Your search keyword '"Tee BCK"' showing total 9 results

1. A nerve-like self-healable conductive wire.

Author

Fu X and Tee BCK

Published

2024

2. Implant-to-implant wireless networking with metamaterial textiles.

Author

Tian X, Zeng Q, Kurt SA, Li RR, Nguyen DT, Xiong Z, Li Z, Yang X, Xiao X, Wu C, Tee BCK, Nikolayev D, Charles CJ, and Ho JS

Subjects

Animals, Humans, Swine, Wireless Technology, Radio Waves, Equipment Design, Prostheses and Implants, Textiles

Abstract

Implanted bioelectronic devices can form distributed networks capable of sensing health conditions and delivering therapy throughout the body. Current clinically-used approaches for wireless communication, however, do not support direct networking between implants because of signal losses from absorption and reflection by the body. As a result, existing examples of such networks rely on an external relay device that needs to be periodically recharged and constitutes a single point of failure. Here, we demonstrate direct implant-to-implant wireless networking at the scale of the human body using metamaterial textiles. The textiles facilitate non-radiative propagation of radio-frequency signals along the surface of the body, passively amplifying the received signal strength by more than three orders of magnitude (>30 dB) compared to without the textile. Using a porcine model, we demonstrate closed-loop control of the heart rate by wirelessly networking a loop recorder and a vagus nerve stimulator at more than 40 cm distance. Our work establishes a wireless technology to directly network body-integrated devices for precise and adaptive bioelectronic therapies., (© 2023. The Author(s).)

Published

2023

3. Battery-free and AI-enabled multiplexed sensor patches for wound monitoring.

Author

Zheng XT, Yang Z, Sutarlie L, Thangaveloo M, Yu Y, Salleh NABM, Chin JS, Xiong Z, Becker DL, Loh XJ, Tee BCK, and Su X

Subjects

Rats, Animals, Machine Learning, Algorithms, Wound Healing, Burns

Abstract

Wound healing is a dynamic process with multiple phases. Rapid profiling and quantitative characterization of inflammation and infection remain challenging. We report a paper-like battery-free in situ AI-enabled multiplexed (PETAL) sensor for holistic wound assessment by leveraging deep learning algorithms. This sensor consists of a wax-printed paper panel with five colorimetric sensors for temperature, pH, trimethylamine, uric acid, and moisture. Sensor images captured by a mobile phone were analyzed by neural network-based machine learning algorithms to determine healing status. For ex situ detection via exudates collected from rat perturbed wounds and burn wounds, the PETAL sensor can classify healing versus nonhealing status with an accuracy as high as 97%. With the sensor patches attached on rat burn wound models, in situ monitoring of wound progression or severity is demonstrated. This PETAL sensor allows early warning of adverse events, which could trigger immediate clinical intervention to facilitate wound care management.

Published

2023

4. Macromolecule conformational shaping for extreme mechanical programming of polymorphic hydrogel fibers.

Author

Wang XQ, Chan KH, Lu W, Ding T, Ng SWL, Cheng Y, Li T, Hong M, Tee BCK, and Ho GW

Subjects

Elasticity, Polyelectrolytes, Hydrogels, Polymers

Abstract

Mechanical properties of hydrogels are crucial to emerging devices and machines for wearables, robotics and energy harvesters. Various polymer network architectures and interactions have been explored for achieving specific mechanical characteristics, however, extreme mechanical property tuning of single-composition hydrogel material and deployment in integrated devices remain challenging. Here, we introduce a macromolecule conformational shaping strategy that enables mechanical programming of polymorphic hydrogel fiber based devices. Conformation of the single-composition polyelectrolyte macromolecule is controlled to evolve from coiling to extending states via a pH-dependent antisolvent phase separation process. The resulting structured hydrogel microfibers reveal extreme mechanical integrity, including modulus spanning four orders of magnitude, brittleness to ultrastretchability, and plasticity to anelasticity and elasticity. Our approach yields hydrogel microfibers of varied macromolecule conformations that can be built-in layered formats, enabling the translation of extraordinary, realistic hydrogel electronic applications, i.e., large strain (1000%) and ultrafast responsive (~30 ms) fiber sensors in a robotic bird, large deformations (6000%) and antifreezing helical electronic conductors, and large strain (700%) capable Janus springs energy harvesters in wearables., (© 2022. The Author(s).)

Published

2022

5. A wireless and battery-free wound infection sensor based on DNA hydrogel.

Author

Xiong Z, Achavananthadith S, Lian S, Madden LE, Ong ZX, Chua W, Kalidasan V, Li Z, Liu Z, Singh P, Yang H, Heussler SP, Kalaiselvi SMP, Breese MBH, Yao H, Gao Y, Sanmugam K, Tee BCK, Chen PY, Loke W, Lim CT, Chiang GSH, Tan BY, Li H, Becker DL, and Ho JS

Abstract

The confluence of wireless technology and biosensors offers the possibility to detect and manage medical conditions outside of clinical settings. Wound infections represent a major clinical challenge in which timely detection is critical for effective interventions, but this is currently hindered by the lack of a monitoring technology that can interface with wounds, detect pathogenic bacteria, and wirelessly transmit data. Here, we report a flexible, wireless, and battery-free sensor that provides smartphone-based detection of wound infection using a bacteria-responsive DNA hydrogel. The engineered DNA hydrogels respond selectively to deoxyribonucleases associated with pathogenic bacteria through tunable dielectric changes, which can be wirelessly detected using near-field communication. In a mouse acute wound model, we demonstrate that the wireless sensor can detect physiologically relevant amounts of Staphylococcus aureus even before visible manifestation of infection. These results demonstrate strategies for continuous infection monitoring, which may facilitate improved management of surgical or chronic wounds.

