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22 results on '"Xie, Zhaoqian"'

2. Design of protective and high sensitivity encapsulation layers in wearable devices.

Author

Wang, XiuFeng, Huang, JieLong, Liu, YangChengYi, Tan, JinYuan, Chen, ShangDa, Avila, Raudel, and Xie, ZhaoQian

Abstract

Elastomeric encapsulation layers are widely used in soft, wearable devices to physically isolate rigid electronic components from external environmental stimuli (e.g., stress) and facilitate device sterilization for reusability. In devices experiencing large deformations, the stress-isolation effect of the top encapsulation layer can eliminate the damage to the electronic components caused by external forces. However, for health monitoring and sensing applications, the strain-isolation effect of the bottom encapsulation layer can partially block the physiological signals of interest and degrade the measurement accuracy. Here, an analytic model is developed for the strain- and stress-isolation effects present in wearable devices with elastomeric encapsulation layers. The soft, elastomeric encapsulation layers and main electronic components layer are modeled as transversely isotropic-elastic mediums and the strain- and stress-isolation effects are described using isolation indexes. The analysis and results show that the isolation effects strongly depend on the thickness, density, and elastic modulus of both the elastomeric encapsulation layers and the main electronic component layer. These findings, combined with the flexible mechanics design strategies of wearable devices, provide new design guidelines for future wearable devices to protect them from external forces while capturing the relevant physiological signals underneath the skin. [ABSTRACT FROM AUTHOR]

Published
2023
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4. Miniaturization of mechanical actuators in skin-integrated electronics for haptic interfaces.

Author

Li, Dengfeng, He, Jiahui, Song, Zhen, Yao, Kuanming, Wu, Mengge, Fu, Haoran, Liu, Yiming, Gao, Zhan, Zhou, Jingkun, Wei, Lei, Zhang, Zhengyou, Dai, Yuan, Xie, Zhaoqian, and Yu, Xinge

Subjects
ELECTRONICS, BIOMEDICAL engineering, ACCURACY, RESONANCE frequency analysis, MATERIALS testing
Abstract

Skin-integrated electronics, also known as electronic skin (e-skin), are rapidly developing and are gradually being adopted in biomedical fields as well as in our daily lives. E-skin capable of providing sensitive and high-resolution tactile sensations and haptic feedback to the human body would open a new e-skin paradigm for closed-loop human–machine interfaces. Here, we report a class of materials and mechanical designs for the miniaturization of mechanical actuators and strategies for their integration into thin, soft e-skin for haptic interfaces. The mechanical actuators exhibit small dimensions of 5 mm diameter and 1.45 mm thickness and work in an electromagnetically driven vibrotactile mode with resonance frequency overlapping the most sensitive frequency of human skin. Nine mini actuators can be integrated simultaneously in a small area of 2 cm × 2 cm to form a 3 × 3 haptic feedback array, which is small and compact enough to mount on a thumb tip. Furthermore, the thin, soft haptic interface exhibits good mechanical properties that work properly during stretching, bending, and twisting and therefore can conformally fit onto various parts of the human body to afford programmable tactile enhancement and Braille recognition with an accuracy rate over 85%. [ABSTRACT FROM AUTHOR]

Published
2021
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5. Fully implantable and bioresorbable cardiac pacemakers without leads or batteries.

Author

Choi, Yeon Sik, Yin, Rose T., Pfenniger, Anna, Koo, Jahyun, Avila, Raudel, Benjamin Lee, K., Chen, Sheena W., Lee, Geumbee, Li, Gang, Qiao, Yun, Murillo-Berlioz, Alejandro, Kiss, Alexi, Han, Shuling, Lee, Seung Min, Li, Chenhang, Xie, Zhaoqian, Chen, Yu-Yu, Burrell, Amy, Geist, Beth, and Jeong, Hyoyoung

Abstract

Temporary cardiac pacemakers used in periods of need during surgical recovery involve percutaneous leads and externalized hardware that carry risks of infection, constrain patient mobility and may damage the heart during lead removal. Here we report a leadless, battery-free, fully implantable cardiac pacemaker for postoperative control of cardiac rate and rhythm that undergoes complete dissolution and clearance by natural biological processes after a defined operating timeframe. We show that these devices provide effective pacing of hearts of various sizes in mouse, rat, rabbit, canine and human cardiac models, with tailored geometries and operation timescales, powered by wireless energy transfer. This approach overcomes key disadvantages of traditional temporary pacing devices and may serve as the basis for the next generation of postoperative temporary pacing technology. A biodegradable pacemaker without external leads improves the safety of temporary cardiac pacing. [ABSTRACT FROM AUTHOR]

Published
2021
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6. Three-dimensional electronic microfliers inspired by wind-dispersed seeds.

