Factors that influence confirmation of Neisseria gonorrhoeae positivity by molecular methods

Several Neisseria gonorrhoeae nucleic acid amplification tests (NAATs) with high sensitivity exist. However, the specificity of N. gonorrhoeae NAATs may be suboptimal, particularly for extragenital biospecimens. Consequently, confirmation with a second NAAT is common, although this represents a burden on resources. Furthermore, the rationale for confirmation is contentious. The objective of this work was to assess N. gonorrhoeae confirmation in over 13,000 N. gonorrhoeae screen-positive samples representing various biospecimens and three separate screening assays, the Abbott RealTime CT/NG (Abbott Molecular, Inc., Des Plaines, IL), the Cobas CT/NG test (Roche Molecular Systems Inc., Alameda, CA), and the BD ProbeTec ET CT/GC amplified DNA assay (BD Diagnostics, Sparks, MD). Factors predictive of confirmation were determined via logistic regression involving sex, year, whether the sample was formally validated, and sample site. Level of confirmation varied according to screening assay (96.2%, 86.0%, and 73.9% for the Abbott, Roche, and BD tests, respectively) in sample types formally included according to the manufacturers’ instructions (i.e., validated). Sex did not affect confirmation for 2/3 assays, and the likelihood of confirmation of samples not formally included in manufacturer instructions (i.e., nonvalidated) was 89.1%, 82.1%, and 59.2% for the Abbott, Roche, and BD tests, respectively. Rectal swabs, which are nonvalidated samples, confirmed in 91.5%, 90.1%, and 87.4% of samples initially tested with the respective assays. The requirement to confirm N. gonorrhoeae in validated samples is not required for all NAATs, although initial assay-specific evaluation is justified given observed variability. Rectal samples represent robust biospecimens for N. gonorrhoeae NAAT testing and may not require confirmation when screened with the assays described.</p

Uptake of hepatitis C specialist services and treatment following diagnosis by dried blood spot in Scotland

Background: Dried blood spot (DBS) testing for hepatitis C (HCV) was introduced to Scotland in 2009. This minimally invasive specimen provides an alternative to venipuncture and can overcome barriers to testing in people who inject drugs (PWID). Objectives: The objective of this study was to determine rates and predictors of: exposure to HCV, attendance at specialist clinics and anti-viral treatment initiation among the DBS tested population in Scotland. Study design: DBS testing records were deterministically linked to the Scottish HCV Clinical database prior to logistic regression analysis. Results: In the first two years of usage in Scotland, 1322 individuals were tested by DBS of which 476 were found to have an active HCV infection. Linkage analysis showed that 32% had attended a specialist clinic within 12 months of their specimen collection date and 18% had begun anti-viral therapy within 18 months of their specimen collection date. A significantly reduced likelihood of attendance at a specialist clinic was evident amongst younger individuals (&#60;35 years), those of unknown ethnic origin and those not reporting injecting drug use as a risk factor. Conclusion: We conclude that DBS testing in non-clinical settings has the potential to increase diagnosis and, with sufficient support, treatment of HCV infection among PWID

Direct Detection and Genotyping of Klebsiella pneumoniae Carbapenemases from Urine by Use of a New DNA Microarray Test

Klebsiella pneumoniae carbapenemases (KPC) are considered a serious threat to antibiotic therapy as they confer resistance to carbapenems, which are used to treat Extended-spectrum beta-lactamase (ESBL) producing bacteria. Here, we describe the development and evaluation of a DNA microarray for detection and genotyping of KPC genes (blaKPC) within 5 hours. To test the whole assay procedure (DNA extraction + DNA microarray assay) directly from clinical specimen, we compared two commercial DNA extraction kits (QIAprep Spin Miniprep Kit (Qiagen), Urine Bacterial DNA Isolation Kit (Norgen)) for the direct DNA extraction from urine samples (dilution series spiked in human urine). A reliable SNP typing from 1×105 CFU/mL urine was demonstrated for Escherichia coli (Qiagen and Norgen) and 80 CFU/mL urine on average for K. pneumoniae (Norgen). The study presents for the first time the combination of a new KPC-microarray with commercial sample preparation for the detection and genotyping of microbial pathogens directly from clinical specimen which paves the way towards tests providing epidemiological and diagnostic data enabling better antimicrobial stewardship

