Determination of respiratory rate is a necessary task in assessing the state of health in humans. This review provides a description of modern devices used for recording and monitoring respiratory rate. The advantages and disadvantages of the principles of operation of these devices are discussed.
Article PDF
Similar content being viewed by others
References
Alekseeva, A. S., Sergeeva, M. S., Baisheva, G. M., et al., Respiratory Physiology. Methodological Guidelines for Medical Students [in Russian], AS-Dizain, Samara (2015), updated.
Zavalishina, S. Yu., Medvedev, I. N., and Kutafina, N. V., Respiratory and Circulatory Physiology [in Russian], Kursk (2017).
Fedin, A. N., Nikitina, E. R., and Krivchenko, A. I., Comparative Respiratory Physiology [in Russian], Russian Academy of Sciences, Moscow (2018).
Minaev, A. V., Respiratory Measurements [in Russian], Nizhnii Novgorod Technical University, Nizhnii Novgorod (2002).
Tuichieva, F. G. and Khodzhieva, A. Yu., “Pathology of the respiratory organs,” in: XXII International Scientific and Applied Conference “International Scientifi c Research-2018,” Olimp Science Center, Moscow (2018), pp., 299-301
Dzhabaeva, S. E. and Akhaeva, A. S., “Characteristics of the clinical manifestations of community-acquired pneumonia in children of different ages,” Ross. Vestn. Perinatol. Pediatr., 63, No. 4, 179- 180 (2018).
Aftaeva, L. N., Mel’nikov, V. L., Kubrina, O. Yu., et al., “Clinical manifestations of community-acquired pneumonia,” Ustoich. Razv. Nau. Obrazovan., No. 2, 258-264 (2019).
Gizinger, O. A., “Coronavirus infection. Information for therapists,” Terapevt, No. 3, 78-81 (2020).
Mochalova, E. S., “Studies of external respiration in humans with the aim of developing a device for identifying respiratory phases in humans,” in: Proceedings of the XIV International Young Scientists Conference ‘Gagarin Readings-2019’ [in Russian], Moscow, Barnaul, Akhtubinsk (2019).
Lapteva, E. A., Kovalenko, I. V., Laptev, A. N., et al., “Use of ‘neural network’ technologies for detection and monitoring auscultatory phenomena in the diagnosis of diseases of the respiratory organs,” Zh Grodn. Gos. Med. Univ., 18, No. 3, 230-235 (2020).
Vinokurov, A. S., Smirnova, A. D., Belen,kaya, O. I., et al., “Clinical and X-ray variants of lung damage in infections due to Staphylococcus aureus,” Klinich. Prakt., 12, No. 3, 71-89 (2021).
Omarova, S. M., Alieva, A. I., Svitich, O. A., and Abserkhanova, D. U., “The effective of current criteria for diagnosis and rational antibiotic treatment of ventilation-associated pneumonia in neonates,” Ross. Immunol. Zh., 9, (18), No. 2-1, 120-122 (2015).
Novikova, E. I., Andrianova, E. A., Udodova, E. E., et al., “Development of an expert system for the diagnosis of lung diseases based on neural network modeling” Sist. Anal. Upravl. Biomed. Sist., 20, No. 1, 155-159 (2021).
Manichev, I. A., Grekova, T. I., and Sivakov, A. P., “Current approaches to high-quality of spirometric investigations: apparatus and expert systems,” in: XII International Scientific and Technical Conference, “Medical Electronics and New Medical Technologies” Medelektronica-2020 [in Russian], Minsk (2020), pp. 206-209.
Nikiforov, V. S., Lunina, M. D., and Davidovskaya, E. I., et al., Standards for Conducting Spirometry and Assessing its Results [in Russian], I. I. Mechnikov North-Western State Medical University, St. Petersburg (2019).
Temporary Methodological Guidelines “Prophylaxis, Diagnosis, and Treatment of the New Coronavirus Infection, COVID-19 [in Russian], Version 15, February 22, 2022; https://cdn.stopcoronovirus.ru/ai/doc/1301/attach/vmr_COVID-19_V15.pdf (accessed April 17, 2022).
Grishin, O. V., “Mobile biomonitoring in the clinic of diseases of the respiratory and circulatory organs,” in: Proceedings of the Seventh All-Russian Scientific and Applied Conference “Fundamental Aspects of Compensatory-Adaptive Processes” [in Russian], Novosibirsk (2015).
Ovchinnikov, Yu. V. and Mostovoi, L. V., “Remote screening monitoring of respiratory functions during sleep in military personnel,” in: Collected Conference Reports “Biotechnical Systems and Technologies” [in Russian], Anapa (2019), pp. 63-64.
Fedorov, V. A. and Borchaninov, M. G., A Method of Recording the Arterial Pulse and Respiratory Rate and a Device for These Purposes [in Russian], Patent No. 2053706 C1 RF, published February 10, 1996.
Dembovskii, M. V. and Pisareva, A. V., “Development of a biotechnical magnetoplethysmography system for monitoring respiratory rate and heart rate,” Sist. Anal. Upravl. Biomed. Sist., 19, No. 4, 119-126 (2020).
