Michael T. Pyne

Large-Scale Analysis of the Prevalence and Geographic Distribution of HIV-1 Non-B Variants in the United States

ABSTRACT The genetic diversity of human immunodeficiency virus type 1 (HIV-1) has significant implications for diagnosis, vaccine development, and clinical management of patients. Although HIV-1 subtype B is predominant in the United States, factors such as global travel, immigration, and military deployment have the potential to increase the proportion of non-subtype B infections. Limited data are available on the prevalence and distribution of non-B HIV-1 strains in the United States. We sought to retrospectively examine the prevalence, geographic distribution, diversity, and temporal trends of HIV-1 non-B infections in samples obtained by ARUP Laboratories, a national reference laboratory, from all regions of the United States. HIV-1 pol sequences from 24,386 specimens collected from 46 states between 2004 and September 2011 for drug resistance genotyping were analyzed using the REGA HIV-1 Subtyping Tool, version 2.0. Sequences refractory to subtype determination or reported as non-subtype B by this tool were analyzed by PHYLIP version 3.5 and Simplot version 3.5.1. Non-subtype B strains accounted for 3.27% (798/24,386) of specimens. The 798 non-B specimens were received from 37 states and included 5 subtypes, 23 different circulating recombinant forms (CRFs), and 39 unique recombinant forms (URFs). The non-subtype B prevalence varied from 0% in 2004 (0/54) to 4.12% in 2011 (201/4,884). This large-scale analysis reveals that the diversity of HIV-1 in the United States is high, with multiple subtypes, CRFs, and URFs circulating. Moreover, the geographic distribution of non-B variants is widespread. Data from HIV-1 drug resistance testing have the potential to significantly enhance the surveillance of HIV-1 variants in the United States.

Evaluation of the Abbott Investigational Use Only RealTime Hepatitis C Virus (HCV) Assay and Comparison to the Roche TaqMan HCV Analyte-Specific Reagent Assay

ABSTRACT The accurate and sensitive measurement of hepatitis C virus (HCV) RNA is essential for the clinical management and treatment of infected patients and as a research tool for studying the biology of HCV infection. We evaluated the linearity, reproducibility, precision, limit of detection, and concordance of viral genotype quantitation of the Abbott investigational use only RealTime HCV (RealTime) assay using the Abbott m2000 platform and compared the results to those of the Roche TaqMan Analyte-Specific Reagent (TaqMan) and Bayer Versant HCV bDNA 3.0 assay. Comparison of 216 samples analyzed by RealTime and TaqMan assays produced the following Deming regression equation: RealTime = 0.940 (TaqMan) + 0.175 log10 HCV RNA IU/ml. The average difference between the assays was 0.143 log10 RNA IU/ml and was consistent across RealTimes dynamic range of nearly 7 log10 HCV RNA IU/ml. There was no significant difference between genotypes among these samples. The limit of detection using eight replicates of the World Health Organization HCV standard was determined to be 7.74 HCV RNA IU/ml by probit analysis. Replicate measurements of commercial genotype panels were significantly higher than TaqMan measurements for most samples and showed that the RealTime assay is able to detect all genotypes with no bias. Additionally, we showed that the amplicon generated by the widely used Roche COBAS Amplicor Hepatitis C Virus Test, version 2.0, can act as a template in the RealTime assay, but potential cross-contamination could be mitigated by treatment with uracil-N-glycosylase. In conclusion, the RealTime assay accurately measured HCV viral loads over a broad dynamic range, with no significant genotype bias.

Evaluation of the Roche Cobas AmpliPrep/Cobas TaqMan HIV-1 Test and Identification of Rare Polymorphisms Potentially Affecting Assay Performance

ABSTRACT We evaluated the FDA-approved Roche Cobas AmpliPrep/Cobas TaqMan (CAP/CTM) HIV-1 viral load assay for sensitivity, reproducibility, linearity, HIV-1 subtype detection, and correlation to the Roche Amplicor HIV-1 monitor test, version 1.5 (Amplicor). The limit of detection calculated by probit analysis was 23.8 copies/ml using the 2nd International WHO Standard and 30.8 copies/ml using Viral Quality Assurance (VQA) standard material. Serial dilutions of six patient samples were used to determine inter- and intra-assay reproducibility and linearity, which were very good (<8% coefficient of variation [CV]; between ∼1.7 and 7.0 log10 copies/ml). Subtype detection was evaluated in the CAP/CTM, Amplicor, and Bayer Versant HIV-1 bDNA 3.0 (Versant) assays using a commercially available panel. Versant averaged 0.829 log10 copies/ml lower than CAP/CTM and Amplicor averaged 0.427 log10 copies/ml lower than CAP/CTM for the subtype panel. Correlation with samples previously tested by Amplicor was excellent (R2 = 0.884; average difference [Amplicor value minus CAP/CTM value], 0.008 log10 copies/ml). Of the 305 HIV samples tested, 7 samples generated CAP/CTM titers between 1.0 and 2.75 log10 copies/ml lower than those for Amplicor. Three of these samples revealed primer and probe mismatches that could account for the discrepancies. Otherwise, the CAP/CTM assay exhibits excellent sensitivity, dynamic range, reproducibility, and correlation with Amplicor in an automated format.

