A Real-Time Multiplexed Microbial Growth Intervalometer for Capturing High-Resolution Growth Curves

Overview

Journal Front Microbiol

Specialty Microbiology

Date 2019 Jun 25

PMID 31231321

Citations 3

Authors

David C Vuono

Bruce Lipp

Carl Staub

Evan Loney

Zoe R Harrold

Joseph J Grzymski

Affiliations

Soon will be listed here.

Abstract

Batch cultures are a low maintenance and routine culturing method in microbiology. Automated tools that measure growth curves from microorganisms grown in traditional laboratory glassware, such as Balch-type tubes, are not commercially available. Here, we present a new MicrobiAl Growth Intervalometer (MAGI) that measures optical density as it correlates to microbial growth by utilizing photo-conduction as opposed to photo-attenuation used by traditional OD measurement equipment. Photo-attenuation occurs when biomass in suspension within a medium blocks and/or diffuses light directed at the detector, such that an increase in biomass results in a decrease in the measured signal. Photo-conduction differs in which the biomass contained in a medium conducts light from the emitter to the detector, where an increase in the biomass results in a corresponding increase in the measured signal. MAGI features software-driven automation that provides investigators with a highly sensitive, low-background noise growth measurement instrument with added capabilities for remote visualization and data acquisition. It is a low maintenance, cost effective, versatile, and robust platform for aerobic/anaerobic cultivation. We demonstrate the versatility of this device by obtaining growth curves from two common laboratory organisms K-12 and . We show that growth rates and generation times in K-12 are reproducible to previously published results and that morphological changes of during growth can be detected as a change in the slope of the growth curve, which is a function of the effects of cell size on photo-conduction through the medium. We also test MAGI to capture growth curves from an environmental organism, C5, under various media compositions. Our results demonstrate that the MAGI platform accurately measures growth curves in media under various redox conditions (aerobic, microaerobic, and anaerobic), complex and minimal medias, and resolving diauxic growth curves when is grown on a disaccharide. Lastly, we demonstrate that the device can resolve growth curves for μM concentrations of resources that yield low biomass. This research advances the tools available to microbiologists aiming to monitor growth curves in a variety of disciplines, such as environmental microbiology, clinical microbiology, and food sciences.

Citing Articles

Cultivating efficiency: high-throughput growth analysis of anaerobic bacteria in compact microplate readers.

Snoeyenbos-West O, Guerrero C, Valencia M, Carini P Microbiol Spectr. 2024; 12(5):e0365023.

PMID: 38501820 PMC: 11064495. DOI: 10.1128/spectrum.03650-23.

Cultivating efficiency: High-throughput growth analysis of anaerobic bacteria in compact microplate readers.

Snoeyenbos-West O, Guerrero C, Valencia M, Carini P bioRxiv. 2023; .

PMID: 37873238 PMC: 10592771. DOI: 10.1101/2023.10.10.561742.

Tolerance, taxonomic and phylogenetic studies of some bacterial isolates involved in bioremediation of crude oil polluted soil in the southern region of Nigeria.

Omenna E, Omage K, Ezaka E, Azeke M Heliyon. 2023; 9(4):e15639.

PMID: 37151690 PMC: 10161795. DOI: 10.1016/j.heliyon.2023.e15639.

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