Published on in Vol 5, No 7 (2017): July

Estimating Heart Rate, Energy Expenditure, and Physical Performance With a Wrist Photoplethysmographic Device During Running

Estimating Heart Rate, Energy Expenditure, and Physical Performance With a Wrist Photoplethysmographic Device During Running

Estimating Heart Rate, Energy Expenditure, and Physical Performance With a Wrist Photoplethysmographic Device During Running

Journals

  1. WELK G, BAI Y, LEE J, GODINO J, SAINT-MAURICE P, CARR L. Standardizing Analytic Methods and Reporting in Activity Monitor Validation Studies. Medicine & Science in Sports & Exercise 2019;51(8):1767 View
  2. Thiebaud R, Funk M, Patton J, Massey B, Shay T, Schmidt M, Giovannitti N. Validity of wrist-worn consumer products to measure heart rate and energy expenditure. DIGITAL HEALTH 2018;4:205520761877032 View
  3. Müller A, Wang N, Yao J, Tan C, Low I, Lim N, Tan J, Tan A, Müller-Riemenschneider F. Heart Rate Measures From Wrist-Worn Activity Trackers in a Laboratory and Free-Living Setting: Validation Study. JMIR mHealth and uHealth 2019;7(10):e14120 View
  4. Santos-Gago J, Ramos-Merino M, Vallarades-Rodriguez S, Álvarez-Sabucedo L, Fernández-Iglesias M, García-Soidán J. Innovative Use of Wrist-Worn Wearable Devices in the Sports Domain: A Systematic Review. Electronics 2019;8(11):1257 View
  5. Henriksen A, Haugen Mikalsen M, Woldaregay A, Muzny M, Hartvigsen G, Hopstock L, Grimsgaard S. Using Fitness Trackers and Smartwatches to Measure Physical Activity in Research: Analysis of Consumer Wrist-Worn Wearables. Journal of Medical Internet Research 2018;20(3):e110 View
  6. Köteles F, Teufel B, Körmendi J, Ferentzi E, Szemerszky R. Cardioceptive accuracy is associated with arousal but not with valence and perceived exertion under physical load. Psychophysiology 2020;57(9) View
  7. Budig M, Höltke V, Keiner M. Accuracy of optical heart rate measurement and distance measurement of a fitness tracker and their consequential use in sports. German Journal of Exercise and Sport Research 2019;49(4):402 View
  8. De Ridder B, Van Rompaey B, Kampen J, Haine S, Dilles T. Smartphone Apps Using Photoplethysmography for Heart Rate Monitoring: Meta-Analysis. JMIR Cardio 2018;2(1):e4 View
  9. Navalta J, Montes J, Bodell N, Salatto R, Manning J, DeBeliso M, Boullosa D. Concurrent heart rate validity of wearable technology devices during trail running. PLOS ONE 2020;15(8):e0238569 View
  10. Mühlen J, Stang J, Lykke Skovgaard E, Judice P, Molina-Garcia P, Johnston W, Sardinha L, Ortega F, Caulfield B, Bloch W, Cheng S, Ekelund U, Brønd J, Grøntved A, Schumann M. Recommendations for determining the validity of consumer wearable heart rate devices: expert statement and checklist of the INTERLIVE Network. British Journal of Sports Medicine 2021;55(14):767 View
  11. Carrier B, Barrios B, Jolley B, Navalta J. Validity and Reliability of Physiological Data in Applied Settings Measured by Wearable Technology: A Rapid Systematic Review. Technologies 2020;8(4):70 View
  12. Levikari S, Immonen A, Kuisma M, Peltonen H, Silvennoinen M, Kyrolainen H, Silventoinen P. Improving Energy Expenditure Estimation in Wrist-Worn Wearables by Augmenting Heart Rate Data With Heat Flux Measurement. IEEE Transactions on Instrumentation and Measurement 2021;70:1 View
  13. Kachel E, Constantini K, Nachman D, Carasso S, Littman R, Eisenkraft A, Gepner Y. A Pilot Study of Blood Pressure Monitoring After Cardiac Surgery Using a Wearable, Non-invasive Sensor. Frontiers in Medicine 2021;8 View
  14. Jia Q, Yan Z, Wang Y. RETRACTED ARTICLE: A comparative study of different acceleration sensors in measuring energy consumption of human martial arts. EURASIP Journal on Advances in Signal Processing 2021;2021(1) View
  15. Gashi S, Min C, Montanari A, Santini S, Kawsar F. A multidevice and multimodal dataset for human energy expenditure estimation using wearable devices. Scientific Data 2022;9(1) View
  16. Wang Z, Zhang Q, Lan K, Yang Z, Gao X, Wu A, Xin Y, Zhang Z. Enhancing instantaneous oxygen uptake estimation by non-linear model using cardio-pulmonary physiological and motion signals. Frontiers in Physiology 2022;13 View
  17. Martín-Escudero P, Cabanas A, Dotor-Castilla M, Galindo-Canales M, Miguel-Tobal F, Fernández-Pérez C, Fuentes-Ferrer M, Giannetti R. Are Activity Wrist-Worn Devices Accurate for Determining Heart Rate during Intense Exercise?. Bioengineering 2023;10(2):254 View
  18. Romagnoli S, Ripanti F, Morettini M, Burattini L, Sbrollini A. Wearable and Portable Devices for Acquisition of Cardiac Signals while Practicing Sport: A Scoping Review. Sensors 2023;23(6):3350 View
  19. Carrier B, Helm M, Cruz K, Barrios B, Navalta J. Validation of Aerobic Capacity (VO2max) and Lactate Threshold in Wearable Technology for Athletic Populations. Technologies 2023;11(3):71 View
  20. Navalta J, Davis D, Malek E, Carrier B, Bodell N, Manning J, Cowley J, Funk M, Lawrence M, DeBeliso M. Heart rate processing algorithms and exercise duration on reliability and validity decisions in biceps-worn Polar Verity Sense and OH1 wearables. Scientific Reports 2023;13(1) View

Books/Policy Documents

  1. Charlton P, Marozas V. Photoplethysmography. View