Emerging infectious diseases in free-ranging wildlife-Australian zoo based wildlife hospitals contribute to national surveillance.

Emerging infectious diseases are increasingly originating from wildlife. Many of these diseases have significant impacts on human health, domestic animal health, and biodiversity. Surveillance is the key to early detection of emerging diseases. A zoo based wildlife disease surveillance program developed in Australia incorporates disease information from free-ranging wildlife into the existing national wildlife health information system. This program uses a collaborative approach and provides a strong model for a disease surveillance program for free-ranging wildlife that enhances the national capacity for early detection of emerging diseases.

Evaluation of the Abbott Investigational Use Only RealTime HIV-1 Assay and Comparison to the Roche Amplicor HIV-1 Monitor Test, Version 1.5

Abbott Moleculars m2000 system and RealTime HIV-1 assay (RealTime) were evaluated for sensitivity, reproducibility, linearity, ability to detect diverse HIV-1 subtypes/groups, and correlation to the Roche AMPLICOR HIV-1 MONITOR Test, Version 1.5 (Amplicor). The limit of detection was determined using the second International World Health Organization Standard and Viral Quality Assurance standard material. Serial dilutions of four patient samples were used to determine inter- and intra-assay reproducibility and linearity. Samples representing HIV-1 groups M, N, and O were evaluated in the RealTime, Amplicor, and Siemens Versant HIV-1 branched chain DNA 3.0 (Versant) assays. Archived Amplicor-tested samples were tested with the 1 ml, 0.5 ml, and 0.6 ml versions of the RealTime assay. Probit analysis predicts a limit of detection of 21.94 IU/ml using the World Health Organization Standard and 26.54 copies/ml using Viral Quality Assurance material with the 1 ml assay. Linearity and reproducibility were very good between approximately 1.60 to 6.0 log(10) copies/ml. All three assays produced similar measurements for all Group M subtypes tested; the RealTime assay was the only assay that detected all three Group O samples tested. Correlation with the Amplicor assay was good, although the RealTime assay measured between 0.342 and 0.716 log(10) copies/ml lower on average, depending on the input volume. The automated RealTime assay exhibits excellent sensitivity, dynamic range, reproducibility, and group/subtype detection, albeit with consistently lower values than Amplicor.

Performance of the COBAS ® AmpliPrep/COBAS TaqMan ® automated system for hepatitis C virus (HCV) quantification in a multi-center comparison

BACKGROUND Quantitative HCV RNA testing is considered standard of care for monitoring during treatment of patients infected with HCV. The COBAS(®) AmpliPrep/COBAS(®) TaqMan(®) HCV Test fully automates specimen processing and reaction assembly for HCV viral load testing using reverse transcription and real-time PCR amplification. OBJECTIVES The performance of the COBAS(®) AmpliPrep/COBAS(®) TaqMan(®) HCV Test was evaluated in a multi-center study. STUDY DESIGN Typical plasma based specimens were tested for accuracy, analytic range of measurement, reproducibility and genotype specific quantitation. RESULTS Linear regression analysis of the quantitative results demonstrated a linear range of detection from 50 to 5 million (1.7-6.7 log(10))IU/mL and a coefficient of determination (R(2)) of 0.9948. The precision of the assay was highly reproducible within and between runs and among laboratories with coefficients of variance (CV) ranging from 6.7% to 40.0% across the seven laboratories. A representative sample for each of the six major HCV genotypes demonstrated reproducible quantitation between the seven laboratories. CONCLUSIONS The COBAS(®) AmpliPrep/COBAS(®) TaqMan(®) HCV Test is a reliable and sensitive assay for HCV RNA quantitation.

