An Overview of Wearable Piezoresistive and Inertial Sensors for Respiration Rate Monitoring

Fazio, Roberto De; Stabile, Marco; Vittorio, Massimo De; Velázquez, Ramiro; Visconti, Paolo

doi:10.3390/electronics10172178

Cited by 52 publications

(26 citation statements)

References 148 publications

(189 reference statements)

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“…The apparatus of the reference methods affects their usability and the feeling of confinement that they can produce would prevent their use in home monitoring conditions. As an alternative to the reference methods, other sensorization technologies have been used, such as accelerometry [ 37 ], inductance plethysmography, bioimpedance pneumography [ 38 ], measurement of temperature in the nose, photoplethysmography, or ultrasound [ 39 ]. However, the precision of these systems is not comparable to that of the reference methods, as in many cases they need to be placed in an uncomfortable or annoying position for the user.…”

Section: Discussionmentioning

confidence: 99%

A Sensor-Based mHealth Platform for Remote Monitoring and Intervention of Frailty Patients at Home

Calvillo-Arbizu

Naranjo-Hernández

Barbarov-Rostán

et al. 2021

IJERPH

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Frailty syndrome is an independent risk factor for serious health episodes, disability, hospitalization, falls, loss of mobility, and cardiovascular disease. Its high reversibility demands personalized interventions among which exercise programs are highly efficient to contribute to its delay. Information technology-based solutions to support frailty have been recently approached, but most of them are focused on assessment and not on intervention. This paper describes a sensor-based mHealth platform integrated in a service-based architecture inside the FRAIL project towards the remote monitoring and intervention of pre-frail and frail patients at home. The aim of this platform is constituting an efficient and scalable system for reducing both the impact of aging and the advance of frailty syndrome. Among the results of this work are: (1) the development of elderly-focused sensors and platform; (2) a technical validation process of the sensor devices and the mHealth platform with young adults; and (3) an assessment of usability and acceptability of the devices with a set of pre-frail and frail patients. After the promising results obtained, future steps of this work involve performing a clinical validation in order to quantify the impact of the platform on health outcomes of frail patients.

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Section: Discussionmentioning

confidence: 99%

A Sensor-Based mHealth Platform for Remote Monitoring and Intervention of Frailty Patients at Home

Calvillo-Arbizu

Naranjo-Hernández

Barbarov-Rostán

et al. 2021

IJERPH

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“…Compared with the stethoscope, miniaturized accelerometers can be taped onto the chest wall, integrated into belts, worn on the skin or mounted into clothing, guaranteeing continuous and unobtrusive cardio–respiratory monitoring. Therefore, they can be wearable sensors, as depicted in Figure 12 , for different applications and operative scenarios, thus, improving users’ life quality and preventing diseases [ 121 , 122 ].…”

Section: Sensing Devices In Healthcarementioning

confidence: 99%

Sensing Devices for Detecting and Processing Acoustic Signals in Healthcare

et al. 2022

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Acoustic signals are important markers to monitor physiological and pathological conditions, e.g., heart and respiratory sounds. The employment of traditional devices, such as stethoscopes, has been progressively superseded by new miniaturized devices, usually identified as microelectromechanical systems (MEMS). These tools are able to better detect the vibrational content of acoustic signals in order to provide a more reliable description of their features (e.g., amplitude, frequency bandwidth). Starting from the description of the structure and working principles of MEMS, we provide a review of their emerging applications in the healthcare field, discussing the advantages and limitations of each framework. Finally, we deliver a discussion on the lessons learned from the literature, and the open questions and challenges in the field that the scientific community must address in the near future.

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“…Therefore, respiratory rate is a crucial health parameter for constant monitoring of COVID-19 infections. Nowadays, wearable devices can provide continual respiratory rate monitoring through piezoresistive and inertial sensors [17]. Most strategies require the placement of sensors in the patient's chest, abdomen, neck, or nose.…”

Section: Respiratory Ratementioning

confidence: 99%

On revisiting vital signs IoT sensors for COVID-19 and long COVID-19 monitoring: a condensed updated review and future directions

et al. 2021

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Background: Although the world has been facing the COVID-19 pandemic for over a year, we understand that there are still some challenges in using Internet of Things (IoT) devices as allies in this fight. Among the main difficulties, we can mention the selection of appropriate devices and the correct measurement and subsequent analysis of previously obtained vital signs. Methods: In this context, we present a condensed compilation of IoT devices to monitor the vital signs often used to monitor COVID-19. We focus on easy-to-use devices currently available on the market to the general user. Also, the presented analysis is helpful for long COVID-19 monitoring, which is particularly useful to governments and hospitals to analyze eventual sequels on those citizens who tested positive beforehand. Results: The review resulted in 148 heterogeneous devices offering different capabilities. Our first contribution resides in detailing several aspects of each IoT device, indicating which are the most suitable for particular use-case situations. Moreover, our article introduces some challenges and insights into assembling a smart city composed of IoT devices. Conclusion: Here, technological trends such as Serverless computing, homomorphic cryptography, Federated Learning, Elixir programming language, Web Assembly, and vertical elasticity are discussed towards enabling vital sign-driven data capturing and processing. Although there are several IoT devices for health monitoring, there is still work to standardize data formats and APIs for data extraction.

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An Overview of Wearable Piezoresistive and Inertial Sensors for Respiration Rate Monitoring

Cited by 52 publications

References 148 publications

A Sensor-Based mHealth Platform for Remote Monitoring and Intervention of Frailty Patients at Home

A Sensor-Based mHealth Platform for Remote Monitoring and Intervention of Frailty Patients at Home

Sensing Devices for Detecting and Processing Acoustic Signals in Healthcare

On revisiting vital signs IoT sensors for COVID-19 and long COVID-19 monitoring: a condensed updated review and future directions

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