Search

Your search keyword '"Tai, Li-Chia"' showing total 36 results
Start Over Author "Tai, Li-Chia"
36 results on '"Tai, Li-Chia"'

1. Metrological Traceability of Optical Sensor

Author

Singh, Kanishk, Tarekegn, Getaneh Berie, Tai, Li-Chia, Agarwal, Tarun, Atai, Javid, Series Editor, Liang, Rongguang, Series Editor, Dinish, U.S., Series Editor, Sonker, Rakesh Kumar, editor, Singh, Kedar, editor, and Sonkawade, Rajendra, editor

Published
2023
Full Text
View/download PDF

3. Glove-based sensors for multimodal monitoring of natural sweat

Author

Bariya, Mallika, Li, Lu, Ghattamaneni, Rahul, Ahn, Christine Heera, Nyein, Hnin Yin Yin, Tai, Li-Chia, and Javey, Ali

Abstract

Sweat sensors targeting exercise or chemically induced sweat have shown promise for noninvasive health monitoring. Natural thermoregulatory sweat is an attractive alternative as it can be accessed during routine and sedentary activity without impeding user lifestyles and potentially preserves correlations between sweat and blood biomarkers. We present simple glove-based sensors to accumulate natural sweat with minimal evaporation, capitalizing on high sweat gland densities to collect hundreds of microliters in just 30 min without active sweat stimulation. Sensing electrodes are patterned on nitrile gloves and finger cots for in situ detection of diverse biomarkers, including electrolytes and xenobiotics, and multiple gloves or cots are worn in sequence to track overarching analyte dynamics. Direct integration of sensors into gloves represents a simple and low-overhead scheme for natural sweat analysis, enabling sweat-based physiological monitoring to become practical and routine without requiring highly complex or miniaturized components for analyte collection and signal transduction.

Published
2020

4. Nicotine Monitoring with a Wearable Sweat Band

Author

Tai, Li-Chia, Ahn, Christine Heera, Nyein, Hnin Yin Yin, Ji, Wenbo, Bariya, Mallika, Lin, Yuanjing, Li, Lu, and Javey, Ali

Subjects
Analytical Chemistry, Engineering, Electronics, Sensors and Digital Hardware, Chemical Sciences, Substance Misuse, Clinical Research, Tobacco Smoke and Health, Tobacco, Drug Abuse (NIDA only), Stroke, Cardiovascular, Cancer, Respiratory, Good Health and Well Being, Humans, Nicotine, Sweat, Tobacco Products, Tobacco Smoke Pollution, Wearable Electronic Devices, nicotine monitoring, electrochemical devices, wearable sweat sensors, flexible electronics, nanodendrites, self-assembled monolayer, Biomedical Engineering, Nanotechnology, Analytical chemistry, Electronics, sensors and digital hardware
Abstract

The tobacco epidemic is a public health threat that has taken a heavy toll of lives around the globe each year. Smoking affects both the smokers and those who are exposed to secondhand smoke, and careful tracking of exposure can be key to mitigating the potential hazards. For smokers, the variation of chemical compositions between commercial cigarettes has led to ambiguity in estimating the health risks, both for active smokers and others involuntarily exposed to tobacco smoke and byproducts. In this regard, sweat possesses an attractive opportunity to monitor smoke exposure due to sweat's abundance in biomolecules and its great accessibility. Here, we present a wearable sweat band to monitor nicotine, a prominent ingredient in cigarettes, as a viable way to quantitatively assess a wearer's exposure to smoking. Both smokers and normal subjects are tested to demonstrate the use of this device for smoke-related health monitoring. Our results exhibit confirmable and elevated nicotine levels in sweat for subjects inhaling cigarette smoke. This continuous and personalized sweat sensing device is leverage to monitor smoke pollution for a potentially broad population.

Published
2020

5. A multi-modal sweat sensing patch for cross-verification of sweat rate, total ionic charge, and Na + concentration

Author

Yuan, Zhen, Hou, Lei, Bariya, Mallika, Nyein, Hnin Yin Yin, Tai, Li-Chia, Ji, Wenbo, Li, Lu, and Javey, Ali

Subjects
Engineering, Materials Engineering, Chemical Sciences, Bioengineering, Good Health and Well Being, Biomarkers, Biosensing Techniques, Electrochemical Techniques, Electrolytes, Humans, Ions, Sodium, Sweat, Analytical Chemistry, Chemical sciences
Abstract

Sweat sensors introduced in recent years have targeted a variety of sweat features and biomarkers for non-invasive health monitoring. Amongst these targets, reliable monitoring of sweat rate is crucial due to its modulation of sweat analyte concentrations and its intrinsic significance to numerous medical and physiological health conditions. Here we present a sweat rate sensor structure comprising of electrodes with interdigitated fingers in a microfluidic channel. Each time the accumulating sweat impinges on an electrode finger, the sensor reports a jump in admittance that can be simply and efficiently counted to estimate sweat rate, overcoming selectivity limitations of previously reported sweat rate sensors. We further integrate an impedimetric sensor for measuring total ionic charge concentration and an electrochemical Na+ sensor, together creating a multi-modal system for analyzing fluid and electrolyte secretion. We demonstrate how low analyte diffusion rates through this microfluidic device allow for multi-purpose sensor function, including utilizing the sweat rate sensor signal to corroborate total ionic sensor measurements. This cross-verification capability ensures data integrity in real time, satisfying a vital consideration for personalized healthcare technologies. We use the presented patch for continuous analysis of sweat rate, total ionic charge concentration, and Na+ concentration during exercise, while demonstrating how multi-modal cross-verification brings new trust to sensor readings.