Author

Kim, Bong Hoon, Li, Kan, Kim, Jin-Tae, Park, Yoonseok, Jang, Hokyung, Wang, Xueju, Xie, Zhaoqian, Won, Sang Min, Yoon, Hong-Joon, Lee, Geumbee, Jang, Woo Jin, Lee, Kun Hyuck, Chung, Ted S., Jung, Yei Hwan, Heo, Seung Yun, Lee, Yechan, Kim, Juyun, Cai, Tengfei, Kim, Yeonha, and Prasopsukh, Poom

Abstract

Large, distributed collections of miniaturized, wireless electronic devices1,2 may form the basis of future systems for environmental monitoring3, population surveillance4, disease management5 and other applications that demand coverage over expansive spatial scales. Aerial schemes to distribute the components for such networks are required, and—inspired by wind-dispersed seeds6—we examined passive structures designed for controlled, unpowered flight across natural environments or city settings. Techniques in mechanically guided assembly of three-dimensional (3D) mesostructures7–9 provide access to miniature, 3D fliers optimized for such purposes, in processes that align with the most sophisticated production techniques for electronic, optoelectronic, microfluidic and microelectromechanical technologies. Here we demonstrate a range of 3D macro-, meso- and microscale fliers produced in this manner, including those that incorporate active electronic and colorimetric payloads. Analytical, computational and experimental studies of the aerodynamics of high-performance structures of this type establish a set of fundamental considerations in bio-inspired design, with a focus on 3D fliers that exhibit controlled rotational kinematics and low terminal velocities. An approach that represents these complex 3D structures as discrete numbers of blades captures the essential physics in simple, analytical scaling forms, validated by computational and experimental results. Battery-free, wireless devices and colorimetric sensors for environmental measurements provide simple examples of a wide spectrum of applications of these unusual concepts.With a design inspired by wind-dispersed seeds, a series of three-dimensional passive fliers at the macro-, meso- and microscale are realized that can bear active electronic payloads. [ABSTRACT FROM AUTHOR]

Published
2021
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7. Battery-free, wireless soft sensors for continuous multi-site measurements of pressure and temperature from patients at risk for pressure injuries.

Author

Oh, Yong Suk, Kim, Jae-Hwan, Xie, Zhaoqian, Cho, Seokjoo, Han, Hyeonseok, Jeon, Sung Woo, Park, Minsu, Namkoong, Myeong, Avila, Raudel, Song, Zhen, Lee, Sung-Uk, Ko, Kabseok, Lee, Jungyup, Lee, Je-Sang, Min, Weon Gi, Lee, Byeong-Ju, Choi, Myungwoo, Chung, Ha Uk, Kim, Jongwon, and Han, Mengdi

Subjects
PRESSURE ulcers, PRESSURE measurement, SKIN temperature, TEMPERATURE measurements, DETECTORS, PRESSURE sensors
Abstract

Capabilities for continuous monitoring of pressures and temperatures at critical skin interfaces can help to guide care strategies that minimize the potential for pressure injuries in hospitalized patients or in individuals confined to the bed. This paper introduces a soft, skin-mountable class of sensor system for this purpose. The design includes a pressure-responsive element based on membrane deflection and a battery-free, wireless mode of operation capable of multi-site measurements at strategic locations across the body. Such devices yield continuous, simultaneous readings of pressure and temperature in a sequential readout scheme from a pair of primary antennas mounted under the bedding and connected to a wireless reader and a multiplexer located at the bedside. Experimental evaluation of the sensor and the complete system includes benchtop measurements and numerical simulations of the key features. Clinical trials involving two hemiplegic patients and a tetraplegic patient demonstrate the feasibility, functionality and long-term stability of this technology in operating hospital settings. Uninterrupted monitoring of pressure and temperature at skin interfaces can help to minimize the potential for pressure injuries in hospitalized or bedridden patients. Here, the authors introduce a soft, skin-mountable sensor that can continuously provide readings via antennas mounted under bedding, and demonstrate the functionality and robustness of the devices on patients. [ABSTRACT FROM AUTHOR]

Published
2021
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9. A metal-electrode-free, fully integrated, soft triboelectric sensor array for self-powered tactile sensing.

