mHealth hyperspectral learning for instantaneous spatiospectral imaging of hemodynamics

Ji, Yuhyun; Park, Sang Mok; Kwon, Semin; Leem, Jung Woo; Nair, Vidhya Vijayakrishnan; Tong, Yunjie; Kim, Young L.

doi:10.1093/pnasnexus/pgad111

Cited by 7 publications

(5 citation statements)

References 98 publications

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“…Hyperspectral line-scan images (hypercube) of human skin were obtained to study inflammation, which is commonly characterized by erythema and changes in hemoglobin concentrations, following skin irritation. , A monochrome camera (GS3-U3-120S6M-C; FLIR) with a slit width of 23 μm and groove density of 150 mm –1 was used for imaging, and an LED light source with a color temperature of 6500 K (D65) was employed for illumination. Spectral calibration of the spectrograph was performed using a xenon calibration light source that emitted multiple narrow peaks at specific wavelengths.…”

Section: Methodsmentioning

confidence: 99%

Rapid Self-Healing Hydrogel with Ultralow Electrical Hysteresis for Wearable Sensing

Hong,

Park,

Lee

et al. 2024

ACS Sens.

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Self-healing hydrogels are in high demand for wearable sensing applications due to their remarkable deformability, high ionic and electrical conductivity, selfadhesiveness to human skin, as well as resilience to both mechanical and electrical damage. However, these hydrogels face challenges such as delayed healing times and unavoidable electrical hysteresis, which limit their practical effectiveness. Here, we introduce a selfhealing hydrogel that exhibits exceptionally rapid healing with a recovery time of less than 0.12 s and an ultralow electrical hysteresis of less than 0.64% under cyclic strains of up to 500%. This hydrogel strikes an ideal balance, without notable trade-offs, between properties such as softness, deformability, ionic and electrical conductivity, selfadhesiveness, response and recovery times, durability, overshoot behavior, and resistance to nonaxial deformations such as twisting, bending, and pressing. Owing to this unique combination of features, the hydrogel is highly suitable for long-term, durable use in wearable sensing applications, including monitoring body movements and electrophysiological activities on the skin.

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Section: Methodsmentioning

confidence: 99%

Rapid Self-Healing Hydrogel with Ultralow Electrical Hysteresis for Wearable Sensing

Hong,

Park,

Lee

et al. 2024

ACS Sens.

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“…This method involves detecting the increasing concentration of hemoglobin on the surface of the skin when inflammation occurs, in order to quantify the inflammation caused by irritants . Line-scan hyperspectral imaging technology was employed as demonstrated in previous research . Hyperspectral images (hypercubes) of human skin were obtained using a monochrome camera (GS3-U3-120S6M-C; FLIR), with a slit width of 23 μm and a groove density of 150 mm –1 .…”

Section: Methodsmentioning

confidence: 99%

“…57 Line-scan hyperspectral imaging technology was employed as demonstrated in previous research. 58 Hyperspectral images (hypercubes) of human skin were obtained using a monochrome camera (GS3-U3-120S6M-C; FLIR), with a slit width of 23 μm and a groove density of 150 mm −1 . An LED light source with a color temperature of 6,500 K (D65) was used for illumination, and spectral calibration of the spectrograph was performed using a xenon calibration light source that emitted multiple narrow peaks at specific wavelengths.…”

Section: Continuity Equationmentioning

confidence: 99%

In Situ Spray Polymerization of Conductive Polymers for Personalized E-textiles

Chang,

Akin,

Cho

et al. 2023

ACS Nano

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E-textiles, also known as electronic textiles, seamlessly merge wearable technology with fabrics, offering comfort and unobtrusiveness and establishing a crucial role in health monitoring systems. In this field, the integration of custom sensor designs with conductive polymers into various fabric types, especially in large areas, has presented significant challenges. Here, we present an innovative additive patterning method that utilizes a dual-regime spray system, eliminating the need for masks and allowing for the programmable inscription of sensor arrays onto consumer textiles. Unlike traditional spray techniques, this approach enables in situ, on-the-fly polymerization of conductive polymers, enabling intricate designs with submillimeter resolution across fabric areas spanning several meters. Moreover, it addresses the nozzle clogging issues commonly encountered in such applications.The resulting e-textiles preserve essential fabric characteristics such as breathability, wearability, and washability while delivering exceptional sensing performance. A comprehensive investigation, combining experimental, computational, and theoretical approaches, was conducted to examine the critical factors influencing the operation of the dual-regime spraying system and its role in e-textile fabrication. These findings provide a flexible solution for producing e-textiles on consumer fabric items and hold significant implications for a diverse range of wearable sensing applications.

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“…Skin Irritation Testing: Hyperspectral line-scan images (hypercube) of human skin were captured to investigate inflammation, typically characterized by erythema and alterations in hemoglobin concentrations, following skin irritation. [16] Imaging was facilitated by a monochrome camera (GS3-U3-120S6M-C; FLIR) equipped with a 23 μm wide slit and a groove density of 150 mm −1 . Illumination was provided by an LED light source with a color temperature of 6500 K (D65).…”

Section: Methodsmentioning

confidence: 99%

Tough Conductive Organohydrogel for Wearable Sensing in Extreme Environmental Conditions

Hong,

Park,

Lee

et al. 2023

Adv Materials Technologies

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Conductive hydrogels, despite their significant potential, have faced historical limitations including vulnerability to dehydration, degradation of performance at extreme temperatures, and susceptibility to freezing in subzero conditions. Furthermore, the development of hydrogels that are both tough and stretchable, capable of maintaining performance under extreme environmental conditions, has remained a challenging task. Here, an innovative conductive organohydrogel, distinguished by its superior toughness, stretchability, stability in regular ambient conditions, vacuum adaptability, and resistance to extreme temperatures is presented. By implementing a unique dry annealing process during synthesis, the mechanical strength of the organohydrogel has been substantially enhanced, dehydration concerns have been alleviated, and the structural integrity has been reinforced. In addition, the composition of the organohydrogel is specifically engineered to achieve both lasting endurance and sustainable longevity. This study signifies a crucial leap forward in creating high‐performing organohydrogels capable of functioning in a wide range of environments and conditions, thereby unlocking an array of adaptable applications.

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mHealth hyperspectral learning for instantaneous spatiospectral imaging of hemodynamics

Cited by 7 publications

References 98 publications

Rapid Self-Healing Hydrogel with Ultralow Electrical Hysteresis for Wearable Sensing

Rapid Self-Healing Hydrogel with Ultralow Electrical Hysteresis for Wearable Sensing

In Situ Spray Polymerization of Conductive Polymers for Personalized E-textiles

Tough Conductive Organohydrogel for Wearable Sensing in Extreme Environmental Conditions

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