A Scalable Laser‐Centric Fabrication of an Epidermal Cardiopulmonary Patch

Rachim, Vega Pradana; Lee, Jina; Kim, Young‐Chan; Oh, Joosung; Jeong, Unyong; Park, Sung Min

doi:10.1002/admt.202200242

Cited by 7 publications

(6 citation statements)

References 53 publications

(66 reference statements)

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“…(B) Epidermal cardiopulmonary patch based on laser fabrication. The images were reprinted from Rachim et al [ 41 ]. (C) Air-silicon composite transducer (ASiT) for breathing pattern monitoring.…”

Section: Recent Progress In the Development Of Wearable Electronics F...mentioning

confidence: 99%

Section: Thoraxmentioning

confidence: 99%

“…Thorax-related wearable electronics, such as patches, chest belts, and brassieres, enable ECG recording, temperature measurement, sleep monitoring, posture analysis, and galvanic skin response (GSR) assessment [11,41,[44][45][46][47][48]. Figure 3B [41] shows a sensor designed for continuous monitoring of the cardiopulmonary biosignal via a CO 2 laser-based manufacturing process. The epidermal patch consisting of a mechanoacoustic sensor and electrophysiological electrodes provides advanced functionality through a gas-permeable and biocompatible layer.…”

Section: Thoraxmentioning

confidence: 99%

See 2 more Smart Citations

Advances and Opportunities of Mobile Health in the Postpandemic Era: Smartphonization of Wearable Devices and Wearable Deviceization of Smartphones

Hong

2024

JMIR Mhealth Uhealth

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Mobile health (mHealth) with continuous real-time monitoring is leading the era of digital medical convergence. Wearable devices and smartphones optimized as personalized health management platforms enable disease prediction, prevention, diagnosis, and even treatment. Ubiquitous and accessible medical services offered through mHealth strengthen universal health coverage to facilitate service use without discrimination. This viewpoint investigates the latest trends in mHealth technology, which are comprehensive in terms of form factors and detection targets according to body attachment location and type. Insights and breakthroughs from the perspective of mHealth sensing through a new form factor and sensor-integrated display overcome the problems of existing mHealth by proposing a solution of smartphonization of wearable devices and the wearable deviceization of smartphones. This approach maximizes the infinite potential of stagnant mHealth technology and will present a new milestone leading to the popularization of mHealth. In the postpandemic era, innovative mHealth solutions through the smartphonization of wearable devices and the wearable deviceization of smartphones could become the standard for a new paradigm in the field of digital medicine.

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Section: Recent Progress In the Development Of Wearable Electronics F...mentioning

confidence: 99%

Section: Thoraxmentioning

confidence: 99%

Section: Thoraxmentioning

confidence: 99%

See 1 more Smart Citation

Advances and Opportunities of Mobile Health in the Postpandemic Era: Smartphonization of Wearable Devices and Wearable Deviceization of Smartphones

Hong

2024

JMIR Mhealth Uhealth

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“…Soft strain sensors typically utilize changes in the electrical resistance or capacitance induced by deformation of their shape. Various piezoresistive-and piezocapacitive-type flexible strain sensors have been suggested using carbon nanotubes (CNTs) (7)(8)(9)(10)(11)(12), nanoparticles (13)(14)(15), nanowires (16)(17)(18), thin metal films (19)(20)(21), conductive polymers (22,23), or laser-induced graphene (LIG) (24)(25)(26)(27) as the conductive layer. Although these sensors differ in their materials and fabrication methods, they show large working ranges and high sensitivity compared with conventional metallic sensors.…”

Section: Introductionmentioning

confidence: 99%

Integrating computer vision and a strain sensor for human–machine interfaces with enhanced versatility and scalability

Park

Hong²,

Rachim

et al. 2023

Preprint

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Soft strain sensors play a major role in emerging human–machine interfaces. Most advanced soft strain sensors rely on nanotechnologies including microfabrication techniques. However, the low reproducibility of these sensors due to their highly specialized fabrication techniques, as well as their vulnerability to environmental noise and short lifetime are remaining challenges to limit their application under real-world conditions. Here, we propose a novel approach of integrating computer vision with streamlined microfabrication techniques to solve the aforementioned problems, which may be challenging to resolve using only nanotechnology. We developed a computer vision-based optical strain (CVOS) sensor system comprising an easily fabricated soft silicone substrate with micro-markers and a tiny camera as a highly sensitive marker detector. We then embedded an artificial intelligence (AI) model with an automated response correction algorithm for tracking markers and detecting the sensor state. The findings in this study confirmed that proposed CVOS sensor is a promising approach that facilitates the development of highly sensitive and versatile human–machine interfaces for long-term operation under real-world conditions.

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“…Monitoring various human vital signs offers valuable insights into pathological status, improving the accuracy and effectiveness of clinical diagnosis and treatment [1][2][3][4][5][6]. Especially in critical care management, monitoring cardiopulmonary functions is crucial for assessing disease status and determining appropriate treatment.…”

Section: Introductionmentioning

confidence: 99%

Rationale and Design of a Wearable Cardiopulmonary Monitoring System for Improving the Efficiency of Critical Care Monitoring

Lee,

Hwang,

Park

2023

Applied Sciences

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Despite the recent development of wearable cardiopulmonary monitoring devices and their necessity in clinical settings, the evidence regarding their application in real-world intensive care units (ICUs) is limited. These devices have notable problems, such as inefficient manufacturing and cumbersome hardware for medical staff and patients. In this study, we propose a simplified cardiopulmonary monitoring system and present a protocol for a single-center prospective study to evaluate the efficacy of the proposed system compared with those from the conventional monitoring system. The system was designed to continuously measure electrocardiogram, respiration rate, and oxygen saturation in a stand-alone device with an intuitive data visualization platform and automatic data collection. The accuracy of the data measured from the proposed device will be pre-validated by comparing them with those from the reference device. Medical staff from the St. Vincent’s Hospital ICU will complete a five-point Likert-type scale questionnaire regarding their experience with conventional ICU monitoring systems. The result will be compared with the second questionnaire conducted after deploying the system. Since this is a study proposal paper, we do not have any data on this study yet. However, compared with the conventional patient monitoring system, the proposed device should be a promising method to relieve medical staff fatigue and that of the patients who must wear and attach the monitoring device for a long time.

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A Scalable Laser‐Centric Fabrication of an Epidermal Cardiopulmonary Patch

Cited by 7 publications

References 53 publications

Advances and Opportunities of Mobile Health in the Postpandemic Era: Smartphonization of Wearable Devices and Wearable Deviceization of Smartphones

Advances and Opportunities of Mobile Health in the Postpandemic Era: Smartphonization of Wearable Devices and Wearable Deviceization of Smartphones

Integrating computer vision and a strain sensor for human–machine interfaces with enhanced versatility and scalability

Rationale and Design of a Wearable Cardiopulmonary Monitoring System for Improving the Efficiency of Critical Care Monitoring

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