Rapid Detection of Methicillin-Resistant Staphylococcus aureus Directly from Sterile or Nonsterile Clinical Samples by a New Molecular Assay

A rapid procedure was developed for detection and identificationof methicillin-resistant Staphylococcus aureus (MRSA) directlyfrom sterile sites or mixed flora samples (e.g., nose or inguinalswabs). After a rapid conditioning of samples, the method consistsof two main steps: (i) immunomagnetic enrichment in S. aureusand (ii) amplification-detection profile on DNA extracts usingmultiplex quantitative PCR (5'-exonuclease qPCR, TaqMan). Thetriplex qPCR assay measures simultaneously the following targets:(i) mecA gene, conferring methicillin resistance, common toboth S. aureus and Staphylococcus epidermidis; (ii) femA genefrom S. aureus; and (iii) femA gene from S. epidermidis. Thisquantitative approach allows discrimination of the origin ofthe measured mecA signal. qPCR data were calibrated using tworeference strains (MRSA and methicillin-resistant S. epidermidis)processed in parallel to clinical samples. This 96-well formatassay allowed analysis of 30 swab samples per run and detectionof the presence of MRSA with exquisite sensitivity comparedto optimal culture-based techniques. The complete protocol mayprovide results in less than 6 h (while standard procedure needs2 to 3 days), thus allowing prompt and cost-effective implementationof contact precautions.

INTRODUCTION

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Introduction

Staphylococcus aureus is a major pathogen responsible for nosocomialand community-acquired infections. Since 1960, the emergenceof multiresistant strains of S. aureus carrying resistance tomethicillin (MRSA) and to most currently available antibiotics(4, 23) has dramatically narrowed the therapeutic arsenal tothe exclusive use of glycopeptides (such as vancomycin and teicoplanin)as the mainstay of MRSA treatment. Unfortunately, vancomycinoveruse has led to the emergence of MRSA strains with decreasedsusceptibilities to glycopeptides (22, 37).

The presence of MRSA in an institution is clearly paralleledby an increased number of bacteremias due to MRSA (41), whichcarry a threefold attributable cost and a threefold excess lengthof hospital stay when compared with methicillin-susceptibleS. aureus (MSSA) bacteremia (1). These data, together with successfulcontainment effort programs (6, 7, 9, 16, 18, 34, 36), promptscreening of high-risk patients even in a setting of high endemicity(43). Screening for MRSA is a key component of successful infectioncontrol strategies (11, 38, 43) aiming to identify hidden reservoirsof MRSA patients and appropriately apply isolation precautions(17, 40). To this end, infection control benefits from automatedalerts upon admission in order to identify patients who havebeen previously colonized by MRSA (39). Early detection of MRSAcarriers is crucial not only for infection control (11) butalso for therapeutic decision with last-line antibiotics againstMRSA, e.g., glycopeptides and oxazolidinones (49).

Rapid detection of MRSA by standard clinical microbiologicalprocedures is tedious and time consuming, since it first requiresidentification of isolated S. aureus colonies within mixed florasamples before assessing their level of methicillin resistance.The development of selective media containing antibiotics andphenol red has provided better sensitivity than conventionalagar-based cultures after 48 h of incubation, but at the expenseof a longer turnaround time (10, 46, 51).

Direct or indirect particle agglutination assays using antibody-coatedbeads offer a rapid alternative to oxacillin susceptibilitytesting. For example, MRSA-Screen (Denka Seiken, Tokyo, Japan)provides sensitive and specific immunodetection of MRSA in apure culture by using anti-PBP2' antibodies, which is similarto standard oxacillin disk diffusion or oxacillin-salt agarscreening (5, 24, 42). However, the specific immunodetectionof MRSA based on PBP2' cannot be performed in the presence ofmethicillin-resistant Staphylococcus epidermidis (MRSE), whichis a frequent commensal contaminant of mixed flora samples (5).Indeed, the high level of sequence homology of the mecA genepresent in S. aureus, S. epidermidis, and potentially othercoagulase-negative staphylococci (CNS) species (52) precludesdiscrimination of methicillin-resistant strains of S. aureusfrom those of S. epidermidis (24).

