Value of Different Assays for Detection of Human Cytomegalovirus (HCMV) in Predicting the Development of HCMV Disease in Human Immunodeficiency Virus-Infected Patients

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Journal of Clinical Microbiology, February 2000, p. 563-569, Vol. 38, No. 2
0095-1137/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Value of Different Assays for Detection of Human Cytomegalovirus (HCMV) in Predicting the Development of HCMV Disease in Human Immunodeficiency Virus-Infected Patients

Brian S. N. Blank,¹^,²^,^* Pieter L. Meenhorst,² Jan Willem Mulder,² Gerrit Jan Weverling,¹^,³ Hein Putter,¹ Wouter Pauw,⁴ Willemien C. van Dijk,⁴ Paul Smits,⁴ Sonja Lie-A-Ling,⁴ Peter Reiss,¹ and Joep M. A. Lange¹

National AIDS Therapy Evaluation Center, Department of Internal Medicine, Academic Medical Center, University of Amsterdam,¹ Department of Internal Medicine² and Department of Microbiology,⁴ Slotervaart Hospital, and Department of Clinical Epidemiology and Biostatistics, Academic Medical Center, University of Amsterdam,³ Amsterdam, The Netherlands

Received 19 January 1999/Returned for modification 26 April 1999/Accepted 1 November 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

In the present prospective study, five blood tests for detection of human cytomegalovirus (HCMV), nucleic acid sequence-basedamplification (NASBA) for detection of early (immediate-earlyantigen) and late (pp67) mRNA, PCR for detection of HCMV DNA (DNAPCR), culture, and pp65 antigenemia assay, and culture and DNAPCR of urine and throat swab specimens were compared for theirabilities to predict the development of disease caused by HCMV(HCMV disease). Of 101 human immunodeficiency virus (HIV)-infectedpatients with $<=$ 100 CD4⁺ lymphocytes per mm³, 25 patients developed HCMV disease. The pp65 antigenemia assay(sensitivity, 50%; specificity, 89%) and DNA PCR of blood (sensitivity,69%; specificity, 75%) were most accurate in predicting the developmentof HCMV disease within the next 12 months. Both blood cultureand late pp67 mRNA NASBA had high specificities (91 and 90%, respectively)but low sensitivities (25 and 13%, respectively). The sensitivitiesof urine culture, DNA PCR, throat swab specimen culture, DNA PCR,and NASBA of blood for detection of the immediate-early antigenwere 73, 87, 53, 67, and 63%, respectively, and the specificitieswere 58, 46, 76, 60, and 72%, respectively. The positive predictivevalues of all tests however, were low and did not exceed 50%.In conclusion, virological screening by these qualitative assaysfor detection of HCMV is of limited value for prediction of thedevelopment of HCMV disease in HIV-infectedpatients.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Human cytomegalovirus (HCMV) is a common opportunistic pathogen in patients infected with the human immunodeficiency virus(HIV) and is responsible for serious morbidity, especially retinitis,in 25 to 30% of patients with low CD4 lymphocyte counts (11,13, 22, 26). Since the introduction of highly active antiretroviraltherapy (HAART), the incidence of disease caused by HCMV (HCMVdisease) has declined (17). However, as sustained success ofHAART fails for a significant proportion of patients, one mightexpect patients to continue to be at risk for HCMV disease. Theidentification of those patients is important, since prophylacticor preemptive therapy with oral ganciclovir or valaciclovir reducesthe risk of development of HCMV disease (16, 28). Becauseof the toxicity and high costs of such treatment for all patientswith low CD4 lymphocyte counts, it is important to identify additionalrisk factors for HCMV disease. HCMV viremia can be detected byPCR for detection of HCMV DNA (DNA PCR) (6, 9, 18, 27,29), pp65 antigenemia assay (12, 21, 23), and conventionalculture or by the more rapid shell vial method. Both DNA PCR andthe pp65 antigenemia assay are considered sensitive tests withhigh predictive values for HCMV disease, especially when largenumbers of DNA copies (6, 27, 29) or pp65 antigen-bearingleukocytes (12, 23) are present, while blood cultures forHCMV appear to be of less value (9, 20, 21, 27). Strategiesfor prophylaxis or preemptive therapy for HCMV disease on thebasis of results of quantitative PCR for detection of HCMV DNAhave recently been proposed but require further investigationto confirm their benefit in terms of efficacy, convenience, andcost (4, 6, 7, 27, 29).