Amplification Free Detection of SARS-CoV-2 Using Multi-valent Binding

[Image: see text] We present the development of electrochemical impedance spectroscopy (EIS)-based biosensors for sensitive detection of SARS-CoV-2 RNA using multi-valent binding. By increasing the number of probe–target binding events per target molecule, multi-valent binding is a viable strategy for improving the biosensor performance. As EIS can provide sensitive and label-free measurements of nucleic acid targets during probe–target hybridization, we used multi-valent binding to build EIS biosensors for targeting SARS-CoV-2 RNA. For developing the biosensor, we explored two different approaches including probe combinations that individually bind in a single-valent fashion and the probes that bind in a multi-valent manner on their own. While we found excellent biosensor performance using probe combinations, we also discovered unexpected signal suppression. We explained the signal suppression theoretically using inter- and intra-probe hybridizations which confirmed our experimental findings. With our best probe combination, we achieved a LOD of 182 copies/μL (303 aM) of SARS-CoV-2 RNA and used these for successful evaluation of patient samples for COVID-19 diagnostics. We were also able to show the concept of multi-valent binding with shorter probes in the second approach. Here, a 13-nt-long probe has shown the best performance during SARS-CoV-2 RNA binding. Therefore, multi-valent binding approaches using EIS have high utility for direct detection of nucleic acid targets and for point-of-care diagnostics

Rapid Electrochemical Detection of New Delhi Metallo-beta-lactamase Genes To Enable Point-of-Care Testing of Carbapenem-Resistant Enterobacteriaceae

The alarming rate at which antibiotic resistance is occurring in human pathogens causes a pressing need for improved diagnostic technologies aimed at rapid detection and point-of-care testing to support quick decision making regarding antibiotic therapy and patient management. Here, we report the successful development of an electrochemical biosensor to detect <i>bla</i>_<i>NDM</i>, the gene encoding the emerging New Delhi metallo-beta-lactamase, using label-free electrochemical impedance spectroscopy (EIS). The presence of this gene is of critical concern because organisms harboring <i>bla</i>_<i>NDM</i> tend to be multiresistant, leaving very few treatment options. For the EIS assay, we used a <i>bla</i>_<i>NDM</i>-specific PNA probe that was designed by applying a new approach that combines <i>in silico</i> probe design and fluorescence-based DNA microarray validation with electrochemical testing on gold screen-printed electrodes. The assay was successfully demonstrated for synthetic targets (LOD = 10 nM), PCR products (LOD = 100 pM), and direct, amplification-free detection from a <i>bla</i>_<i>NDM</i>-harboring plasmid. The biosensor’s specificity, preanalytical requirements, and performance under ambient conditions were demonstrated and successfully proved its suitability for further point-of-care test development

Evolution of the Hepatitis E virus hypervariable region

The presence of a hypervariable (HVR) region within the genome of hepatitis E virus (HEV) remains unexplained. Previous studies have described the HVR as a proline-rich spacer between flanking functional domains of the ORF1 polyprotein. Others have proposed that the region has no function, that it reflects a hypermutable region of the virus genome, that it is derived from the insertion and evolution of host sequences or that it is subject to positive selection. This study attempts to differentiate between these explanations by documenting the evolutionary processes occurring within the HVR. We have measured the diversity of HVR sequences within acutely infected individuals or amongst sequences derived from epidemiologically linked samples and, surprisingly, find relative homogeneity amongst these datasets. We found no evidence of positive selection for amino acid substitution in the HVR. Through an analysis of published sequences, we conclude that the range of HVR diversity observed within virus genotypes can be explained by the accumulation of substitutions and, to a much lesser extent, through deletions or duplications of this region. All published HVR amino acid sequences display a relative overabundance of proline and serine residues that cannot be explained by a local bias towards cytosine in this part of the genome. Although all published HVRs contain one or more SH3-binding PxxP motifs, this motif does not occur more frequently than would be expected from the proportion of proline residues in these sequences. Taken together, these observations are consistent with the hypothesis that the HVR has a structural role that is dependent upon length and amino acid composition, rather than a specific sequence

User acceptability of saliva and gargle samples for identifying COVID-19 positive high-risk workers and household contacts

Throughout the COVID-19 pandemic nasopharyngeal or nose and/or throat swabs (NTS) have been the primary approach for collecting patient samples for the subsequent detection of viral RNA. However, this procedure, if undertaken correctly, can be unpleasant and therefore deters individuals from providing high quality samples. To overcome these limitations other modes of sample collection have been explored. In a cohort of frontline health care workers we have compared saliva and gargle samples to gold-standard NTS. 93% of individuals preferred providing saliva or gargle samples, with little sex-dependent variation. Viral titers collected in samples were analyzed using standard methods and showed that gargle and saliva were similarly comparable for identifying COVID-19 positive individuals compared to NTS (92% sensitivity; 98% specificity). We suggest that gargle and saliva collection are viable alternatives to NTS swabs and may encourage testing to provide better disease diagnosis and population surveillance