MEDI-NET: CLOUD-BASED FRAMEWORK FOR MEDICAL DATA RETRIEVAL SYSTEM USING DEEP LEARNING

Authors

  • SAKTHIVEL PALANISAMY Sona College of Technology, Salem, India. Author
  • THANGARAJAN RAMASAMY Kongu Engineering College, Erode, India. Author

DOI:

https://doi.org/10.59277/RRST-EE.2024.2.23

Keywords:

Medical record retrieval, Deep learning, Health Records, Indexing, Inception ResNet

Abstract

Medical data retrieval is becoming increasingly crucial, aiding physicians and domain experts in more effectively accessing knowledge and information related to medicine and facilitating informed decision-making. The centralized architectures need help with scalability and real-time indexing, leading to extended retrieval times and decreased efficiency. To address these issues, a novel MEdical Data retrieval using Inception resNET (MEDI-NET) has been proposed to retrieve medical data efficiently. The proposed system introduces a deep learning network for a dynamic poly-indexing model and concurrent indexing, ensuring the real-time retrieval of the latest medical records. EMRBots and MIMIC-III are the two datasets used to compare the performance of the proposed MEDI-NET approach with existing MRCG, HCAC-EHR, and FedCBMIR method, which is implemented using Python. The effectiveness of the proposed MEDI-NET approach has been determined using evaluation metrics such as precision, accuracy, recall, F1-score, indexing time, and retrieval time. Comparative analysis with existing methods demonstrates superior precision, accuracy, recall, and F1 score for the proposed method. Additionally, the proposed system exhibits reduced indexing and retrieval times, showcasing its efficiency in handling large-scale medical data. The proposed MEDI-NET approach's accuracy is 0.60 %, 9.87 %, and 21.1 % higher than the existing MRCG, HCAC-EHR, and FedCBMIR techniques, respectively.

References

(1) T. Jacquemard, C.P. Doherty, M.B. Fitzsimons, The anatomy of electronic patient record ethics: a framework to guide design, development, implementation, and use, BMC Medical Ethics, 22, 1, pp. 1–14 (2021).

(2) C. Dinh-Le, R. Chuang, S. Chokshi, D. Mann, Wearable health technology and electronic health record integration: scoping review and future directions, JMIR mHealth and Health, 7, 9, pp. e12861 (2019).

(3) L.G. Timme, Social Workers’ Perspectives of the effectiveness of EMDR in telehealth for PTSD patients (Doctoral dissertation, Millersville University of Pennsylvania). (2023).

(4) H.G. Eichler, B. Bloechl‐Daum, K. Broich, P.A. Kyrle, J. Oderkirk, G. Rasi, R. Santos Ivo, A. Schuurman, T. Senderovitz, L. Slawomirski, M. Wenzl, Data rich, information poor: can we use electronic health records to create a learning healthcare system for pharmaceuticals? Clin. Pharmacol. Ther., 105, 4, pp. 912–922 (2019).

(5) K.H. Nguyen, C. Wright, D. Simpson, L. Woods, T. Comans, C. Sullivan, Economic evaluation and analyses of hospital-based electronic medical records (EMRs): a scoping review of international literature, NPJ Digital Med., 5, 1, pp. 29 (2022).

(6) I.C. Stanica, F. Moldoveanu, M.I. Dascalu, I.V. Nemoianu, G.P. Portelli, Advantages of telemedicine in neurorehabilitation and quality of life improvement, Rev. Roum. Sci. Techn. – Électrotechn. Et Énerg., 66, 3, pp. 195–199 (2021).

(7) R. Cerchione, P. Centobelli, E. Riccio, S. Abbate, E. Oropallo, Blockchain’s coming to hospital to digitalize healthcare services: Designing a distributed electronic health record ecosystem, Technovation, 120, pp. 102480 (2023).

(8) D.R. Friedman, V. Patil, C. Li, K.M. Rassmussen, Z. Burningham, S. Hamilton-Hill, M.J. Kelley, A.S. Halwani, Integration of patient-reported outcome measures in the electronic health record: The Veterans Affairs experience, JCO Clin. Cancer Inf. 6, pp. e2100086 (2022).

(9) L.S. Dhingra, M. Shen, A. Mangla, R. Khera, Cardiovascular care innovation through data-driven discoveries in the electronic health record, American Journal of Cardiology, 203, pp.136–148 (2023).

