Wearable Health Devices—Vital Sign Monitoring, Systems and Technologies

Dias, Duarte; Cunha, João Paulo Silva

doi:10.3390/s18082414

Cited by 655 publications

(414 citation statements)

References 87 publications

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“…During the last two decades, rapid developments in battery technology, low-power embedded processors, and integrated sensors have led to technologies being increasingly wearable. Current generations of wearable, noninvasive biosignal acquisition systems can be roughly categorized by their runtime and the physiological parameters of interest [10], as well as their implementation, biosignal selection, and whether or not they are organized into networks [11]. The physiological parameters addressed are oriented on the identified large health issues of the present and future.…”

Section: Clinical Background and State-of-the-artmentioning

confidence: 99%

Wearable Cardiorespiratory Monitoring Employing a Multimodal Digital Patch Stethoscope: Estimation of ECG, PEP, LVET and Respiration Using a 55 mm Single-Lead ECG and Phonocardiogram

Klum

Tigges

Pielmuş

et al. 2020

Sensors

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Cardiovascular diseases are the main cause of death worldwide, with sleep disordered breathing being a further aggravating factor. Respiratory illnesses are the third leading cause of death amongst the noncommunicable diseases. The current COVID-19 pandemic, however, also highlights the impact of communicable respiratory syndromes. In the clinical routine, prolonged postanesthetic respiratory instability worsens the patient outcome. Even though early and continuous, long-term cardiorespiratory monitoring has been proposed or even proven to be beneficial in several situations, implementations thereof are sparse. We employed our recently presented, multimodal patch stethoscope to estimate Einthoven electrocardiogram (ECG) Lead I and II from a single 55 mm ECG lead. Using the stethoscope and ECG subsystems, the pre-ejection period (PEP) and left ventricular ejection time (LVET) were estimated. ECG-derived respiration techniques were used in conjunction with a novel, phonocardiogram-derived respiration approach to extract respiratory parameters. Medical-grade references were the SOMNOmedics SOMNO HD TM and Osypka ICON-Core TM . In a study including 10 healthy subjects, we analyzed the performances in the supine, lateral, and prone position. Einthoven I and II estimations yielded correlations exceeding 0.97. LVET and PEP estimation errors were 10% and 21%, respectively. Respiratory rates were estimated with mean absolute errors below 1.2 bpm, and the respiratory signal yielded a correlation of 0.66. We conclude that the estimation of ECG, PEP, LVET, and respiratory parameters is feasible using a wearable, multimodal acquisition device and encourage further research in multimodal signal fusion for respiratory signal estimation.

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Section: Clinical Background and State-of-the-artmentioning

confidence: 99%

Wearable Cardiorespiratory Monitoring Employing a Multimodal Digital Patch Stethoscope: Estimation of ECG, PEP, LVET and Respiration Using a 55 mm Single-Lead ECG and Phonocardiogram

Klum

Tigges

Pielmuş

et al. 2020

Sensors

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“…There has been a growing demand for the development of smart monitoring systems to collect, quantify, and qualify information associated with the human body . The monitoring systems are equipped with smart electronic sensors that are either worn externally or implanted into the body .…”

Section: Cnt Yarn As An Electronic Sensormentioning

confidence: 99%

“…Temperature sensors can be classified into several types based on the material and their operation and include thermistors (temperature‐sensitive resistors) and thermocouples (voltage generating metal junctions) and silicon‐based sensors 2b,21c,31. Many types of temperature sensors are used to detect the temperature by sensing changes in electrical resistance of the thermosensitive materials such as ceramics, polymers, and metals 2b,21c,31. Importantly, new types of temperature sensor have attempted to monitor the body temperature in the real‐time through the wearable sensor 2b,21c,31…”

Section: Cnt Yarn As An Electronic Sensormentioning

confidence: 99%

“…Many types of temperature sensors are used to detect the temperature by sensing changes in electrical resistance of the thermosensitive materials such as ceramics, polymers, and metals 2b,21c,31. Importantly, new types of temperature sensor have attempted to monitor the body temperature in the real‐time through the wearable sensor 2b,21c,31…”

Section: Cnt Yarn As An Electronic Sensormentioning

confidence: 99%

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Carbon Nanotube Yarn for Fiber‐Shaped Electrical Sensors, Actuators, and Energy Storage for Smart Systems

et al. 2019

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The ORCID identification number(s) for the author(s) of this article can be found under https://doi.org/10.1002/adma.201902670. Smart systems are those that display autonomous or collaborative functionalities, and include the ability to sense multiple inputs, to respond with appropriate operations, and to control a given situation. In certain circumstances, it is also of great interest to retain flexible, stretchable, portable, wearable, and/or implantable attributes in smart electronic systems. Among the promising candidate smart materials, carbon nanotubes (CNTs) exhibit excellent electrical and mechanical properties, and structurally fabricated CNT-based fibers and yarns with coil and twist further introduce flexible and stretchable properties. A number of notable studies have demonstrated various functions of CNT yarns, including sensors, actuators, and energy storage. In particular, CNT yarns can operate as flexible electronic sensors and electrodes to monitor strain, temperature, ionic concentration, and the concentration of target biomolecules. Moreover, a twisted CNT yarn enables strong torsional actuation, and coiled CNT yarns generate large tensile strokes as an artificial muscle. Furthermore, the reversible actuation of CNT yarns can be used as an energy harvester and, when combined with a CNT supercapacitor, has promoted the next-generation of energy storage systems. Here, progressive advances of CNT yarns in electrical sensing, actuation, and energy storage are reported, and the future challenges in smart electronic systems considered.

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“…The evolution of this medical device resulted in an integrated smart pressure sensor(Dias and Paulo Silva, 2018). Moreover, blood oxygen saturation, a valuable vital parameter, can nowadays be easily measured through the exploitation of PPG technology.…”

mentioning

confidence: 99%

Biosensors and Internet of Things in smart healthcare applications: challenges and opportunities

Pateraki

Fysarakis²,

Sakkalis

et al. 2020

Wearable and Implantable Medical Devices

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Wearable Health Devices—Vital Sign Monitoring, Systems and Technologies

Cited by 655 publications

References 87 publications

Wearable Cardiorespiratory Monitoring Employing a Multimodal Digital Patch Stethoscope: Estimation of ECG, PEP, LVET and Respiration Using a 55 mm Single-Lead ECG and Phonocardiogram

Wearable Cardiorespiratory Monitoring Employing a Multimodal Digital Patch Stethoscope: Estimation of ECG, PEP, LVET and Respiration Using a 55 mm Single-Lead ECG and Phonocardiogram

Carbon Nanotube Yarn for Fiber‐Shaped Electrical Sensors, Actuators, and Energy Storage for Smart Systems

Biosensors and Internet of Things in smart healthcare applications: challenges and opportunities

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