Published

2021

6. Artificially innervated self-healing foams as synthetic piezo-impedance sensor skins.

Author

Guo H, Tan YJ, Chen G, Wang Z, Susanto GJ, See HH, Yang Z, Lim ZW, Yang L, and Tee BCK

Subjects

Biomimetic Materials, Biomimetics methods, Biosensing Techniques methods, Electric Conductivity, Electrochemical Techniques methods, Electrodes, Equipment Design, Humans, Mechanical Phenomena, Nanostructures, Nanotechnology instrumentation, Nanotechnology methods, Surface Properties, Wound Healing, Biomimetics instrumentation, Biosensing Techniques instrumentation, Electric Impedance, Electrochemical Techniques instrumentation, Skin injuries

Abstract

Human skin is a self-healing mechanosensory system that detects various mechanical contact forces efficiently through three-dimensional innervations. Here, we propose a biomimetic artificially innervated foam by embedding three-dimensional electrodes within a new low-modulus self-healing foam material. The foam material is synthesized from a one-step self-foaming process. By tuning the concentration of conductive metal particles in the foam at near-percolation, we demonstrate that it can operate as a piezo-impedance sensor in both piezoresistive and piezocapacitive sensing modes without the need for an encapsulation layer. The sensor is sensitive to an object's contact force directions as well as to human proximity. Moreover, the foam material self-heals autonomously with immediate function restoration despite mechanical damage. It further recovers from mechanical bifurcations with gentle heating (70 °C). We anticipate that this material will be useful as damage robust human-machine interfaces.

Published

2020

7. Near-hysteresis-free soft tactile electronic skins for wearables and reliable machine learning.

Author

Yao H, Yang W, Cheng W, Tan YJ, See HH, Li S, Ali HPA, Lim BZH, Liu Z, and Tee BCK

Subjects

Humans, Materials Science, Pressure, Pulse Wave Analysis, Machine Learning, Wearable Electronic Devices

Abstract

Electronic skins are essential for real-time health monitoring and tactile perception in robots. Although the use of soft elastomers and microstructures have improved the sensitivity and pressure-sensing range of tactile sensors, the intrinsic viscoelasticity of soft polymeric materials remains a long-standing challenge resulting in cyclic hysteresis. This causes sensor data variations between contact events that negatively impact the accuracy and reliability. Here, we introduce the Tactile Resistive Annularly Cracked E-Skin (TRACE) sensor to address the inherent trade-off between sensitivity and hysteresis in tactile sensors when using soft materials. We discovered that piezoresistive sensors made using an array of three-dimensional (3D) metallic annular cracks on polymeric microstructures possess high sensitivities (> 10 7 Ω ⋅ kPa -1 ), low hysteresis (2.99 ± 1.37%) over a wide pressure range (0-20 kPa), and fast response (400 Hz). We demonstrate that TRACE sensors can accurately detect and measure the pulse wave velocity (PWV) when skin mounted. Moreover, we show that these tactile sensors when arrayed enabled fast reliable one-touch surface texture classification with neuromorphic encoding and deep learning algorithms., Competing Interests: The authors declare no competing interest.

Published

2020

8. Wireless battery-free body sensor networks using near-field-enabled clothing.

Author

Lin R, Kim HJ, Achavananthadith S, Kurt SA, Tan SCC, Yao H, Tee BCK, Lee JKW, and Ho JS

Subjects

Electric Power Supplies, Electromagnetic Phenomena, Equipment Design, Exercise physiology, Humans, Knee, Posture physiology, Spine physiology, Temperature, Walking physiology, Clothing, Monitoring, Ambulatory instrumentation, Monitoring, Ambulatory methods, Wireless Technology instrumentation

Abstract

Networks of sensors placed on the skin can provide continuous measurement of human physiological signals for applications in clinical diagnostics, athletics and human-machine interfaces. Wireless and battery-free sensors are particularly desirable for reliable long-term monitoring, but current approaches for achieving this mode of operation rely on near-field technologies that require close proximity (at most a few centimetres) between each sensor and a wireless readout device. Here, we report near-field-enabled clothing capable of establishing wireless power and data connectivity between multiple distant points around the body to create a network of battery-free sensors interconnected by proximity to functional textile patterns. Using computer-controlled embroidery of conductive threads, we integrate clothing with near-field-responsive patterns that are completely fabric-based and free of fragile silicon components. We demonstrate the utility of the networked system for real-time, multi-node measurement of spinal posture as well as continuous sensing of temperature and gait during exercise.

Published

2020

9. Design and applications of stretchable and self-healable conductors for soft electronics.

Author

Zhao Y, Kim A, Wan G, and Tee BCK

Abstract

Soft and conformable electronics are emerging rapidly and is envisioned as the future of next-generation electronic devices where devices can be readily deployed in various environments, such as on-body, on-skin or as a biomedical implant. Modern day electronics require electrical conductors as the fundamental building block for stretchable electronic devices and systems. In this review, we will study the various strategies and methods of designing and fabricating materials which are conductive, stretchable and self-healable, and explore relevant applications such as flexible and stretchable sensors, electrodes and energy harvesters.

Published

2019