Amy E. Reece
University of Wyoming
5 Papers
53 Citations
Amy E. Reece is an academic researcher from University of Wyoming. The author has contributed to research in topics: Particle & Denaturation (biochemistry). The author has an hindex of 5, co-authored 5 publications.
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Papers
Microfluidic techniques for high throughput single cell analysis
TL;DR: The microfabrication of microfluidic control systems and the development of increasingly sensitive molecular amplification tools have enabled the miniaturization of single cells analytical platforms, enabling a class of single cell analytical platforms within great potential for data driven biomedicine, genomics and transcriptomics.
138
Unusual Cold Denaturation of a Small Protein Domain
TL;DR: A thermal unfolding study of the 45-residue α-helical domain UBA(2) using circular dichroism is presented, and the resulting thermodynamic parameters are compared to those of other small protein domains.
21
Staged inertial microfluidic focusing for complex fluid enrichment
TL;DR: In this article, a staged device capable of high throughput particle and cell concentration and efficient single-pass complex fluid enrichment is presented, where straight and asymmetrically curved microchannels are combined in series to accelerate focusing dynamics and improve concentration efficiency.
Staged inertial microfluidic focusing for complex fluid enrichment
Amy E. Reece,Kaja Kaastrup,Hadley D. Sikes,John Oakey +3 more
- 01 Jan 2015
TL;DR: The utility of single and multiple pass concentration efficiency devices are demonstrated by performing a ubiquitous fluorescence staining assay on-chip while sacrificing very little sample or processing time relative to centrifugation.
17
Long-range forces affecting equilibrium inertial focusing behavior in straight high aspect ratio microfluidic channels
Amy E. Reece,John Oakey +1 more
TL;DR: Balancing geometry mediated inertial forces with estimates for interparticle repulsive forces now provide a complete picture of pattern formation among concentrated inertially focused particles and enhance the understanding of the fundamental limits of inertial focusing for technological applications.