key: cord-0885795-qbhymg6y
authors: Berning, Lucia; Aberle, Stephan W.; Simon, Benedikt; Luger, Christoph; Apfalter, Petra; Machherndl-Spandl, Sigrid; Kerschner, Heidrun
title: Evaluation of a multiplex ligation-dependent probe amplification assay for the detection of respiratory pathogens in oncological patients
date: 2014-03-06
journal: J Clin Virol
DOI: 10.1016/j.jcv.2014.02.010
sha: 2d9ea8d268e89f7b19e3f1782f955933195283e3
doc_id: 885795
cord_uid: qbhymg6y

BACKGROUND: Respiratory tract infections are widespread and may cause significant morbidity and mortality in immunosuppressed populations such as oncological patients. OBJECTIVES: The RealAccurate Respiratory RT PCR Kit covering 14 respiratory viruses was compared to the RespiFinder Smart22, a broad-spectrum multiplex ligation-dependent probe amplification (MLPA) test, targeting 22 viral and bacterial respiratory pathogens. STUDY DESIGN: After verification of its analytical performance, the clinical performance of the RespiFinder Smart22 was evaluated by re-analysis of 96 respiratory samples from oncological patients. Additionally, the time to result (TTR) of both methods was compared. RESULTS: The analytical performance of the RespiFinder Smart22 fulfilled all previously specified criteria. Concordant results in both assays were achieved in 74.0% of all clinical specimens and in 91.2% when only positive results were taken into account. The RespiFinder Smart22 yielded additional results in a total of 22 (22.9% of 96) samples due to higher test sensitivity and a broader, highly multiplexed spectrum of pathogens. The TTR of a typical routine test consisting of three samples were 206 and 356 min for the RealAccurate Respiratory RT PCR Kit and the RespiFinder Smart22, respectively. However, hands-on time was reduced by 59.0% applying the MLPA method. CONCLUSIONS: In our hands, the RespiFinder Smart22 showed excellent analytical performance while hands-on time was halved in comparison to the RT PCR method. Regarding the clinical evaluation, the MLPA method provided additional results in 22.9% (22/96) of specimens due to its comprehensive format, higher test sensitivity and the capability to detect 22 pathogens compared to 14 with the RealAccurate Respiratory RT PCR Kit.

Respiratory tract infections are the most common infections worldwide, with an estimate of two to four infections per year in adults [1] . Especially during the colder season respiratory tract infections occur frequently and may cause significant morbidity and mortality in immunosuppressed populations such as oncological patients [2] [3] [4] . The clinical presentation of an infection with respiratory pathogens can range from asymptomatic to severe disease. Considering the broad range of respiratory pathogens it is hardly possible to assign clinical symptoms to a distinct etiology. Hence, molecular diagnostic methods have been established as gold standard and are replacing less sensitive and more http laborious traditional diagnostic methods such as virus isolation by culture or direct immunofluorescence [1, 3, [5] [6] [7] [8] [9] [10] . However, the comprehensive investigation of a respiratory tract infection is timeand resource-consuming when applying singleplex PCR. Therefore, multiplex-based test methods for the detection of numerous respiratory pathogens are entering routine diagnostics [8, 9, 11, 12] .

In the present study a broad spectrum multiplex method, the RespiFinder Smart22 (PathoFinder, Maastricht, The Netherlands), was compared to the routinely used test (RealAccurate Respiratory RT PCR Kit, also PathoFinder) analyzing respiratory samples of oncological patients.

The evaluation of the RespiFinder Smart22 comprised three major parts: the verification of its analytical performance, its routine performance in comparison to the RT PCR method and the evaluation of the time to result (TTR) of both methods. The study was approved by the local ethics committee.