Comparison of Three Roche Hepatitis B Virus Viral Load Assay Formats

ABSTRACT Two FDA-approved (in vitro diagnostic [IVD]) hepatitis B virus (HBV) viral load assays, the manual Cobas TaqMan HBV Test for use with the High Pure System (HP) and the automated Cobas AmpliPrep/Cobas TaqMan HBV Test v2.0 (CAP/CTM), were compared to a modified (not FDA-approved) version of the HP assay by automating the DNA extraction using the Total Nucleic Acid Isolation (TNAI) kit on the Cobas AmpliPrep. On average, CAP/CTM measurements were 0.08 log IU/ml higher than HP results (n = 206), and TNAI results were 0.17 log IU/ml higher than HP results (n = 166). The limit of detection (LOD), as determined by probit analysis using dilutions of the 2nd HBV international standard, was 10.2 IU/ml for CAP/CTM. The data sets for HP and TNAI were insufficient for probit analysis; however, there was 100% detection at ≥5 or ≥10 IU/ml for TNAI and HP, respectively. Linearity was demonstrated between 60 and 2,000,000 IU/ml, with slopes between 0.95 and 0.99 and R 2 values of >0.99 for all assays. Total precision (log percent coefficient of variance [CV]) was between 0.8% and 2.1% at 4.3 log IU/ml and between 1.4% and 4.9% at 2.3 log IU/ml. Correlation of samples, reproducibility, linearity, and LOD were acceptable and similar in all assays. The CAP/CTM assay and, to a lesser extent, the TNAI assay reduced hands-on time due to automation. There were no instances of contamination detected in negative samples during the course of the study, despite testing several samples up to 9.6 log IU/ml. The incidence of false-positive negative controls in HP and CAP/CTM clinical testing was <0.5% over 6 to 7 months of testing.

A retrospective review of UroVysion fish interpretations over 8.6 years: a major shift in the patient test population.

UroVysion FISH detects chromosomal aberrations associated with urothelial carcinoma. In our laboratory, UroVysion FISH was initially evaluated manually with a change to image‐aided interpretation using the BioView Duet imaging system. This retrospective study examined diagnostic findings over an 8.6 year period, with 1,869 manual interpretations over 4.8 years and 3,936 image‐aided interpretations over 3.8 years. Although the initial goal was to evaluate possible impacts of the imaging system on diagnostic interpretations, the most important finding was that the demographics of the test population changed significantly. Female specimens increased incrementally from an average of 29% compared to 43% of the samples during periods of manual interpretation versus image‐aided interpretation, respectively. The shift may reflect a gradual increase in the percentage of low‐risk hematuria patients being evaluated for initial diagnosis of bladder cancer, rather than bladder cancer recurrence. Interpretation rates, evaluated separately for males and females, changed significantly over the test period. Male interpretation results were negative (75.1 vs. 67%), positive (18.6 vs. 14.6%), unsatisfactory (5.0 vs. 16.9%), and equivocal (1.4 vs. 1.5%) during periods of manual versus image‐aided interpretation, respectively (Fisher Exact Test P‐value = <0.0001). For females, results were negative (86.1 vs. 79.3%), positive (9.2 vs. 11.1%), unsatisfactory (2.8 vs. 8.9%), and equivocal (1.8 vs. 0.7%) over the same periods (Fisher Exact Test P‐value = <0.0001). Logistic regression analysis identified the change in test population as the variable with the greatest impact on observed interpretation rate changes. Diagn. Cytopathol. 2013.

Large-scale comparison of Roche Cobas AmpliPrep/Cobas TaqMan and Abbott RealTime HIV assays

Significant underquantitation of HIV RNA has been reported with the Roche Cobas AmpliPrep/Cobas TaqMan HIV Test (Version 1) compared to other assays. However, these studies have generally involved limited numbers of samples from select patient populations or analysis of samples that were undetectable in the TaqMan assay. Random plasma samples submitted from throughout the United States for HIV RNA quantitation (n=1263) were compared in the Roche TaqMan and Abbott RealTime assays. Twenty-four samples (1.9%) were discrepant, with a maximum difference between the two assays of 1.9logcopies/mL. These data indicate that both tests may be susceptible to underquantitation, but the incidence is low in this large cohort of samples from across the United States.

Sequencing-Based Genotyping of Mixed Human Papillomavirus Infections by Use of RipSeq Software

ABSTRACT Sequencing-based pathogen identification directly from clinical specimens requires time-consuming interpretation, especially with mixed chromatograms when multiple microorganisms are detected. We assessed RipSeq Mixed software for human papillomavirus (HPV) genotyping by comparison to the linear array HPV genotyping assay. RipSeq Mixed provided rapid, sequencing-based HPV typing for single-type infections and coinfections with 2 types.