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Yeo,
Woon-Hong
Yeo,
Woon-Hong
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ItemSkin-like, Soft Patch for Continuous Cognitive Stress Monitoring(Georgia Institute of Technology, 2023-01-26) Zavanelli, Nathan ; Yeo, Woon-HongHere, we present a skin-like, wearable patch microfabricated to seamlessly integrate with the human body and provide high fidelity physiological monitoring in a simple, minimally obtrusive platform. Specifically, this device has been optimized to capture minute chest vibrations produced by the heart’s mechanical beats, referred to as the seismocardiogram (SCG). along with the traditional electrocardiogram (ECG) and pulse oximetry (PPG) signals in a single platform located on the sternum; mathematical tools developed in the study of seismology are then implemented to characterize the heart’s mechanical function and arousal state. In tandem with the PPG and ECG signals, this SCG analysis is used to continuously monitor cognitive stress, which is a notoriously difficult challenge because traditional monitoring signals, like heart rate variability and galvanic skin response are modulated by numerous confounding physiological factors. In contrast, preliminary studies with the soft device demonstrated an r2 correlation with salivary cortisol during controlled stressor activities of 0.81 compared to 0.59 for heart rate variability. Additional clinical testing is being pursued, and should this correlation be proven, this device would represent a substantial improvement in long-duration, continuous stress monitoring in daily life over alternative approaches. This in turn would have wide applications in dementia care, pain assessment, high stress workplace management (e.g., for surgeons and pilots), mental health treatment, and simple wellness.
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ItemNanomaterials and Scalable, Low-Cost Screen Printing for Soft Wearable Bioelectronics(Georgia Institute of Technology, 2022-04-07) Zavanelli, Nathan ; Yeo, Woon-HongStretchable electronics have demonstrated tremendous potential in wearable healthcare, advanced diagnostics, soft robotics, and persistent human–machine interfaces. Still, their applicability is limited by a reliance on low-throughput, high-cost fabrication methods. Traditional MEMS/NEMS metallization and off-contact direct-printing methods are not suitable at scale. In contrast, screen printing is a high-throughput, mature printing method. The recent development of conductive nanomaterial inks that are intrinsically stretchable provides an exciting opportunity for scalable fabrication of stretchable electronics. The design of screen-printed inks is constrained by strict rheological requirements during printing, substrate–ink attraction, and nanomaterial properties that determine dispersibility and percolation threshold. Here, we present our recent work developing screen-printable nanomaterial inks, optimizing printing parameters for ultrafine patterning down to <60 µm, investigating multilevel material adhesion and reliability, designing complex sensors, and integrating these innovations into functional bioelectronics. Specifically, we present high precision screen printing of functional nanomaterials to enable fabrication of highly functional biopotential electrodes, thermoelectric nanogenerators, flexible circuits, semiconductors, printed vias, solderable circuit pads, strain gauges, and pressure sensors. These fundamental advances in materials fabrication and high-throughput bioelectronics fabrication have transformative potential for the field of soft electronics, and we are committed to further studies on these systems to validate their potential in functional devices.
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ItemSoft Sternal Patch to Detect Sleep Stages and Sleep Apnea(Georgia Institute of Technology, 2022-01-27) Zavanelli, Nathan ; Yeo, Woon-HongObstructive sleep apnea (OSA) affects over 900 million adults globally, and around eighty percent of cases remain undiagnosed. This critical failure leaves millions of people at an increased risk for serious health complications, like hypertension, obesity, diabetes, and cardiac irregularities. Current diagnostic techniques are fundamentally limited by low throughputs, in the case of polysomnography, and high failure rates, in the case of home sleep tests. Here, we report a wireless, fully integrated, soft sternal patch with mechanics optimized to detect the mechanical, electrical, and optical signals that characterize the cardiovascular response to OSA. Analytical and computational studies in mechanics and material interfaces yielded a fully integrated, multi-sensor system capable of capturing ultrafine, low-frequency, sternal vibrations caused by the heart’s motion, cardiac electrical signals, and optical measurements of arterial blood oxygenation from a single location on the sternum, which has not been previously realized. Advanced digital signal processing and machine learning techniques are used to detect apneas and characterize each event’s acute cardiovascular consequences. In trials with symptomatic and control subjects conducted in their homes, the soft device demonstrates excellent ability to detect blood-oxygen saturation, respiratory effort, respiration rate, heart rate, cardiac pre-ejection period and ejection timing, aortic opening mechanics, heart rate variability, and sleep staging, making it the first single patch capable of capturing all the clinically essential metrics for OSA diagnosis recommended by the American Academy of Sleep Medicine. Finally, these metrics are used to autodetect apneas and hypopneas with 100% sensitivity and 95% precision with symptomatic patients compared to data scored by professionally certified sleep clinicians.
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ItemSoft Nanomembrane Sensors and Electronics for Integration with Robots(Georgia Institute of Technology, 2021-08-25) Yeo, Woon-Hong
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ItemSmart and Connected Soft Bioelectronics for Advancing Human Healthcare and Human-Machine Interfaces( 2020-09-10) Yeo, Woon-HongIn this talk, Dr. Yeo will share the results of the fundamental study in soft materials, flexible mechanics, nanomanufacturing, and machine learning to develop soft electronics. In addition, he will talk about the details of how the basic knowledge can be applied to develop smart and connected wearable electronics. He will share some of the applications that used soft electronics for advancing human healthcare, persistent human-machine interfaces, and advanced therapeutics.
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ItemWireless, Stretchable Hybrid Electronics for Smart and Connected Physiological Monitoring(Georgia Institute of Technology, 2019-10-10) Yeo, Woon-HongThe goal of Dr. Yeo’s research is to understand fundamentals of soft materials, deformable mechanics, biological interface forces, and nanomanufacturing methods for development of stretchable hybrid biosensors and bioelectronics. The comprehensive study of mechanics, materials, and manufacturing for biosystems aims to advance human healthcare, disease diagnostics, therapeutics, and human-machine interaction. In this talk, he will discuss about recent research outcomes on fully portable, wireless, soft wearable electronics for advanced physiological monitoring and persistent brain-machine interfaces.