Author

Wang, Lingyun, Liu, Yiming, Liu, Qing, Zhu, Yuyan, Wang, Haoyu, Xie, Zhaoqian, Yu, Xinge, and Zi, Yunlong

Abstract

The dramatic advances in flexible/wearable electronics have garnered great attention for touch sensors for practical applications in human health monitoring and human–machine interfaces. Self-powered triboelectric tactile sensors with high sensitivity, reduced crosstalk, and simple processing routes are highly desirable. Herein, we introduce a facile and low-cost fabrication approach for a metal-electrode free, fully integrated, flexible, and self-powered triboelectric tactile sensor array with 8-by-8 sensor units. Through the height difference between the sensor units and interconnect electrodes, the crosstalk derived from the electrodes has been successfully suppressed with no additional shielding layers. The tactile sensor array shows a remarkable sensitivity of 0.063 V kPa–1 with a linear range from 5 to 50 kPa, which covers a broad range of testing objects. Furthermore, due to the advanced mechanical design, the flexible sensor array exhibits great capability of pressure sensing even under a curved state. The voltage responses from the pattern mapping by finger touching demonstrate the uniformity of the sensor array. Finally, real-time tactile sensing associated with light-emitting diode (LED) array lighting demonstrates the potential application of the sensor array in position tracking, self-powered touch screens, human–machine interfaces and many others. Sensors: Fully integrated, soft sensor array for self-powered tactile sensing A fully integrated soft tactile sensor array (ISTSA) that is self-powered and without metal electrodes has been developed using a low-cost, easily performed fabrication process. A sensor array is a group of sensors used for collecting and processing electromagnetic signals, and arrays of tactile sensors have recently attracted substantial attention with the growth of wearable electronics and application in health monitoring and human-machine interfaces. A team headed by Yunlong Zi at The Chinese University of Hong Kong succeeded in developing an ISTSA with remarkable sensitivity. The ISTSA is so flexible that it exhibits excellent pressure sensing even in a curved state. The authors conducted real-time tactile sensing with LED lighting and finger touching, and they believe their ISTSA has considerable potential for application in such areas as position tracking, self-powered touch screens, and wearable electronics. [ABSTRACT FROM AUTHOR]

Published
2020
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10. Flexible and stretchable metal oxide nanofiber networks for multimodal and monolithically integrated wearable electronics.

Author

Wang, Binghao, Thukral, Anish, Xie, Zhaoqian, Liu, Limei, Zhang, Xinan, Huang, Wei, Yu, Xinge, Yu, Cunjiang, Marks, Tobin J., and Facchetti, Antonio

Subjects
METALLIC oxides, INDIUM gallium zinc oxide, COPPER oxide, WEARABLE technology, BODY movement, DETECTION limit, ELASTOMERS
Abstract

Fiber-based electronics enabling lightweight and mechanically flexible/stretchable functions are desirable for numerous e-textile/e-skin optoelectronic applications. These wearable devices require low-cost manufacturing, high reliability, multifunctionality and long-term stability. Here, we report the preparation of representative classes of 3D-inorganic nanofiber network (FN) films by a blow-spinning technique, including semiconducting indium-gallium-zinc oxide (IGZO) and copper oxide, as well as conducting indium-tin oxide and copper metal. Specifically, thin-film transistors based on IGZO FN exhibit negligible performance degradation after one thousand bending cycles and exceptional room-temperature gas sensing performance. Owing to their great stretchability, these metal oxide FNs can be laminated/embedded on/into elastomers, yielding multifunctional single-sensing resistors as well as fully monolithically integrated e-skin devices. These can detect and differentiate multiple stimuli including analytes, light, strain, pressure, temperature, humidity, body movement, and respiratory functions. All of these FN-based devices exhibit excellent sensitivity, response time, and detection limits, making them promising candidates for versatile wearable electronics. Designing energy efficient, flexible opto-electronic systems integrated with textiles remains a challenge. Here, the authors propose a solution-based blow-spinning technique for 3D flexible and stretchable metal oxide nanofiber networks for multimodal and monolithically integrated wearable electronics. [ABSTRACT FROM AUTHOR]

Published
2020
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11. Wireless, battery-free, fully implantable multimodal and multisite pacemakers for applications in small animal models.