The currently used method to detect respiratory pathogens, the RealAccurate Respiratory RT PCR Kit, allows the differentiation of 14 respiratory viruses: influenzavirus A/B (InfA/B), respiratory syncytical virus A and B (RSV A/B), parainfluenzavirus 1 (PIV-1), PIV-2/4, PIV-3, coronavirus OC43 (CoV-OC43) and CoV-229E, rhino-/enterovirus (Rhv/Entero), human metapneumovirus (hMPV) and adenovirus (Adv). The principle of the test is a one-step reverse transcription with subsequent amplification and detection via TaqMan probes on the LightCycler 2.0 platform, requiring a separate master mix for each pathogen. Hence, for analysis of all 14 pathogens in a single clinical specimen 29 capillaries, including all controls, are necessary [13] . The referring physician has the possibility to order individual pathogens as well as the whole panel.

The new method, the RespiFinder Smart22, has been available in Austria since December 2011 and allows the simultaneous differentiation of 22 pathogens. The panel consists of the same viruses as the RealAccurate Respiratory RT PCR Kit, but it covers in addition InfA(H1N1)pdm09, CoV-NL63 and CoV-HKU1, Bocavirus and four bacterial pathogens (Chlamydophila pneumoniae, Mycoplasma pneumoniae, Legionella pneumophila, and Bordetella pertussis). The principle of the test is a multiplex ligation-dependent probe amplification (MLPA) subsequent to a reverse transcription requiring two LightCycler capillaries per specimen.

Prior to the analysis, all samples were extracted with the QIAamp MinElute Virus Spin Kit (Qiagen, Hilden, Germany) according to the instruction for use with a specimen input volume of 200 l and an output volume of 100 l for both methods. All samples were stored at −20 • C prior to routine diagnostics with the RealAccurate Respiratory RT PCR Kit to minimize possible effects on the analytical performance and thawed once again for extraction and analysis with the MLPA method.

Clinical samples with discrepant results were retested at the Department of Virology of the Medical University of Vienna with singleplex real time PCRs with detection via TaqMan probes and a nested PCR was employed for the detection of Rhinovirus [14] [15] [16] [17] [18] [19] .

The analytical performance of the RespiFinder Smart22 was verified by testing for accuracy, inter-and intra-assay variability, specificity and sensitivity based on established guidelines [20] . Known positive samples from two different external quality assessment services, QCMD and UKNEQAS that contained Adv, Bordetella pertussis, CoV-NL63, hMPV, InfA, InfB, PIV-2, Rhinovirus B Type 72 (Rhv-72), RSV A, and RSV B were tested for the determination of accuracy. The inter-and intra-assay variability were determined by repeatedly analyzing a sample positive for Rhv-72 and a negative sample. To test for specificity, ATCC strains of Streptococcus pneumoniae, Haemophilus influenzae, Staphylococcus aureus, Pseudomonas aeruginosa, and Klebsiella pneumoniae were spiked into a previously negative tested pharyngeal wash sample. A dilution series of Rhv-72 and hMPV (undiluted to 1:10,000) was analyzed to compare the sensitivity.

In this retrospective study the MLPA method was compared to the RealAccurate Respiratory RT PCR Kit by testing 96 respiratory samples (71.9% pharyngeal washes, 18.8% nasopharyngeal swabs, 9.4% lower respiratory tract samples) of 71 oncological patients treated at the 1st Internal Department of the Elisabethinen Hospital Linz received during the respiratory season of November 2011 to April 2012. After routine diagnostics with the RealAccurate Respiratory RT PCR Kit the original samples were anonymized by assigning a continuous ID number. For analysis with the RespiFinder Smart22 all samples were re-extracted as described in Section 3.1.

The TTR of both methods was evaluated to also elucidate economical aspects on the capability of the MLPA method. It comprises the period of time from the beginning of the analysis of a sample, including the purification of the nucleic acids, to its final result. TTR consists of the hands on time (HOT) and the periods of incubation and was determined for a typical run with three samples by measurement with a stopwatch.

Data were analyzed with SPSS version 17.0, using descriptive statistics and contingency tables for Fisher's exact test. P values of <0.05 were considered significant.

