Repeat testing of mpox specimens with late CTs improves detection of potential false positive cases.

The mpox pandemic necessitated the rapid development of clinical assays for monkeypox virus detection. While the majority of mpox specimens have high viral loads with corresponding early cycle threshold (CT) values, reports have indicated some specimens with late CT values can represent false positive results. To mitigate this risk, the Centers for Disease Control and Prevention (CDC) published an advisory recommending repeat testing of all specimens with CT values ≥34. However, limited experimental data were available to support this specific cutoff. In this study, we examine whether a more conservative approach in which all specimens with CT values ≥29 are repeated would improve the detection of potential false positive results. Compared to the CDC algorithm, our approach identified an additional 20% (5/25) of potential false positive results. To assess the impact of this cutoff on laboratory workload, we modeled the expected increase in test volume and turnaround time (TAT) relative to the CDC method. Using a lower repeat threshold, test volume increased by 0.7% while mean TAT increased by less than 15 minutes. Overall, a lower threshold than recommended by the CDC for repeating late CT mpox specimens may reduce the number of false positives reported while minimally impacting testing volume and TAT.

Development and validation of a next-generation sequencing assay with open-access analysis software for detecting resistance-associated mutations in CMV.

Cytomegalovirus (CMV) resistance testing by targeted next-generation sequencing (NGS) allows for the simultaneous analysis of multiple genes. We developed and validated an amplicon-based Ion Torrent NGS assay to detect CMV resistance mutations in UL27, UL54, UL56, and UL97 and compared the results to standard Sanger sequencing. NGS primers were designed to generate 83 overlapping amplicons of four CMV genes (~10 kb encompassing 138 mutation sites). An open-access software plugin was developed to perform read alignment, call variants, and interpret drug resistance. Plasmids were tested to determine NGS error rate and minor variant limit of detection. NGS limit of detection was determined using the CMV WHO International Standard and quantified clinical specimens. Reproducibility was also assessed. After establishing quality control metrics, 185 patient specimens previously tested using Sanger were reanalyzed by NGS. The NGS assay had a low error rate (<0.05%) and high accuracy (95%) for detecting CMV-associated resistance mutations present at ≥5% in contrived mixed populations. Mutation sites were reproducibly sequenced with 40× coverage when plasma viral loads were ≥2.6 log IU/mL. NGS detected the same resistance-associated mutations identified by Sanger in 68/69 (98.6%) specimens. In 16 specimens, NGS detected 18 resistance mutations that Sanger failed to detect; 14 were low-frequency variants (<20%), and six would have changed the drug resistance interpretation. The NGS assay showed excellent agreement with Sanger and generated high-quality sequence from low viral load specimens. Additionally, the higher resolution and analytic sensitivity of NGS potentially enables earlier detection of antiviral resistance.

HIV-1 Drug Resistance Assay Using Ion Torrent Next Generation Sequencing and On-Instrument End-to-End Analysis Software.

HIV-1 antiretroviral therapy management requires sequencing the protease, reverse transcriptase, and integrase portions of the HIV-1 pol gene. Most resistance testing is performed with Sanger sequencing, which has limited ability to detect minor variants. Next generation sequencing (NGS) platforms enable variant detection at frequencies as low as 1% allowing for earlier detection of resistance and modification of therapy. Implementation of NGS assays in the clinical laboratory is hindered by complicated assay design, cumbersome wet bench procedures, and the complexity of data analysis and bioinformatics. We developed a complete NGS protocol and companion analysis and reporting pipeline using AmpliSeq multiplex PCR, Ion Torrent S5 XL sequencing, and Stanford's HIVdb resistance algorithm. Implemented as a Torrent Suite software plugin, the pipeline runs automatically after sequencing. An optimum variant frequency threshold of 10% was determined by comparing Sanger sequences of archived samples from ViroSeq testing, resulting in a sensitivity of 98.2% and specificity of 99.0%. The majority (91%) of drug resistance mutations were detected by both Sanger and NGS, with 1.7% only by Sanger and 7.3% only by NGS. Variant calls were highly reproducible and there was no cross-reactivity to VZV, HBV, CMV, EBV, and HCV. The limit of detection was 500 copies/mL. The NGS assay performance was comparable to ViroSeq Sanger sequencing and has several advantages, including a publicly available end-to-end analysis and reporting plugin. The assay provides a straightforward path for implementation of NGS for HIV drug resistance testing in the laboratory setting without additional investment in bioinformatics infrastructure and resources.

Respiratory Viral Detection in Children and Adults: Comparing Asymptomatic Controls and Patients With Community-Acquired Pneumonia.