Author

Gutruf, Philipp, Yin, Rose T., Lee, K. Benjamin, Ausra, Jokubas, Brennan, Jaclyn A., Qiao, Yun, Xie, Zhaoqian, Peralta, Roberto, Talarico, Olivia, Murillo, Alejandro, Chen, Sheena W., Leshock, John P., Haney, Chad R., Waters, Emily A., Zhang, Changxing, Luan, Haiwen, Huang, Yonggang, Trachiotis, Gregory, Efimov, Igor R., and Rogers, John A.

Subjects
CARDIAC pacemakers, ANIMAL models in research, PHENOTYPES, CARDIOVASCULAR diseases, ELECTROTHERAPEUTICS
Abstract

Small animals support a wide range of pathological phenotypes and genotypes as versatile, affordable models for pathogenesis of cardiovascular diseases and for exploration of strategies in electrotherapy, gene therapy, and optogenetics. Pacing tools in such contexts are currently limited to tethered embodiments that constrain animal behaviors and experimental designs. Here, we introduce a highly miniaturized wireless energy-harvesting and digital communication electronics for thin, miniaturized pacing platforms weighing 110 mg with capabilities for subdermal implantation and tolerance to over 200,000 multiaxial cycles of strain without degradation in electrical or optical performance. Multimodal and multisite pacing in ex vivo and in vivo studies over many days demonstrate chronic stability and excellent biocompatibility. Optogenetic stimulation of cardiac cycles with in-animal control and induction of heart failure through chronic pacing serve as examples of modes of operation relevant to fundamental and applied cardiovascular research and biomedical technology. Pacing tools that support small animals and can serve as models for pathogenesis of cardiovascular diseases are currently not available. Here, the authors report a miniaturized wireless battery-free implantable multimodal and multisite pacemaker that provides unlimited stimulation to test subjects. [ABSTRACT FROM AUTHOR]

Published
2019
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12. Skin-integrated wireless haptic interfaces for virtual and augmented reality.

Author

Yu, Xinge, Xie, Zhaoqian, Yu, Yang, Lee, Jungyup, Vazquez-Guardado, Abraham, Luan, Haiwen, Ruban, Jasper, Ning, Xin, Akhtar, Aadeel, Li, Dengfeng, Ji, Bowen, Liu, Yiming, Sun, Rujie, Cao, Jingyue, Huo, Qingze, Zhong, Yishan, Lee, ChanMi, Kim, SeungYeop, Gutruf, Philipp, and Zhang, Changxing

Abstract

Traditional technologies for virtual reality (VR) and augmented reality (AR) create human experiences through visual and auditory stimuli that replicate sensations associated with the physical world. The most widespread VR and AR systems use head-mounted displays, accelerometers and loudspeakers as the basis for three-dimensional, computer-generated environments that can exist in isolation or as overlays on actual scenery. In comparison to the eyes and the ears, the skin is a relatively underexplored sensory interface for VR and AR technology that could, nevertheless, greatly enhance experiences at a qualitative level, with direct relevance in areas such as communications, entertainment and medicine1,2. Here we present a wireless, battery-free platform of electronic systems and haptic (that is, touch-based) interfaces capable of softly laminating onto the curved surfaces of the skin to communicate information via spatio-temporally programmable patterns of localized mechanical vibrations. We describe the materials, device structures, power delivery strategies and communication schemes that serve as the foundations for such platforms. The resulting technology creates many opportunities for use where the skin provides an electronically programmable communication and sensory input channel to the body, as demonstrated through applications in social media and personal engagement, prosthetic control and feedback, and gaming and entertainment. Interfaces for epidermal virtual reality technology are demonstrated that can communicate by programmable patterns of localized mechanical vibrations. [ABSTRACT FROM AUTHOR]

Published
2019
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15. Laser quenching and ion sulphidizing complex surface treat technology for diesel engine cylinder.

Author

Xie, Zhaoqian, Zeng, Qingqiang, Huang, Huayuan, Cai, Zhihai, and Zhao, Yuqiang

Abstract

In order to solve the problem of wear-out-failure of diesel engine cylinder, the laser-quenching and low temperature ion sulfurizing complex surface treatment technology was operated on the surface of 42MnCr52 steel. And the tribological properties of the complex layer were investigated. The experimental results indicated that the complex layer was composed of soft surface sulphide layer and sub-surface laserquenching harden layer, and showed excellent friction-reduction and wear-resistance performance at high temperature. The synergistic effect of the complex layer resulted in 20% increase in hardness, 10% reduction in friction coefficient and 50% reduction in wear weight loss, respectively, compared with those of the standard samples. The bench-test further demonstrated that this technology can improve the lubricating condition between cylinder and piston ring, and reduce both abnormity wear when the lubricating oil is deficiency at the time of start-up and sticking wear at high temperature during the operating period, and then prolong the service life of engine. [ABSTRACT FROM AUTHOR]

Published
2012
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16. A more robust Boolean model describing inhibitor binding.

