Lisa Y. Chen scite author profile

Continuous monitoring of internal physiological parameters is essential for critical care patients, but currently can only be practically achieved via tethered solutions. Here we report a wireless, real-time pressure monitoring system with passive, flexible, millimetre-scale sensors, scaled down to unprecedented dimensions of 1 Â 1 Â 0.1 cubic millimeters. This level of dimensional scaling is enabled by novel sensor design and detection schemes, which overcome the operating frequency limits of traditional strategies and exhibit insensitivity to lossy tissue environments. We demonstrate the use of this system to capture human pulse waveforms wirelessly in real time as well as to monitor in vivo intracranial pressure continuously in proof-of-concept mice studies using sensors down to 2.5 Â 2.5 Â 0.1 cubic millimeters. We further introduce printable wireless sensor arrays and show their use in real-time spatial pressure mapping. Looking forward, this technology has broader applications in continuous wireless monitoring of multiple physiological parameters for biomedical research and patient care.

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Measuring surface dislocation nucleation in defect-scarce nanostructures

Chen

et al. 2015

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Linear defects in crystalline materials, known as dislocations, are central to the understanding of plastic deformation and mechanical strength, as well as control of performance in a variety of electronic and photonic materials. Despite nearly a century of research on dislocation structure and interactions, measurements of the energetics and kinetics of dislocation nucleation have not been possible, as synthesizing and testing pristine crystals absent of defects has been prohibitively challenging. Here, we report experiments that directly measure the surface dislocation nucleation strengths in high-quality 〈110〉 Pd nanowhiskers subjected to uniaxial tension. We find that, whereas nucleation strengths are weakly size- and strain-rate-dependent, a strong temperature dependence is uncovered, corroborating predictions that nucleation is assisted by thermal fluctuations. We measure atomic-scale activation volumes, which explain both the ultrahigh athermal strength as well as the temperature-dependent scatter, evident in our experiments and well captured by a thermal activation model.

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Optimizing partners’ choice in IS/IT outsourcing projects: The strategic decision of fuzzy VIKOR

Chen

Wang

2009

International Journal of Production Economics

252

108

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Wireless power transfer to a cardiac implant

et al. 2012

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Lattice Anharmonicity in Defect-Free Pd Nanowhiskers

et al. 2012

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Lisa Y. Chen

Continuous wireless pressure monitoring and mapping with ultra-small passive sensors for health monitoring and critical care

Measuring surface dislocation nucleation in defect-scarce nanostructures

Optimizing partners’ choice in IS/IT outsourcing projects: The strategic decision of fuzzy VIKOR

Wireless power transfer to a cardiac implant

Lattice Anharmonicity in Defect-Free Pd Nanowhiskers

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