Published
2019

6. A multi-modal sweat sensing patch for cross-verification of sweat rate, total ionic charge, and Na+ concentration.

Author

Yuan, Zhen, Hou, Lei, Bariya, Mallika, Nyein, Hnin Yin Yin, Tai, Li-Chia, Ji, Wenbo, Li, Lu, and Javey, Ali

Subjects
Sweat, Humans, Electrolytes, Ions, Sodium, Biosensing Techniques, Electrochemical Techniques, Biomarkers, Chemical Sciences, Engineering, Analytical Chemistry
Abstract

Sweat sensors introduced in recent years have targeted a variety of sweat features and biomarkers for non-invasive health monitoring. Amongst these targets, reliable monitoring of sweat rate is crucial due to its modulation of sweat analyte concentrations and its intrinsic significance to numerous medical and physiological health conditions. Here we present a sweat rate sensor structure comprising of electrodes with interdigitated fingers in a microfluidic channel. Each time the accumulating sweat impinges on an electrode finger, the sensor reports a jump in admittance that can be simply and efficiently counted to estimate sweat rate, overcoming selectivity limitations of previously reported sweat rate sensors. We further integrate an impedimetric sensor for measuring total ionic charge concentration and an electrochemical Na+ sensor, together creating a multi-modal system for analyzing fluid and electrolyte secretion. We demonstrate how low analyte diffusion rates through this microfluidic device allow for multi-purpose sensor function, including utilizing the sweat rate sensor signal to corroborate total ionic sensor measurements. This cross-verification capability ensures data integrity in real time, satisfying a vital consideration for personalized healthcare technologies. We use the presented patch for continuous analysis of sweat rate, total ionic charge concentration, and Na+ concentration during exercise, while demonstrating how multi-modal cross-verification brings new trust to sensor readings.

Published
2019

7. Wearable Sweat Band for Noninvasive Levodopa Monitoring

Author

Tai, Li-Chia, Liaw, Tiffany S, Lin, Yuanjing, Nyein, Hnin YY, Bariya, Mallika, Ji, Wenbo, Hettick, Mark, Zhao, Chunsong, Zhao, Jiangqi, Hou, Lei, Yuan, Zhen, Fan, Zhiyong, and Javey, Ali

Subjects
Health Sciences, Sports Science and Exercise, Behavioral and Social Science, Parkinson's Disease, Neurodegenerative, Clinical Research, Neurosciences, Brain Disorders, Drug Monitoring, Female, Humans, Levodopa, Parkinson Disease, Sweat, Wearable Electronic Devices, Wearable sweat sensor, Parkinson's disease, levodopa detection, noninvasive drug monitoring, dosage optimization, Parkinson’s disease, Nanoscience & Nanotechnology
Abstract

Levodopa is the standard medication clinically prescribed to patients afflicted with Parkinson's disease. In particular, the monitoring and optimization of levodopa dosage are critical to mitigate the onset of undesired fluctuations in the patients' physical and emotional conditions such as speech function, motor behavior, and mood stability. The traditional approach to optimize levodopa dosage involves evaluating the subjects' motor function, which has many shortcomings due to its subjective and limited quantifiable nature. Here, we present a wearable sweat band on a nanodendritic platform that quantitatively monitors levodopa dynamics in the body. Both stationary iontophoretic induction and physical exercise are utilized as our methods of sweat extraction. The sweat band measures real-time pharmacokinetic profiles of levodopa to track the dynamic response of the drug metabolism. We demonstrated the sweat band's functionalities on multiple subjects with implications toward the systematic administering of levodopa and routine management of Parkinson's disease.

Published
2019

8. Regional and correlative sweat analysis using high-throughput microfluidic sensing patches toward decoding sweat.

Author

Nyein, Hnin Yin Yin, Bariya, Mallika, Kivimäki, Liisa, Uusitalo, Sanna, Liaw, Tiffany Sun, Jansson, Elina, Ahn, Christine Heera, Hangasky, John A, Zhao, Jiangqi, Lin, Yuanjing, Happonen, Tuomas, Chao, Minghan, Liedert, Christina, Zhao, Yingbo, Tai, Li-Chia, Hiltunen, Jussi, and Javey, Ali

Subjects
Sweat, Humans, Diabetes Mellitus, Ions, Potassium, Sodium, Glucose, Biosensing Techniques, Microfluidics, High-Throughput Screening Assays
Abstract

Recent technological advancements in wearable sensors have made it easier to detect sweat components, but our limited understanding of sweat restricts its application. A critical bottleneck for temporal and regional sweat analysis is achieving uniform, high-throughput fabrication of sweat sensor components, including microfluidic chip and sensing electrodes. To overcome this challenge, we introduce microfluidic sensing patches mass fabricated via roll-to-roll (R2R) processes. The patch allows sweat capture within a spiral microfluidic for real-time measurement of sweat parameters including [Na+], [K+], [glucose], and sweat rate in exercise and chemically induced sweat. The patch is demonstrated for investigating regional sweat composition, predicting whole-body fluid/electrolyte loss during exercise, uncovering relationships between sweat metrics, and tracking glucose dynamics to explore sweat-to-blood correlations in healthy and diabetic individuals. By enabling a comprehensive sweat analysis, the presented device is a crucial tool for advancing sweat testing beyond the research stage for point-of-care medical and athletic applications.