Although qualitative PCR of blood specimen DNA is a sensitive technique, it does not necessarily correlate with active HCMVinfection, since latently present viral DNA or incomplete viralgenomes may be amplified (25, 30). The detection of HCMV latemRNA in peripheral blood leukocytes may improve the ability toidentify patients at risk for the development of HCMV diseaseas it directly reflects viral transcriptional activity (1).In a study with bone marrow recipients, detection of HCMV latemRNA by reverse transcriptase (RT) PCR (RT-PCR) was more predictiveof the onset of HCMV disease-related symptoms than PCR for detectionof HCMV DNA (15). Furthermore, in a study with 102 HIV-infectedindividuals, detection of late mRNA by RT-PCR was more specific,although it was less sensitive, than DNA PCR for the diagnosisof acute HCMV disease (14). Recently, a method for the detectionof mRNA by nucleic acid sequence-based amplification (NASBA) wasdeveloped. In contrast to RT-PCR, NASBA allows direct isothermalamplification of specific sequences of single-stranded RNA (8).Screening for late pp67 mRNA by NASBA proved to be a sensitivetechnique for the detection of HCMV infection in renal transplantpatients and highly predictive of the development of HCMV disease(3).

In the prospective study described here, the prognostic value of monitoring of HCMV mRNA for the immediate-early antigen (IEA)and mRNA for the late pp67 antigen by NASBA for the developmentof HCMV disease was investigated. The results were compared withthose of culture and DNA PCR of blood, urine, and throat swabspecimens and a pp65-antigenemia assay with blood from 101 HIV-infectedpatients considered to be at risk for the development of HCMVdisease on the basis of CD4 lymphocyte counts of $<=$ 100/mm³.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Patients. Between March 1993 and November 1996, HIV-infected patients from the AIDS Clinic of the Slotervaart Hospital in Amsterdam,The Netherlands, with CD4 lymphocyte counts of $<=$ 100/mm³ were asked to participate in this study. All participating patientsgave written informed consent. Patients with a history of priorHCMV disease were included, provided that they had not receivedmedication for HCMV disease within 3 months prior to study entry.All participants underwent a complete physical examination, wereseen by an ophthalmologist with experience in HIV disease, andhad a chest X-ray taken to rule out active HCMV disease at studyentry. All patients already had or were offered prophylactic treatmentfor Pneumocystis carinii pneumonia and treatment for HIV infection.The treating physicians, including the ophthalmologists, werenot informed of the test results for any patient during follow-up.

Diagnosis of HCMV disease. Patients were considered to have HCMV retinitis if retinal damage typically caused by HCMV was seen upon examination of theretina through a dilated pupil (19). Gastrointestinal disease,including esophagitis, colitis, and cholangitis, was confirmedby endoscopy and histological examination of biopsy specimenswith detection of one or more inclusion bodies and/or by immunohistochemicaldetection of HCMV antigens. Radiculomyelitis was diagnosed onthe basis of typical findings upon medical history and physicalexamination together with detection of HCMV by DNA PCR of cerebrospinalfluid and recovery after treatment for HCMV infection. In addition,other findings that could possibly explain the illness were excluded.HCMV-related adrenalitis was diagnosed whenever the medical historyand physical examination were suggestive of adrenal insufficiency,as confirmed by typical laboratory abnormalities and recoveryafter treatment for HCMVinfection.

Collection of samples. At the start of the study and at each follow-up visit, scheduled every 2 to 3 months, whole blood (10 ml of heparinized bloodand 10 ml of EDTA-anticoagulated blood), freshly donated urine,and a throat swab specimen (which was placed in viral culturemedium) were collected and were immediately processed for culture,pp65 antigenemia assay, and qualitative DNAPCR.

One milliliter of the whole-blood specimen was added to 9 ml of lysis buffer (4.7 M guanidinium thiocyanate, 46 mM Tris [pH6.4], 20 mM EDTA, 1.2% [wt/vol] Triton X-100) and was stored at $-$ 70°C until assayed for IEA mRNA and late pp67 mRNA byNASBA.

