Ballistocardiogram signal processing: a review

Sadek, Ibrahim; Biswas, Jit; Abdulrazak, Bessam

doi:10.1007/s13755-019-0071-7

Cited by 139 publications

(112 citation statements)

References 102 publications

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“…On the one hand, there are some standard features that these sensors claim to measure, such as heart rate, respiration, sleep and wake-up time, and sleep interruptions. There are several publications in the existing literature that can support these claims, as mentioned in [20].…”

Section: Iot Sleep Trackersmentioning

confidence: 89%

“…These sensors technologies are preferred than those popular sensors (e.g., ECG) when we are considering long-term (trend over time, early detection and intervention by sending alarms to family members or caregivers through well-designed user interfaces), mobile, convenient and practical (aging-in-place, senior activity centers). However, in critical situations, gold-standard methods should be considered [20].…”

Section: Iot Sleep Trackersmentioning

confidence: 99%

See 1 more Smart Citation

Privacy and Security of IoT Based Healthcare Systems: Concerns, Solutions, and Recommendations

Sadek

Rehman

Codjo

et al. 2019

How AI Impacts Urban Living and Public Health

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Although emerging IoT paradigms in sleep tracking have a substantial contribution to enhancing current healthcare systems, there are several privacy and security considerations that end-users need to consider. End-users can be susceptible to malicious threats when they allow permission to potentially vulnerable or leaky third-party apps. Since the data is migrated to the cloud, it goes over insecure communication channels, all of which have their security concerns. Moreover, there are alternative data violation concerns when the data projects into the proprietor's cloud storage facility. In this study, we present some of the existing IoT sleep trackers, also we discuss the most common features associated with these sleep trackers. As the majority of end-users are not aware of the privacy and security concerns affiliated with emerging IoT sleep trackers. We review existing solutions that can apply to IoT sleep tracker architecture. Also, we describe a deployed IoT platform that can address these concerns. Finally, we provide some of the recommendations to end-users and service providers to ensure a safer approach while leveraging the IoT sleep tracker in caregiving. This incorporates recommendations for software updates, awareness programs, software installation, and social engineering.

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Section: Iot Sleep Trackersmentioning

confidence: 89%

Section: Iot Sleep Trackersmentioning

confidence: 99%

Privacy and Security of IoT Based Healthcare Systems: Concerns, Solutions, and Recommendations

Sadek

Rehman

Codjo

et al. 2019

How AI Impacts Urban Living and Public Health

Self Cite

View full text Add to dashboard Cite

show abstract

“…Under real life conditions it would be preferable to do this online from automated analysis of vital signs recorded with minimally obtrusive sensor systems. In fact, several approaches have already been explored (Canisius and Penzel, 2007;Romine et al, 2019;Sadek et al, 2019) to achieve this. Various medical applications are easy to imagine, but perhaps more important are practical applications in which vigilance plays an important role.…”

Section: Introductionmentioning

confidence: 99%

Heart Rhythm Analyzed via Shapelets Distinguishes Sleep From Awake

et al. 2020

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Automatically determining when a person falls asleep from easily available vital signals is important, not just for medical applications but also for practical ones, such as traffic safety or smart homes. Heart dynamics and respiration cycle couple differently during sleep and awake. Specifically, respiratory modulation of heart rhythm or respiratory sinus arrhythmia (RSA) is more prominent during sleep, as both sleep and RSA are connected to strong vagal activity. The onset of sleep can be recognized or even predicted as the increase of cardio-respiratory coupling. Here, we employ this empirical fact to design a method for detecting the change of consciousness status (sleep/awake) based only on heart rate variability (HRV) data. Our method relies on quantifying the (self)similarity among shapelets-short chunks of HRV time series-whose "shapes" are related to the respiration cycle. To test our method, we examine the HRV data of 75 healthy individuals recorded with microsecond precision. We find distinctive patterns stable across age and sex, that are not only indicative of sleep and awake, but allow to pinpoint the change from awake to sleep almost immediately. More systematic analysis along these lines could lead to a reliable prediction of sleep.

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“…Non-contact sensors have been developed using under-the-mattress piezoelectric-, strain gauge-, or radio frequency-based sensing, and are highly sensitive to dynamic respiratory and ballistocardiographic signals (16,17). However, they are sensitive to subject-sensor proximity and orientation and are unable to reliably differentiate signals from individuals who share a bed with a partner or pet (18)(19)(20).…”

Section: Introductionmentioning

confidence: 99%

Bedscales: A non-contact adherence-independent multi-person sensor for longitudinal physiologic monitoring in the home bed

Harrington

Wei

Hernandez-Pacheco

et al. 2020

Preprint

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Home health monitoring technologies promise to improve care and reduce costs, yet they are limited by the need for adherence to self-monitoring, usage of an app, or application of a wearable. While implantable sensors overcome the adherence barrier, they are expensive and require invasive procedures. Here, we describe a non-invasive, non-contact, adherence-independent sensor, that when placed beneath the legs of a patient's home bed, longitudinally monitors total body weight, detailed respiratory signals, and ballistocardiograms for months, without requiring any active patient participation.Accompanying algorithms demix weight and respiratory signals when the bed is shared by a partner or a pet. Validation studies during overnight clinical sleep studies exhibit quantitative equivalence to commercial sensors and allow discrimination of obstructive and central sleep apneas. In-home studies discriminate atrial fibrillation from normal sinus rhythm. To demonstrate real-world feasibility, we performed 3 months of continuous in-home monitoring in a patient with heart failure as he awaited and recovered from coronary artery bypass surgery. By overcoming the adherence barrier, Bedscales has the potential to create a multidimensional picture of chronic disease, learn signatures of impending hospitalization, and enable optimization of care in the home.

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Ballistocardiogram signal processing: a review

Cited by 139 publications

References 102 publications

Privacy and Security of IoT Based Healthcare Systems: Concerns, Solutions, and Recommendations

Privacy and Security of IoT Based Healthcare Systems: Concerns, Solutions, and Recommendations

Heart Rhythm Analyzed via Shapelets Distinguishes Sleep From Awake

Bedscales: A non-contact adherence-independent multi-person sensor for longitudinal physiologic monitoring in the home bed

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