APPLICATION OF MATHEMATICAL MODELS IN THE DIAGNOSIS OF DISEASES OF INTERNAL ORGANS

Authors

DOI:

https://doi.org/10.37943/17ODJA2930

Keywords:

Diagnosing diseases with the automated system, medical diagnostic expert systems, decision support systems, mathematical modelling

Abstract

The application of diagnostic expert systems in medical technology signifies a notable progression, as they provide a computerized framework for decision-support, assisting healthcare practitioners in the process of disease diagnosis. These systems facilitate the integration of patient data, encompassing symptoms and medical history, with a knowledge base in order to produce a comprehensive compilation of potential diagnoses. Through the utilization of knowledge-based methodologies, they enhance these potentialities in order to ascertain the most probable diagnosis. The present study examines expert systems, investigating their historical development, architectural structure, and the approaches utilized for knowledge representation. There is a significant emphasis placed on the advancement and implementation of these systems within the medical industry of Kazakhstan. This paper provides a comprehensive analysis of the benefits and drawbacks associated with diagnostic expert systems, emphasizing their potential to bring about significant advancements in medical fields. The study places significant emphasis on the necessity of developing and conducting thorough testing of these systems in order to improve the precision and effectiveness of medical diagnostics. The statement recognizes the importance of continuous research in order to enhance the design and implementation of these systems in various healthcare settings. This research makes a notable addition by examining optimization theory in the field of medical diagnosis. This study presents novel approaches for effectively addressing the intricacies and uncertainties associated with the diagnosis of complicated disorders. The work presents methodology for navigating the complex field of medical diagnostics by utilizing mathematical modeling and optimization approaches, specifically the gradient projection method. The utilization of diverse ways to tackle qualitative ambiguities in this approach signifies a significant progression inside the domain of diagnostic expert systems.

References

Martínez-Pérez, B., De la Torre Díez, I., Lopez-Coronado, M., & Sainz de Abajo, B. (2014). Mobile Clinical Decision Support Systems and Applications: A Literature and Commercial Review. Journal of Medical Systems, 38(1), 4. https://doi.org/10.1007/s10916-013-0004-y

Myrzakerimova, A.B., Kolesnikova, K.V., & Nurmaganbetova, M.O. (2024). Use of Mathematical Modeling Tools to Support Decision-Making in Medicine. Procedia Computer Science, 231, 335-340. https://doi.org/10.1016/j.procs.2023.12.213

Malmir, B., Amini, M., & Chang, S. I. (2017). A Medical Decision Support System for Disease Diagnosis under Uncertainty. Expert Systems with Applications, 88, 1-10. https://doi.org/10.1016/j.eswa.2017.06.031

Smith, J., Lee, M., & Kim, D. (2020). Artificial Intelligence for Medical Diagnosis: A Comprehensive Review. Journal of Medical Systems.

Ganesan, N., Venkatesh, K., Rama, M.A., & Palani, A. M. (2010). Application of neural networks in diagnosing cancer disease using demographic data. International Journal of Computer Applications, 1(26), 76-85.

Licata, G. (2010). Employing fuzzy logic in the diagnosis of a clinical case. Health, 2(3), 211-224. https://doi.org/10.4236/health.2010.23031

Isabel Healthcare. (2010). Isabel Healthcare. Retrieved from https://www.isabelhealthcare.com/

Vert, J.P., Maraia, R.J., & Eddy, S.R. (2005). Inferring Gene Networks from Expressions Profiles with Inferelator. Nature Genetics, 37, 489-496.

Edberg, S. C. (2005). Global Infectious Diseases and Epidemiology Network (GIDEON): A worldwide Web-based program for diagnosis and informatics in infectious diseases. Clinical Infectious Diseases, 40(1), 123-126. https://doi.org/10.1086/426549

IBM Watson Health. (2021). Watson Health. Retrieved from https://www.ibm.com/watson-health/

DeepMind Health. (2021). Retrieved from https://deepmind.com/applied/deepmind-health/about

Tao, C., Jiang, G., Oniki, T.A., Freimuth, R.R., Zhu, Q., Sharma, D., Pathak, J., M Huff, S., & G Chute, C. (2013). A semantic-web oriented representation of the clinical element model for secondary use of electronic health records data. Journal of the American Medical Informatics Association, 20(3), 554-562. https://doi.org/10.1136/amiajnl-2012-001326

Saikia, D., & Dutta, J. C. (2016). Early diagnosis of dengue disease using fuzzy inference system. In 2016 International Conference on Microelectronics, Computing and Communications (MicroCom), 1-6.

