Your search keyword '"Namkoong, Myeong"' showing total 5 results

1. Molecularly Imprinted Wearable Sensor with Paper Microfluidics for Real-Time Sweat Biomarker Analysis

Author

Garg, Mayank, Guo, Heng, Maclam, Ethan, Zhanov, Elizabeth, Samudrala, Sathwika, Pavlov, Anton, Rahman, Md Saifur, Namkoong, Myeong, Moreno, Jennette P., and Tian, Limei

Abstract

The urgent need for real-time and noninvasive monitoring of health-associated biochemical parameters has motivated the development of wearable sweat sensors. Existing electrochemical sensors show promise in real-time analysis of various chemical biomarkers. These sensors often rely on labels and redox probes to generate and amplify the signals for the detection and quantification of analytes with limited sensitivity. In this study, we introduce a molecularly imprinted polymer (MIP)-based biochemical sensor to quantify a molecular biomarker in sweat using electrochemical impedance spectroscopy, which eliminates the need for labels or redox probes. The molecularly imprinted biosensor can achieve sensitive and specific detection of cortisol at concentrations as low as 1 pM, 1000-fold lower than previously reported MIP cortisol sensors. We integrated multimodal electrochemical sensors with an iontophoresis sweat extraction module and paper microfluidics for real-time sweat analysis. Several parameters can be simultaneously quantified, including sweat volume, secretion rate, sodium ion, and cortisol concentration. Paper microfluidic modules not only quantify sweat volume and secretion rate but also facilitate continuous sweat analysis without user intervention. While we focus on cortisol sensing as a proof-of-concept, the molecularly imprinted wearable sensors can be extended to real-time detection of other biochemicals, such as protein biomarkers and therapeutic drugs.

Published

2024

2. Nanoengineered Ink for Designing 3D Printable Flexible Bioelectronics

Author

Deo, Kaivalya A., Jaiswal, Manish K., Abasi, Sara, Lokhande, Giriraj, Bhunia, Sukanya, Nguyen, Thuy-Uyen, Namkoong, Myeong, Darvesh, Kamran, Guiseppi-Elie, Anthony, Tian, Limei, and Gaharwar, Akhilesh K.

Abstract

Flexible electronics require elastomeric and conductive biointerfaces with native tissue-like mechanical properties. The conventional approaches to engineer such a biointerface often utilize conductive nanomaterials in combination with polymeric hydrogels that are cross-linked using toxic photoinitiators. Moreover, these systems frequently demonstrate poor biocompatibility and face trade-offs between conductivity and mechanical stiffness under physiological conditions. To address these challenges, we developed a class of shear-thinning hydrogels as biomaterial inks for 3D printing flexible bioelectronics. These hydrogels are engineered through a facile vacancy-driven gelation of MoS2nanoassemblies with naturally derived polymer-thiolated gelatin. Due to shear-thinning properties, these nanoengineered hydrogels can be printed into complex shapes that can respond to mechanical deformation. The chemically cross-linked nanoengineered hydrogels demonstrate a 20-fold rise in compressive moduli and can withstand up to 80% strain without permanent deformation, meeting human anatomical flexibility. The nanoengineered network exhibits high conductivity, compressive modulus, pseudocapacitance, and biocompatibility. The 3D-printed cross-linked structure demonstrates excellent strain sensitivity and can be used as wearable electronics to detect various motion dynamics. Overall, the results suggest that these nanoengineered hydrogels offer improved mechanical, electronic, and biological characteristics for various emerging biomedical applications including 3D-printed flexible biosensors, actuators, optoelectronics, and therapeutic delivery devices.

Published

2022

3. Printed Ultrastable Bioplasmonic Microarrays for Point-of-Need Biosensing

Author

Guo, Heng, Yin, Ze, Namkoong, Myeong, Li, Yixuan, Nguyen, Tan, Salcedo, Elizabeth, Arizpe, Ivanna, and Tian, Limei