Author

Xie, Zhaoqian and Tang, Chao

Abstract

From the first application of the Boolean model to the cell cycle regulation network of budding yeast, new regulative pathways have been discovered, particularly in the G1/S transition circuit. This discovery called for finer modeling to study the essential biology, and the resulting outcomes are first introduced in the article. A traditional Boolean network model set up for the new G1/S transition circuit shows that it cannot correctly simulate real biology unless the model parameters are fine tuned. The deficiency is caused by an overly coarsegrained description of the inhibitor binding process, which shall be overcome by a two-vector model proposed whose robustness is surveyed using random perturbations. Simulations show that the proposed two-vector model is much more robust in describing inhibitor binding processes within the Boolean framework. [ABSTRACT FROM AUTHOR]

Published
2008
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17. Author Correction: Battery-free, wireless soft sensors for continuous multi-site measurements of pressure and temperature from patients at risk for pressure injuries.

Author

Oh, Yong Suk, Kim, Jae-Hwan, Xie, Zhaoqian, Cho, Seokjoo, Han, Hyeonseok, Jeon, Sung Woo, Park, Minsu, Namkoong, Myeong, Avila, Raudel, Song, Zhen, Lee, Sung-Uk, Ko, Kabseok, Lee, Jungyup, Lee, Je-Sang, Min, Weon Gi, Lee, Byeong-Ju, Choi, Myungwoo, Chung, Ha Uk, Kim, Jongwon, and Han, Mengdi

Subjects
PRESSURE ulcers, PRESSURE measurement, TEMPERATURE measurements, DETECTORS
Abstract

These authors contributed equally: Yong Suk Oh, Jae-Hwan Kim, Zhaoqian Xie. In the Acknowledgements section of this article the grant number relating to Korea Government (MSIT) given for Yong Suk Oh, Seokjoo Cho, Hyeonseok Han, Kyuyoung Kim, Seunghwan Kim, Min Seong Kim, Jungrak Choi, and Inkyu Park was incorrectly given as 2018R1A2B200491013 and should have been 2021R1A2C3008742. [Extracted from the article]

Published
2021
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18. Author Correction: Stretchable, dynamic covalent polymers for soft, long-lived bioresorbable electronic stimulators designed to facilitate neuromuscular regeneration.

Author

Choi, Yeon Sik, Hsueh, Yuan-Yu, Koo, Jahyun, Yang, Quansan, Avila, Raudel, Hu, Buwei, Xie, Zhaoqian, Lee, Geumbee, Ning, Zheng, Liu, Claire, Xu, Yameng, Lee, Young Joong, Zhao, Weikang, Fang, Jun, Deng, Yujun, Lee, Seung Min, Vázquez-Guardado, Abraham, Stepien, Iwona, Yan, Ying, and Song, Joseph W.

Subjects
POLYMERS, DESIGN, SUGAMMADEX
Abstract

A Correction to this paper has been published: https://doi.org/10.1038/s41467-020-20857-y [ABSTRACT FROM AUTHOR]

Published
2021
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19. Stretchable, dynamic covalent polymers for soft, long-lived bioresorbable electronic stimulators designed to facilitate neuromuscular regeneration.

Author

Choi, Yeon Sik, Hsueh, Yuan-Yu, Koo, Jahyun, Yang, Quansan, Avila, Raudel, Hu, Buwei, Xie, Zhaoqian, Lee, Geumbee, Ning, Zheng, Liu, Claire, Xu, Yameng, Lee, Young Joong, Zhao, Weikang, Fang, Jun, Deng, Yujun, Lee, Seung Min, Vázquez-Guardado, Abraham, Stepien, Iwona, Yan, Ying, and Song, Joseph W.

