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Artificial dirt: microfluidic substrates for nematode neurobiology and behavior.


ABSTRACT: With a nervous system of only 302 neurons, the free-living nematode Caenorhabditis elegans is a powerful experimental organism for neurobiology. However, the laboratory substrate commonly used in C. elegans research, a planar agarose surface, fails to reflect the complexity of this organism's natural environment, complicates stimulus delivery, and is incompatible with high-resolution optophysiology experiments. Here we present a new class of microfluidic devices for C. elegans neurobiology and behavior: agarose-free, micron-scale chambers and channels that allow the animals to crawl as they would on agarose. One such device mimics a moist soil matrix and facilitates rapid delivery of fluid-borne stimuli. A second device consists of sinusoidal channels that can be used to regulate the waveform and trajectory of crawling worms. Both devices are thin and transparent, rendering them compatible with high-resolution microscope objectives for neuronal imaging and optical recording. Together, the new devices are likely to accelerate studies of the neuronal basis of behavior in C. elegans.

SUBMITTER: Lockery SR 

PROVIDER: S-EPMC2693186 | biostudies-literature | 2008 Jun

REPOSITORIES: biostudies-literature

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Artificial dirt: microfluidic substrates for nematode neurobiology and behavior.

Lockery S R SR   Lawton K J KJ   Doll J C JC   Faumont S S   Coulthard S M SM   Thiele T R TR   Chronis N N   McCormick K E KE   Goodman M B MB   Pruitt B L BL  

Journal of neurophysiology 20080312 6


With a nervous system of only 302 neurons, the free-living nematode Caenorhabditis elegans is a powerful experimental organism for neurobiology. However, the laboratory substrate commonly used in C. elegans research, a planar agarose surface, fails to reflect the complexity of this organism's natural environment, complicates stimulus delivery, and is incompatible with high-resolution optophysiology experiments. Here we present a new class of microfluidic devices for C. elegans neurobiology and b  ...[more]

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