An Integrated Wearable Sweat Sensing Patch for Passive Continuous Analysis of Stress Biomarkers at Rest

Zhao, Hong; Zhang, Xieli; Qin, Yanxia; Xia, Yong; Xu, Xin; Sun, Xiguang; Yu, Deng‐Guang; Mugo, Samuel M.; Wang, Dong; Zhang, Qiang

doi:10.1002/adfm.202212083

Cited by 33 publications

(29 citation statements)

References 67 publications

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“…[1][2][3][4][5][6][7][8][9] While commercially available wearable health DOI: 10.1002/adma.202212161 monitors mainly track physical vital signs, wearable sweat biosensors could offer rich health information at molecular levels. [10][11][12][13][14][15][16][17][18][19][20][21][22][23] Continuous analysis of sweat biomarkers including amino acids, vitamins, metabolites, drugs, hormones, and proteins could have a profound impact in remote monitoring and management of a variety of health conditions such as stress, gout, metabolic disorders, cardiovascular diseases, and cancers. [24][25][26][27][28][29][30][31][32][33][34][35][36][37][38][39][40]21] Most currently reported wearable electrochemical sweat biosensors can only monitor a limited group of small molecules (e.g., glucose, lactate, and ions) using enzymatic or ionselective sensors.…”

Section: Introductionmentioning

confidence: 99%

A Computationally Assisted Approach for Designing Wearable Biosensors toward Non‐Invasive Personalized Molecular Analysis

et al. 2023

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Wearable sweat sensors have the potential to revolutionize precision medicine as they can non‐invasively collect molecular information closely associated with an individual's health status. However, the majority of clinically relevant biomarkers cannot be continuously detected in situ using existing wearable approaches. Molecularly imprinted polymers (MIPs) are a promising candidate to address this challenge but haven't yet gained widespread use due to their complex design and optimization process yielding variable selectivity. Here, QuantumDock is introduced, an automated computational framework for universal MIP development toward wearable applications. QuantumDock utilizes density functional theory to probe molecular interactions between monomers and the target/interferent molecules to optimize selectivity, a fundamentally limiting factor for MIP development toward wearable sensing. A molecular docking approach is employed to explore a wide range of known and unknown monomers, and to identify the optimal monomer/cross‐linker choice for subsequent MIP fabrication. Using an essential amino acid phenylalanine as the exemplar, experimental validation of QuantumDock is performed successfully using solution‐synthesized MIP nanoparticles coupled with ultraviolet–visible spectroscopy. Moreover, a QuantumDock‐optimized graphene‐based wearable device is designed that can perform autonomous sweat induction, sampling, and sensing. For the first time, wearable non‐invasive phenylalanine monitoring is demonstrated in human subjects toward personalized healthcare applications.

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Section: Introductionmentioning

confidence: 99%

A Computationally Assisted Approach for Designing Wearable Biosensors toward Non‐Invasive Personalized Molecular Analysis

et al. 2023

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“…Wearable sweat sensors offer the remarkable capability to capture crucial physiological parameters in a noninvasive, on-site manner. − These sensors are emerging as promising alternatives to conventional methods, such as those relying on blood, urine, interstitial fluid, and saliva, for comprehensive physiological monitoring. , In the pursuit of in situ biomarker detection, sweat sampling has posed a challenge. However, innovative sampling approaches such as patches, electronic devices, and skin-interfaced soft microfluidic systems have emerged to address this concern. ,, Recent strides in microfluidic technology have ushered in a new era of noninvasive and economically viable diagnostic tools for monitoring sweat biomarkers. − An exemplar of this progress is the utilization of skin-interfaced soft microfluidic systems to discern biomarkers within sweat, offering invaluable insights into metabolic health. ,, An indispensable factor in the advancement of wearable sensors based on skin-interfaced soft microfluidics is the analytical signaling method. These methods play a pivotal role in the effective detection of sweat components, with colorimetric, electrochemical, and fluorometric assays being the forefront contenders. ,− Among these techniques, fluorescence assays stand out for their capability to detect species at remarkably low concentrations visually, providing a complementary approach. , However, conventional device designs necessitate chemical reactions to attain equilibrium, rendering materials like carbon dots, carbon polymer dots (CPDs), and natural chlorophylls .…”

Section: Introductionmentioning

confidence: 99%

Enhancing On-Skin Analysis: A Microfluidic Device and Smartphone Imaging Module for Real-Time Quantitative Detection of Multianalytes in Sweat

Dashtian,

Binabaji,

Zare-Dorabei

2023

Anal. Chem.