HCMV cultures. For the detection of infectious HCMV, two conventional cell culture protocols were performed as described below. In brief,the buffy coat of heparinized whole blood was obtained by centrifugation(at 120 × g for 10 min). The leukocytes were then separated byadding 9 ml of 0.85% (wt/vol) NH₄Cl (pH 7.4; prepared in house)to the buffy coat and were incubated for 5 min at 4°C to rupturethe remaining erythrocytes. After centrifugation (at 400 × g for5 min) and three washings of the cell pellet with 10 ml of phosphate-bufferedsaline (PBS), the whole leukocyte suspension was resuspended in3 ml of Earl's HEPES with 10% fetal bovine serum (EH-10%; LifeTechnology, Paisley, United Kingdom). For the detection of infectiousHCMV, human embryonic lung (HEL) fibroblasts (provided by theDepartment of Virology of the Academic Medical Center, Amsterdam,The Netherlands) that had been grown for 5 to 10 days in glasstubes and plastic 24-well plates (Costar, Badhoevedorp, The Netherlands)were used. Aliquots of 0.2 ml of the 3-ml leukocyte suspensionwere inoculated into two tubes and wells (two by two) of the 24-wellplate. Inoculated HEL fibroblasts were maintained in EH-2% at37°C and were observed weekly for a period of 6 weeks for theappearance of cytopathic effects typical of those of replicatingHCMV.

In a separate rapid shell vial culture, in duplicate, HCMV-specific antigens were detected 24 to 48 h and 5 to 7 days afterinoculation by indirect immunofluorescence staining. Cultureswere fixed with methanol-acetone solution (1:1 [vol/vol]) for20 min at $-$ 20°C. Monoclonal antibody E13 (dilution, 1:1,000; Biosoft,Paris, France), which is directed against the HCMV IEA, was addedfor 60 min at 37°C. Subsequent incubation with fluorescein isothiocyanate-conjugatedgoat anti-mouse immunoglobulin antibody (dilution, 1:1,000; Biosoft)for 60 min at 37°C yielded fluorescence of the nuclei of infectedcells. Cultures were read with a Zeiss fluorescent inverted microscopeat ×100 magnification. For the detection of infectious HCMV inurine and throat swab specimens, essentially the same methodsdescribed above were used. In brief, urine samples were mixedwith EH-10% (1:1 [vol/vol]), whereas throat swab specimens weremixed with a virus transport medium and were subsequently addedto HEL fibroblasts as describedabove.

The blood culture result was considered positive if HCMV was detectable by one or both culture procedures and was negativeif HCMV was not detectable by bothprocedures.

PCR for HCMV DNA detection. DNA was extracted from patient materials by guanidinium thiocyanate lysis, binding to silica particles, and washing and elutionwith 100 µl of Tris-EDTA buffer as described by Boom et al. (5).For the blood PCR for HCMV DNA detection, DNA was extracted from100 µl of whole blood. The PCR was performed with 10 µl of theextracted DNA with primers that are specific for the fourth exonof the immediate-early gene of HCMV (primer 1, 5'-GAGCCTTTCGAGGAGATGAA-3';primer 2, 5'-GAAGGCTGAGTTCTTGGTAA-3'). After amplification, thePCR products were analyzed on a 2% agarose gel and were subsequentlytransferred to a nitrocellulose membrane (Amersham, Rainham, UnitedKingdom). The blots were hybridized with a digoxigenin-labelledinternal 40-bp probe (5'-CTAACTATGCAGAGCATGTATGAGAACTACATTGTACCTG-3').Hybrids were visualized with a digoxigenin nucleic acid detectionkit (Boehringer Mannheim). With our primers, which were locatedin the immediate-early gene, the analytic sensitivity of the PCRfor HCMV DNA detection was measured to be 20 to 50 DNAmolecules.

