Can mHealth Technology Help Mitigate the Effects of the COVID-19 Pandemic?

Adans-Dester, Catherine; Bamberg, Stacy J. Morris; Bertacchi, Francesco; Caulfield, Brian; Chappie, Kara; Demarchi, Danilo; Erb, Michael Kelley; Estrada, Juan; Fabara, Eric; Freni, Michael; Friedl, Karl E.; Ghaffari, Roozbeh; Gill, Geoffrey; Greenberg, Mark S.; Hoyt, Reed W.; Jovanov, Emil; Kanzler, Christoph M.; Katabi, Dina; Kernan, Meredith; Kigin, Colleen M.; Lee, Sunghoon I.; Leonhardt, Steffen; Lovell, Nigel H.; Mantilla, J. A.; McCoy, Thomas H.; Luo, Nell Meosky; Miller, Glenn A.; Moore, John T.; O’Keeffe, Derek; Palmer, Jeffrey S.; Parisi, Federico; Patel, Shyamal; Po, Jack; Pugliese, Benito L.; Quatieri, Thomas F.; Rahman, Tauhidur; Ramasarma, Nathan; Rogers, John A.; Ruiz–Esparza, Guillermo U.; Sapienza, Stefano; Schiurring, Gregory; Schwamm, Lee H; Shafiee, Hadi; Silacci, Sara; Sims, Nathaniel M.; Talkar, Tanya; Tharion, William J.; Toombs, James A.; Uschnig, Christopher; Vergara‐Diaz, Gloria; Wacnik, Paul W.; Wang, May D.; Welch, James P.; Williamson, Lina; Zafonte, Ross; Zai, Adrian H.; Zhang, Yuan-Ting; Tearney, Guillermo J.; Ahmad, Rushdy; Walt, David R.; Bonato, Paolo

doi:10.1109/ojemb.2020.3015141

Cited by 75 publications

(61 citation statements)

References 46 publications

(49 reference statements)

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“…If specificity versus flu and other respiratory viruses cannot be demonstrated, early-warning systems triggered on wearable data should be considered as more non-specific “infection screening,” and therefore be coupled with appropriate confirmatory testing mechanisms that can help to quickly relieve self-imposed quarantine of non-COVID-19 infections. 17 , 18 …”

Section: Discussionmentioning

confidence: 99%

“… 14 , 16 Therefore, wearables could potentially support use cases, such as return to work and college reopening, 18 where most of the cohort can be asked to wear the sensors frequently. 17 To better understand feasibility, however, further research is needed. First, it is important to accurately quantify the sensitivity of wearable-based alert systems in prospective validation, and especially for asymptomatic/pre-symptomatic patients (who collectively seem to be responsible for more than 40% of the total infections).…”

Section: Discussionmentioning

confidence: 99%

“…In addition to being used in aggregate form for population-level hotspot detection, PGHD is also being proposed as a candidate for individual-level applications, such as to support detection and monitoring of COVID-19 and other respiratory viruses. 14 , 15 , 16 , 17 , 18 …”

Section: Introductionmentioning

confidence: 99%

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Characterizing COVID-19 and Influenza Illnesses in the Real World via Person-Generated Health Data

et al. 2021

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Characterizing COVID-19 and Influenza Illnesses in the Real World via Person-Generated Health Data Highlights d We use data from smartphones and wearables from~7,000 people to compare flu and COVID-19 d While symptoms have some overlap, patients report longer COVID-19 illnesses than flu d Elevated resting heart rate measures are more frequent around illness symptoms onset d It is important to consider flu as a confounder in COVID-19 real-world studies

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Characterizing COVID-19 and Influenza Illnesses in the Real World via Person-Generated Health Data

et al. 2021

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“…59 Additionally, monitoring physiological signals of patients continuously may offer a deeper understanding of the development of COVID-19 infections as well as the process of recovery or potential long-term sequelae. 60 , 61 Population level mHealth monitoring will unveil the true incidence among communities, guide local reopening policies, and provide an early warning system to help reduce viral transmission and mortality rate. In this section, we summarize the clinical translation of physiological biomarkers that are strongly related with COVID-19 symptoms, introduce the wearable sensor platforms developed to track them, and then discuss the current progress of using these wearable vital sign monitors and the collected relevant data for COVID-19 monitoring and management.…”

Section: Telemedicine Tools For Vital Sign Monitoring and Contact Tramentioning

confidence: 99%

Emerging Telemedicine Tools for Remote COVID-19 Diagnosis, Monitoring, and Management

et al. 2020

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The management of the COVID-19 pandemic has relied on cautious contact tracing, quarantine, and sterilization protocols while we await a vaccine to be made widely available. Telemedicine or mobile health (mHealth) is well-positioned during this time to reduce potential disease spread and prevent overloading of the healthcare system through at-home COVID-19 screening, diagnosis, and monitoring. With the rise of mass-fabricated electronics for wearable and portable sensors, emerging telemedicine tools have been developed to address shortcomings in COVID-19 diagnostics, monitoring, and management. In this Perspective, we summarize current implementations of mHealth sensors for COVID-19, highlight recent technological advances, and provide an overview on how these tools may be utilized to better control the COVID-19 pandemic.

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“…Nowadays, mobile devices in all everyday tasks are increasing, and their usage allows users to stay connected and communicate with ease [1,2]. The current pandemic situation discourages social interaction and personal contacts, enhancing the role of technology in promoting social distancing while being connected [3,4] and active, avoiding sedentary positions [5,6]. Several studies use mobile devices to identify human activities and create a personal agenda to track people [7][8][9][10].…”

Section: Introductionmentioning

confidence: 99%

Homogeneous Data Normalization and Deep Learning: A Case Study in Human Activity Classification

et al. 2020

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One class of applications for human activity recognition methods is found in mobile devices for monitoring older adults and people with special needs. Recently, many studies were performed to create intelligent methods for the recognition of human activities. However, the different mobile devices in the market acquire the data from sensors at different frequencies. This paper focuses on implementing four data normalization techniques, i.e., MaxAbsScaler, MinMaxScaler, RobustScaler, and Z-Score. Subsequently, we evaluate the impact of the normalization algorithms with deep neural networks (DNN) for the classification of the human activities. The impact of the data normalization was counterintuitive, resulting in a degradation of performance. Namely, when using the accelerometer data, the accuracy dropped from about 79% to only 53% for the best normalization approach. Similarly, for the gyroscope data, the accuracy without normalization was about 81.5%, whereas with the best normalization, it was only 60%. It can be concluded that data normalization techniques are not helpful in classification problems with homogeneous data.

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Can mHealth Technology Help Mitigate the Effects of the COVID-19 Pandemic?

Cited by 75 publications

References 46 publications

Characterizing COVID-19 and Influenza Illnesses in the Real World via Person-Generated Health Data

Characterizing COVID-19 and Influenza Illnesses in the Real World via Person-Generated Health Data

Emerging Telemedicine Tools for Remote COVID-19 Diagnosis, Monitoring, and Management

Homogeneous Data Normalization and Deep Learning: A Case Study in Human Activity Classification

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