For accuracy ten different pathogens were correctly detected in accordance to the results of the external QC. A relative standard deviation (RSD) of <16% was determined for inter-assay variability and an RSD of <6% for intra-assay variability when analyzing Crossing Point-values. For specificity, no cross-reactions were seen when spiking common respiratory bacteria into a negative tested pharyngeal wash sample. Concerning sensitivity, the RespiFinder Smart22 was able to detect Rhv-72 in a 100-fold higher dilution and hMPV with equal sensitivity compared to the RealAccurate Respiratory RT PCR Kit. The results are summarized in Table 4 .

Demographic and clinical data are summarized in Tables 1 and 2 Table 3 .

The RespiFinder Smart22 yielded 22 additional positive results due to various factors.

The RealAccurate Respiratory RT PCR Kit allows selection of individual pathogens by the referring physician. In our study, only a partial panel was ordered for 50 (52.1%) samples, mostly limiting diagnostics to influenza viruses. When analyzing these samples with the RespiFinder Smart22, an additional pathogen was detected in six (6.3% of the total 96) samples. These two additional rhino-/enterovirus infections, two coronavirus infections, and one hMPV and RSV infection each were successfully confirmed in the reference laboratory except for one Rhv/Entero positive sample. Upon retesting with the RealAccurate Respiratory RT PCR Kit all pathogens except Rhv/Entero were detected correctly ( Table 3) .

The higher test sensitivity of the RespiFinder Smart22 was also shown by nine additional positive results (Rhv/Entero, CoV-229E and hMPV) that were ordered but not found in routine testing but could be confirmed by the reference laboratory.

Finally, the RespiFinder Smart22 has an extended spectrum of four viral and four bacterial additional pathogens of which Bocavirus and CoV-HKU1 were detected in seven (7.3%) samples of the study collective. All but one sample containing CoV-HKU1 could be confirmed at the reference laboratory (Table 3) .

Using routine diagnostics, a respiratory pathogen was detected at least once during the study period in 24/69 patients. However, using the comprehensive approach of RespiFinder Smart22, this result was achieved in a significantly higher proportion of patients (33/69 patients, p < 0.001, Fisher's exact test). Two patients of each group were excluded from the analysis because of unresolved differences in testing.

At the time of sampling, 32 (45.1%) of 71 patients had undergone hematopoietic stem cell transplantation (HSCT, median of days after HSCT: 194.5 days) and three (4.2%) patients underwent conditioning for HSCT. Over the study period, a respiratory pathogen was detected by analysis with RespiFinder Smart22 in 11/35 patients who had not received HSCT, whereas 22/34 patients shortly before or after HSCT had a pathogen detected. Thus, patients shortly before or after HSCT had a significantly higher burden of proven viral respiratory tract infection than patients without HSCT (p = 0.0081, Fisher's exact test).

First, the time requirement for the extraction of nucleic acids was analyzed. For a typical test of three samples, a TTR of 85 min (incubation 25 min, HOT 60 min) was determined for the RT PCR method, which demands the purification of a supplementary negative control, in comparison to a TTR of 77 min (incubation 25 min, HOT 52 min) for the RespiFinder Smart22.

Using the RealAccurate Respiratory RT PCR Kit, the analysis of the complete respiratory panel in three clinical samples with the corresponding negative and positive controls requires 49 LightCycler positions. A LightCycler carousel for 20 l capillaries holds 32 capillaries, thus two runs are needed to test three samples. Due to the possibility to use two LightCyclers in parallel, the period of incubation of 123 min was counted only once. HOT was 83 min for the processing of three samples, resulting in a total TTR of 206 min.

In an analysis using the RespiFinder Smart22 two vials per sample have to be processed which have to be manually transferred between pre-amplification, hybridization, and 2-step PCR with melting curve analysis. The analysis of three specimens took a HOT of 34 min and a period of incubation of 322 min.

The total TTR for the parallel analysis of three samples was 206 min [123 min (59.7%) period of incubation and 83 min (40.3%) HOT] for the RealAccurate Respiratory RT PCR Kit, and 356 min [322 min (90.4%) period of incubation and 34 min (9.6%) HOT] for the RespiFinder Smart22 (Fig. 1) .

In this study we evaluated a new commercially available multiplex format for the molecular biological diagnosis of respiratory pathogens, the RespiFinder Smart22, in comparison to the routinely used RealAccurate Respiratory RT PCR Kit.