pp65 antigenemia assay. The pp65 antigen was detected immunocytochemically, essentially as described by Van der Bij et al. (31), with a few modifications.In brief, the leukocytes were isolated from 10 ml of EDTA-anticoagulatedblood by centrifugation as described above within 8 h of collection.The total cell pellet was fixed (10 min at room temperature) in2% paraformaldehyde (818 715.0100; Merck, Darmstadt, Germany).After centrifugation (at 400 × g for 5 min) and three washingsof the cell pellet with PBS-1% bovine serum albumin (BSA; Boseral20 T, Organon Teknika, Boxtel, The Netherlands), the whole leukocytesuspension was resuspended in PBS-1% BSA to give a final celldensity comparable to that of a McFarland no. 3 standard (2 ×10⁶ leukocytes/ml). A volume of 0.1 ml of the cell suspension wasused for each of four cytospin slides. The cytospin slides werestored directly at $-$ 70°C until staining. Before staining, theslides (two per patient; one as a control and one for testing)were fixed in cold acetone for 15 min directly from the $-$ 70°Cfreezer. Subsequently, the slides were incubated for 30 min withanti-pp65 monoclonal mouse antibody (C10/C11; dilution, 1:25;Biotest, Dreieich, Germany), and the control samples were incubatedwith PBS. For immunoenzymatic staining of those cell componentsto which the mouse anti-pp65 monoclonal antibody specificallybinds, the alkaline phosphatase-anti-alkaline phosphatase methodwas used according to the protocol of the manufacturer (ClonabCMV;Biotest).

The quantification of pp65 antigen-bearing cells was achieved under a light microscope by counting the number of positivelystained leukocytes and the total number of leukocytes per slideby using an eyepiece with a counting grid. The results were givenas the total number of positive leukocytes/total number of leukocytes× 10⁵, which is equal to the number of positive leukocytes/10⁵leukocytes.

NASBA for IEA mRNA and pp67 mRNA. For the analysis by NASBA, 1 ml of the lysed whole-blood suspension, which equals 100 µl of the whole-blood input sample at100:1, was used. Processing of blood specimens for isolation ofHCMV IEA and late (pp67) mRNA and monitoring of the expressionof these mRNAs by NASBA (Organon Teknika) were done as recentlydescribed by Blok et al. (2, 3). The primers CMV IEA-1.5(T7 primer [sequence, 5'-AATTCTAATACGACTCACTATAGGGAGACTTAATACAAGCCATCCACA-3';the T7 promoter sequence is depicted in small capital letter])and CMV 2.3 (primer 2; sequence, 5'-TAGATAAGGTTCATGAGCCT-3') weredesigned to amplify part of the mRNA encoding IEA. For the amplificationof part of the mRNA encoding pp67, primers CMVpp67-1.2 and CMVpp67-2.4,which have been described before (3), were used. The NASBAreactions were carried out as described by Blok et al. (3).After the NASBA reaction, the amplification products were analyzedby an enzyme-linked gel assay, as described by Van der Vliet etal. (32), with the use of a specific horseradish peroxidase5'-labelled oligonucleotide probe (CMV IEA HRP1; sequence, 5'-HRP-GAGGATAAGCGGGAGATGTGGATGGC-3')for NASBA of IEA mRNA. Electrochemiluminescence-based detectionwas used for the NASBA of pp67 mRNA (3). The analytical sensitivitiesof the NASBAs for IEA mRNA and pp67 mRNA detection were about10 to 100 RNAmolecules.

Statistical analysis. For each test the sensitivity, specificity, positive predictive value (PPV), and negative predictive value (NPV) were determined,by using standard formulas, by comparing the test results forpatients who developed HCMV disease with those for patients whodid not. Relative risks and likelihood ratios (sensitivity/1 $-$ specificity) were calculated with 95% confidence intervals (CIs).Initially, the sensitivity, specificity, PPV, NPV, relative risk,and likelihood ratio for the development of HCMV disease within12 months were determined for each test on the basis of the firstavailable test result for all patients. As the pp65 antigenemiaassay provides a quantitative result, the cutoff value for a positivepp65 antigenemia test result was determined by constructing areceiver-operating characteristic curve. By using such an analysis,the cutoff value with the highest combination of sensitivity andspecificity can be distinguished. The value of repeat testingfor the identification of patients who develop HCMV disease wasdetermined by dividing the patients into those who had never hada positive test result and those with a positive test result onat least one occasion during follow-up. Relative risk, likelihoodratio, sensitivity, specificity, PPV, and NPV were again determinedfor eachtest.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Characteristics of the study population. A total of 116 patients entered the study. Of these patients, 15 were excluded from further analysis; 1 had received maintenancetreatment for HCMV-related meningoencephalitis within 3 monthsprior to study entry and 14 were diagnosed with HCMV disease atthe time ofinclusion.

