Abstract
Shigella spp., the etiological agent of shigellosis or “bacillary dysentery,” are responsible for considerable morbidity and mortality in excess of a million deaths globally per year. Although PCR-based techniques (such as PCR-based dipstick biosensors) have been used for the molecular diagnosis of infectious disease, these assays were restricted due to the need for a sophisticated thermal cycling apparatus to denature target templates. To facilitate simple and rapid detection of target pathogens, we successfully devised an inexpensive, reliable and nearly instrument-free molecular technique, which incorporates multiple cross displacement amplification (MCDA) combined with a newly designed lateral flow biosensor (LFB) for visual, sensitive and specific detection of Shigella. The MCDA-LFB assay was conducted at 65°C for only 20 min during the amplification stage, and then products were directly analyzed on the biosensor, alleviating the use of special reagents, electrophoresis equipment and amplicon detection instruments. The entire process, including specimen processing (35 min), amplification (20) and detection (2–5 min), can be finished within 1 h. The MCDA-LFB assay demonstrated high specificity for Shigella detection. The analytical sensitivity of the assay was 10 fg of genomic templates per reaction in pure culture and 5.86 CFU per tube in human fecal samples, which was consistent with MCDA by colorimetric indicator, gel electrophoresis, real time turbidity and fluorescence detection. Hence, the simplicity, rapidity and nearly instrument-free platform of the MCDA-LFB assay make it practical for ‘on-site’ diagnosis, point-of-care testing and more. Moreover, the proof-of-concept approach can be reconfigured to detect a wide variety of target sequences by re-designing the specific MCDA primers.
Highlights
Shigella spp. are exquisitely fastidious gram-negative pathogens that are responsible for as many as 167 million cases of shigellosis worldwide, resulting in a million deaths annually (Schroeder and Hilbi, 2008)
The limit of detection (LoD) of ET-multiple cross displacement amplification (MCDA) assay for Shigella detection was 10 fg of genomic DNA in pure culture (Figure 5D). These results indicated that the analytical sensitivity by Fluorescent Detection Reagent (FD) reagent, real time turbidity, real time fluorescence and agarose gel electrophoresis detection for Shigella-MCDA amplifications was conformity with biosensor analysis
The results indicated that the analytical sensitivity of MCDA-lateral flow biosensor (LFB) assay was in complete accordance with MCDA-FD, MCDA-turbidity, MCDA-gel electrophoresis and endonuclease restrictionmediated real-time multiple cross displacement amplification (ET-MCDA) assays
Summary
Shigella spp. are exquisitely fastidious gram-negative pathogens that are responsible for as many as 167 million cases of shigellosis worldwide, resulting in a million deaths annually (Schroeder and Hilbi, 2008). Four Shigella species, including S. sonnei, S. boydii, S. flexneri, and S. dysenteriae, are considered as pathogenic to humans, in young children (Koh et al, 2012). The. MCDA-LFB for Detection of Shigella spp. typical symptoms of Shigella infection include dysentery and/or diarrhea with frequent mucoid boldly stools, fever, abdominal pain, tenesmus and malaise (Khan et al, 2013). The individuals, including young children, older adults and immunecompromised populations, may be at more risk for Shigella infection (Njuguna et al, 2013). A reliable detection tool is needed to offer accurate diagnosis of Shigella to achieve infection control, clinical care and epidemiologic investigations
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