Since the mecA gene, encoding the low-affinity penicillin-bindingprotein (PBP2') (44), represents the "gold standard" for detectingmethicillin resistance (32), several assays based on the directdetection of the mecA gene have been described, using chemiluminescentprobes (53), amplification methods such as PCR (42), or cyclingprobe technology (12). A PCR immunoassay was reported by Towneret al., based on the amplification and immunodetection of mecAand femB amplicons, and performed after overnight culture enrichmentof clinical samples. This technique outperforms conventionaldetection methods (48) by providing rapid immunodetection andavoiding the use of acrylamide gel. In another approach, PCR-amplifiedproducts were detected with low-density oligoarrays, providingdetection of several targets during the same hybridization step(13). Other more elaborated multiplexed PCR, using differenttargets (coagulase and femA genes) (25, 50) or S. aureus toxins(47), yielded promising results with good specificity. Promisingresults were also obtained by using either triplex PCR assaysbased on the detection of S. aureus rRNA, mecA, and nuc (27,29) or clfA genes (30) or by in situ hybridization performedon blood culture bottles (35).

The recent introduction of multiplexed real-time qPCR techniques(19, 26) combining accurate identification with limits of detectionclose to a single gene copy/sample provided a significant technologicaladvantage for the rapid and large-scale identification of variousmicroorganisms (8, 28, 31). This report describes a novel immuno-qPCRprocedure allowing rapid detection of MRSA from mixed florasamples. The procedure consists in a direct one-step enrichmentof MRSA present in either nasal or inguinal swabs, followedby DNA extraction of immunocaptured bacteria and their identificationby a triplex qPCR. The specificity of MRSA molecular identificationis based on the presence of the mecA gene and the presence ofan S. aureus-specific femA signal that does not cross-reactwith other bacterial species, including S. epidermidis. Thisnovel qPCR assay allows detection and identification of MRSAin less than 6 h after sample collection and may provide substantialbenefits for infection control by allowing prompt and cost-effectiveimplementation of contact precautions.

MATERIALS AND METHODS

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Materials and Methods

Materials. Biotinylated mouse monoclonal antibodies raised against S. aureusprotein A (anti-spa, mouse immunoglobulin G1 clone spa-27) wereobtained from Fluka (Sigma Chemie, Buchs, Switzerland), andstreptavidin-coated paramagnetic beads were obtained from Merck(Basel, Switzerland). qPCR kits, primers, and TaqMan probeswere purchased from Eurogentec (Seraing, Belgium).

Strains. Reference strains were ATCC33591 (MRSA), ATCC25923 or NCTC8530(MSSA), and ATCC12228 (methicillin-susceptible S. epidermidis[MSSE]). The reference MRSE and a panel of various bacterialspecies were clinical isolates identified using NCCLS proceduresat the Clinical Microbiology Laboratory (University Hospitalsof Geneva, Geneva, Switzerland). For these assays, overnightcultures were washed in saline and quantified by turbidimetry(ATB 1550; API bioMérieux). Titers were adjusted using10-fold dilutions in saline and checked by plating on agar.

Specimen collection. Samples consisting in nasal, inguinal, and wound swabs (Copanswabs;Copan Italia S.p.a, Brescia, Italy) were collected directlyfrom patients admitted to University Hospitals of Geneva accordingto a previously defined infection control strategy (16, 39).Samples were simultaneously analyzed by molecular and conventionalculture-based techniques. Swabs were suspended in 2 ml of colistin-saltbroth (CS broth: brain-heart infusion with 10 µg of colistin/mland 2.5% NaCl) and then divided equally and processed in parallel.

Identification of MRSA by standard microbiological procedure. One milliliter of CS broth was incubated at 35°C for 24h and inoculated on phenylethyl alcohol agar plates. Suspectcolonies were identified as MRSA based on Pastorex agglutination(Bio-Rad, Reinach, Switzerland), positive reaction on DNaseagar, and growth on Mueller-Hinton (MH) oxacillin agar (6 µgof oxacillin/ml, according to NCCLS [33]). The presence of MRSAwas confirmed using the Vitek 2 identification and susceptibilitytesting cards for gram-positives (bioMérieux, Marcy l'Etoile,France).