BACKGROUND: The clinical significance of viruses detected in patients with community-acquired pneumonia (CAP) is often unclear. METHODS: We conducted a prospective study to identify the prevalence of 13 viruses in the upper respiratory tract of patients with CAP and concurrently enrolled asymptomatic controls with real-time reverse-transcriptase polymerase chain reaction. We compared age-stratified prevalence of each virus between patients with CAP and controls and used multivariable logistic regression to calculate attributable fractions (AFs). RESULTS: We enrolled 1024 patients with CAP and 759 controls. Detections of influenza, respiratory syncytial virus, and human metapneumovirus were substantially more common in patients with CAP of all ages than in controls (AFs near 1.0). Parainfluenza and coronaviruses were also more common among patients with CAP (AF, 0.5-0.75). Rhinovirus was associated with CAP among adults (AF, 0.93) but not children (AF, 0.02). Adenovirus was associated with CAP only among children <2 years old (AF, 0.77). CONCLUSIONS: The probability that a virus detected with real-time reverse-transcriptase polymerase chain reaction in patients with CAP contributed to symptomatic disease varied by age group and specific virus. Detections of influenza, respiratory syncytial virus, and human metapneumovirus among patients with CAP of all ages probably indicate an etiologic role, whereas detections of parainfluenza, coronaviruses, rhinovirus, and adenovirus, especially in children, require further scrutiny.

Evaluation of the FilmArray® Respiratory Panel for clinical use in a large children's hospital.

BACKGROUND: Respiratory pathogens are a leading cause of hospital admission and traditional detection methods are time consuming and insensitive. Multiplex molecular detection methods have recently been investigated in hope of replacing these traditional techniques with rapid panel-based testing. OBJECTIVES: This study evaluated the FilmArray(®) Respiratory Panel ([FARP], Idaho Technology Inc., Salt Lake City, UT) as a replacement for direct fluorescent antibody (DFA) testing in a pediatric hospital. METHODS: Eleven of the 21 FARP analytes (Adenovirus, Bordetella pertussis, human Metapneumovirus, Influenza A, Influenza A H1N1 2009, Influenza B, Parainfluenza [1, 2, & 3], Respiratory Syncytial Virus, and rhinovirus) were evaluated using nasopharyngeal specimens. Positive samples were pooled in groups of 5. Samples identified by reference methods as positive for respiratory pathogens were used for the majority of positive samples. DFA was the reference method for ten analytes; Luminex™ xTAG Respiratory Virus Panel (RVP) was the reference method for rhinovirus. Discrepant results were resolved by positive culture and fluorescent antibody stain and/or laboratory-developed real-time polymerase chain reaction (PCR) assays (LDT). RESULTS: The agreement for most analytes was in concordance with the established reference methods with the exception of Adenovirus. Additionally, the FARP detected several pathogens not previously detected by DFA, and most were confirmed by LDT. Several DFA-positive analytes were confirmed as true-negatives by the FARP and LDT. CONCLUSION: FARP overall performed better than DFA with the exception of Adenovirus, making the FARP an attractive alternative to laboratories looking to replace DFA with a rapid, user-friendly, multiplex molecular assay.

A novel capillary electrophoresis-based multiplex PCR assay for detection of respiratory pathogens.

The field of infectious disease testing has recently experienced rapid expansion in the number of multiplexed PCR-based assays available for detecting respiratory pathogens. This study provides a preliminary evaluation of a multiplex assay from Seegene that uses capillary electrophoresis as the detection platform for viral and bacterial respiratory pathogens. We compared this technology to a real-time PCR assay for 3 viral targets. Thirty respiratory samples were collected that had previously tested positive for either Flu A, Flu B, or RSV (ten of each). The Seegene assay detected 9/10 Flu A samples, 9/10 Flu B, and 10/10 RSV, for a total detection rate of 93%. The two samples that were undetected by the Seegene assay both generated late-crossing thresholds on the real-time platform, consistent with low viral loads. The Seeplex assay provides a promising alternative for multiplex respiratory testing.

Identifying respiratory viruses in nasal mucus from children.

Large amounts of respiratory viruses are shed in nasal secretions by children. Nasal mucus was compared with nasopharyngeal swabs as a source for respiratory virus testing. Multiplex reverse transcription-polymerase chain reaction detected virus in nasal mucus specimens in 73% (11/15) of positive cases, demonstrating the potential utility of less invasive specimens when a highly sensitive method is used for respiratory virus detection.

Limited utility of culture for Mycoplasma pneumoniae and Chlamydophila pneumoniae for diagnosis of respiratory tract infections.

