Remote Patient Monitoring System Using Wireless Communication

Authors

  • Miss. Vrushali Pawar  (M. Tech), Department of Electrical Engineering, Assistant Professor, Gramin Technical & Management Campus Nanded, Maharashtra, India
  • Syed Zaker Hussain  Assistant Professor, Department of Electrical Engineering, Gramin Technical & Management Campus Nanded, Maharashtra, India

Keywords:

Neonate, Weight, GSM, LabVIEW

Abstract

In today’s world the health sector in the rural areas of our country are facing deplorable conditions. This scenario had worsen over the years. The age groups mostly affected are neonates because of their lower immunity are more prone to disease and infections. This has led to an increase in the neonatal mortality rate. Monitoring of vital parameters is essential in neonatal care. This paper, focuses on the development of a contactless measurement method for the body parameter of infants. The weight of the neonate is measured using load cell. The method proposed has been designed to verify the ability of the neonatal body parameters, to measure and correctly operate the process of weight on the neonate. The remote monitoring of the physiological parameter can be acquired by interfacing GSM (Global System for Mobile Communications) through LabVIEW to the primary health care hospital (Anganvadi). Patient monitoring systems measure either endlessly or at frequent intervals over time by the ASHA workers. So that they can travel to the particular site in consequential neonatal conditions and treat them efficiently without time straggle.

References

  1. Asada, H.H., et al., Mobile monitoring with wearable biosensor photo plethysmography Biosensors. Engg. in Med and Bio Magazine.
  2. Ming-Zher, P., N.C. Swenson, and R.W. Information Technology in Biomedicine science.
  3. Patel, review of wearable sensors and systems with application in Rehabilitation. Journal of neuro-engg and rehabilitation.
  4. Altini, M., J. Penders, and O. Amft. Personalizing energy expenditure estimation using a cardiorespiratory fitness predication. In Pervasive Computing Technologies for Healthcare.
  5. Flow Sensors and wearable in Biomedical Engineering. Available from: http://vista.ir/article/258815.
  6. Stuart, Tucker, Jessica Hanna, and Philipp Gutruf. "Wearable devices for continuous monitoring of biosignals: Challenges and opportunities." APL bioengineering 6.2 (2022). 
  7. Lin, Yuanjing, Mallika Bariya, and Ali Javey. "Wearable biosensors for body computing." Advanced Functional Materials (2021).
  8. Kim, Jayoung, Alan S. Campbell, Berta Esteban-Fernández de Ávila, and Joseph Wang. "Wearable biosensors for healthcare monitoring." Nature biotechnology (2019). [4] Song, Yu, Daniel Mukasa, Haixia Zhang, and Wei Gao. "Self-powered wearable biosensors." Accounts of Materials Research (2021).
  9. Yoon, Jinho, Hyeon-Yeol Cho, Minkyu Shin, Hye Kyu Choi, Taek Lee, and Jeong-Woo Choi. "Flexible electrochemical biosensors for healthcare monitoring." Journal of Materials Chemistry (2020).
  10. Ma, Yuan, Rongfeng Li, Jiaxin Lei, Milin Zhang, and Lan Yin. "Design of a Wireless Compact Implantable Electrochemical Biosensor System for Health Monitoring Application." IEEE International Conference on Integrated Circuits, Technologies and Applications (ICTA), 2020. 

International Journal of Scientific Research in Science, Engineering and Technology

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Published

2022-12-31

Issue

Volume 9, Issue 6, November-December-2022

Section

Research Articles

License

Copyright (c) IJSRSET

Creative Commons License

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

How to Cite

[1]
Miss. Vrushali Pawar, Syed Zaker Hussain "Remote Patient Monitoring System Using Wireless Communication" International Journal of Scientific Research in Science, Engineering and Technology (IJSRSET), Print ISSN : 2395-1990, Online ISSN : 2394-4099, Volume 9, Issue 6, pp.371-377, November-December-2022.