Immunomagnetic enrichment. The remaining 1 ml of CS broth was immediately processed byadding an optimized titer of biotinylated anti-spa antibodyin the presence of 1% human serum albumin (HSA) (injectablegrade; Swiss Red Cross, Bern, Switzerland). After a 30-min incubationat room temperature on a rotary shaker, the bacterial suspensionwas centrifuged for 10 min at 5,000 x g. The pellet was resuspendedin 200 µl of phosphate-buffered saline (PBS) (Invitrogen;Basel, Switzerland) containing 1% human serum albumin (PBS-HSA)and supplemented with 20 µl of streptavidin-coated paramagneticbeads. After a 30-min incubation on a rotary shaker, the magneticbeads were rinsed twice in PBS-HSA on the magnetic holder. Theefficiency of the immunomagnetic capture was assessed by platingdiluted portions on MH plates and determining the number ofCFU after 24 h of incubation.

Optimization of anti-spa antibody titer. To optimize the antibody titer, 10³ CFU of Cowan I (NCTC8530)was incubated with increasing antibody dilutions (1:166 to 1:5'400).The percentage of immunocaptured bacteria recovered from theoriginal spiking was determined by viable counts on MH agar.

Efficiency of the recovery rate for various MRSA titers. The recovery rate as a function of the number of spiked bacteriawas evaluated by incubating a range of MRSA suspensions (ATCC33591) in the presence of the optimized anti-spa titer in 1ml of CS broth. The yield was determined by viable counts.

Immunocapture of MRSA from mixed cultures. Various numbers of MRSA (ATCC 33591) were mixed with increasingtiters of MRSE, yielding ratios ranging from 1:1 to 1:1,000.Immunocapture was evaluated by viable CFU counts performed onMH agar. Strains were visually discriminated by their pigmentation.

Bacterial lysis and DNA extraction. Immunocaptured bacteria were suspended in 400 µl of chaotropicbuffer (DNeasy kit; Qiagen) with 200 mg of glass beads (diameter,100 to 200 µm). Bacteria were lysed at 4°C in a bead-beater(Mixer Mill; Qiagen) using two homogenization cycles of 45 seach at a frequency of 30 Hertz. The liquid phase was clearedfrom beads and debris by a 10-min centrifugation at 5.000 xg and then transferred into clean tubes containing 200 µlof ethanol. The nucleic acids were purified according to themanufacturer's instructions (Qiagen), eluted in water, driedin an evaporator, and finally resuspended in 20 µl ofwater.

DNA extraction from reference strains. Genomic DNA was extracted after a 10-min treatment at 37°Cin TE containing 100 µg of lysostaphin (Ambicin; AppliedMicrobiology, Tarrytown, N.Y.)/ml. DNA concentration and puritywere assessed by spectrophotometry (45) using an Uvikon 942(Kontron; Basel, Switzerland).

Oligonucleotide design and sequences. Sequences of primers and TaqMan probes are listed in Table 1.The design was performed using the software Primer Express version1.0 (PE Biosystems, Foster City, Calif.). Since the sequencesof both S. aureus and S. epidermidis mecA genes showed 100%homology, primers and TaqMan probe were determined based onthe S. aureus gene (GenBank accession no. X52593). On the opposite,whereas femA nucleotide sequences are phylogenetically conservedamong the staphylococci (13), S. aureus femA and S. epidermidisfemA displayed only 78% homology as determined by LALVIEW (http://www.expasy.ch/).Primers and TaqMan probes were selected in regions displayinglow homology with at least four mismatches between both femAoligonucleotide sequences (2, 3). Selected primers and probeswere checked against GenBank to exclude potential cross-reactingsequences. Sequence identity between S. aureus femA and theStreptococcus milleri gene for millericin B (GenBank accessionno. AF243359) was detected for both primer sequences as wellas a homology of 25 of 29 nucleotides in the probe. However,the length of the generated amplicon (703 bp) was found to beexcessive for reliable qPCR detection (not shown).

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TABLE 1. List and characteristics of oligonucleotides used in the triplex qPCR assay