Published
2019

9. A Fully Integrated and Self-Powered Smartwatch for Continuous Sweat Glucose Monitoring

Author

Zhao, Jiangqi, Lin, Yuanjing, Wu, Jingbo, Nyein, Hnin Yin Yin, Bariya, Mallika, Tai, Li-Chia, Chao, Minghan, Ji, Wenbo, Zhang, George, Fan, Zhiyong, and Javey, Ali

Subjects
Chemical Sciences, Physical Chemistry, Engineering, Electronics, Sensors and Digital Hardware, Materials Engineering, Affordable and Clean Energy, Adult, Biosensing Techniques, Electric Power Supplies, Electrochemical Techniques, Equipment Design, Ferrocyanides, Glucose, Glucose Oxidase, Humans, Male, Manganese Compounds, Monitoring, Physiologic, Nickel, Oxides, Solar Energy, Sweat, Wearable Electronic Devices, Young Adult, Zinc, flexible biosensors, noninvasive glucose monitoring, self-powered system, wearable electronics, healthcare and fitness management, Analytical Chemistry, Biomedical Engineering, Nanotechnology, Analytical chemistry, Electronics, sensors and digital hardware
Abstract

Wearable devices for health monitoring and fitness management have foreseen a rapidly expanding market, especially those for noninvasive and continuous measurements with real-time display that provide practical convenience and eliminated safety/infection risks. Herein, a self-powered and fully integrated smartwatch that consists of flexible photovoltaic cells and rechargeable batteries in the forms of a "watch strap", electrochemical glucose sensors, customized circuits, and display units integrated into a "dial" platform is successfully fabricated for real-time and continuous monitoring of sweat glucose levels. The functionality of the smartwatch, including sweat glucose sensing, signal processing, and display, can be supported with the harvested/converted solar energy without external charging devices. The Zn-MnO2 batteries serve as intermediate energy storage units and the utilization of aqueous electrolytes eliminated safety concerns for batteries, which is critical for wearable devices. Such a wearable system in a smartwatch fashion realizes integration of energy modules with self-powered capability, electrochemical sensors for noninvasive glucose monitoring, and in situ and real-time signal processing/display in a single platform for the first time. The as-fabricated fully integrated and self-powered smartwatch also provides a promising protocol for statistical study and clinical investigation to reveal correlations between sweat compositions and human body dynamics.

Published
2019

10. Roll-to-Roll Gravure Printed Electrochemical Sensors for Wearable and Medical Devices

Author

Bariya, Mallika, Shahpar, Ziba, Park, Hyejin, Sun, Junfeng, Jung, Younsu, Gao, Wei, Nyein, Hnin Yin Yin, Liaw, Tiffany Sun, Tai, Li-Chia, Ngo, Quynh P, Chao, Minghan, Zhao, Yingbo, Hettick, Mark, Cho, Gyoujin, and Javey, Ali

Subjects
Analytical Chemistry, Chemical Sciences, Engineering, Information and Computing Sciences, Electronics, Sensors and Digital Hardware, Data Management and Data Science, Materials Engineering, Bioengineering, Good Health and Well Being, Electrochemical Techniques, Electrodes, Printing, Wearable Electronic Devices, wearable biosensors, flexible electronics, roll-to-roll processing, gravure printing, multiplexed sensing, in situ analysis, Nanoscience & Nanotechnology
Abstract

As recent developments in noninvasive biosensors spearhead the thrust toward personalized health and fitness monitoring, there is a need for high throughput, cost-effective fabrication of flexible sensing components. Toward this goal, we present roll-to-roll (R2R) gravure printed electrodes that are robust under a range of electrochemical sensing applications. We use inks and electrode morphologies designed for electrochemical and mechanical stability, achieving devices with uniform redox kinetics printed on 150 m flexible substrate rolls. We show that these electrodes can be functionalized into consistently high performing sensors for detecting ions, metabolites, heavy metals, and other small molecules in noninvasively accessed biofluids, including sensors for real-time, in situ perspiration monitoring during exercise. This development of robust and versatile R2R gravure printed electrodes represents a key translational step in enabling large-scale, low-cost fabrication of disposable wearable sensors for personalized health monitoring applications.

