An automated microfluidic multiplexer for fast delivery of C. elegans populations from multiwells

Automated biosorter platforms, including recently developed microfluidic devices, enable and accelerate high-throughput and/or high-resolution bioassays on small animal models. However, time-consuming delivery of different organism populations to these systems introduces a major bottleneck to execut...

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Veröffentlicht in:	PloS one 2013-09, Vol.8 (9), p.e74480-e74480
Hauptverfasser:	Ghorashian, Navid, Gökçe, Sertan Kutal, Guo, Sam Xun, Everett, William Neil, Ben-Yakar, Adela
Format:	Artikel
Sprache:	eng
Schlagworte:	Animal models Animal populations Animals Automation Bioassays Biomedical engineering Bubbles Caenorhabditis elegans Colonies Computer engineering Contamination Data collection Fruit flies High-Throughput Nucleotide Sequencing - methods Larvae Mechanical engineering Mechanical systems Microfluidic Analytical Techniques - instrumentation Microfluidic Analytical Techniques - methods Microfluidics Multiplexing Nematodes Organisms Population Populations Reproducibility of Results Robotics Screens Specimen Handling - instrumentation Specimen Handling - methods Studies Suction Telecommunications equipment Valves Worms Zebrafish
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creator	Ghorashian, Navid Gökçe, Sertan Kutal Guo, Sam Xun Everett, William Neil Ben-Yakar, Adela
description	Automated biosorter platforms, including recently developed microfluidic devices, enable and accelerate high-throughput and/or high-resolution bioassays on small animal models. However, time-consuming delivery of different organism populations to these systems introduces a major bottleneck to executing large-scale screens. Current population delivery strategies rely on suction from conventional well plates through tubing periodically exposed to air, leading to certain disadvantages: 1) bubble introduction to the sample, interfering with analysis in the downstream system, 2) substantial time drain from added bubble-cleaning steps, and 3) the need for complex mechanical systems to manipulate well plate position. To address these concerns, we developed a multiwell-format microfluidic platform that can deliver multiple distinct animal populations from on-chip wells using multiplexed valve control. This Population Delivery Chip could operate autonomously as part of a relatively simple setup that did not require any of the major mechanical moving parts typical of plate-handling systems to address a given well. We demonstrated automatic serial delivery of 16 distinct C. elegans worm populations to a single outlet without introducing any bubbles to the samples, causing cross-contamination, or damaging the animals. The device achieved delivery of more than 90% of the population preloaded into a given well in 4.7 seconds; an order of magnitude faster than delivery modalities in current use. This platform could potentially handle other similarly sized model organisms, such as zebrafish and drosophila larvae or cellular micro-colonies. The device's architecture and microchannel dimensions allow simple expansion for processing larger numbers of populations.
doi_str_mv	10.1371/journal.pone.0074480
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subjects	Animal models Animal populations Animals Automation Bioassays Biomedical engineering Bubbles Caenorhabditis elegans Colonies Computer engineering Contamination Data collection Fruit flies High-Throughput Nucleotide Sequencing - methods Larvae Mechanical engineering Mechanical systems Microfluidic Analytical Techniques - instrumentation Microfluidic Analytical Techniques - methods Microfluidics Multiplexing Nematodes Organisms Population Populations Reproducibility of Results Robotics Screens Specimen Handling - instrumentation Specimen Handling - methods Studies Suction Telecommunications equipment Valves Worms Zebrafish
title	An automated microfluidic multiplexer for fast delivery of C. elegans populations from multiwells
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