The demographic characteristics of the remaining 101 patients are shown in Table 1. Ten patients (9.9%) were HCMV immunoglobulinG antibody negative. None of these patients had received HCMVtreatment at any time prior to study entry, and no patient hada history of previous HCMV disease. Two patients were on HAARTat the time of study entry, and another two started HAART at thetime of study entry. The other 97 patients used one or a combinationof nucleoside analogue RT inhibitors or no antiretroviral therapyat all.

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TABLE 1. Baseline characteristics of study population

Development of HCMV disease. The median follow-up time for the patients was 15.2 months (interquartile range [IQR], 10.1 to 23.8 months). Of the 101 patients,25 developed HCMV disease during follow-up: retinitis (n = 17),colitis (n = 4), esophagitis (n = 1), cholangitis (n = 1), adrenalitis(n = 1), and radiculomyelitis (n = 1). The median time to thedevelopment of HCMV disease was 10.6 months (IQR, 8.8 to 16.0months). The patients who were HCMV immunoglobulin G antibodynegative and the four patients on HAART remained free of HCMVdisease during follow-up. Seventy-two patients died after a medianfollow-up of 12.9 months (IQR, 9.5 to 19.3 months), and four patientswere lost to follow-up. Eighteen of these 72 patients had developedHCMV disease and died a median of 4.1 months (IQR, 2.6 to 8.0months) after the diagnosis of HCMV disease. Since most patientsdied at home and postmortem examinations were not routinely performed,some patients may have had clinically unrecognized HCMV disease.However, in only one of the five patients who did undergo a postmortemexamination and who had not developed HCMV disease during hislife, a duodenal ulcer was found, and this was possibly causedby HCMV. This patient also suffered from visceral Kaposi's sarcomaand a non-Hodgkin's lymphoma, the combination of which was thoughtto have been the cause ofdeath.

PPVs, NPVs, and relative risk for the development of HCMV disease over the next 12 months by testing a single sample. Calculations of the predictive value of each assay for the development of HCMV disease over the next 12 months were basedon results of a sample taken at the start of the study. Of the25 patients who developed HCMV disease, 16 developed HCMV diseasewithin 1 year after study entry. As the pp65 antigenemia assayresult was quantified as numbers of positive leukocytes per 10⁵ leukocytes counted, a cutoff level of 6 positive leukocytes/10⁵ leukocytes was determined by using a receiver-operating characteristiccurve; a result above the cutoff was given a positive score. Thetest results for patients who did and who did not develop HCMVdisease over the next 12 months are presented in Table 2.

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TABLE 2. Test results for a single sample taken at start of study from 101 patients

DNA PCR and culture of urine had the highest sensitivities (87 and 73%, respectively), but the specificities of these testswere low. Blood culture and NASBA for pp67 mRNA were not verysensitive but had higher specificities (91 and 90%, respectively).The sensitivities of the NASBA for IEA mRNA detection (63%), DNAPCR with blood (69%), and DNA PCR with throat swab specimens (67%)were comparable, but the specificity of the DNA PCR with throatswab specimens was lower than the specificity of the NASBA forIEA mRNA detection and DNA PCR with blood. The combined valueof sensitivity and specificity favored the pp65 antigenemia assay,with a likelihood ratio of 4.6 (95% CI, 2.1 to 10.9). The PPVfor the development of HCMV disease over the next 12 months waslow for all assays and did not exceed 50%. The PPV was highestfor the pp65 antigenemia assay (47%) and the DNA PCR with blood(35%). The NPV, on the other hand, was fairly high for all tests,ranging from 86% (blood culture) to 95% (DNA PCR with urine).Thus, patients with no detectable HCMV by any test were unlikelyto develop HCMV disease in the near future. The NPV of the pp65antigenemia assay was slightly lower than the NPV of the DNA PCRwith blood (90 versus 93%). The combined value of PPV and NPV(relative risk) favored the pp65 antigenemia assay and qualitativeDNA PCR with blood (Fig. 1A).

