Approach to Displaying Data to Users of Telemedicine Systems for Early Detection of Diseases by ECG

With the development of modern technologies in medical organizations, there is an opportunity to modernize existing methods of monitoring public health and detecting diseases. The use of telemedicine can reduce costs and increase the efficiency and accessibility of medical services including monitoring the state of health by remote (outside of medical and preventive institutions) registration and processing of ECG that helps to detect diseases in the initial stages. In this paper, we propose an approach to displaying data to users of telemedicine systems for independent (without medical staff) early detection of diseases by ECG. This approach can be used in the development of a graphical interface for telemedicine systems for the early detection of diseases by ECG.

1. Ryan P., McGrath C. et al. Enhancing efficiency in a cardiac investigations department by increasing remote patient monitoring. International Journal for Quality in Health Care, vol. 31, issue Supplement_1, 2019, pp. 29-34.

2. Kędzierski K., Radziejewska J. et al. Telemedicine in Cardiology: Modern Technologies to Improve Cardiovascular Patients’ Outcomes – A Narrative Review. Medicina, vol. 58, issue 2, 2022, article no. 210, 12 p.

3. de Moraes E.R.F.L., Cirenza C. et al. Prevalence of atrial fibrillation and stroke risk assessment based on telemedicine screening tools in a primary healthcare setting. European Journal of Internal Medicine, vol. 67, 2019, pp. 36-41.

4. Dedov I., Shestakova M. et al. Prevalence of type 2 diabetes mellitus (T2DM) in the adult Russian population (NATION study). Diabetes Research and Clinical Practice, vol. 115, 2016, pp. 90-95.

5. Dedov I.I., Shestakova M.V. et al. Standards of specialized diabetes care. 9th edition. Diabetes mellitus, vol. 22, issue 1S1, 2-19, pp. 1-144 (in Russian) / Дедов И.И., Шестакова М.В. и др. Алгоритмы специализированной медицинской помощи больным сахарным диабетом. 9-й выпуск. Сахарный диабет, том 22, вып. 1S1, 2019 г., стр. 1-144.

6. Muscovites can check their hearts on cardiac chairs in 25 public service centers. My documents. Available at: https://md.mos.ru/presscenter/news/detail/10271712.html, accessed: 30.03.2022 (in Russian). / В 25 центрах госуслуг москвичи могут проверить сердце на кардиокреслах. Мои документы.

7. Federal Law 242-FZ, dated 29.07.2017 «On amendments to certain legislative acts of the Russian federation on the use of information technologies in the field of health care» (in Russian) / Федеральный закон от 29.07.2017 № 242-ФЗ «О внесении изменений в отдельные законодательные акты Российской Федерации по вопросам применения информационных технологий в сфере охраны здоровья».

8. Shmid A.V., Novopashin M.A. et al. Computerized method for non-invasive detection of carbohydrate metabolism disorders by heart rate variability and wearable autonomous device for its implementation. Patent 2751817, Russian Federation, 2021 (in Russian) / Шмид А.В., Новопашин М.А. et al. Компьютеризированный способ неинвазивного выявления нарушений углеводного обмена по вариабельности сердечного ритма и носимое автономное устройство для его реализации. Патент 2751817, Российская Федерация, 2021.

9. Peraspera Cardio. Official Website of the Unified Register of Russian Programs for Electronic Computers and Databases. Available at: https://reestr.digital.gov.ru/reestr/354134/?sphrase_id=364046, accessed: 30.03.2022 (in Russian) / Peraspera Cardio. Официальный сайт единого реестра российских программ для электронных вычислительных машин и баз данных.

10. Shmid A.V., Berezin A.A. et al. Computerized method for non-invasive detection of carbohydrate metabolism disorders by electrocardiogram. Patent 2728869, Russian Federation, 2020 (in Russian) / Шмид A.В., Березин А.А. et al. Компьютеризированный способ неинвазивного выявления нарушений углеводного обмена по электрокардиограмме. Патент 2728869, Российская Федерация, 2020.