The analytical performance of the RespiFinder Smart22 fulfilled all preset criteria; of note the MLPA method was more sensitive in the detection of Rhv/Entero. Results from other groups indicate that the analytical sensitivity of the RespiFinder Smart22 ranges from 5 to 50 copies per reaction for most targets using commercially available quantitated DNA/RNA PCR controls [12] , which equals singleplex PCR sensitivity [8] . However, absolute limits of detection for the individual targets are not available for either method.

The results of the clinical performance revealed a higher test sensitivity of the MLPA test principle in comparison to the RT PCR method as the positivity rate rose from 31.3% to 50.0% in the analyzed collective. Besides higher test sensitivity the extended spectrum of the RespiFinder Smart22 contributed to the higher positivity rate as Bocavirus and CoV-HKU1 were detected in 7.3% of the samples. A further reason for the difference in the positivity rate is the selective ordering in routine diagnosis. In six (6.3% of the total 96) samples the MLPA method detected an additional pathogen, which is actually included in the range of the RealAccurate Respiratory RT PCR Kit but had not been ordered. The results of five of these samples were confirmed by the reference laboratory. Retesting with the RT PCR method yielded a result in four of the six samples, confirming the higher test sensitivity of the RespiFinder Smart22 for Rhv/Entero. Narrow spectrum diagnostics of respiratory tract infections is considered problematic because of their nonspecific clinical presentation [3] . Therefore, PCR detection of InfA/B, RSV, PIV and in second line hMPV, Rhv/Entero, CoV and Adv is recommended for at-risk patients [21, 22] . Especially in HSCT recipients it is important to accurately and swiftly diagnose respiratory infections because of potential progression to severe complications such as pneumonia and also for hospital hygiene reasons [23] [24] [25] [26] [27] .

Accordingly, HSCT recipients in our sample collective had a significantly higher burden of respiratory tract infections than other oncological patients. In a similar study with 122 HSCT recipients, a lower number of 26.2% of positive cases was reported but only seven viral pathogens (InfA and B, PIV 1, 2 and 3, hMPV) were targeted [28] . Brittain-Long et al. used a multiplex real-time PCR with a similar spectrum of pathogens as the RespiFinder Smart22 in a patient collective with no underlying disease. They reported a positivity rate of 48% out of 954 samples, with InfA the commonest pathogen, followed by Rhv, which is comparable to our results [29] .

The MLPA method has an extended pathogen spectrum compared to the RT PCR method and in our study we have detected two viral pathogens of this spectrum; Bocavirus in two samples of one patient and CoV-HKU1 in five samples of four different patients. The role of the human Bocavirus in respiratory tract infections is not yet fully understood, a pathogenic potential is only attributed to infections with high viral loads [22, 30] or to the function of a helper virus which may trigger the replication of another respiratory virus [30] . Unlike the Bocavirus, CoV-HKU1 has a clear clinical relevance in respiratory tract infections as reported by Milano et al. in a sample collective of 215 HSCT recipients [25] . In our study collective a Coronavirus was detected in 12 (12.5%) of the samples of which 5 (5.2%) were CoV-HKU1.

Timely reporting of molecular diagnostic tests for respiratory infections is of importance for correct treatment of the patients and adequate hospital hygiene measures. The RespiFinder Smart22 showed a TTR of 5 h 56 min for three clinical samples which is consistent with the 6 h indicated by the manufacturer. Since 90.4% of the TTR consist of incubation time the manufacturer recently introduced an updated version of the kit with a reduction of incubation time by 2 h [31] . Thus, reporting results within a working day of 8 h should easily be possible. The TTR of the RealAccurate Respiratory RT PCR Kit was 3 h 26 min which is significantly longer than the TTR of 2 h stated by the manufacturer since independent of the numbers of patient samples already the LC-run lasts 123 min [32] . When analyzing the complete respiratory panel of three samples in parallel, two LightCyclers are needed or, if there is only one machine, incubation time doubles and the receipt of the results is delayed by 123 min. However, if a 96-well Real Time PCR instrument is available three samples can be processed in a single run. The multiplex format of the RespiFinder Smart22 allows analysis of up to 15 patient samples in parallel, underscoring the advantage of multiplex-based methods in comparison to singleplex PCR concerning the factor time [5] . Most important, hands on time (HOT) was more than halved by the MLPA method, which is a significant improvement regarding lab staff time commitment.

