Assessment of physiological signs associated with COVID-19 measured using wearable devices

Natarajan, Aravind; Su, Hao-Wei; Heneghan, Conor

doi:10.1038/s41746-020-00363-7

Cited by 177 publications

(236 citation statements)

References 22 publications

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“…Several recent works have explored use of wearable data, including RHR, to detect symptoms of COVID before they appear toward applications that can prompt users to intervene in pre-symptomatic disease phases and curb the spread of infection (e.g., self-quarantine while waiting for a confirmatory test). 22 , 23 , 24 , 35 While these systems have shown moderate discriminative ability between COVID-19 patients versus healthy persons in retrospective cohorts, our findings suggest that the specificity of those systems should also be measured as compared with flu patients, as they will be the overwhelming majority as flu season starts. 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.…”

Section: Discussionmentioning

confidence: 70%

“…In the specific context of COVID-19, our findings support the case made by recent work that data from wearable sensors may provide low-sensitivity testing capability with daily frequency. 22 , 23 , 24 , 35 Low-sensitivity/high-frequency testing when combined with a low-delay confirmatory testing strategy has been shown by computation models to significantly reduce prevalence of spreading with minimal burden on pre-emptive quarantine for false positives. 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.…”

Section: Discussionmentioning

confidence: 99%

“…Along these lines, several efforts are currently underway to explore the potential of using wearable technology to detect COVID-19 onset, 19 , 20 , 21 and preliminary results have shown that wearables may be able to predict COVID-19 symptoms before onset, 22 , 23 , 24 with potential application to large-scale, low-sensitivity/high-frequency testing to enable reopening in the wait for a vaccine. 14 , 15 , 16 …”

Section: Introductionmentioning

confidence: 99%

“…However, the lack of a canonical COVID-19 symptom presentation, including how symptoms progress over time, 24 , 25 undermines our ability to track, predict, and control disease progression and manage critical care. In addition, to evaluate performances of any detection system, being that for individual-level early warnings or population-level hotspot detection, it is crucial to compare and contrast symptoms, behavioral, and physiological manifestation with other ILIs, especially flu.…”

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: 70%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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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“…It shows that a combination of increased resting heart rate (HR), decreased physical activity, and increased amount of sleep hours (so, both physiological and behavioral data) may be a crisp sign of the onset of a viral illness, like (in particular) COVID-19 but also other infections. A project like this (which may be considered a sort of digital clinical trial [ 7 ]) – also together with other studies collecting physiological data from thousands of citizens [ 8 , 9 ] – allows scientists to merge data from worldwide populations, thus properly feeding artificial intelligence (AI) algorithms [ 10 ] to identify possible patterns able to discriminate between healthy and sick people. The project potential impact could be significant in terms of the early detection of possible risk, hence limiting the number of contacts and hindering the virus diffusion.…”

Section: Resultsmentioning

confidence: 99%

Wearable devices as a valid support for diagnostic excellence: lessons from a pandemic going forward

et al. 2021

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Today, the use of wearable devices is continuously increasing with many different application fields. Their low-cost and wide availability make these devices proper instruments for long-term monitoring, potentially useful to detect physiological changes related to influenza or other viruses. The relevance of this aspect and the impact of such technology have become evident particularly in the last year, during COVID-19 emergency; (big) data from wearable devices (already worn by many citizens) together with artificial intelligence techniques gave birth to specific studies dedicated to quickly identify patterns discriminating between healthy and infected people. These evaluations are made on the basis of parameters measured by these devices, among which heart rate, physical activity, and sleep seem to play a dominant role. This could be extremely significant in terms of early detection and limit of contagion risk. However, there is still a lot of research to be conducted in terms of measurement accuracy, data management (privacy and security issues), and results exploitation, in order to reach an accurate and reliable solution helping the whole healthcare system particularly in epidemic events, such as the SARS-CoV-2 pandemic.

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Assessment of the Feasibility of Using Noninvasive Wearable Biometric Monitoring Sensors to Detect Influenza and the Common Cold Before Symptom Onset

et al. 2021

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IMPORTANCE Currently, there are no presymptomatic screening methods to identify individuals infected with a respiratory virus to prevent disease spread and to predict their trajectory for resource allocation.OBJECTIVE To evaluate the feasibility of using noninvasive, wrist-worn wearable biometric monitoring sensors to detect presymptomatic viral infection after exposure and predict infection severity in patients exposed to H1N1 influenza or human rhinovirus. DESIGN, SETTING, AND PARTICIPANTSThe cohort H1N1 viral challenge study was conducted during 2018; data were collected from September 11, 2017, to May 4, 2018. The cohort rhinovirus challenge study was conducted during 2015; data were collected from September 14 to 21, 2015. A total of 39 adult participants were recruited for the H1N1 challenge study, and 24 adult participants were recruited for the rhinovirus challenge study. Exclusion criteria for both challenges included chronic respiratory illness and high levels of serum antibodies. Participants in the H1N1 challenge study were isolated in a clinic for a minimum of 8 days after inoculation. The rhinovirus challenge took place on a college campus, and participants were not isolated.EXPOSURES Participants in the H1N1 challenge study were inoculated via intranasal drops of diluted influenza A/California/03/09 (H1N1) virus with a mean count of 10 6 using the median tissue culture infectious dose (TCID50) assay. Participants in the rhinovirus challenge study were inoculated via intranasal drops of diluted human rhinovirus strain type 16 with a count of 100 using the TCID50 assay. MAIN OUTCOMES AND MEASURESThe primary outcome measures included cross-validated performance metrics of random forest models to screen for presymptomatic infection and predict infection severity, including accuracy, precision, sensitivity, specificity, F1 score, and area under the receiver operating characteristic curve (AUC). RESULTSA total of 31 participants with H1N1 (24 men [77.4%]; mean [SD] age, 34.7 [12.3] years) and 18 participants with rhinovirus (11 men [61.1%]; mean [SD] age, 21.7 [3.1] years) were included in the analysis after data preprocessing. Separate H1N1 and rhinovirus detection models, using only data on wearble devices as input, were able to distinguish between infection and noninfection with accuracies of up to 92% for H1N1 (90% precision, 90% sensitivity, 93% specificity, and 90% F1 score, 0.85 [95% CI, 0.70-1.00] AUC) and 88% for rhinovirus (100% precision, 78% sensitivity, 100% specificity, 88% F1 score, and 0.96 [95% CI, 0.85-1.00] AUC). The infection severity prediction model was able to distinguish between mild and moderate infection 24 hours prior to symptom onset with an accuracy of 90% for H1N1 (88% precision, 88% sensitivity, 92% specificity, 88% F1 (continued) Key Points Question Can noninvasive, wrist-worn wearable devices detect acute viral respiratory infection and predict infection severity before symptom onset? Findings In a cohort study of 31 participants inoculated with H1N1 and 18participants wi...

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Assessment of physiological signs associated with COVID-19 measured using wearable devices

Cited by 177 publications

References 22 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

Wearable devices as a valid support for diagnostic excellence: lessons from a pandemic going forward

Assessment of the Feasibility of Using Noninvasive Wearable Biometric Monitoring Sensors to Detect Influenza and the Common Cold Before Symptom Onset

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