Nguen, M. T. and Yuldashev, Z. M., “Method and programmable system for comprehensive assessment of the physiological reserves of sportsmen during training,” Biotekhnosfera, No. 5 (65), 3-11 (2020).
Zhivolupova, Yu. A., “Information and methodological support of a remote cardiorespiratory monitoring system for diagnosis of breathing disorders during sleep,” Biotekhnosfera, No. 6 (64), 41-46 (2019).
Gurzhin, S. G. and Nguen, V. L., “Implementation of a contactless method for monitoring the processes of breathing and heartbeat of patients during magnetic therapy sessions,” Biomed. Radioelektr., 24, No. 4, 23-32 (2021).
Anishchenko, L. N., Lobanova, V. S., Davydova, I. A., et al., “Monitoring the breathing pattern of people during sleep using a dual-channel bioradiolocator,” Biomed. Radioelektr., 24, No. 5, 47-58 (2021).
Revinskaya, I. I., Kamlach, P. V., Dalidovich, V. O., et al., “A system for monitoring patient’s breathing parameters,” in: XIII International Scientific and Technical Conference “Medical Electronics and New Medical Technologies” - “Medicine-2020,” [in Russian], Minsk (2020), pp. 190-193.
Alekhin, M. D., “Results of contactless monitoring of the breathing pattern in sleep,” in: Proceedings of the IX International Scientific Conference “System Analysis in Medicine (CAM 2015)” [in Russian], Blagoveshchensk (2015), pp. 47-50.
Sharipova, E. S., Blinova, A. B., and Terent’eva, A. V., “Methods for studies of external respiration,” in: Proceedings of the XXX All-Russian Scientifi c and Technical Conference of Students, Young Scientists, and Specialists “Biotechnical, Medical, Ecological Systems and Robotic Complexes – ‘Biomedsystems-2017,’” [in Russian], Ryazan (2017), pp. 209-212.
Grigorovskii, B. K. and Safiullin, S. V., “Pneuomometry techniques,” in: Collected Reports from the International Scientific and Applied Conference “New Information Technologies in Science in Three Parts” [in Russian], Ufa (2019), pp. 22-25.
Revinskaya, I. I., Kamlach, P. V., Madveiko, C. I., et al., “Information technology in the diagnosis of obstructive sleep apnea syndrome,” Big Data and Advanced Analytics, No. 6-3, 362-369 (2020).
Zuev, A. L., Sudakov, A. I., and Shakirov, N. V., A Method of Impedance Spirography for Studying the Dynamics of Human Respiratory Functions and a Programmable System for its Implementation [in Russian], Patent No. 2682936, Published March 22, 2019; Byul. No. 9.
Malyugin, D. A., Klyukin, A. A., and Taratuta, R. V., “The use of spirography for assessing the external respiratory apparatus in patients after COVID-19 (clinical case review),” Molodezh. Innovats. Vestn., 10, No. S1, 157-159 (2021).
Cherkashin, D. V., Sharova, N. V., and Kuchmin, A. N., Spirography in Clinical Practice. A Textbook [in Russian], Svistov, A (ed.), Polytechnic Press, St. Petersburg (2019).
Kurgalin, S. D., Zalygaeva, M. E., and Maksimov, A. V., “Application of a spirographic human-machine interface in medicine,” in Proc. Int. Conf. “Modern Methods for Theories of Boundary Value Problems” [in Russian], (2015), pp. 124-125.
A Respiratory Rate Sensor [in Russian]; https://www.medius.ru/catalog/uchebnye_klassy/kabinet_biologii/programmno_tsifrovoy_izmeritelnyy_kompleks/datchik_chastoty_dykhaniya_tsifrovoy.html (accessed December 7, 2021).
Releon Respiratory Rate Sensor [in Russian]; https://rl.ru/products/sensors/datchik-chastoty-dykhaniya/ (accessed December 7, 2021).
PASCO Digital Breathing Rate Sensor [in Russian]; https://bazis-ufa.ru/catalog/4946.html (accessed December 15, 2021).
A Digital USB Respiratory Rate Sensor [in Russian]; http://lmicro.ru/index.php?page_id = 2 (accessed December 22, 2021).
The GDX-RB Contactless Respiratory Belt [in Russian]; https://www.vernier.com/product/go-direct-respiration-belt/ (accessed December 22, 2021).
Author information
Authors and Affiliations
Corresponding author
Additional information
Translated from Meditsinskaya Tekhnika, Vol. 56, No. 4, Jul.-Aug., 2022, pp. 49-52.
Rights and permissions
Springer Nature or its licensor (e.g. a society or other partner) holds exclusive rights to this article under a publishing agreement with the author(s) or other rightsholder(s); author self-archiving of the accepted manuscript version of this article is solely governed by the terms of such publishing agreement and applicable law.
About this article
Cite this article
Varlamova, N.V., Komlev, A.E., Potapov, P.K. et al. Recording Methods and the Capabilities of Modern Respiratory Rate Monitoring Devices (literature review). Biomed Eng 56, 286–290 (2022). https://doi.org/10.1007/s10527-022-10221-3
Received:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10527-022-10221-3