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FIG. 1. (A) Relative risk for the development of HCMV disease within the next 12 months after a single positive test result for a sample taken at the start of the study. (B) Relative risk for the development of HCMV disease after at least one positive test result for samples taken during follow-up. $Psi$ , infinite relative risk as NPV was 100%.

Repeat testing for prediction of HCMV disease. The median number of follow-up samples per patient-year of follow-up was 6.4 (IQR, 4.9 to 8.0) among patients who developedHCMV disease and 5.9 (IQR, 4.8 to 7.0) among patients who didnot develop HCMV disease (P = 0.34 by the Wilcoxon two-sampletest).

For many patients who initially had negative test results at the start of the study, HCMV became detectable on at least oneoccasion during follow-up, regardless of the development of HCMVdisease (Table 3). Although an increase in the sensitivity ofeach test for the detection of HCMV disease was observed by repeattesting, the specificity of each test decreased. The pp65 antigenemiaassay and blood culture had the highest likelihood ratios (2.5and 2.7, respectively), mainly because these tests were more specific,while they were less sensitive than DNA PCR with blood, NASBAfor IEA mRNA detection, and both culture and DNA PCR with urineand throat swab specimens at detecting HCMV disease. During follow-up,a positive result of each test except the DNA PCR with urine wassignificantly associated with the development of HCMV disease(Fig. 1B), with culture of urine having the highest relative riskfor the development of HCMV disease (12.0; 95% CI, 1.7 to 85.3).However, upon repeat testing the PPV of a positive test resultduring follow-up for the subsequent development of HCMV diseasewas still less than 50% for all tests.

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TABLE 3. Test results for 101 patients during follow-up

Test results during follow-up for patients who developed HCMV disease. For 20 of the 25 patients who developed HCMV disease, samples were drawn at the time of diagnosis of HCMV disease. Not allpatients who tested positive at least once during follow-up werealso positive at the time of diagnosis of HCMV disease. NASBAfor detection of IEA mRNA was positive for 16 of 20 patients (80%).DNA PCR with blood was positive for 15 of 20 patients (75%). Thepp65 antigenemia assay was positive for 10 of 18 patients (55.6%),while for 2 patients no test results were available due to theavailability of an insufficient number of leukocytes after samplepreparation. Blood culture was positive for 10 of 19 patients(52.6%); for 1 patient no test result was available. The NASBAassay for detection of pp67 mRNA was positive for 11 of 20 patients(55%). The urine culture was positive for 16 of 18 patients (88.9%),and the DNA PCR with urine was positive for 15 of 18 patients(83.3%), while no urine samples were taken from 2 patients. Thethroat swab culture was positive for 15 of 19 patients (78.9%),and the DNA PCR with throat swab specimens was positive for 17of 19 patients (89.5%). No throat swab was taken from onepatient.

The time between the first positive test result and the development of HCMV disease differed considerably between the assays.At a median of 4.5 months (IQR, 3.2 to 8.5 months), 3.1 months(IQR, 1.9 to 6.6 months), and 4.7 months (IQR, 2.1 to 9.2 months)before the development of HCMV disease, the NASBA for pp67 mRNAdetection, blood culture, and pp65 antigenemia assay, respectively,became positive. The other assays became positive much earlierbefore diagnosis of HCMV disease: NASBA for IEA mRNA detection,9.2 months (IQR, 4.1 to 11.3 months); DNA PCR with blood, 9.4months (IQR, 4.6 to 12.8 months); urine culture, 9.2 months (IQR,3.6 to 18.4 months); DNA PCR with urine, 9.7 months (IQR, 6.7to 18.4 months); culture of throat swab specimen, 8.8 months (IQR,4.4 to 13.2 months); and DNA PCR with throat swab specimen, 9.1months (IQR, 5.5 to 15.0months).

However, after testing positive before the development of HCMV disease, a considerable number of patients again had negativetest results during further follow-up. For the NASBA for IEA mRNAdetection this was observed for 10 of 20 patients (50%), for DNAPCR with blood this was observed for 11 of 20 patients (52.4%),for the pp65 antigenemia assay this was observed for 8 of 18 patients(44.4%), for the NASBA for detection of pp67 mRNA this was observedfor 9 of 20 patients (45%), for blood culture this was observedfor 8 of 20 patients (40%), for urine culture this was observedfor 7 of 18 patients (38.9%), for DNA PCR with urine this wasobserved for 12 of 18 patients (66.7%), for culture of throatswab this was observed for 8 of 19 patients (42.1%), and for DNAPCR with throat swab specimens this was observed for 6 of 19 patients(31.6%).