Subjects
ELECTRIC stimulation, POLYMERS, ELECTRONIC equipment, PERIPHERAL nervous system
Abstract

Bioresorbable electronic stimulators are of rapidly growing interest as unusual therapeutic platforms, i.e., bioelectronic medicines, for treating disease states, accelerating wound healing processes and eliminating infections. Here, we present advanced materials that support operation in these systems over clinically relevant timeframes, ultimately bioresorbing harmlessly to benign products without residues, to eliminate the need for surgical extraction. Our findings overcome key challenges of bioresorbable electronic devices by realizing lifetimes that match clinical needs. The devices exploit a bioresorbable dynamic covalent polymer that facilitates tight bonding to itself and other surfaces, as a soft, elastic substrate and encapsulation coating for wireless electronic components. We describe the underlying features and chemical design considerations for this polymer, and the biocompatibility of its constituent materials. In devices with optimized, wireless designs, these polymers enable stable, long-lived operation as distal stimulators in a rat model of peripheral nerve injuries, thereby demonstrating the potential of programmable long-term electrical stimulation for maintaining muscle receptivity and enhancing functional recovery. Bioresorbable electronic stimulators can deliver electrical stimulation in rodents to enhance functional muscle recovery after nerve injury. Here, the authors present a bioresorbable dynamic covalent polymer that enables reliable, long-lived operation of soft, stretchable devices of this type. [ABSTRACT FROM AUTHOR]

Published
2020
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21. Fracture mode control: a bio-inspired strategy to combat catastrophic damage.

Author

Yao, Haimin, Xie, Zhaoqian, He, Chong, and Dao, Ming

Subjects
*BIOMATERIALS, *FRACTURE mechanics, *SUBSTRATES (Materials science), *FRACTURES of laminated composites, *MECHANICAL behavior of materials
Abstract

The excellent mechanical properties of natural biomaterials have attracted intense attention from researchers with focus on the strengthening and toughening mechanisms. Nevertheless, no material is unconquerable under sufficiently high load. If fracture is unavoidable, constraining the damage scope turns to be a practical way to preserve the integrity of the whole structure. Recent studies on biomaterials have revealed that many structural biomaterials tend to be fractured, under sufficiently high indentation load, through ring cracking which is more localized and hence less destructive compared to the radial one. Inspired by this observation, here we explore the factors affecting the fracture mode of structural biomaterials idealized as laminated materials. Our results suggest that fracture mode of laminated materials depends on the coating/substrate modulus mismatch and the indenter size. A map of fracture mode is developed, showing a critical modulus mismatch (CMM), below which ring cracking dominates irrespective of the indenter size. Many structural biomaterials in nature are found to have modulus mismatch close to the CMM. Our results not only shed light on the mechanics of inclination to ring cracking exhibited by structural biomaterials but are of great value to the design of laminated structures with better persistence of structural integrity. [ABSTRACT FROM AUTHOR]

Published
2015
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22. Mechano-acoustic sensing of physiological processes and body motions via a soft wireless device placed at the suprasternal notch.

Author

Lee K, Ni X, Lee JY, Arafa H, Pe DJ, Xu S, Avila R, Irie M, Lee JH, Easterlin RL, Kim DH, Chung HU, Olabisi OO, Getaneh S, Chung E, Hill M, Bell J, Jang H, Liu C, Park JB, Kim J, Kim SB, Mehta S, Pharr M, Tzavelis A, Reeder JT, Huang I, Deng Y, Xie Z, Davies CR, Huang Y, and Rogers JA

Subjects
Clavicle, Equipment Design, Exercise physiology, Humans, Signal Processing, Computer-Assisted, Skin Physiological Phenomena, Sleep physiology, Vibration, Biosensing Techniques instrumentation, Biosensing Techniques methods, Monitoring, Physiologic instrumentation, Monitoring, Physiologic methods, Physiological Phenomena, Wireless Technology instrumentation
Abstract

Skin-mounted soft electronics that incorporate high-bandwidth triaxial accelerometers can capture broad classes of physiologically relevant information, including mechano-acoustic signatures of underlying body processes (such as those measured by a stethoscope) and precision kinematics of core-body motions. Here, we describe a wireless device designed to be conformally placed on the suprasternal notch for the continuous measurement of mechano-acoustic signals, from subtle vibrations of the skin at accelerations of around 10 -3  m s -2 to large motions of the entire body at about 10 m s -2 , and at frequencies up to around 800 Hz. Because the measurements are a complex superposition of signals that arise from locomotion, body orientation, swallowing, respiration, cardiac activity, vocal-fold vibrations and other sources, we exploited frequency-domain analysis and machine learning to obtain-from human subjects during natural daily activities and exercise-real-time recordings of heart rate, respiration rate, energy intensity and other essential vital signs, as well as talking time and cadence, swallow counts and patterns, and other unconventional biomarkers. We also used the device in sleep laboratories and validated the measurements using polysomnography.

Published
2020
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