Nucleic acid detection by qPCR. For robustness issues, each analysis was performed in triplicate.Nucleic acids from reference MRSA, MSSA, MRSE, and MSSE strains(100 pg of genomic DNA in each well) were simultaneously analyzedin each run and used as standards to adjust threshold values(C_t). Amplification procedure on the SDS 7700 (PE Biosystems)was the following: t_1, 2 min at 50°C; t₂, 10 min at 95°C;t₃, 15 s at 95°C; t₄, 1 min at 60°C (t₃ and t₄, repeated50 times). The final volume of the PCR mixture was 20 µland contained all primers and TaqMan probes at 100 nM concentrationsexcept the mecA probe, which was adjusted to 75 nM, followingassay optimization (data not shown). The cycling procedure wasimmediately started upon addition of 6 µl of sample. Thespecificity of qPCR identification was assessed using the followingpathogens (number of different strains): Escherichia coli (10),Campylobacter fetus (4), Proteus vulgaris (4), Enterococcusfaecalis (11), Enterococcus faecium (4), Enterobacter cloacae(3), Klebsiella pneumoniae (3), Streptococcus pneumoniae (4),Streptococcus alpha-haemolyticus (4), S. agalactiae (2), S.milleri (3), Pseudomonas aeruginosa (10), Stenotrophomonas maltophilia(1), Lactococcus cremoris (1), Neisseria sp. (1), and Staphylococcushaemolyticus (10); also Candida glabrata (2) and Candida albicans(2). None of these different species yielded any false-positiveqPCR signal.

Analysis of multiplex qPCR signals. After fluorescence background subtraction, we calibrated eachrun using the signals of the reference strains MRSA and MRSE.Detection thresholds were adjusted so that the mecA signal matchedthe corresponding femA signal for each reference strain. MRSAwas considered present only when average C_t values (triplicates)met the following conditions: (i) average C_t for mecA of <50;(ii) average C_t for S. aureus femA of <50; and (iii) C_t formecA that is less than the C_t for S. epidermidis femA.

RESULTS

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Results

Optimization of S. aureus immunocapture. The enrichment procedure for S. aureus was based on the ubiquitousand specific presence of protein A on S. aureus bacterial cells(either MRSA or MSSA). To optimize the conditions for S. aureusrecovery, we incubated bacterial suspensions with various anti-spaantibody dilutions, ranging from 1:166 to 1:5,400. An optimalrecovery of 85% from a suspension of 10³ Cowan I CFU/ml wasobtained with a titer of 1:666, equivalent to 1.5 µl ofanti-spa antibody per milliliter of CS broth (Fig. 1A). Higherantibody concentrations led to lower bacterial recovery, presumablydue to saturation of streptavidin-coated beads. Using this optimalantibody titer, we assessed the recovery rates from S. aureussuspensions over >7 orders of magnitude. Figure 1B showsthat the highest recovery rates (>60%) were consistentlyobtained from bacterial suspensions of 0.8 to 6 log₁₀ CFU/ml.This good recovery of diluted bacterial suspensions is a prerequisitefor sensitive molecular detection and molecular identificationof MRSA.

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FIG. 1. Effect of antibody concentration on S. aureus recovery rate. Cowan I strain (NCTC8530; 10³ CFU) was used to evaluate the optimal concentration of anti-spa antibodies required for the enrichment step. (A) Recovery was determined by CFU counts of immunocaptured colonies. The curve showed maximal recovery at an antibody dilution of 1:666. (B). Using this optimized anti-spa dilution, recovery was assessed across >7 orders of magnitude in inoculum size. Average values ± standard errors of the means for four experiments performed in duplicate are given.

Optimized recovery conditions in mixed cultures of S. aureus and S. epidermidis. To validate the immunocapture procedure, three different titersof MRSA (5, 60, and 1,000 CFU/ml) were incubated with increasingamounts of MRSE (Fig. 2A, B, and C). The recovery of MRSA wasexcellent and not significantly affected by adding MRSE in ratiosranging from 1:1 to 1:1,000. Constant recovery rates (>80%)were recorded for MRSA concentrations ranging from 5 to 1,000CFU/ml, even in the presence of a 1,000-fold excess amount ofMRSE. Equivalent data were recorded with two Pastorex-negativeMRSA isolates (not shown). This suggests that the minimal amountof protein A expressed by Pastorex-negative strains can be reliablyimmunocaptured.

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FIG. 2. Immunocapture of MRSA from mixed cultures. 5 (A), 60 (B), or 1,000 (C) CFU of MRSA (ATCC 33591) was mixed with increasing titers of MRSE, yielding ratios ranging from 1:1 to 1:1,000 for S. aureus (black bars) versus S. epidermidis (grey bars). Immunocapture was evaluated by viable CFU counts performed on MH agar. Means ± ranges for two experiments performed in duplicate are shown. _*, <10 CFU of MRSE.

