Efficacy of alcohol-based hand sanitizers against human norovirus using RNase-RT-qPCR with validation by human intestinal enteroid replication.

Successful human norovirus (HuNoV) cultivation in stem cell-derived human intestinal enteroids (HIE) was recently reported. The purpose of this study was to evaluate the anti-HuNoV efficacy of two alcohol-based commercial hand sanitizers and 60% ethanol by suspension assay using RNase-RT-qPCR, with subsequent validation of efficacy by HuNoV cultivation using the HIE model. In suspension, when evaluated by RNase-RT-qPCR, 60% ethanol resulted in less than one log10 reduction in HuNoV genome equivalent copies (GEC) regardless of contact time (30 or 60s) or soil load. The two commercial products outperformed 60% ethanol regardless of contact time or soil load, providing 2·2-3·2 log10 HuNoV GEC reductions by suspension assay. Product B could not be validated in the HIE model due to cytotoxicity. Following a 60s exposure, viral replication in the HIE model increased 1·9 ± 0·2 log10 HuNoV GEC for the neutralization (positive) control and increased 0·9 ± 0·2 log10 HuNoV GEC in challenged HIE after treatment with 60% ethanol. No HuNoV replication in HIE was observed after a 60 s exposure to Product A.

An Affordable and Portable Thermocycler for Real-Time PCR Made of 3D-Printed Parts and Off-the-Shelf Electronics.

The polymerase chain reaction (PCR) is a sought-after nucleic acid amplification technique used in the detection of several diseases. However, one of the main limitations of this and other nucleic acid amplification assays is the complexity, size, maintenance, and cost of their operational instrumentation. This limits the use of PCR applications in settings that cannot afford the instruments but that may have access to basic electrical, electronic, and optical components and the expertise to build them. To provide a more accessible platform, we developed a low-cost, palm-size, and portable instrument to perform real-time PCR (qPCR). The thermocycler leverages a copper-sheathed power resistor and a computer fan, in tandem with basic electronic components controlled from a single-board computer. The instrument incorporates a 3D-printed chassis and a custom-made fluorescence optical setup based on a CMOS camera and a blue LED. Results are displayed in real-time on a tablet. We also fabricated simple acrylic microdevices consisting of four wells (2 µL in volume each) where PCR reactions take place. To test our instrument, we performed qPCR on a series of cDNA dilutions spanning 4 orders of magnitude, achieving similar limits of detection as those achieved by a benchtop thermocycler. We envision our instrument being utilized to enable routine monitoring and diagnosis of certain diseases in low-resource areas.

Development and Comparison of TaqMan-Based Real-Time PCR Assays for Detection and Differentiation of Ralstonia solanacearum strains.

Bacterial wilt caused by Ralstonia solanacearum is destructive to many plant species worldwide. The race 3 biovar 2 (r3b2) strains of R. solanacearum infect potatoes in temperate climates and are listed as select agents by the U.S. government. TaqMan-based real-time quantitative PCR (qPCR) is commonly used in federal and state diagnostic laboratories over conventional PCR due to its speed and sensitivity. We developed the Rs16S primers and probe set and compared it with a widely used set (RS) for detecting R. solanacearum species complex strains. We also developed the RsSA3 primers and probe set and compared it with the previously published B2 and RsSA2 sets for specific detection of r3b2 strains. Both comparisons were done under standardized qPCR master mix and cycling conditions. The Rs16S and RS assays detected all 90 R. solanacearum species complex strains and none of the five outgroups, but the former was more sensitive than the latter. For r3b2 strain detection, the RsSA2 and RsSA3 sets specifically detected the 34 r3b2 strains and none of the 56 R. solanacearum non-r3b2 strains or out-group strains. The B2 set, however, detected five non-r3b2 R. solanacearum strains and was less sensitive than the other two sets under the same testing conditions. We conclude that the Rs16S, RsSA2, and RsSA3 sets are best suited under the standardized conditions for the detection of R. solanacearum species complex and r3b2 strains by TaqMan-based qPCR assays.

RT-PCR and real-time RT-PCR methods for the detection of potato virus Y in potato leaves and tubers.

Potato virus Y (PVY) is a major threat to potato crops around the world. It is an RNA virus of the family Potyviridae, exhibiting many different strains that cause a range of symptoms in potato. ELISA detection of viral proteins has traditionally been used to quantify virus incidence in a crop or seed lot. ELISA, however, cannot reliably detect the virus directly in dormant tubers, requiring several weeks of sprouting tubers to produce detectable levels of virus. Nor can ELISA fully discriminate between the wide range of strains of the virus. Several techniques for directly detecting the viral RNA have been developed which allow rapid detection of PVY in leaf or tuber tissue, and that can be used to easily distinguish between different strains of the virus. Described in this chapter are several protocols for the extraction of RNA from leaf and tuber tissues, and three detection methods based upon reverse-transcription-PCR (RT-PCR). First described is a traditional two-step protocol with separate reverse transcription of viral RNA into cDNA, then PCR to amplify the viral cDNA fragment. Second described is a one-step RT-PCR protocol combining the cDNA production and PCR in one tube and one step, which greatly reduces material and labor costs for PVY detection. The third protocol is a real-time RT-PCR procedure which not only saves on labor but also allows for more precise quantification of PVY titre. The three protocols are described in detail, and accompanied with a discussion of their relative advantages, costs, and possibilities for cost-saving modifications. While these techniques have primarily been developed for large-scale screening of many samples for determining viral incidence in commercial fields or seed lots, they are also amenable to use in smaller-scale research applications.