Published
2018

11. Methylxanthine Drug Monitoring with Wearable Sweat Sensors

Author

Tai, Li‐Chia, Gao, Wei, Chao, Minghan, Bariya, Mallika, Ngo, Quynh P, Shahpar, Ziba, Nyein, Hnin YY, Park, Hyejin, Sun, Junfeng, Jung, Younsu, Wu, Eric, Fahad, Hossain M, Lien, Der‐Hsien, Ota, Hiroki, Cho, Gyoujin, and Javey, Ali

Subjects
Engineering, Chemical Sciences, Physical Sciences, Clinical Research, Good Health and Well Being, Drug Monitoring, Humans, Monitoring, Physiologic, Sweat, Wearable Electronic Devices, Xanthines, drug monitoring, electrochemical sensors, flexible electronics, wearable biosensors, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences
Abstract

Drug monitoring plays crucial roles in doping control and precision medicine. It helps physicians tailor drug dosage for optimal benefits, track patients' compliance to prescriptions, and understand the complex pharmacokinetics of drugs. Conventional drug tests rely on invasive blood draws. While urine and sweat are attractive alternative biofluids, the state-of-the-art methods require separate sample collection and processing steps and fail to provide real-time information. Here, a wearable platform equipped with an electrochemical differential pulse voltammetry sensing module for drug monitoring is presented. A methylxanthine drug, caffeine, is selected to demonstrate the platform's functionalities. Sweat caffeine levels are monitored under various conditions, such as drug doses and measurement time after drug intake. Elevated sweat caffeine levels upon increasing dosage and confirmable caffeine physiological trends are observed. This work leverages a wearable sweat sensing platform toward noninvasive and continuous point-of-care drug monitoring and management.

Published
2018

12. A Wearable Microfluidic Sensing Patch for Dynamic Sweat Secretion Analysis

Author

Nyein, Hnin Yin Yin, Tai, Li-Chia, Ngo, Quynh Phuong, Chao, Minghan, Zhang, George B, Gao, Wei, Bariya, Mallika, Bullock, James, Kim, Hyungjin, Fahad, Hossain M, and Javey, Ali

Subjects
Engineering, Materials Engineering, Electronics, Sensors and Digital Hardware, Chemical Sciences, Neurosciences, Bioengineering, Biotechnology, Detection, screening and diagnosis, 4.1 Discovery and preclinical testing of markers and technologies, Humans, Lab-On-A-Chip Devices, Radio Waves, Smartphone, Sweat, Wearable Electronic Devices, wearable biosensors, microfluidic device, sweat patch, multiplexed sensing electrochemical sensor, flexible electronics, electrochemical sensor, multiplexed sensing, Analytical Chemistry, Biomedical Engineering, Nanotechnology, Analytical chemistry, Electronics, sensors and digital hardware
Abstract

Wearable sweat sensing is a rapidly rising research area driven by its promising potential in health, fitness, and diagnostic applications. Despite the growth in the field, major challenges in relation to sweat metrics remain to be addressed. These challenges include sweat rate monitoring for its complex relation with sweat compositions and sweat sampling for sweat dynamics studies. In this work, we present a flexible microfluidic sweat sensing patch that enhances real-time electrochemical sensing and sweat rate analysis via sweat sampling. The device contains a spiral-patterned microfluidic component that is embedded with ion-selective sensors and an electrical impedance-based sweat rate sensor on a flexible plastic substrate. The patch is enabled to autonomously perform sweat analysis by interfacing the sensing component with a printed circuit board that is capable of on-site signal conditioning, analysis, and transmission. Progressive sweat flow in the microfluidic device, governed by the pressure induced by the secreted sweat, enhances sweat sampling and electrochemical detection via a defined sweat collection chamber and a directed sweat route. The characteristic of the sweat rate sensor is validated through a theoretical simulation, and the precision and accuracy of the flow rate is verified with a commercial syringe pump and a Macroduct sweat collector. On-body simultaneous monitoring of ion (H+, Na+, K+, Cl-) concentration and sweat rate is also demonstrated for sensor functionality. This sweat sensing patch provides an integrated platform for a comprehensive sweat secretion analysis and facilitates physiological and clinical investigations by closely monitoring interrelated sweat parameters.

Published
2018

14. Wearable Microfluidic Diaphragm Pressure Sensor for Health and Tactile Touch Monitoring

Author

Gao, Yuji, Ota, Hiroki, Schaler, Ethan W, Chen, Kevin, Zhao, Allan, Gao, Wei, Fahad, Hossain M, Leng, Yonggang, Zheng, Anzong, Xiong, Furui, Zhang, Chuchu, Tai, Li‐Chia, Zhao, Peida, Fearing, Ronald S, and Javey, Ali

Subjects
Engineering, Materials Engineering, Electronics, Sensors and Digital Hardware, Neurosciences, Clinical Research, Diaphragm, Humans, Microfluidics, Pressure, Touch, Wearable Electronic Devices, diaphragm pressure sensors, flexible pressure sensors, liquid metal, microfluidics, wearable, Physical Sciences, Chemical Sciences, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences
Abstract

Flexible pressure sensors have many potential applications in wearable electronics, robotics, health monitoring, and more. In particular, liquid-metal-based sensors are especially promising as they can undergo strains of over 200% without failure. However, current liquid-metal-based strain sensors are incapable of resolving small pressure changes in the few kPa range, making them unsuitable for applications such as heart-rate monitoring, which require a much lower pressure detection resolution. In this paper, a microfluidic tactile diaphragm pressure sensor based on embedded Galinstan microchannels (70 µm width × 70 µm height) capable of resolving sub-50 Pa changes in pressure with sub-100 Pa detection limits and a response time of 90 ms is demonstrated. An embedded equivalent Wheatstone bridge circuit makes the most of tangential and radial strain fields, leading to high sensitivities of a 0.0835 kPa-1 change in output voltage. The Wheatstone bridge also provides temperature self-compensation, allowing for operation in the range of 20-50 °C. As examples of potential applications, a polydimethylsiloxane (PDMS) wristband with an embedded microfluidic diaphragm pressure sensor capable of real-time pulse monitoring and a PDMS glove with multiple embedded sensors to provide comprehensive tactile feedback of a human hand when touching or holding objects are demonstrated.

