Our lab built a new cooling stage and associated immobilization protocol for strong immobilization of C. elegans on their original cultivation plate. Despite its profound impact on biology, most high-resolution in vivo microscopy approaches remain low throughput because current immobilization techniques require significant manual effort. We greatly accelerate imaging of the nematode Caenorhabditis elegans by implementing a simple cooling approach to easily immobilize entire populations directly on their cultivation plates. We optimize and characterize cooling immobilization. Counterintuitively, relatively warmer temperatures immobilize animals significantly more effectively than colder temperatures utilized in prior studies. This enhanced immobilization enables clear submicron-resolution fluorescence imaging, which is challenging to achieve with most current immobilization techniques. We demonstrate 64ร magnification 3D imaging and timelapse recording of neurons in adults and embryos without motion blur. Compared to standard azide immobilization, cooling immobilization reduces the animal preparation and recovery time by >98%, significantly increasing experimental speed. By obviating individual animal manipulation, our approach could also empower automated imaging of large C. elegans populations within standard experimental setups and workflows.
wangyaomoon / cooling-stage Goto Github PK
View Code? Open in Web Editor NEWThis project forked from wormneurolab/cooling-stage
Our lab built a new cooling stage and associated immobilization protocol for strong immobilization of C. elegans on their original cultivation plate.
License: MIT License