Daphne Archonta scite author profile

In this paper, the novel effect of electric field (EF) on adult C. elegans egg-laying in a microchannel is discovered and correlated with neural and muscular activities. The quantitative effects of worm aging and EF strength, direction, and exposure duration on egg-laying is studied phenotypically using egg-count, body length, head movement, and transient neuronal activity readouts. Electric egg-laying rate increases significantly when worms face the anode and the response is EF-dependent, i.e. stronger (6V/cm) and longer EF (40s) exposure result in a shorter egg laying response duration. Worm aging significantly deteriorates the electric egg-laying behaviour with 88% decrease in the egg-count from Day-1 to Day-4 post young-adult stage. Fluorescent imaging of intracellular calcium dynamics in the main parts of the egg-laying neural circuit demonstrate the involvement and sensitivity of the serotonergic hermaphrodite specific neurons (HSNs), vulva muscles, and ventral cord neurons to the EF. HSN mutation also results in a reduced rate of electric egg-laying allowing the use of this technique for cellular screening and mapping of the neural basis of electrosensation in C. elegans. This novel assay can be parallelized and performed in a high-throughput manner for drug and gene screening applications.

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Microfluidic electric parallel egg-laying assay and application to in-vivo toxicity screening of microplastics using C. elegans

Youssef

Archonta

Kubiseski

et al. 2021

Science of The Total Environment

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Semi-mobile C. elegans electrotaxis assay for movement screening and neural monitoring of Parkinson’s disease models

Youssef

Archonta

Kubiseski

et al. 2020

Sensors and Actuators B: Chemical

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Electric egg-laying: a new approach for regulatingC. elegansegg-laying behaviour in a microchannel using electric field

et al. 2021

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Parallel-Channel Electrotaxis and Neuron Screening of Caenorhabditis elegans

et al. 2020

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In this paper, we report a novel microfluidic method to conduct a Caenorhabditis elegans electrotaxis movement assay and neuronal imaging on up to 16 worms in parallel. C. elegans is a model organism for neurodegenerative disease and movement disorders such as Parkinson’s disease (PD), and for screening chemicals that alleviate protein aggregation, neuronal death, and movement impairment in PD. Electrotaxis of C. elegans in microfluidic channels has led to the development of neurobehavioral screening platforms, but enhancing the throughput of the electrotactic behavioral assay has remained a challenge. Our device consisted of a hierarchy of tree-like channels for worm loading into 16 parallel electrotaxis screening channels with equivalent electric fields. Tapered channels at the ends of electrotaxis channels were used for worm immobilization and fluorescent imaging of neurons. Parallel electrotaxis of worms was first validated against established single-worm electrotaxis phenotypes. Then, mutant screening was demonstrated using the NL5901 strain, carrying human α-synuclein in the muscle cells, by showing the associated electrotaxis defects in the average speed, body bend frequency (BBF), and electrotaxis time index (ETI). Moreover, chemical screening of a PD worm model was shown by exposing the BZ555 strain, expressing green fluorescence protein (GFP) in the dopaminergic neurons (DNs), to 6-hydroxydopamine neurotoxin. The neurotoxin-treated worms exhibited a reduction in electrotaxis swimming speed, BBF, ETI, and DNs fluorescence intensity. We envision our technique to be used widely in C. elegans-based movement disorder assays to accelerate behavioral and cellular phenotypic investigations.

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Daphne Archonta

Electric Egg-Laying: Effect of Electric Field in a Microchannel onC. elegansEgg-Laying Behavior

Microfluidic electric parallel egg-laying assay and application to in-vivo toxicity screening of microplastics using C. elegans

Semi-mobile C. elegans electrotaxis assay for movement screening and neural monitoring of Parkinson’s disease models

Electric egg-laying: a new approach for regulatingC. elegansegg-laying behaviour in a microchannel using electric field

Parallel-Channel Electrotaxis and Neuron Screening of Caenorhabditis elegans

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