Electrical sorting of Caenorhabditis elegans

Rezai, Pouya; Salam, Sangeena; Selvaganapathy, P. Ravi; Gupta, Bhagwati P.

doi:10.1039/c2lc20967e

Cited by 66 publications

(82 citation statements)

References 30 publications

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“…[15][16][17][18][19][20][21][22] In previous work from our group, we designed a simple microfluidic device to examine the swimming behaviors of C. elegans under electric fields, termed electrotaxis, and demonstrated that changes in movement are reliable indicators of neurodegeneration and harmful effects of toxic chemicals on C. elegans health. [23][24][25] However, the inherent manual operation of the devices makes the screening process labor intensive and time consuming, which limits largely the practical application of the method. [23][24][25] In order to enable widespread use of the electrotactic assay, we have addressed the current limitations and developed an entirely new automated microfluidic system, which can perform electrotaxis assay for a batch of worms, without human intervention, one worm at a time while substantially increasing the throughput of analysis.…”

Section: Introductionmentioning

confidence: 99%

“…[23][24][25] However, the inherent manual operation of the devices makes the screening process labor intensive and time consuming, which limits largely the practical application of the method. [23][24][25] In order to enable widespread use of the electrotactic assay, we have addressed the current limitations and developed an entirely new automated microfluidic system, which can perform electrotaxis assay for a batch of worms, without human intervention, one worm at a time while substantially increasing the throughput of analysis. This system can load, isolate, perform electrotaxis assay, and flush C. elegans in a computer-controlled sequence.…”

Section: Introductionmentioning

confidence: 99%

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An automated microfluidic system for screening Caenorhabditis elegans behaviors using electrotaxis

Gupta

Selvaganapathy

2016

Biomicrofluidics

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Caenorhabditis elegans (C. elegans) is a widely used animal model to study mechanisms of biological processes and human diseases. To facilitate manipulations of C. elegans in the laboratory, researchers have developed various tools that permit careful monitoring of behavior and changes in cellular processes. Earlier, we had reported a novel microfluidic assay device to study the neuronal basis of movement and to investigate the effects of cellular and environmental factors that can induce degeneration in certain neurons leading to movement disorder. The system involved the use of an electric field to perform electrotaxis assays, which allows detailed examination of movement responses of animals. One of the potential uses of this system is to perform genetic and chemical screenings for neuroprotective factors; however, it could not be done due to manual operations and low throughput. In this paper, we present an integrated microfluidic system that automates screening of C. elegans behavioral response using electrotaxis. The core component of system is a multilayer poly dimethyl siloxane (PDMS) device, which enables C. elegans loading, capture, flush, release, electrotaxis, and clean sequentially with the help of other components. The system is capable of screening C. elegans, at a throughput of more than 20 worms per hour, automatically and continually without human intervention. To demonstrate the effectiveness of the system, C. elegans neuronal mutants were screened, and the phenotype data were extracted and analyzed. We envision that the automatic screening potential of the system will accelerate the study of neuroscience, drug discovery, and genetic screens in C. elegans. V C 2016 AIP Publishing LLC. [http://dx

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

An automated microfluidic system for screening Caenorhabditis elegans behaviors using electrotaxis

Gupta

Selvaganapathy

2016

Biomicrofluidics

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“…Rezai et al spatially separated different worms in a simple planar microchannel with a narrowed trap region based on the age-dependent or stagedependent electrotactic responses of worms. 25 In addition, continuous sorting can be achieved in a parallel manner. Han et al proposed another sorting strategy based on the size-dependent motility and electrotaxis of worms in a microstructured channel.…”

Section: Electrotactic Sortingmentioning

confidence: 99%

Recent Developments in Electrotaxis Assays

Lin

2014

Advances in Wound Care

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“…Using this device, authors sorted the young adult worms from older worms, young adult worms from larval staged worms and wild-type young adult worms from mutant worms. Although the sorter works at a selectivity of ~90% for worms of different age and mutants, multi-stage sorting of worms can potentially overcome this issue [38].…”

Section: Application Of Electrotaxis Behavior In Worm Researchmentioning

confidence: 99%

“…Handful of devices/setup and microfluidic devices had been introduced to scientific community which can sort worms based on electro-sensation behavior of worm into age, size and locomotion defective groups. Rezai et al (2012) introduced a microfluidic device that can sort worms using differential electrotactic response of the worm at different age. The microfluidic device created contains an electrical trap with narrow microchannel, which enhances the EF in the narrow channel when compared to the wider channel on either side.…”

Section: Application Of Electrotaxis Behavior In Worm Researchmentioning

confidence: 99%

Galvanotaxis of Caenorhabditis elegans: current understanding and its application in improving research

Shanmugam¹

2017

Biol Eng Med

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Electrosensation and movement towards a desired pole in an electric field, electrotaxis or galvanotaxis, is a behavior which is conserved in variety of species from a unicellular organism to multi-cellular organisms. In most cases this behavior is closely related with prey detection, predator detection, host identification by parasite and navigation. Electroreception is widely associated with aquatic organisms, but not restricted to aquatic organisms. Understanding the basic sensory-motor and molecular mechanism behind this behavior in model organisms will provide clues of potential application of this phenomenon. C. elegans has been developed as a simple model organisms to understand basic aspects of biology over several decades. Early analysis of C. elegans for electroreception and electrotaxis proved the existence for movement of worms towards the negative electrode in electric field. Following which several research led to improved, but not complete, understanding of the galvanotaxis behavior and mapping of neuronal circuit involved in sensory-motor decision making. Thus, understood behavioral parameters are used in various aspects of worm research such as sorting of worm population for research, analysis of neuro-muscular function of worms in mutants and disease models.

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Electrical sorting of Caenorhabditis elegans

Cited by 66 publications

References 30 publications

An automated microfluidic system for screening Caenorhabditis elegans behaviors using electrotaxis

An automated microfluidic system for screening Caenorhabditis elegans behaviors using electrotaxis

Recent Developments in Electrotaxis Assays

Galvanotaxis of Caenorhabditis elegans: current understanding and its application in improving research

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