Multiplex PCR assay. The limits of detection as well as the linearity of the qPCRassay were calibrated using increasing amounts (2 fg to 10 ng)of purified genomic DNA from MRSA (ATCC 33591). The C_t valuesfor mecA (Fig. 3) and S. aureus femA (not shown) were linearacross 6 orders of magnitude of DNA input. The upper limit oflinearity was >5 ng of template DNA, equivalent to 10⁶ genomecopies. The lower limit of MRSA DNA detection was reached with5 fg of genomic DNA, which is nearly equivalent to the genomeof 1 to 2 S. aureus bacterial cells (3.5 fg/cell). As expected,the qPCR signals were no longer consistently detected when usingless than 10 fg of genomic DNA. On the other hand, the mecAand S. aureus femA signals detected from an input genomic DNAamount of 100 pg (100 pg of genomic DNA corresponds to >4log₁₀ CFU) yielded similar C_t values without generating a nonspecificS. epidermidis femA signal. The specificity of the femA signalswas also verified with other reference strains (Table 2).

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FIG. 3. Linearity and limits of detection of the qPCR assay. The linear response of the qPCR mecA assay as a function of input genomic DNA (2 fg to 10 ng) purified from strain ATCC33591 is shown. Correlation coefficient, >0.99; slope, -3.59. Values are means ± standard errors of the means of 4 to 16 determinations. _*, value excluded from linear regression. _*_*, amounts of input DNA leading to irregular signal detection.

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TABLE 2. qPCR results for reference strains

Impact of the immunocapture procedure on the qPCR assay. When 10³ CFU of MRSA was incubated with MRSE at ratios rangingfrom 1:1 to 1:1,000, detection of MRSA after immunocapture remainedoptimal even in the presence of a 100-fold excess amount ofMRSE (Fig. 4). Equivalent MRSA detection efficacy was achievedusing as few as 5 CFU of MRSA. Average C_t values for S. aureusfemA and mecA were then constantly observed around 39.5 ±0.4. On the opposite, the immunocapture of a 100-fold excessamount of MRSE led to S. epidermidis femA signals >42. Suchlevels of residual MRSE contamination do not affect appropriateMRSA identification. As suggested by Fig. 2B, the qPCR assayidentified correctly the presence of 60 CFU of MRSA even whenit was incubated with a 1,000-fold excess amount of MRSE.

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FIG. 4. Effect of the immunocapture procedure on the qPCR assay. S. aureus (ATCC 33591; 10³ CFU) was mixed with various S. epidermidis titers (MRSE) and analyzed by qPCR following ( ${circ}$ ) or not following (•) immunocapture enrichment. MRSA in the presence of >100-fold-excess amounts of MRSE was not detected (NA). Values are means ± standard errors of the means for three experiments performed in triplicate.

When the immunocapture procedure was omitted, the detectionof MRSA by the S. aureus femA (Fig. 4) or mecA signals (notshown) was drastically affected by the presence of increasingamounts of MRSE. In the presence of a 1,000-fold excess amountof MRSE, nonimmunocaptured MRSA in suspension failed to be detectedby the qPCR assay. Contamination of MRSA suspensions by otherbacterial species, such as E. coli or Pseudomonas aeruginosa,in excess amounts yielded similar results (data not shown).

Evaluation of the qPCR assay with consecutive clinical swab samples. To test the specificity of the qPCR assay, 100 pg of genomicDNA from reference strains was analyzed (Table 2). Manual adjustmentof detection thresholds led to an improved matching of species-specificfemA signals with their corresponding mecA signal. The mecAsignal was specifically detected in MRSA, MRSE, and a methicillin-resistantS. haemolyticus clinical isolate. Furthermore, femA signalswere strictly species specific.

Table 3 shows the comparative results of immuno-qPCR and anoptimal bacteriological procedure applied to 48 clinical swabsamples. All the culture-positive samples were also detectedby the immuno-qPCR assay (n = 23). Among the samples found tobe MRSA negative by microbiological criteria (n = 25), 16 werealso scored as negative by immuno-qPCR. In contrast, a subgroupof nine culture-negative samples was scored as positive by immuno-qPCR.Altogether, these data yielded sensitivity and negative predictivevalues of 100%. In contrast, the specificity and positive predictivevalues were 64 and 72%, respectively. A possible reason forthe high proportion of false-positive cases might be the recentuse of topical antimicrobial agents in those previously identifiedMRSA carriers. This suggests that the immuno-qPCR proceduredetected the presence of nonviable MRSA and yielded misleadingresults in this subgroup. Furthermore, all these recently decontaminatedMRSA carriers relapsed shortly (<2 weeks) after the comparativeanalysis.

