M
Michelle Khine
Researcher at University of California, Irvine
Publications - 110
Citations - 4321
Michelle Khine is an academic researcher from University of California, Irvine. The author has contributed to research in topics: Signal & Electroporation. The author has an hindex of 30, co-authored 107 publications receiving 3499 citations. Previous affiliations of Michelle Khine include University of California, Berkeley & University of California.
Papers
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Journal ArticleDOI
Wearable sensors: modalities, challenges, and prospects
Jason Heikenfeld,Andrew J. Jajack,John A. Rogers,Philipp Gutruf,Limei Tian,Tingrui Pan,Ronald A. Li,Michelle Khine,Jitae Kim,Joseph Wang +9 more
TL;DR: A deeper understanding of the fundamental challenges faced for wearable sensors and of the state-of-the-art for wearable sensor technology, the roadmap becomes clearer for creating the next generation of innovations and breakthroughs.
Journal ArticleDOI
A single cell electroporation chip.
TL;DR: A polymeric chip that can selectively immobilize and locally electroporate single cells and focuses the electric field, eliminating the need to manipulate electrodes or glass pipettes is developed.
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Tunable Nanowrinkles on Shape Memory Polymer Sheets
Chi-Cheng Fu,Anthony Grimes,Maureen Long,Christopher G. L. Ferri,Brent D. Rich,Somnath Ghosh,Sayantani Ghosh,Luke P. Lee,Ajay Gopinathan,Michelle Khine +9 more
TL;DR: In this paper, a simple two-step approach is used to fabricate controllable biaxial and uniaxially nanowrinkles based on shape memory polymer (prestressed polystyrene) sheets.
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Respiration rate and volume measurements using wearable strain sensors.
Michael Chu,Thao Nguyen,Vaibhav Pandey,Yongxiao Zhou,Hoang N. Pham,Ronen Bar-Yoseph,Shlomit Radom-Aizik,Ramesh Jain,Dan M. Cooper,Michelle Khine +9 more
TL;DR: A wearable sensor capable of simultaneously measuring both respiration rate and volume with high fidelity is introduced, and it is demonstrated that both metrics are highly correlated to measurements from a medical grade continuous spirometer on participants at rest.
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Shrinky-Dink microfluidics: rapid generation of deep and rounded patterns.
TL;DR: This novel approach to microfluidic pattern generation by leveraging the inherent shrinkage properties of biaxially oriented polystyrene thermoplastic sheets yields channels deep enough for mammalian cell assays, and can consistently and easily achieve rounded channels, multi-height channels, and channels as thin as 65 microm in width.