William R. Gaillard scite author profile

William R. Gaillard

4Publications

18Citation Statements Received

82Citation Statements Given

How they've been cited

How they cite others

126

Affiliations

Sandia National Laboratories California, University of Alabama in Huntsville, Joint BioEnergy Institute

Publications

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Scalable and automated CRISPR-based strain engineering using droplet microfluidics

et al. 2022

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We present a droplet-based microfluidic system that enables CRISPR-based gene editing and high-throughput screening on a chip. The microfluidic device contains a 10 × 10 element array, and each element contains sets of electrodes for two electric field-actuated operations: electrowetting for merging droplets to mix reagents and electroporation for transformation. This device can perform up to 100 genetic modification reactions in parallel, providing a scalable platform for generating the large number of engineered strains required for the combinatorial optimization of genetic pathways and predictable bioengineering. We demonstrate the system’s capabilities through the CRISPR-based engineering of two test cases: (1) disruption of the function of the enzyme galactokinase (galK) in E. coli and (2) targeted engineering of the glutamine synthetase gene (glnA) and the blue-pigment synthetase gene (bpsA) to improve indigoidine production in E. coli.

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Isotherm analysis of the solution-phase uptake of chlorotrimethyl silane on a photosensitive glass

Gaillard

Maharanwar

Weimer

et al. 2018

Surfaces and Interfaces

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In-plane spectroscopy of microfluidic systems made in photosensitive glass

et al. 2012

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Surface Free Energy Determination of APEX Photosensitive Glass

2016

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Surface free energy (SFE) plays an important role in microfluidic device operation. Photosensitive glasses such as APEX offer numerous advantages over traditional glasses for microfluidics, yet the SFE for APEX has not been previously reported. We calculate SFE with the Owens/Wendt geometric method by using contact angles measured with the Sessile drop technique. While the total SFE for APEX is found to be similar to traditional microstructurable glasses, the polar component is lower, which is likely attributable to composition. The SFE was modified at each stage of device fabrication, but the SFE of the stock and fully processed glass was found to be approximately the same at a value of 51 mJ·m−2. APEX exhibited inconsistent wetting behavior attributable to an inhomogeneous surface chemical composition. Means to produce more consistent wetting of photosensitive glass for microfluidic applications are discussed.

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