Laser Optical Sensor, a Label-Free On-Plate Salmonella enterica Colony Detection Tool

Singh, Atul K.; Bettasso, Amanda; Bae, Euiwon; Rajwa, Bartek; Dündar, Murat; Forster, Mark D.; Liu, Lixia; Barrett, Brent; Lovchik, Judith C.; Robinson, J. Paul; Hirleman, E. Dan; Bhunia, Arun K.

doi:10.1128/mbio.01019-13

Cited by 51 publications

(70 citation statements)

References 47 publications

(76 reference statements)

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“…We observed that the scatter patterns of the WT and mutant strains were different on BHIA and LBA but were similar on different brands of BHIA. It has been reported in our previous studies that bacterial colony scatter patterns vary with the growth medium used (5,7,9,11). Thus, we expect that any mutation in the genes involved in the biochemical pathways for substrate utilization will also result in differential scatter patterns.…”

Section: Discussionmentioning

confidence: 99%

“…BARDOT proved to be useful for studying the streptomycin-induced stress response in Salmonella enterica serovar Typhimurium (12) and as a bioanalytical detection tool to validate the performance of a sample processing and enrichment device, i.e., PED (pathogen enrichment device) (13). BARDOT-generated colony scatter phenograms exhibited strong relationships with the genotypes of bacteria (5), suggesting that BARDOT can be used to screen mutant strains that are deficient in specific virulence genes. In the present study, we used Listeria monocytogenes as a model pathogen and used BARDOT to screen mutant strains that are deficient in specific virulence genes.…”

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confidence: 99%

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Virulence Gene-Associated Mutant Bacterial Colonies Generate Differentiating Two-Dimensional Laser Scatter Fingerprints

Singh

Leprun

Drolia

et al. 2016

Appl Environ Microbiol

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In this study, we investigated whether a laser scatterometer designated BARDOT (bacterial rapid detection using optical scattering technology) could be used to directly screen colonies of Listeria monocytogenes, a model pathogen, with mutations in several known virulence genes, including the genes encoding Listeria adhesion protein (LAP; lap mutant), internalin A (⌬inlA strain), and an accessory secretory protein (⌬secA2 strain). Here we show that the scatter patterns of lap mutant, ⌬inlA, and ⌬secA2 colonies were markedly different from that of the wild type (WT), with >95% positive predictive values (PPVs), whereas for the complemented mutant strains, scatter patterns were restored to that of the WT. The scatter image library successfully distinguished the lap mutant and ⌬inlA mutant strains from the WT in mixed-culture experiments, including a coinfection study using the Caco-2 cell line. Among the biophysical parameters examined, the colony height and optical density did not reveal any discernible differences between the mutant and WT strains. We also found that differential LAP expression in L. monocytogenes serotype 4b strains also affected the scatter patterns of the colonies. The results from this study suggest that BARDOT can be used to screen and enumerate mutant strains separately from the WT based on differential colony scatter patterns. IMPORTANCEIn studies of microbial pathogenesis, virulence-encoding genes are routinely disrupted by deletion or insertion to create mutant strains. Screening of mutant strains is an arduous process involving plating on selective growth media, replica plating, colony hybridization, DNA isolation, and PCR or immunoassays. We applied a noninvasive laser scatterometer to differentiate mutant bacterial colonies from WT colonies based on forward optical scatter patterns. This study demonstrates that BARDOT can be used as a novel, label-free, real-time tool to aid researchers in screening virulence gene-associated mutant colonies during microbial pathogenesis, coinfection, and genetic manipulation studies.