We assessed the utility of culture for Mycoplasma pneumoniae and Chlamydophila pneumoniae to diagnose respiratory tract infections. Compared to PCR and IgM serology, culture was less sensitive and had extremely low yield. Culture is not recommended for these pathogens, and this method should be eliminated from routine practice.

Performance of diagnostic tests to detect respiratory viruses in older adults.

The performance of 4 laboratory methods for diagnosis of viral respiratory tract infections (RTI) in older adults was evaluated. Seventy-four nasopharyngeal (NP) swab specimens were obtained from 60 patients with RTI at a long-term care facility over 2 respiratory seasons. Sixteen specimens were positive for a respiratory virus by at least 1 method. Multiplex reverse transcriptase polymerase chain reaction (RT-PCR) by the Luminex xTAG Respiratory Viral Panel (RVP) detected 16 (100%) of the positive specimens, RVP of 24-h culture supernatant detected 8 (50%), direct fluorescent antibody testing detected 4 (25%), rapid culture detected 2 (12.5%), and rapid antigen testing detected none. For a comparison group, RVP was performed on NP swabs from 20 outpatient children with RTI. The mean fluorescence intensity by RVP was significantly lower for positive adult patients than pediatric patients (P = 0.0373). Our data suggest that older adult patients shed lower titers of viruses, necessitating a highly sensitive assay such as RT-PCR to reliably detect respiratory viral pathogens.

Development of a multiplex real-time RT-PCR assay for detection of influenza A, influenza B, RSV and typing of the 2009-H1N1 influenza virus.

A high-throughput real-time RT-PCR assay was developed to amplify and detect a conserved region of the hemagglutinin gene of the 2009-H1N1 influenza A virus using a minor groove binder-conjugated hybridization probe. The assay was paired with a separate triplex real-time assay that detects influenza A via the matrix gene, influenza B and RSV in a multiplex format and compared with the Centers for Disease Control and Prevention (CDC) rRT-PCR assay using 143 samples. The 2009-H1N1 portion of the multiplex assay had 100% correlation with the CDC assay, while the triplex assay had a 99% agreement. An additional 105 samples collected from October to November 2009 were also tested using both the individual 2009-H1N1 and triplex assays. Of these 105 samples, eight were positive for the hemagglutinin target in the H1N1 assay and negative for the matrix target in the triplex assay. Discrepant analysis revealed single nucleotide polymorphisms within the matrix gene of 2009-H1N1 virus-positive samples. The limit of detection for the 2009-H1N1 assay was between 750 and 1,500 copies/reaction and no cross-reactivity with other respiratory pathogens was observed. Overall, this multiplexed format proved to be sensitive, robust and easy to use and serves as a useful tool for pandemic testing.

Performance of enterovirus genotyping targeting the VP1 and VP2 regions on non-typeable isolates and patient specimens.

Culture and serotyping of human enteroviruses are time-consuming and labor-intensive. Targeted nucleic acid sequencing has emerged as a powerful alternative to conventional methods. Many published genotyping assays use two-step reverse transcription and polymerase chain reaction (RT-PCR), nested PCR protocols, and/or reflexive testing algorithms. The performance of a one-step RT-PCR protocol, a more clinically practical approach, was evaluated. The VP1 and/or VP2 region of archived enterovirus isolates (n=36, representing 32 serotypes), patient enterovirus isolates not typeable by immunofluorescence antibodies (n=50), and enterovirus from direct patient specimens (48 cerebrospinal fluid, 2 plasma/serum, 1 blood) were amplified and sequenced for genotype identification. The analytical sensitivity of the genotyping assays was 100-fold less than detection by RT-PCR of the 5'-untranslated region. Thirty-four of 36 archived isolates could be genotyped by combining results of VP1 and VP2 target sequencing. Non-typeable isolates included 17 echovirus 18, 6 enterovirus 68, 6 rhinovirus, and 7 which could not be classified further. From clinical specimens, 23 of 51 (45%) could be identified using VP2 typing and the most common types were coxsackievirus B1, echovirus 30, and echovirus 6. Using a one-step RT-PCR without nesting, most enterovirus isolates and a subset of clinical samples with high viral titer could be genotyped.

Evaluation of Nanogen MGB Alert Detection Reagents in a multiplex real-time PCR for influenza virus types A and B and respiratory syncytial virus.