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

In the prospective study described here five different blood tests, including detection of early and late mRNAs by NASBA andtwo tests with urine and throat swab specimens for the detectionof HCMV, were compared to establish the most accurate test forthe identification of HIV-infected patients who will go on todevelop HCMV disease. So far, other studies that have evaluateda limited number of available tests for the detection of HCMVhave shown that, in particular, the pp65 antigenemia assay andDNA PCR with blood or plasma may identify patients who will developHCMV disease, while culture of blood and urine appeared to beof less value (9, 18, 21, 24, 27, 29).

For patient management, assays accurate in predicting the development of HCMV disease may contribute to the decision to startprophylactic or preemptive treatment against HCMV in individualpatients. We therefore assessed the value of a single test resultas well as the results of repeat tests for the identificationof patients who will develop HCMV disease. On the basis of a singletest result, the pp65 antigenemia assay and DNA PCR with bloodwere highly associated with the development of HCMV disease within1 year, whereas the results of a single test by conventional bloodculture, a NASBA assay for pp67 mRNA detection, and DNA PCR withthroat swab specimens were not. The DNA PCR with blood was moresensitive than the pp65 antigenemia assay, but the pp65 antigenemiaassay was more specific and had a higher PPV for the developmentof HCMV disease. By using the likelihood ratio, the probabilityof a positive test result while getting the disease can be relatedto the probability of a positive test result while not gettingHCMV disease. The pp65 antigenemia assay had a higher likelihoodratio than the DNA PCR with blood. When multivariate logisticregression analysis was used, including data for all tests witha positive or negative result, the only remaining test with asignificant relative risk for the development of HCMV diseasewas the pp65 antigenemia assay (data notshown).

It has been reported that quantification of the HCMV load may improve the ability to identify patients who will develop HCMVdisease (4, 12, 24, 27, 29). The pp65 antigenemia assay,in contrast to the other tests used in this study, allows an indirectquantification of HCMV load by counting the number of antigen-bearingcells. A threshold level of six antigen-positive cells was usedto assign a positive result. This may explain why the antigenemiaassay was more predictive of the development of HCMV disease thanthe DNA PCR. Still, however, it should be stressed that the predictivevalue of the pp65 antigenemia assay was low, since less than 50%of the patients with a positive test result went on to developHCMVdisease.

The detection of late pp67 mRNA by NASBA in a single sample was not associated with the development of HCMV disease in thenear future. Although this test was highly specific, it had alow sensitivity and a low PPV for the development of HCMV disease.This is in contrast to the findings for a group of renal transplantpatients, for whom the detection of late mRNA by NASBA was highlypredictive and specific for the onset of HCMV disease (3).Gozlan et al. (14), who earlier described an indirect methodfor the detection of HCMV late mRNA by RT-PCR, found it to bea highly specific and only a slightly less sensitive marker thanthe pp65 antigenemia assay and DNA PCR with blood for the diagnosisof HCMV disease in HIV-infected patients. However, no data onits value in predicting HCMV disease areavailable.

DNA PCR with urine, culture of urine, DNA PCR with throat swab specimens, and culture of throat swab specimens were all highlysensitive tests for the identification of patients who will goon to develop HCMV disease, but their specificities were low.This suggests that many HIV-infected patients with low CD4 lymphocytecounts may at times shed HCMV in urine or the throat without subsequentlydeveloping HCMV disease. Repeat testing during follow-up increasedthe sensitivity of each test for the identification of patientswho will develop HCMV disease. However, an increasing number ofpatients who did not develop HCMV disease also had positive testresults during follow-up. Overall, each test (except DNA PCR withurine), when positive at least once during follow-up, was significantlyassociated with the development of HCMV disease, but again, thePPVs of these tests did not exceed 50%. The observation that foreach test approximately 50% of the patients who developed HCMVdisease had negative test results after a positive test resultfurther attenuates the relevance of repeattesting.