Abstract

Paper-based point-of-need (PON) biosensors are attractive for various applications, including food safety, agriculture, disease diagnosis, and drug screening, owing to their low cost and ease of use. However, existing paper-based biosensors mainly rely on biolabels, colorimetric reagents, and biorecognition elements and exhibit limited stability under harsh environments. Here, we report a label-free paper-based biosensor composed of bioplasmonic microarrays for sensitive detection and quantification of protein targets in small volumes of biofluids. Bioplasmonic microarrays were printed using an ultrastable bioplasmonic ink, rendering the PON sensors excellent thermal, chemical, and biological stability for their reliable performance in resource-limited settings. We fabricated silicone hydrophobic barriers and bioplasmonic microarrays with direct writing and droplet jetting approaches on a three-dimensional (3D) nanoporous paper. Direct writing hydrophobic barriers can define hydrophilic channels less than 100 μm wide. High-resolution patterning of hydrophilic test domains enables the handling and analysis of small fluid volumes. We show that the plasmonic sensors based on a vertical flow assay provide similar sensitivity and low limit of detection with a 60 μL sample volume compared to those with 500 μL samples based on an immersion approach and can shorten assay time from 90 to 20 min.

Published

2022

4. Skin-interfaced biosensors for advanced wireless physiological monitoring in neonatal and pediatric intensive-care units

Author

Chung, Ha Uk, Rwei, Alina Y., Hourlier-Fargette, Aurélie, Xu, Shuai, Lee, KunHyuck, Dunne, Emma C., Xie, Zhaoqian, Liu, Claire, Carlini, Andrea, Kim, Dong Hyun, Ryu, Dennis, Kulikova, Elena, Cao, Jingyue, Odland, Ian C., Fields, Kelsey B., Hopkins, Brad, Banks, Anthony, Ogle, Christopher, Grande, Dominic, Park, Jun Bin, Kim, Jongwon, Irie, Masahiro, Jang, Hokyung, Lee, JooHee, Park, Yerim, Kim, Jungwoo, Jo, Han Heul, Hahm, Hyoungjo, Avila, Raudel, Xu, Yeshou, Namkoong, Myeong, Kwak, Jean Won, Suen, Emily, Paulus, Max A., Kim, Robin J., Parsons, Blake V., Human, Kelia A., Kim, Seung Sik, Patel, Manish, Reuther, William, Kim, Hyun Soo, Lee, Sung Hoon, Leedle, John D., Yun, Yeojeong, Rigali, Sarah, Son, Taeyoung, Jung, Inhwa, Arafa, Hany, Soundararajan, Vinaya R., Ollech, Ayelet, Shukla, Avani, Bradley, Allison, Schau, Molly, Rand, Casey M., Marsillio, Lauren E., Harris, Zena L., Huang, Yonggang, Hamvas, Aaron, Paller, Amy S., Weese-Mayer, Debra E., Lee, Jong Yoon, and Rogers, John A.

Abstract

Standard clinical care in neonatal and pediatric intensive-care units (NICUs and PICUs, respectively) involves continuous monitoring of vital signs with hard-wired devices that adhere to the skin and, in certain instances, can involve catheter-based pressure sensors inserted into the arteries. These systems entail risks of causing iatrogenic skin injuries, complicating clinical care and impeding skin-to-skin contact between parent and child. Here we present a wireless, non-invasive technology that not only offers measurement equivalency to existing clinical standards for heart rate, respiration rate, temperature and blood oxygenation, but also provides a range of important additional features, as supported by data from pilot clinical studies in both the NICU and PICU. These new modalities include tracking movements and body orientation, quantifying the physiological benefits of skin-to-skin care, capturing acoustic signatures of cardiac activity, recording vocal biomarkers associated with tonality and temporal characteristics of crying and monitoring a reliable surrogate for systolic blood pressure. These platforms have the potential to substantially enhance the quality of neonatal and pediatric critical care.

Published

2020

5. Wireless sensors for continuous, multimodal measurements at the skin interface with lower limb prostheses

Author

Kwak, Jean Won, Han, Mengdi, Xie, Zhaoqian, Chung, Ha Uk, Lee, Jong Yoon, Avila, Raudel, Yohay, Jessica, Chen, Xuexian, Liang, Cunman, Patel, Manish, Jung, Inhwa, Kim, Jongwon, Namkoong, Myeong, Kwon, Kyeongha, Guo, Xu, Ogle, Christopher, Grande, Dominic, Ryu, Dennis, Kim, Dong Hyun, Madhvapathy, Surabhi, Liu, Claire, Yang, Da Som, Park, Yoonseok, Caldwell, Ryan, Banks, Anthony, Xu, Shuai, Huang, Yonggang, Fatone, Stefania, and Rogers, John A.

Abstract

Wireless, soft sensors continuously monitor pressure and temperature at the interface between a residual limb and a prosthesis.

Published

2020