In conclusion, the RespiFinder Smart22 provided reliable results in the diagnosis of respiratory pathogens. Due to the unmodifiable multiplex format of this test, a broad spectrum of pathogens is covered in every run, which significantly increased the positivity rate in the examined collective from 31.3% with the RealAccurate Respiratory RT PCR Kit to 50.0%. Furthermore, the use of RespiFinder Smart22 offers significant advantages concerning HOT compared to the RT PCR method.

None.

Why diagnose respiratory viral infection? Respiratory viral diagnostics -the pathogens, the challenges and the solutions introducing the xTAGTM Respiratory Viral Panel

Common community respiratory viruses in patients with cancer

The challenge of respiratory virus infections in hematopoietic cell transplant recipients

Viral infections in patients with hematological malignancies

Detection of respiratory viruses by molecular methods

Comparison of two commercial molecular assays for simultaneous detection of respiratory viruses in clinical samples using two automatic electrophoresis detection systems

Currently used nucleic acid amplification tests for the detection of viruses and atypicals in acute respiratory infections

RespiFinder: a new multiparameter test to differentially identify fifteen respiratory viruses

Timely diagnosis of respiratory tract infections: evaluation of the performance of the Respifinder assay compared to the xTAG respiratory viral panel assay

Comparison of conventional and molecular detection of respiratory viruses in hematopoietic cell transplant recipients

Principles of the xTAG TM respiratory viral panel assay (RVP Assay)

Performance of different mono-and multiplex nucleic acid amplification tests on a multipathogen external quality assessment panel

Molekularbiologie/Gemonics. 3rd ed. Heidelberg/Berlin: Spektrum Akademischer Verlag GmbH

Reduced interferon-␥ expression in peripheral blood mononuclear cells of infants with severe respiratory syncytial virus disease

Adenovirus DNA in serum of children hospitalized due to an acute respiratory adenovirus infection

Biennial spring activity of human metapneumovirus in Austria

Early detection of acute rhinovirus infections by a rapid reverse transcription-PCR assay

Effectiveness of reverse transcription-PCR, virus isolation, and enzyme-linked immunosorbent assay for diagnosis of influenza A virus infection in different age groups

Simultaneous detection and identification of human parainfluenza viruses 1, 2, and 3 from clinical samples by multiplex PCR

Muster-Verfahrensanweisung zur Validierung/Verifizierung von In-house Tests

Community-acquired respiratory virus (CARV) infections other than influenza and adenovirus: respiratory syncytial-, human metapneumo-, parainfluenza-, rhino

Respiratory viral infections after bone marrow/peripheral stem-cell transplantation: the Christie hospital experience

Rhinovirus as a cause of fatal lower respiratory tract infection in adult stem cell transplantation patients: a report of two cases

Human rhinovirus and coronavirus detection among allogeneic hematopoietic stem cell transplantation recipients

EBMT-ESH handbook on haemopoietic stem cell transplantation

Viral disease prevention after hematopoietic cell transplantation

Respiratory virus infection among hematopoietic cell transplant recipients: evidence for asymptomatic parainfluenza virus infection

Multiplex real-time PCR for detection of respiratory tract infections: respiratory viruses special issue European Society for Clinical Virology Symposium on respiratory viruses

Human bocavirus: passenger or pathogen in acute respiratory tract infections?

RespiFinder ® SMART22 FAST: detection of 22 respiratory pathogens within four hours

RealAccurate Respiratory RT PCR Kit

None declared.

Given by the Ethics Commission of Upper Austria (Reference number: C-37-12).

Supplementary data associated with this article can be found, in the online version, at http://dx.doi.org/10.1016/j.jcv.2014.02.010.