2016
DOI: 10.1038/nprot.2016.144
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A microfluidics-based method for measuring neuronal activity in Drosophila chemosensory neurons

Abstract: Animals possess highly specialized sensory neurons that are capable of perceiving information about a continuously changing environment. Measuring neuronal activity in these cells is an important step toward understanding the basic coding principles, as well as the spatial and temporal dynamics, of sensory systems. The fruit fly Drosophila melanogaster is widely used as a genetic model organism to uncover basic mechanisms of taste coding and odor perception [1][2][3][4][5][6][7] . Recent insights into the mole… Show more

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Cited by 23 publications
(18 citation statements)
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“…Once the stimulus perfuses through the system to the neuron and the Ca 2+ response becomes detectable, it takes on the order of 30 s to reach peak amplitude (Figure 7D,E). This rise time is comparable to that observed for some tastants in pharyngeal neurons of the larval taste system (Apostolopoulou et al, 2016; Choi et al, 2016; van Giesen et al, 2016b). However, the rise time of the Gr43a neuron, once it begins to respond to sugar, is faster (LeDue et al, 2015), suggesting that the Gr43a neuron activates a circuit that stimulates feeding before the IR60b neuron activates a circuit that inhibits feeding.…”
Section: Resultssupporting
confidence: 84%
“…Once the stimulus perfuses through the system to the neuron and the Ca 2+ response becomes detectable, it takes on the order of 30 s to reach peak amplitude (Figure 7D,E). This rise time is comparable to that observed for some tastants in pharyngeal neurons of the larval taste system (Apostolopoulou et al, 2016; Choi et al, 2016; van Giesen et al, 2016b). However, the rise time of the Gr43a neuron, once it begins to respond to sugar, is faster (LeDue et al, 2015), suggesting that the Gr43a neuron activates a circuit that stimulates feeding before the IR60b neuron activates a circuit that inhibits feeding.…”
Section: Resultssupporting
confidence: 84%
“…Here, we leveraged the unique wealth of Drosophila data for direct comparison of total cell numbers and cell lineage over different stages of retinal development. We note that cells isolated from developing eye brain complexes of the third instar stage are neuroblasts, known to only differentiate into retinal neurons or glia during the later stages of development [28,62]. These RPCs have been shown to respond to stimuli collectively, in vivo, by a variety of studies using genetics with live imaging techniques [28,63] as well as conventional fixation over time [4,55,64].…”
Section: Resultsmentioning
confidence: 99%
“…This invertebrate model, thereby, provides unique opportunities for development of biomaterials used in regenerative therapies for inherited diseases and retinal disorders more broadly [77]. In vitro study of the collective behaviors of Drosophila progenitors has been surprisingly scarce [52,78,79,80,81], largely because cells extracted from developing organisms are notoriously difficult to maintain in vitro: The average viability of cells isolated from Drosophila visual system has been reported to be 12% after 24 h [46,82]. We here report achieving cell viability approaching 80% after 48 h in vitro (Figure 5), presumably by using sterility protocols of mammalian cell culture in combination with specific substrate-coated surfaces (Figure 1).…”
Section: Discussionmentioning
confidence: 99%