Published
2017

16. 3D Printed “Earable” Smart Devices for Real-Time Detection of Core Body Temperature

Author

Ota, Hiroki, Chao, Minghan, Gao, Yuji, Wu, Eric, Tai, Li-Chia, Chen, Kevin, Matsuoka, Yasutomo, Iwai, Kosuke, Fahad, Hossain M, Gao, Wei, Nyein, Hnin Yin Yin, Lin, Liwei, and Javey, Ali

Subjects
Engineering, Electronics, Sensors and Digital Hardware, Assistive Technology, Clinical Research, Bioengineering, Cardiovascular, Health Services, Generic health relevance, Good Health and Well Being, 3D printing, flexible electronics, wearable device, liquid metal, core body temperature, bone conduction hearing aid, Analytical Chemistry, Biomedical Engineering, Nanotechnology, Analytical chemistry, Electronics, sensors and digital hardware
Abstract

Real-time detection of basic physiological parameters such as blood pressure and heart rate is an important target in wearable smart devices for healthcare. Among these, the core body temperature is one of the most important basic medical indicators of fever, insomnia, fatigue, metabolic functionality, and depression. However, traditional wearable temperature sensors are based upon the measurement of skin temperature, which can vary dramatically from the true core body temperature. Here, we demonstrate a three-dimensional (3D) printed wearable "earable" smart device that is designed to be worn on the ear to track core body temperature from the tympanic membrane (i.e., ear drum) based on an infrared sensor. The device is fully integrated with data processing circuits and a wireless module for standalone functionality. Using this smart earable device, we demonstrate that the core body temperature can be accurately monitored regardless of the environment and activity of the user. In addition, a microphone and actuator are also integrated so that the device can also function as a bone conduction hearing aid. Using 3D printing as the fabrication method enables the device to be customized for the wearer for more personalized healthcare. This smart device provides an important advance in realizing personalized health care by enabling real-time monitoring of one of the most important medical parameters, core body temperature, employed in preliminary medical screening tests.

Published
2017

18. A Wearable Electrochemical Platform for Noninvasive Simultaneous Monitoring of Ca2+ and pH

Author

Nyein, Hnin Yin Yin, Gao, Wei, Shahpar, Ziba, Emaminejad, Sam, Challa, Samyuktha, Chen, Kevin, Fahad, Hossain M, Tai, Li-Chia, Ota, Hiroki, Davis, Ronald W, and Javey, Ali

Subjects
Analytical Chemistry, Chemical Sciences, Engineering, Information and Computing Sciences, Electronics, Sensors and Digital Hardware, Data Management and Data Science, Bioengineering, 4.1 Discovery and preclinical testing of markers and technologies, Detection, screening and diagnosis, Calcium, Electrolytes, Humans, Hydrogen-Ion Concentration, Ions, Sweat, Wearable Electronic Devices, wearable biosensors, flexible electronics, multiplexed sensing, system integration, in situ analysis, Nanoscience & Nanotechnology
Abstract

Homeostasis of ionized calcium in biofluids is critical for human biological functions and organ systems. Measurement of ionized calcium for clinical applications is not easily accessible due to its strict procedures and dependence on pH. pH balance in body fluids greatly affects metabolic reactions and biological transport systems. Here, we demonstrate a wearable electrochemical device for continuous monitoring of ionized calcium and pH of body fluids using a disposable and flexible array of Ca(2+) and pH sensors that interfaces with a flexible printed circuit board. This platform enables real-time quantitative analysis of these sensing elements in body fluids such as sweat, urine, and tears. Accuracy of Ca(2+) concentration and pH measured by the wearable sensors is validated through inductively coupled plasma-mass spectrometry technique and a commercial pH meter, respectively. Our results show that the wearable sensors have high repeatability and selectivity to the target ions. Real-time on-body assessment of sweat is also performed, and our results indicate that calcium concentration increases with decreasing pH. This platform can be used in noninvasive continuous analysis of ionized calcium and pH in body fluids for disease diagnosis such as primary hyperparathyroidism and kidney stones.