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

Virulence Gene-Associated Mutant Bacterial Colonies Generate Differentiating Two-Dimensional Laser Scatter Fingerprints

Singh

Leprun

Drolia

et al. 2016

Appl Environ Microbiol

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“…Over the last several decades, there have been significant developments in rapid Salmonella detection methods using multiple novel approaches reducing preenrichment or detection time (e.g., In-situ immuno-gold nanoparticle network ELISA biosensors, immunomagnetic separation, automated microfiltration system, pathogen enrichment device, laser optical sensor, modified media, isothermal amplication) [79][80][81][82][83][84][85][86][87][88][89]. (Figure 2).…”

Section: Salmonella Detectionmentioning

confidence: 99%

“…One major recent development has been the reports of the use of an enzyme based approach coupled to a short enrichment and microfiltration steps for reducing time for sample preparation. This allowed Salmonella to be detected at very low levels (≤ 1 CFU/g) in different contaminated foods in 8 hours or less than one work shift [82][83][84]. The major concept is shown in Figure 3.…”

Section: Salmonella Detectionmentioning

confidence: 99%

Salmonella in Shell Eggs: Mechanisms, Prevention and Detection

Seockmo¹,

Eduardo²,

Thomas³

et al. 2016

J Nutr Food Sci

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Contaminated shell egg is one of the key Salmonella infection routes for human, causing food-borne illnesses. Multiple salmonellosis infections due to egg contamination still occur in developed countries even though preventive methods, such as vaccination or washing followed by rinsing process, are carried out following certified national standards. Recent outbreaks indicated that current strategies for Salmonella control need to be optimized to further minimize contamination of commercial eggs. Therefore, there is a critical need to develop more sensitive and rapid Salmonella detection methods. In this review, we address (i) egg production; (ii) preventive methods that minimize contamination; (iii) mechanisms of Salmonella contamination; (iv) Salmonella detection methods.

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“…Our technique uses back scatter spectra from a tissue surface, unlike Mie scatter imaging which uses forward scatter images through colonies to identify patterns 21 . Mie scatter imaging systems, often referred to as BARDOT systems, require bacteria to be cultured on before identification of bacterial species, as BARDOT systems are used to identify fully developed cultures on an optically transparent substrate 22,23,24 . The system designed here does not require the additional steps of culturing a wound sample to determine the presence or cause of bacterial infection.…”

Section: Introductionmentioning

confidence: 99%

Instant scanner device for identifying wound infection utilizing Mie scatter spectra

2017

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Tissue biopsy and swab culture are the gold standards for diagnosing tissue infection; these tests require significant time, diagnostic costs, and resources. Towards earlier and specific diagnosis of infection, a non-destructive, rapid, and mobile detection device is described to distinguish bacterial species via light scatter spectra from the surface of an infected tissue, reagent-free. Porcine skin and human cadaveric skin models of wound infection were used with a 650 nm LED and an angular photodiode array to detect bacterial infections on the tissue surface, which can easily be translated to a typical CMOS array or smartphone. Tissue samples were inoculated with Escherichia coli, Salmonella Typhimurium, or Staphylococcus aureus and backscatter was collected from 100° to 170° in 10° increments; each bacterial species resulted in unique Mie scatter spectra. Distinct Mie scatter spectra were obtained from epidermis (intact skin model) and dermis (wound model) samples, as well as from porcine and human cadaveric skin samples. Interactions between bacterial colonies and lipid particles within dermis samples generated a characteristic Mie scatter spectrum, while the lipid itself did not contribute to such characteristic spectrum as corroborated with body lotion experiments. The designed angular photodiode array is able to immediately and non-destructively detect tissue bacterial infection and identify the species of infection within three seconds, which could greatly improve point of care diagnostics and antibiotic treatments.

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Laser Optical Sensor, a Label-Free On-Plate Salmonella enterica Colony Detection Tool

Cited by 51 publications

References 47 publications

Virulence Gene-Associated Mutant Bacterial Colonies Generate Differentiating Two-Dimensional Laser Scatter Fingerprints

Virulence Gene-Associated Mutant Bacterial Colonies Generate Differentiating Two-Dimensional Laser Scatter Fingerprints

Salmonella in Shell Eggs: Mechanisms, Prevention and Detection

Instant scanner device for identifying wound infection utilizing Mie scatter spectra

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