TY - JOUR
T1 - Simple and Precise Counting of Viable Bacteria by Resazurin-Amplified Picoarray Detection
AU - Hsieh, Kuangwen
AU - Zec, Helena C.
AU - Chen, Liben
AU - Kaushik, Aniruddha M.
AU - MacH, Kathleen E.
AU - Liao, Joseph C.
AU - Wang, Tza Huei
N1 - Funding Information:
The authors thank Dong Jin Shin, Christine O’Keefe, Sarah Friedrich, and Pornpat Athamanolap for assay development, device operation, and helpful discussions during this project. This work is financially supported by the National Institutes of Health (R01AI117032 and R01AI137272), the National Science Foundation (1159771 and 1033744), and Burroughs Wellcome Fund (1017497). K.H. is financially supported through a Hartwell Postdoctoral Fellowship.
Publisher Copyright:
© 2018 American Chemical Society.
PY - 2018/8/7
Y1 - 2018/8/7
N2 - Simple, fast, and precise counting of viable bacteria is fundamental to a variety of microbiological applications such as food quality monitoring and clinical diagnosis. To this end, agar plating, microscopy, and emerging microfluidic devices for single bacteria detection have provided useful means for counting viable bacteria, but they also have their limitations ranging from complexity, time, and inaccuracy. We present herein our new method RAPiD (Resazurin-Amplified Picoarray Detection) for addressing this important problem. In RAPiD, we employ vacuum-assisted sample loading and oil-driven sample digitization to stochastically confine single bacteria in Picoarray, a microfluidic device with picoliter-sized isolation chambers (picochambers), in <30 s with only a few minutes of hands-on time. We add AlamarBlue, a resazurin-based fluorescent dye for bacterial growth, in our assay to accelerate the detection of "microcolonies" proliferated from single bacteria within picochambers. Detecting fluorescence in picochambers as an amplified surrogate for bacterial cells allows us to count hundreds of microcolonies with a single image taken via wide-field fluorescence microscopy. We have also expanded our method to practically test multiple titrations from a single bacterial sample in parallel. Using this expanded "multi-RAPiD" strategy, we can quantify viable cells in E. coli and S. aureus samples with precision in â3 h, illustrating RAPiD as a promising new method for counting viable bacteria for microbiological applications.
AB - Simple, fast, and precise counting of viable bacteria is fundamental to a variety of microbiological applications such as food quality monitoring and clinical diagnosis. To this end, agar plating, microscopy, and emerging microfluidic devices for single bacteria detection have provided useful means for counting viable bacteria, but they also have their limitations ranging from complexity, time, and inaccuracy. We present herein our new method RAPiD (Resazurin-Amplified Picoarray Detection) for addressing this important problem. In RAPiD, we employ vacuum-assisted sample loading and oil-driven sample digitization to stochastically confine single bacteria in Picoarray, a microfluidic device with picoliter-sized isolation chambers (picochambers), in <30 s with only a few minutes of hands-on time. We add AlamarBlue, a resazurin-based fluorescent dye for bacterial growth, in our assay to accelerate the detection of "microcolonies" proliferated from single bacteria within picochambers. Detecting fluorescence in picochambers as an amplified surrogate for bacterial cells allows us to count hundreds of microcolonies with a single image taken via wide-field fluorescence microscopy. We have also expanded our method to practically test multiple titrations from a single bacterial sample in parallel. Using this expanded "multi-RAPiD" strategy, we can quantify viable cells in E. coli and S. aureus samples with precision in â3 h, illustrating RAPiD as a promising new method for counting viable bacteria for microbiological applications.
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U2 - 10.1021/acs.analchem.8b02096
DO - 10.1021/acs.analchem.8b02096
M3 - Article
C2 - 29969556
AN - SCOPUS:85049656895
SN - 0003-2700
VL - 90
SP - 9449
EP - 9456
JO - Analytical Chemistry
JF - Analytical Chemistry
IS - 15
ER -