Published
2016

19. Wearable Microsensor Array for Multiplexed Heavy Metal Monitoring of Body Fluids

Author

Gao, Wei, Nyein, Hnin YY, Shahpar, Ziba, Fahad, Hossain M, Chen, Kevin, Emaminejad, Sam, Gao, Yuji, Tai, Li-Chia, Ota, Hiroki, Wu, Eric, Bullock, James, Zeng, Yuping, Lien, Der-Hsien, and Javey, Ali

Subjects
Analytical Chemistry, Chemical Sciences, flexible electronics, wearable biosensors, heavy metals monitoring, sweat, multiplexed sensing, temperature compensation, Biomedical Engineering, Nanotechnology, Analytical chemistry, Electronics, sensors and digital hardware
Abstract

A flexible and wearable microsensor array is described for simultaneous multiplexed monitoring of heavy metals in human body fluids. Zn, Cd, Pb, Cu, and Hg ions are chosen as target analytes for detection via electrochemical square wave anodic stripping voltammetry (SWASV) on Au and Bi microelectrodes. The oxidation peaks of these metals are calibrated and compensated by incorporating a skin temperature sensor. High selectivity, repeatability, and flexibility of the sensor arrays are presented. Human sweat and urine samples are collected for heavy metal analysis, and measured results from the microsensors are validated through inductively coupled plasma mass spectrometry (ICP-MS). Real-time on-body evaluation of heavy metal (e.g., zinc and copper) levels in sweat of human subjects by cycling is performed to examine the change in concentrations with time. This platform is anticipated to provide insightful information about an individual's health state such as heavy metal exposure and aid the related clinical investigations.

Published
2016

20. Deep Learning in Label-free Cell Classification.

Author

Chen, Claire Lifan, Mahjoubfar, Ata, Tai, Li-Chia, Blaby, Ian K, Huang, Allen, Niazi, Kayvan Reza, and Jalali, Bahram

Subjects
T-Lymphocytes, Cell Line, Tumor, Humans, Chlamydomonas reinhardtii, Reproducibility of Results, Computational Biology, Algorithms, Neural Networks (Computer), Artificial Intelligence, Software Validation, Pattern Recognition, Automated, Support Vector Machine, Neural Networks, Computer, Cell Line, Tumor, Neural Networks, Pattern Recognition, Automated, Computer, Genetics, Cancer, Bioengineering, Biotechnology, Biochemistry and Cell Biology, Other Physical Sciences
Abstract

Label-free cell analysis is essential to personalized genomics, cancer diagnostics, and drug development as it avoids adverse effects of staining reagents on cellular viability and cell signaling. However, currently available label-free cell assays mostly rely only on a single feature and lack sufficient differentiation. Also, the sample size analyzed by these assays is limited due to their low throughput. Here, we integrate feature extraction and deep learning with high-throughput quantitative imaging enabled by photonic time stretch, achieving record high accuracy in label-free cell classification. Our system captures quantitative optical phase and intensity images and extracts multiple biophysical features of individual cells. These biophysical measurements form a hyperdimensional feature space in which supervised learning is performed for cell classification. We compare various learning algorithms including artificial neural network, support vector machine, logistic regression, and a novel deep learning pipeline, which adopts global optimization of receiver operating characteristics. As a validation of the enhanced sensitivity and specificity of our system, we show classification of white blood T-cells against colon cancer cells, as well as lipid accumulating algal strains for biofuel production. This system opens up a new path to data-driven phenotypic diagnosis and better understanding of the heterogeneous gene expressions in cells.

Published
2016

21. Empowering Portable Optoelectronics With Computer Vision for Intraoral Cavity Detection

Author

Khuntia, Sucharita, Fan, Sue-Yuan, Juan, Po-Hsiang, Liou, Ci-Ruei, Huang, Yi-Hsiang, Singh, Kanishk, Ogwo, Chukwuebuka, and Tai, Li-Chia

Abstract

Tooth decay is a chronic disease resulting in pain, infection, and tooth loss. This illness is common because many factors, such as poor oral hygiene, sugar consumption, and microbial flora, contribute to dental cavities. Untreated or undetected tooth decay often escalates to a more severe stage, emphasizing the importance of early detection and intervention. We propose a portable, low-cost, and ergonomic optoelectronic device to provide a possible solution for the early detection of dental cavities before annual or regular dental checkups for the first time. This device integrates mini cameras on top of a dental impression tray to capture images of the teeth, and the photographs can be transmitted via Wi-Fi to the cloud for real-time cavity detection through a you only look once (YOLO) algorithm that is based on a convolutional neural network (CNN). Our results show the precision, recall, and mean average precision (mAP)@0.5:0.95 for YOLOv5 (0.72, 0.70, 0.75), YOLOv6 (0.59, 0.50, 0.58), and YOLOv7 (0.93, 0.94, 0.82). We also compared the YOLO algorithm with traditional techniques such as support vector machine (SVM) and k-nearest neighbor (kNN) algorithms. This intraoral cavity detection system paves the way for early detection of dental cavities with quick accessibility and affordable cost. We foresee that this optoelectronic device will play a role in advancing biomedical technologies, ultimately promoting the long-term well-being of individuals.