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TABLE 3. Comparison between culture-based and immuno-qPCR methods in the detection of MRSA in clinical swab samples^a

Altogether, the immuno-qPCR assay yields performance equivalentto that of optimal culture methods but has a dramatic impacton the delay for MRSA identification and implementation of infectioncontrol measures.

DISCUSSION

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Discussion

The identification of MRSA in biological samples is a time-consumingprocess relying on phenotypic or molecular analysis of isolatedbacteria. We describe here a novel molecular method that doesnot require any bacterial culture, the time-limiting step. Themajor advantage of this approach, compared to other publishedtechniques, is same-day MRSA identification directly from swabsamples or other potentially polymicrobial samples. This two-stepmolecular assay involves the immunocapture of S. aureus, followedby MRSA identification using a multiplex qPCR. This assay isbased on the highly conserved mecA sequence within all methicillin-resistantstrains and species of staphylococci, thus warranting the detectionof any organism carrying this resistance determinant (52). Tostrictly discriminate MRSA from any other methicillin-resistantstaphylococcal species, the qPCR assay unambiguously detectsa species-specific femA region. The femA target was selectedbecause of the following: (i) its presence in all S. aureusand S. epidermidis strains, (ii) the identification of species-specificoligonucleotides, and (iii) the successful development of atriplex qPCR assay. Other conserved sequences, such as nuc forS. aureus and femB for S. epidermidis, might represent alternatetargets. Experiments using samples spiked with known amountsof S. aureus and S. epidermidis not only accurately discriminatedeither species but also maintained the lower limit of detectionto one or two genome copies.

A critical innovative step of this method is the enrichmentprocedure that specifically immunocaptures virtually all strainsof S. aureus. The target of our antibody, the protein A, isroutinely used to confirm S. aureus identification because ofits high prevalence and specificity. Control experiments verifiedthe absence of significant immunocapture by a wide range ofgram-positive and gram-negative species (data not shown). Recoveryof MRSA was marginally influenced by the presence of S. epidermidiseven at a 1,000-fold excess amount. This assumption was verifiedeven for very low titers of S. aureus (<10 CFU) or for twoexceptional Pastorex-negative MRSA clinical isolates.

Several groups have already reported on the use of multiplexedPCR assays on pure cultures (25, 47, 48). Two recently describedprocedures (27, 29) detected the presence of MRSA from positiveblood culture bottles, with a limit of detection around 10⁵CFU/ml (29). The implementation of an immunocapture step allowedthe use of qPCR directly on mixed flora samples.

The clinical performance of this immuno-qPCR assay was evaluatedby testing 48 consecutive clinical swab samples. All culture-positiveMRSA samples were successfully detected by immuno-qPCR. Among25 culture-negative samples, a surprisingly high number of false-positiveresults were recorded (n = 9). A retrospective analysis revealedthat these nine cases were previously known as MRSA carriersand relapsed, as evidenced by culture. However, in this high-riskpopulation sample, 50% of the 16 cases identified as MRSA negativeby both techniques became MRSA positive during their hospitalstay. Thus, this low specificity does not compromise the utilityof the assay, since it mostly reflects situations of transientdecolonization (14, 15, 20, 21).

Larger numbers of samples are warranted to assess the sensitivityand specificity of the immuno-qPCR assay, especially in low-riskpatients. A large-scale prospective comparative study was recentlyinitiated in our institution to evaluate the impact of single-dayMRSA identification on patient management and infection controldecisions.

ACKNOWLEDGMENTS

This work was supported by grants from the Swiss National ScienceFoundation, no. 631-057950.99 (J.S.), 32-63710.00 (P.V.), and31-55344.98 (D.L.).

We thank Rosemary Sudan for comments on the manuscript.

FOOTNOTES

* Corresponding author. Mailing address: Division of Infectious Diseases/Genomic Research Laboratory, University Hospitals of Geneva, CH-1211 Geneva 14, Switzerland. Phone: (41)-22 372 9338. Fax: (41)-22 372 9830. E-mail: patrice.francois{at}hcuge.ch.

REFERENCES

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