A multiplex real-time RT-PCR assay that detects influenza A, influenza B and respiratory syncytial virus (RSV) using the MGB Alert Influenza A&B/RSV Detection Reagent RUO (Nanogen, San Diego, CA) was developed. The Nanogen detection reagents consist of PCR primers and minor groove binder-conjugated hybridization probes for each virus and an internal control. Virus typing was determined by post-PCR melt curve analysis. A non-competitive armored RNA internal control was co-extracted with each sample to monitor nucleic acid extraction and RT-PCR. The assay was evaluated using a collection of culture, DFA and RT-PCR (Hexaplex, Prodesse, Waukesha, WI) positive and negative samples. The real-time multiplex assay detected 236 of 237 positive specimens for a 99% correlation. Of 30 Hexaplex negative samples tested, the multiplex real-time assay detected an additional 7 positives confirmed using additional PCR assays. Melt curve analysis for each virus produced average melting peaks of 60.4 degrees C, 66.7 degrees C and 69.4 degrees C for influenza A, influenza B and RSV respectively. Sequence analysis of 7 influenza A samples producing aberrant melt curves, confirmed the presence of a single nucleotide polymorphism beneath the influenza A probe. The limit of detection of each virus in 4 different sample types was measured to be between 7 and 806 copies. Overall, the multiplexed real-time RT-PCR assay was sensitive, robust and easy to use.

Description and validation of a novel real-time RT-PCR enterovirus assay.

BACKGROUND: Enteroviruses are a leading cause of aseptic meningitis in adult and pediatric populations. We describe the development of a real-time RT-PCR assay that amplifies a small target in the 5' nontranslated region upstream of the classical Rotbart enterovirus amplicon. The assay includes an RNA internal control and incorporates modified nucleotide chemistry. METHODS: We evaluated the performance characteristics of this design and performed blinded parallel testing on clinical samples, comparing the results with a commercially available RT-PCR assay (Pan-Enterovirus OligoDetect kit) that uses an enzyme immunoassay-like plate end detection. RESULTS: We tested 778 samples and found 14 discrepant samples between the 2 assays. Of these, the real-time assay detected 6 samples that were negative by the OligoDetect kit, 5 of which were confirmed as positive by sequence analysis using an alternative primer set. Eight discrepant samples were positive by the OligoDetect kit and real-time negative, with 6 confirmed by sequencing. Overall, detection rates of 97% and 96% were obtained for the OligoDetect kit and real-time assays, respectively. Sequence analysis revealed the presence of a number of single nucleotide polymorphisms in the targeted region. The comparative sensitivities of the 2 assays were equivalent, with the limit of detection for the real-time assay determined to be approximately 430 copies per milliliter in cerebrospinal fluid. CONCLUSIONS: This novel real-time enterovirus assay is a sensitive and suitable assay for routine clinical testing. The presence of single nucleotide polymorphisms can affect real-time PCR assays.

Description of a multiplex Bordetella pertussis and Bordetella parapertussis LightCycler PCR assay with inhibition control.

While culture for Bordetella species is highly specific, sensitivity is extremely variable due to patient age, immunization status, antibiotic treatment, and specimen transport conditions. We evaluated a real-time multiplex PCR assay as an alternative to culture for the detection and differentiation of Bordetella pertussis and Bordetella parapertussis. The PCR conditions allowed the simultaneous detection of one B. pertussis organism and five B. parapertussis organisms per reaction. An inhibition control was incorporated into the assay. Of 163 total samples evaluated, 37 of 38 samples positive by either culture or direct fluorescent antibody testing (DFA) were also positive by PCR (97% sensitivity). Of 125 culture- or DFA-negative samples, 101 were also negative by PCR (81% specificity). The described multiplex assay is a rapid, sensitive, contamination-limiting, real-time PCR assay that controls for inhibition. The assay performs well using liquid or swab samples and from dried material on slides.

Ultrasonic enhancement of antibiotic action on several species of bacteria.

The effect of the antibiotics gentamicin, streptomycin, kanamycin, tetracycline, and ampicillin on planktonic cultures of Enterobacter aerogenes, Serratia marcescens, Salmonella derby, Streptococcus mitis, and Staphylococcus epidermidis with and without an application of 70 kHz ultrasound was studied. The ultrasound was applied at levels that had no inhibitory effect on planktonic cultures of bacteria. Measurements of viability at, above, and below the minimum inhibitory concentration of the above antibiotics on the planktonic cultures of these bacteria showed that a simultaneous application of 70 kHz ultrasound and antibiotic significantly increased the effectiveness of selected antibiotics. Bacterial viability was reduced several orders of magnitude when harmless levels of ultrasound were combined with some antibiotics, especially the aminoglycosides. Similar synergistic effects of combined ultrasound and antibiotic treatment were seen in both Gram-positive and Gram-negative bacteria with several classes of antibiotics. These results may have application in the treatment of bacterial infections normally resistant to some antibiotics.