Published
2024
Full Text
View/download PDF

25. Drug Monitoring with Wearable Sweat Sensors

Author

Tai, Li-Chia

Subjects
Electrical engineering, Computer science, Biomedical engineering
Abstract

Wearable sensors have been very popular among us to monitor our physical wellness, and they are potentially important for health monitoring with implications toward preventive care and clinical treatment. On the market, noninvasive wearables can be used to track external metrics such as heart rate and ECG signal. However, they fail to inform users about elusive biomarkers at the molecular level, which can potentially provide more insight into a person’s health situation. Traditionally, accessing bio-molecular information requires collecting blood or urine samples with invasive extraction or logistic complications. In this regard, sweat stands out as a great candidate because of its noninvasive property and abundance in biomolecules, such as electrolytes, metabolites, xenobiotic molecules, and heavy metals. Our group has demonstrated noninvasive and multiplexed sensing of biomolecules by interfacing flexible printed circuit boards and electrode arrays. The advantage of this kind of sensor is that it enables real-time monitoring, requires small sample volume, and detects multiple biomolecules simultaneously. The sweat monitoring device allows us to potentially monitor our health statuses and screen diseases. However, a challenge that is equally important to screening diseases is to have an effective treatment that typically involves drug intake. So the question that remains is whether we can monitor drug molecules using a wearable sweat sensor? After an introduction in Chapter 1, we will explore this possibility in Chapter 2. A methylxanthine drug, caffeine, is selected to validate the sensor’s functionalities. Chapter 3 seeks the sensor’s potential applications in clinical settings. The focus is on levodopa, which is typically used for treating patients with Parkinson’s disease. In Chapter 4, the sensing platform is reconfigured for secondhand smoke detection, which can potentially be used by a broader population. In summary, we have demonstrated wearable sweat sensors capable of monitoring selected molecules related to drugs. This work leverages a wearable sweat sensor towards noninvasive and continuous point-of-care drug monitoring and management.

Published
2020

30. Methylxanthine Drug Monitoring with Wearable Sweat Sensors.

Author

Tai, Li-Chia, Tai, Li-Chia, Gao, Wei, Chao, Minghan, Bariya, Mallika, Ngo, Quynh P, Shahpar, Ziba, Nyein, Hnin YY, Park, Hyejin, Sun, Junfeng, Jung, Younsu, Wu, Eric, Fahad, Hossain M, Lien, Der-Hsien, Ota, Hiroki, Cho, Gyoujin, Javey, Ali, Tai, Li-Chia, Tai, Li-Chia, Gao, Wei, Chao, Minghan, Bariya, Mallika, Ngo, Quynh P, Shahpar, Ziba, Nyein, Hnin YY, Park, Hyejin, Sun, Junfeng, Jung, Younsu, Wu, Eric, Fahad, Hossain M, Lien, Der-Hsien, Ota, Hiroki, Cho, Gyoujin, and Javey, Ali

Abstract

Drug monitoring plays crucial roles in doping control and precision medicine. It helps physicians tailor drug dosage for optimal benefits, track patients' compliance to prescriptions, and understand the complex pharmacokinetics of drugs. Conventional drug tests rely on invasive blood draws. While urine and sweat are attractive alternative biofluids, the state-of-the-art methods require separate sample collection and processing steps and fail to provide real-time information. Here, a wearable platform equipped with an electrochemical differential pulse voltammetry sensing module for drug monitoring is presented. A methylxanthine drug, caffeine, is selected to demonstrate the platform's functionalities. Sweat caffeine levels are monitored under various conditions, such as drug doses and measurement time after drug intake. Elevated sweat caffeine levels upon increasing dosage and confirmable caffeine physiological trends are observed. This work leverages a wearable sweat sensing platform toward noninvasive and continuous point-of-care drug monitoring and management.

Published
2018

31. Wearable sweat biosensors

Author

Gao, Wei, Nyein, Hnin Yin Yin, Shahpar, Ziba, Tai, Li-Chia, Wu, Eric, Bariya, Mallika, Ota, Hiroki, Fahad, Hossain M., Chen, Kevin, Javey, Ali, Gao, Wei, Nyein, Hnin Yin Yin, Shahpar, Ziba, Tai, Li-Chia, Wu, Eric, Bariya, Mallika, Ota, Hiroki, Fahad, Hossain M., Chen, Kevin, and Javey, Ali

Abstract

Wearable perspiration biosensors enable real-time analysis of the sweat composition and can provide insightful information about health conditions. In this review, we discuss the recent developments in wearable sweat sensing platforms and detection techniques. Specifically, on-body monitoring of a wide spectrum of sweat biomarkers are illustrated. Opportunities and challenges in the field are discussed. Although still in an early research stage, wearable sweat biosensors may enable a wide range of personalized diagnostic and physiological monitoring applications.

Published
2017

32. Wearable sweat biosensors

Author

Gao, Wei, primary, Nyein, Hnin Y. Y., additional, Shahpar, Ziba, additional, Tai, Li-Chia, additional, Wu, Eric, additional, Bariya, Mallika, additional, Ota, Hiroki, additional, Fahad, Hossain M., additional, Chen, Kevin, additional, and Javey, Ali, additional

Published
2016
Full Text
View/download PDF

33. A multi-modal sweat sensing patch for cross-verification of sweat rate, total ionic charge, and Na+ concentration.

Author

Yuan, Zhen, Hou, Lei, Bariya, Mallika, Nyein, Hnin Yin Yin, Tai, Li-Chia, Ji, Wenbo, Li, Lu, and Javey, Ali

Subjects
PERSPIRATION, MICROFLUIDICS, MICROFLUIDIC devices, ELECTROCHEMICAL sensors, DATA integrity, ELECTRIC admittance
Abstract