(10) A. Prasanth, N. Muthukumaran, Primary open-angle glaucoma severity prediction using deep learning technique, International Journal of Current Bio-Medical Engineering, 01, 1, pp. 30–37 (2023).

(11) S. Han, R.F. Zhang, L. Shi, R. Richie, H. Liu, A. Tseng, W. Quan, N. Ryan, D. Brent, F.R. Tsui, Classifying social determinants of health from unstructured electronic health records using deep learning-based natural language processing, J. Biomed. Inf., 127, pp.103984 (2022).

(12) M. Jesi, A. Appathurai, M. Kumaran, A. Kumar, Load balancing in cloud computing via mayfly optimization algorithm, Rev. Roum. Sci. Techn. – Électrotechn. Et Énerg., 69, 1, pp.79–84 (2024).

(13) A. Rehman, S. Naz, I. Razzak, Leveraging big data analytics in healthcare enhancement: trends, challenges and opportunities, Multimedia Syst., 28, 4, pp.1339–1371 (2022).

(14) M. Wornow, Y. Xu, R. Thapa, B. Patel, E. Steinberg, S. Fleming, M.A. Pfeffer, J. Fries, N.H. Shah, The shaky foundations of large language models and foundation models for electronic health records, NPJ Digital Med. 6, 1, pp.135 (2023).

(15) J.S. Ilgen, K.W. Eva, A. de Bruin, D.A. Cook, G. Regehr, Comfort with uncertainty: reframing our conceptions of how clinicians navigate complex clinical situations, Advances in Health Sciences Education, 24, 4, pp. 797–809 (2019).

(16) M. Shen, Y. Deng, L. Zhu, X. Du, N. Guizani, Privacy-preserving image retrieval for medical IoT systems: A blockchain-based approach, IEEE Network, 33, 5, pp. 27–33 (2019).

(17) Z. Tang, Z.H. Sun, E.Q. Wu, C.F. Wei, D. Ming, S. Chen, MRCG: An MRI retrieval system with convolutional and graph neural networks for secure and private IoMT, IEEE J. Biomed. Health. Inf. (2021).

(18) C.A. Hussain, D.V. Rao, S.A. Mastani, RetrieveNet: a novel deep network for medical image retrieval, Evol. Intell., 14, 4, pp.1449–1458 (2021).

(19) P. Chinnasamy, P. Deepalakshmi, HCAC-EHR: hybrid cryptographic access control for secure EHR retrieval in healthcare cloud, J. Ambient Intell. Hum. Comput., pp. 1–19, (2022).

(20) P. Shamna, V.K. Govindan, K.A. Nazeer, Content-based medical image retrieval by spatial matching of visual words, Journal of King Saud University-Computer and Information Sciences, 34, 2, pp. 58–71 (2022).

(21) T. Sunitha, T.S. Sivarani, Novel content-based medical image retrieval based on BoVW classification method. Biomed. Signal Process, Control, 77, pp. 103678 (2022).

(22) Z. Tabatabaei, Y. Wang, A. Colomer, J. Oliver Moll, Z. Zhao, V. Naranjo, WWFedCBMIR: world-wide federated content-based medical image retrieval, Bioeng., 10, 10, pp.1144 (2023).

(23) A.S. Ghazanfar, X. Cheng, Brain aneurysm classification via whale optimized dense neural network, International Journal of Data Science and Artificial Intelligence, 02, 2, pp. 63–67 (2024).

Downloads

Published

07.07.2024

Issue

Vol. 69 No. 2 (2024): RRST-EE

Section

Génie biomédical | Biomedical Engineering

License

Copyright (c) 2024 REVUE ROUMAINE DES SCIENCES TECHNIQUES — SÉRIE ÉLECTROTECHNIQUE ET ÉNERGÉTIQUE

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

How to Cite

MEDI-NET: CLOUD-BASED FRAMEWORK FOR MEDICAL DATA RETRIEVAL SYSTEM USING DEEP LEARNING. (2024). REVUE ROUMAINE DES SCIENCES TECHNIQUES — SÉRIE ÉLECTROTECHNIQUE ET ÉNERGÉTIQUE, 69(2), 255-260. https://doi.org/10.59277/RRST-EE.2024.2.23