AI Article Synopsis
- The study demonstrates the use of patterned polyacrylamide layers to create microfluidic devices that can enclose living cells and organisms for microscopy purposes.
- The polyacrylamide gels are capable of being molded into tiny structures that are liquid-permeable and transparent, enabling clear observation of the enclosed organisms.
- The devices allow for precise control over growth conditions, including nutrients and drug exposure, facilitating studies on bacterial, yeast, and C. elegans development through time-lapse microscopy.
Article Abstract
The ability to spatially confine living cells or small organisms while dynamically controlling their aqueous environment is important for a host of microscopy applications. Here, we show how polyacrylamide layers can be patterned to construct simple microfluidic devices for this purpose. We find that polyacrylamide gels can be molded like PDMS into micron-scale structures that can enclose organisms, while being permeable to liquids, and transparent to allow for microscopic observation. We present a range of chemostat-like devices to observe bacterial and yeast growth, and C. elegans nematode development. The devices can integrate PDMS layers and allow for temporal control of nutrient conditions and the presence of drugs on a minute timescale. We show how spatial confinement of motile C. elegans enables for time-lapse microscopy in a parallel fashion.
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Source |
|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3782435 | PMC |
| http://journals.plos.org/plosone/article?id=10.1371/journal.pone.0075537 | PLOS |
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