Sweat sensors introduced in recent years have targeted a variety of sweat features and biomarkers for non-invasive health monitoring. Amongst these targets, reliable monitoring of sweat rate is crucial due to its modulation of sweat analyte concentrations and its intrinsic significance to numerous medical and physiological health conditions. Here we present a sweat rate sensor structure comprising of electrodes with interdigitated fingers in a microfluidic channel. Each time the accumulating sweat impinges on an electrode finger, the sensor reports a jump in admittance that can be simply and efficiently counted to estimate sweat rate, overcoming selectivity limitations of previously reported sweat rate sensors. We further integrate an impedimetric sensor for measuring total ionic charge concentration and an electrochemical Na+ sensor, together creating a multi-modal system for analyzing fluid and electrolyte secretion. We demonstrate how low analyte diffusion rates through this microfluidic device allow for multi-purpose sensor function, including utilizing the sweat rate sensor signal to corroborate total ionic sensor measurements. This cross-verification capability ensures data integrity in real time, satisfying a vital consideration for personalized healthcare technologies. We use the presented patch for continuous analysis of sweat rate, total ionic charge concentration, and Na+ concentration during exercise, while demonstrating how multi-modal cross-verification brings new trust to sensor readings. [ABSTRACT FROM AUTHOR]

Published
2019
Full Text
View/download PDF

34. Wearable Sweat Band for Noninvasive Levodopa Monitoring

Author

Tai, Li-Chia, Liaw, Tiffany S., Lin, Yuanjing, Nyein, Hnin Y. Y., Bariya, Mallika, Ji, Wenbo, Hettick, Mark, Zhao, Chunsong, Zhao, Jiangqi, Hou, Lei, Yuan, Zhen, Fan, Zhiyong, and Javey, Ali

Abstract

Levodopa is the standard medication clinically prescribed to patients afflicted with Parkinson’s disease. In particular, the monitoring and optimization of levodopa dosage are critical to mitigate the onset of undesired fluctuations in the patients’ physical and emotional conditions such as speech function, motor behavior, and mood stability. The traditional approach to optimize levodopa dosage involves evaluating the subjects’ motor function, which has many shortcomings due to its subjective and limited quantifiable nature. Here, we present a wearable sweat band on a nanodendritic platform that quantitatively monitors levodopa dynamics in the body. Both stationary iontophoretic induction and physical exercise are utilized as our methods of sweat extraction. The sweat band measures real-time pharmacokinetic profiles of levodopa to track the dynamic response of the drug metabolism. We demonstrated the sweat band’s functionalities on multiple subjects with implications toward the systematic administering of levodopa and routine management of Parkinson’s disease.

Published
2024
Full Text
View/download PDF

35. Wearable sweat biosensors

Author

Gao, Wei, Nyein, Hnin Y. Y., Shahpar, Ziba, Tai, Li-Chia, Wu, Eric, Bariya, Mallika, Ota, Hiroki, Fahad, Hossain M., Chen, Kevin, Javey, Ali, Gao, Wei, Nyein, Hnin Y. Y., Shahpar, Ziba, Tai, Li-Chia, Wu, Eric, Bariya, Mallika, Ota, Hiroki, Fahad, Hossain M., Chen, Kevin, and Javey, Ali

Abstract

Wearable perspiration biosensors enable real-time analysis of the sweat composition and can provide insightful information about health conditions. In this review, we discuss the recent developments in wearable sweat sensing platforms and detection techniques. Specifically, on-body monitoring of a wide spectrum of sweat biomarkers are illustrated. Opportunities and challenges in the field are discussed. Although still in an early research stage, wearable sweat biosensors may enable a wide range of personalized diagnostic and physiological monitoring applications.

Published
2016

36. A Wearable Electrochemical Platform for Noninvasive Simultaneous Monitoring of Ca2+and pH

Author

Nyein, Hnin Yin Yin, Gao, Wei, Shahpar, Ziba, Emaminejad, Sam, Challa, Samyuktha, Chen, Kevin, Fahad, Hossain M., Tai, Li-Chia, Ota, Hiroki, Davis, Ronald W., and Javey, Ali

Abstract

Homeostasis of ionized calcium in biofluids is critical for human biological functions and organ systems. Measurement of ionized calcium for clinical applications is not easily accessible due to its strict procedures and dependence on pH. pH balance in body fluids greatly affects metabolic reactions and biological transport systems. Here, we demonstrate a wearable electrochemical device for continuous monitoring of ionized calcium and pH of body fluids using a disposable and flexible array of Ca2+and pH sensors that interfaces with a flexible printed circuit board. This platform enables real-time quantitative analysis of these sensing elements in body fluids such as sweat, urine, and tears. Accuracy of Ca2+concentration and pH measured by the wearable sensors is validated through inductively coupled plasma-mass spectrometry technique and a commercial pH meter, respectively. Our results show that the wearable sensors have high repeatability and selectivity to the target ions. Real-time on-body assessment of sweat is also performed, and our results indicate that calcium concentration increases with decreasing pH. This platform can be used in noninvasive continuous analysis of ionized calcium and pH in body fluids for disease diagnosis such as primary hyperparathyroidism and kidney stones.

Published
2016
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results