant medication is required. Another important feature of the proposed system was that as soon as any real-time parameter of the patient exceeds the threshold, the prescribed doctor is notified at once through GSM technology.
References
[1]
Hazra, A., Mandal, S., Gupta, A. and Mukherjee, A. (2017) Heart Disease Diagnosis and Prediction Using Machine Learning and Data Mining Techniques: A Review. Advances in Computational Sciences and Technology, 10, 2137-2159.
[2]
Patel, J., Upadhyay, P. and Patel, D. (2016) Heart Disease Prediction Using Machine learning and Data Mining Technique. Journals of Computer Science & Electronics, 7, 129-137.
[3]
Chavan Patil, A.B. and Sonawane, P. (2017) To Predict Heart Disease Risk and Medications Using Data Mining Techniques with an IoT Based Monitoring System for Post-Operative Heart Disease Patients. International Journal on Emerging Trends in Technology (IJETT), 4, 8274-8281.
[4]
Weng, S.F., Reps, J., Kai, J., Garibaldi, J.M. and Qureshi, N. (2017) Can Machine-Learning Improve Cardiovascular Risk Prediction Using Routine Clinical Data? PLoS ONE, 12, e0174944. https://doi.org/10.1371/journal.pone.0174944
[5]
Zhao, W., Wang, C. and Nakahira, Y. (2011) Medical Application on Internet of Things. IET International Conference on Communication Technology and Application (ICCTA 2011), Beijing, 14-16 October 2011, 660-665.
[6]
Chiuchisan, I. and Geman, O. (2014) An Approach of a Decision Support and Home Monitoring System for Patients with Neurological Disorders Using Internet of Things Concepts. WSEAS Transactions on Systems, 13, 460-469.
[7]
Soni, J., Ansari, U. and Sharma, D. (2011) Intelligent and Effective Heart Disease Prediction System Using Weighted Associative Classifiers. International Journal on Computer Science and Engineering (IJCSE), 3, 2385-2392.
[8]
Yuce, M.R. (2010) Implementation of Wireless Body Area Networks for Healthcare Systems. Sensor and Actuators A: Physical, 162, 116-129.
https://doi.org/10.1016/j.sna.2010.06.004
[9]
Singh, M., Martins, L.M., Joanis, P. and Mago, V.K. (2016) Building a Cardiovascular Disease Predictive Model Using Structural Equation Model and Fuzzy Cognitive Map. IEEE International Conference on Fuzzy Systems (FUZZ), Vancouver, 24-29 July 2016, 1377-1382. https://doi.org/10.1109/FUZZ-IEEE.2016.7737850
[10]
Ghadge, P., Girme, V., Kokane, K. and Deshmukh, P. (2016) Intelligent Heart Attack Prediction System Using Big Data. International Journal of Recent Research in Mathematics Computer Science and Information Technology, 2, 73-77.
[11]
Shouman, M., Turner, T. and Stocker, R. (2012) Using Data Mining Techniques in Heart Disease Diagnosis and Treatment. Electronics, Communications, and Computers, Alexandria, 173-177.
[12]
Alemdar, H. and Ersoy, C. (2010) Wireless Sensor Networks for Healthcare: A Survey. Computer Networks, 54, 2688-2710.
https://doi.org/10.1016/j.comnet.2010.05.003
[13]
Antony, G. and Francis, S. (2015) Patient Monitoring System Using Raspberry PI. International Journal of Science and Research, 6, 687-689.
[14]
Kumari, M. and Godara, S. (2011) Comparative Study of Data Mining Classification Methods in Cardiovascular Disease Prediction. International Journal of Computer Science and Technology, 2, 304-308.
[15]
UCI Machine Learning Repository: Heart Disease Data Set.
http://archive.ics.uci.edu/ml/datasets/Heart+Disease
Soni, J., Ansari, U., Sharma, D. and Soni, S. (2011) Predictive Data Mining for Medical Diagnosis: An Overview of Heart Disease Prediction. International Journal of Computer Applications, 17, 43-48.
[18]
Dangare, C.S. and Apte, S.S. (2012) Improved Study of Heart Disease Prediction System Using Data Mining Classification Techniques. International Journal of Computer Applications, 47, 44-48.
[19]
Masethe, H. and Masethe, M. (2014) Prediction of Heart Disease Using Classification Algorithms. Proceedings of the World Congress on Engineering and Computer Science, San Francisco, 809-812.
[20]
Elgendi, M., Liang, Y. and Ward, R. (2018) Toward Generating More Diagnostic Features from Photoplethysmogram Waveforms. Diseases, 6, 20.
https://doi.org/10.3390/diseases6010020
[21]
Ahmed, F. (2017) An Internet of Things (IoT) Application for Predicting the Quantity of Future Heart Attack Patients. International Journal of Computer Applications, 164, 36-40.
