This paper is in the following e-collection/theme issue:

Wearable Devices and Sensors (876) Hygiene and Infection Prevention (310) Fitness Trackers and Smart Pedometers/Accelerometers (558)

Published on in Vol 8, No 3 (2020): March

Preprints (earlier versions) of this paper are available at https://preprints.jmir.org/preprint/17001, first published .
Accurate Measurement of Handwash Quality Using Sensor Armbands: Instrument Validation Study

Accurate Measurement of Handwash Quality Using Sensor Armbands: Instrument Validation Study

Accurate Measurement of Handwash Quality Using Sensor Armbands: Instrument Validation Study

Authors of this article:

Chaofan Wang1 Author Orcid Image ;   Zhanna Sarsenbayeva1 Author Orcid Image ;   Xiuge Chen1 Author Orcid Image ;   Tilman Dingler1 Author Orcid Image ;   Jorge Goncalves1 Author Orcid Image ;   Vassilis Kostakos1 Author Orcid Image
Article Authors Cited by (21) Tweetations (3) Metrics

Journals

  1. Fagherazzi G, Goetzinger C, Rashid M, Aguayo G, Huiart L. Digital Health Strategies to Fight COVID-19 Worldwide: Challenges, Recommendations, and a Call for Papers. Journal of Medical Internet Research 2020;22(6):e19284 View
  2. Lin K, Wei C, Lai C, Cheng I, Chen N. Development of a badminton teaching system with wearable technology for improving students’ badminton doubles skills. Educational Technology Research and Development 2021;69(2):945 View
  3. Samyoun S, Shubha S, Sayeed Mondol M, Stankovic J. iWash: A smartwatch handwashing quality assessment and reminder system with real-time feedback in the context of infectious disease. Smart Health 2021;19:100171 View
  4. Herbert J, Horsham C, Ford H, Wall A, Hacker E. Deployment of a Smart Handwashing Station in a School Setting During the COVID-19 Pandemic: Field Study. JMIR Public Health and Surveillance 2020;6(4):e22305 View
  5. Zhang Y, Xue T, Liu Z, Chen W, Vanrumste B. Detecting hand washing activity among activities of daily living and classification of WHO hand washing techniques using wearable devices and machine learning algorithms. Healthcare Technology Letters 2021;8(6):148 View
  6. Hadian K, Fernie G, Roshan Fekr A. A New Performance Metric to Estimate the Risk of Exposure to Infection in a Health Care Setting: Descriptive Study. JMIR Formative Research 2022;6(2):e32384 View
  7. Xie T, Tian J, Ma L. A vision-based hand hygiene monitoring approach using self-attention convolutional neural network. Biomedical Signal Processing and Control 2022;76:103651 View
  8. Wang C, Jiang W, Yang K, Sarsenbayeva Z, Tag B, Dingler T, Goncalves J, Kostakos V. A System for Computational Assessment of Hand Hygiene Techniques. Journal of Medical Systems 2022;46(6) View
  9. Wang T, Xia J, Wu T, Ni H, Long E, Li J, Zhao L, Chen R, Wang R, Xu Y, Huang K, Lin H. Handwashing quality assessment via deep learning: a modelling study for monitoring compliance and standards in hospitals and communities. Intelligent Medicine 2022;2(3):152 View
  10. Wang C, Jiang W, Yang K, Yu D, Newn J, Sarsenbayeva Z, Goncalves J, Kostakos V. Electronic Monitoring Systems for Hand Hygiene: Systematic Review of Technology. Journal of Medical Internet Research 2021;23(11):e27880 View
  11. Lattanzi E, Calisti L, Freschi V. Unstructured Handwashing Recognition Using Smartwatch to Reduce Contact Transmission of Pathogens. IEEE Access 2022;10:83111 View
  12. Özakar R, Gedikli E. Evaluation of Hand Washing Procedure Using Vision-Based Frame Level and Spatio-Temporal Level Data Models. Electronics 2023;12(9):2024 View
  13. Wang C, Jiang W, Yang K, Sarsenbayeva Z, Tag B, Dingler T, Goncalves J, Kostakos V. Use of thermal imaging to measure the quality of hand hygiene. Journal of Hospital Infection 2023;139:113 View
  14. Asif S, Xu X, Zhao M, Chen X, Tang F, Zhu Y. ResMFuse-Net: Residual-based multilevel fused network with spatial–temporal features for hand hygiene monitoring. Applied Intelligence 2024;54(4):3606 View