Decree of the Minister of Health of the Republic of Kazakhstan about approval of the minimum requirements for medical information systems in the field of healthcare. (2021). Retrieved from https://adilet.zan.kz/rus/docs/V2100023926

List of medical information systems that meet the requirements for work in the OSMS (Compulsory social health insurance) system used in Kazakhstan. (2021). Retrieved from https://www.gov.kz/memleket/entities/dsm/documents/details/196758?directionId=14999&lang=ru

Info TRACKER. (2015). Info Tracker system. https://kz.bizorg.su/laboratornaya-informatsionnaya-sistema-r/p6246989-sistema-informatsionnaya-info-tracker

Komek 103. (2015). Komek system. https://polikliniki.kz/ru/catalog/stanciya-skoroy-medicinskoy-pomoschi_270/

Synkar. (2019). Sunkar medical information system. https://e-clinic.kz//

Infomed Kazakhstan. (2020). Medical information system Infomed Kazakhstan. https://www.infomed.com.kz/welcome/

KazMedGIS. (2020). Medical information system. https://vcabinet.kz/kazmedinfo.html

IS BARS. (2013). Medical information system. https://bars.group/health/meditsinskaya-informatsionnaya-sistema2/

Info DONOR. (2014). Medical information system. https://kz.bizorg.su/laboratornaya-informatsionnaya-sistema-r/p6246474-sistema-informatsionnaya-info-donor

IS Komek 112. (2020). Medical information system. https://www.gov.kz/memleket/entities/mdai/press/article/details/25588?lang=ru

MIS Avicena. (2016). Medical information system. https://avicenna.online/

Damumed. (2015). Medical information system. https://damumed.kz/#/

MIS MedElement. (2013). Medical information system. https://medelement.com/page/avtomatizatsiya_kliniki

AKGÜN. (2008). AKGÜN Hastane Bilgi YönetimSistemleri (HBYS). https://www.akgunyazilim.com.tr/ru/urunler/akgun-hastane-bilgi-yonetim-sistemleri-hbys

NgSoft. (2012). Medical information system. http://www.ngsoft.kz/his/

Arianda. (2010). Medical information system. https://reshenie-soft.ru/about-system

MIS Zhetysu. (2021). Information syst. http://cav.kz/catalog/MISZHetysu/MISZHetysu/

Medialog. (2014). Medical information system. https://ppt-online.org/973312

iMedHub. (2015). Medical information syst. https://astanahub.com/ru/article/uchastnik-astana-hub-razrabotal-meditsinskuiu-sistemu-diagnostiki-zabolevanii-legkikh

PneumoNet. (2012). System. https://damu.kz/news/detail.php?ELEMENT_ID=41828

Myrzakerimova, A., Kolesnikova, K., & Nurmaganbetova, M. (2022). DEVELOPMENT OF THE STRUCTURE OF AN AUTOMATED SYSTEM FOR DIAGNOSING DISEASES. Scientific Journal of Astana IT University, 12(12), 101–112. https://doi.org/10.37943/12AVGE4585

International Classification of Diseases. (2012). https://www.who.int/standards/classifications/classification-of-diseases

Ahmadi, H., Gholamzadeh, M., & Shahmoradi, L. (2018). Diseases Diagnosis Using Fuzzy Logic Methods: A Systematic and Meta-Analysis Review. Computer Methods and Programs in Biomedicine, 161, 145-172. https://doi.org/10.1016/j.cmpb.2018.04.013

Turimov, D., Muhamediyeva, D., Safarova, L., Primova, H., & Kim, W. (2023). Improved Cattle Disease Diagnosis Based on Fuzzy Logic Algorithms. Sensors, 23(4), 2107. https://doi.org/10.3390/s23042107

Parin, V., & Bayevskii, R. (1966). Introduction to medical cybernetics. Prague

Bhatla, N., & Jyoti, K. (2012). A Novel Approach for Heart Disease Diagnosis using Data Mining and Fuzzy Logic. International Journal of Computer Applications, 54(17).

Abushariah, M.A.M., Alqudah, A.A.M., Adwan, O.Y., & Yousef, R.M.M. (2014). Automatic Heart Disease Diagnosis System Based on Artificial Neural Network (ANN) and Adaptive Neuro-Fuzzy Inference Systems (ANFIS) Approaches. Journal of Software Engineering and Applications, 7(12). https://doi.org/10.4236/jsea.2014.712093

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Published

2024-03-31

How to Cite

Myrzakerimova, A., Kolesnikova, K. ., Khlevna, I. ., & Nurmaganbetova, M. . (2024). APPLICATION OF MATHEMATICAL MODELS IN THE DIAGNOSIS OF DISEASES OF INTERNAL ORGANS. Scientific Journal of Astana IT University, 17(17), 68–82. https://doi.org/10.37943/17ODJA2930

Issue

2024: Volume 17

Section

Information Technologies

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