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Wearable sweat sensors present exciting opportunities for advancing personal health monitoring and noninvasive biomarker measurements. However, existing sensors often fall short in accurate detection of low analyte volumes and concentrations and lack multimodal sensing capabilities. Herein, we present a highly portable four-channel microfluidic device capable of conducting simultaneous sweat sampling and fluorometric sensing of potential biomarkers, such as L-Tyr, L-Trp, Crt, and NH 4 + , specifically designed for kidney disease monitoring. Our microfluidic device seamlessly integrates with smartphones, facilitating easy data retrieval and analysis. The core of the sensing array is a novel fluorometric solid-state mechanism utilizing carbon polymer dots derived from dopamine, catechol, and o-phenylenediamine monomers embedded in gelatin hydrogels. The sensors exhibit exceptional performance, offering linear ranges of 5−275, 6−170, 4−220, and 5−170 μM, with impressively low detection limits of 1.5, 1.2, 1.3, and 1.4 μM for L-Tyr, L-Trp, Crt, and NH 4 + , respectively. Through meticulous optimization of operational variables, comprising the temperature, sample volume, and assay time, we achieved the best performance of the device. Furthermore, the sensors exhibited remarkable selectivity, effectively distinguishing between biologically similar species and other potential biological compounds found in sweat. Our evaluation also extended to monitoring kidney diseases in patients and healthy individuals, showcasing the device's utility in world scenarios. Promising results showcase the potential of low-cost, multidiagnostic microfluidic sensor arrays, especially with synthetic skin integration, for enhanced disease detection and healthcare outcomes.

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“…Compared with the high sweat rate and complex interference of exercise sweat, the detection of resting sweat can better reflect the body condition. , At present, the monitoring of resting sweat biomarkers is becoming a new way to provide noninvasive health examination. Nyein et al developed wearable patches to detect resting sweat pH, Cl – , and l -dopamine for continuous and autonomous monitoring of body physiology at rest; Zhao et al analyzed stress biomarkers (cortisol, Mg 2+ , and pH) in resting sweat by integrating a wearable sweat sensing patch for diagnostic studies of psychological stress; Saha et al developed a lactate transient sensor under low sweat secretion to continuously monitor sweat lactate changes. Similarly, the increase of the sweat uric acid (UA) level is related to the occurrence and progression of metabolic syndrome, obesity, diabetes, coronary heart disease, and other diseases. , However, most of the current wearable sensors for UA detection are tested in exercise sweat, − and there is a lack of sensors that can detect UA in resting sweat.…”

Section: Introductionmentioning

confidence: 99%

Fe Single-Atom Nanozyme-Modified Wearable Hydrogel Patch for Precise Analysis of Uric Acid at Rest

Zhang,

Hou,

Zhao

et al. 2023

ACS Appl. Mater. Interfaces

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Resting sweat analysis could provide unique insight into the metabolic levels of physiological and pathological states. However, the low secretion rate of resting sweat and the low concentration of metabolic molecules pose challenges for the development of noninvasive wearable sensors. Here, we demonstrated a wearable patch for the precise analysis of uric acid at rest. Fe single-atom nanozymes (FeSAs) with excellent electrocatalytic activity were used to develop a sensor for selective catalysis of uric acid (UA, 1–425 μM), and the catalytic mechanism of UA was later explored by density functional theory. In addition, polyaniline was integrated into the wearable patch for pH detection; thus, accurate analysis of sweat UA molecules can be achieved by pH calibration. Then, we explored the possibility of collecting resting sweat with different ratios of agarose hydrogels to reduce the sweat accumulation time. Finally, the possibility of a wearable patch for accurate UA detection in volunteer sweat samples was experimentally verified. We believe that our work provides novel insights and ideas for the analysis of resting sweat using wearable devices, further driving advancements in the field of personalized medicine.

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An Integrated Wearable Sweat Sensing Patch for Passive Continuous Analysis of Stress Biomarkers at Rest

Cited by 33 publications

References 67 publications

A Computationally Assisted Approach for Designing Wearable Biosensors toward Non‐Invasive Personalized Molecular Analysis

A Computationally Assisted Approach for Designing Wearable Biosensors toward Non‐Invasive Personalized Molecular Analysis

Enhancing On-Skin Analysis: A Microfluidic Device and Smartphone Imaging Module for Real-Time Quantitative Detection of Multianalytes in Sweat

Fe Single-Atom Nanozyme-Modified Wearable Hydrogel Patch for Precise Analysis of Uric Acid at Rest

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