biostudies-literatureRussell JNational Bioresource Project of JapanNIH NINDSNINDS NIH HHSNSF Graduate FellowshipNIH Office of Research Infrastructure ProgramsNIH HHS54-9https://www.ebi.ac.uk/biostudies/studies/S-EPMC4440416biostudies-literatureUnknown237<h4>Background</h4>While many studies have assayed behavioral responses of animals to chemical, temperature and light gradients, fewer studies have assayed how animals respond to humidity gradients. Our novel humidity chamber has allowed us to study the neuromolecular basis of humidity sensation in the nematode Caenorhabditis elegans (Russell et al., 2014).<h4>New method</h4>We describe an easy-to-construct, low-cost humidity chamber to assay the behavior of small animals, including soft-bodied invertebrates, in controlled humidity gradients.<h4>Results</h4>We show that our humidity-chamber design is amenable to soft-bodied invertebrates and can produce reliable gradients ranging 0.3-8% RH/cm across a 9-cm long × 7.5-cm wide gel-covered arena.<h4>Comparison with existing method(s)</h4>Previous humidity chambers relied on circulating dry and moist air to produce a steep humidity gradient in a small arena (e.g. Sayeed and Benzer, 1996). To remove the confound of moving air that may elicit mechanical responses independent of humidity responses, our chamber controlled the humidity gradient using reservoirs of hygroscopic materials. Additionally, to better observe the behavioral mechanisms for humidity responses, our chamber provided a larger arena. Although similar chambers have been described previously, these approaches were not suitable for soft-bodied invertebrates or for easy imaging of behavior because they required that animals move across wire or fabric mesh.<h4>Conclusion</h4>The general applicability of our humidity chamber overcomes limitations of previous designs and opens the door to observe the behavioral responses of soft-bodied invertebrates, including genetically powerful C. elegans and Drosophila larvae.Journal of neuroscience methodsApparatus for investigating the reactions of soft-bodied invertebrates to controlled humidity gradients.PMC4440416NS075541R01 NS075541P40 OD010440Pierce-Shimomura JTRussell JfalseApparatus for investigating the reactions of soft-bodied invertebrates to controlled humidity gradients.<h4>Background</h4>While many studies have assayed behavioral responses of animals to chemical, temperature and light gradients, fewer studies have assayed how animals respond to humidity gradients. Our novel humidity chamber has allowed us to study the neuromolecular basis of humidity sensation in the nematode Caenorhabditis elegans (Russell et al., 2014).<h4>New method</h4>We describe an easy-to-construct, low-cost humidity chamber to assay the behavior of small animals, including soft-bodied invertebrates, in controlled humidity gradients.<h4>Results</h4>We show that our humidity-chamber design is amenable to soft-bodied invertebrates and can produce reliable gradients ranging 0.3-8% RH/cm across a 9-cm long × 7.5-cm wide gel-covered arena.<h4>Comparison with existing method(s)</h4>Previous humidity chambers relied on circulating dry and moist air to produce a steep humidity gradient in a small arena (e.g. Sayeed and Benzer, 1996). To remove the confound of moving air that may elicit mechanical responses independent of humidity responses, our chamber controlled the humidity gradient using reservoirs of hygroscopic materials. Additionally, to better observe the behavioral mechanisms for humidity responses, our chamber provided a larger arena. Although similar chambers have been described previously, these approaches were not suitable for soft-bodied invertebrates or for easy imaging of behavior because they required that animals move across wire or fabric mesh.<h4>Conclusion</h4>The general applicability of our humidity chamber overcomes limitations of previous designs and opens the door to observe the behavioral responses of soft-bodied invertebrates, including genetically powerful C. elegans and Drosophila larvae.2014-01-01T00:00:00Z2014 Nov2024-11-06T03:28:41.289Z2019-03-27T01:52:02ZS-EPMC44404162517602510.1016/j.jneumeth.2014.08.021