For most patients, HCMV was already detectable by the different assays months before HCMV disease developed. In addition,some patients had negative test results at the time of diagnosisof HCMV disease after they had been positive on an earlier occasion.This confirms the findings of Shinkai et al. (27), who demonstratedthat peak HCMV DNA levels occurred months before the developmentof HCMV disease in some patients, while at the time of diagnosisof HCMV disease few or no DNA copies were found. Therefore, onemay speculate that viral seeding of an organ takes place monthsbefore HCMV disease develops. Ultimately, local host defense mechanismsdetermine to what extent clinical symptoms develop. Two observationsmay support this concept. First, it was shown that in 91% of patientswith HCMV retinitis, DNA PCR with ocular fluid was positive, whileonly 44% of these patients had positive results by DNA PCR withblood (10). Second, patients with HCMV retinitis may developa transient intraocular inflammation after the institution ofcombination antiretroviral therapy, possibly reflecting an improvedimmune response against HCMV (33). Therefore, the finding ofHCMV in other clinical specimens like blood, urine, and throatswabs may not accurately reflect disease progression in an organwhere the virus ultimatelyresides.

HCMV disease is most likely to develop in patients with less than 50 CD4 lymphocytes/mm³. This study also included patients with 50 to 100 CD4 lymphocytes/mm³. However, a subanalysis that included the test results for only66 patients with 50 CD4 lymphocytes/mm³ or less essentially revealed identical sensitivities, specificities,and relative risks for the development of HCMV disease for eachassay.

In summary, the results indicate that, if any of the tests are useful, the pp65 antigenemia assay and DNA PCR with blood arethe most useful tests for the identification of those patientswho will develop HCMV disease over time. However, when consideringthe result of a single test by DNA PCR with blood or the pp65antigenemia assay, only 60 to 70% of patients with HCMV diseasewill be accurately identified and less than half of the patientswho test positive will actually develop HCMV disease in the nearfuture. Furthermore, many patients with a negative test resultwill still develop HCMV disease. These results indicate that screeningfor HCMV in HIV-infected patients by any of the reported qualitativeassays is of limited value for the management of HCMVdisease.

	ACKNOWLEDGMENTS

We are indebted to Hanneke Paap and Lillian van Belle, AIDS nurses of the Slotervaart Hospital, Amsterdam, for their effortsin patient recruitment and provision of clinical samples and dataand Joeri Vrooland and Francis Neuteboom for providing ophthalmologicdata. We also thank Anneke Stouten and Loes Buisman of the Departmentof Microbiology of the Slotervaart Hospital for the provisionof virological and serological data. We gratefully thank OrganonTeknika for technical support and provision of NASBA assays fordetection of early and late HCMV mRNA. This work was performedat the Slotervaart Hospital, and at the National AIDS TherapyEvaluation Center, Department of Internal Medicine, Academic MedicalCenter, Amsterdam, TheNetherlands.

	FOOTNOTES

^* Corresponding author. Mailing address: National AIDS Evaluation Center, Department of Internal Medicine, Academic MedicalCenter, University of Amsterdam, Meibergdreef 9, 1105 AZ Amsterdam,The Netherlands. Phone: 31 20 5664479. Fax: +31 20 6918821. E-mail:S.N.Blank{at}amc.uva.nl.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Bitsch, A., H. Kirchner, R. Dupke, and G. Bein. 1993. Cytomegalovirus transcripts in peripheral blood leukocytes of actively infected transplant patients detected by reverse transcription-polymerase chain reaction. J. Infect. Dis. 167:740-743[Medline].

2. Blok, M. J., M. H. Christiaans, V. J. Goossens, J. P. van Hooff, B. Top, J. M. Middeldorp, and C. A. Bruggeman. 1998. Evaluation of a new method for early detection of active cytomegalovirus infections. A study in kidney transplant recipients. Transpl. Int. 11(Suppl. 1):S107-S109.

3. Blok, M. J., V. J. Goossens, S. J. V. Vanherle, B. Top, N. Tacken, J. M. Middeldorp, M. H. Christiaans, J. P. van Hooff, and C. A. Bruggeman. 1998. Diagnostic value of monitoring human cytomegalovirus late pp67 mRNA expression in renal allograft recipients by nucleic acid sequence-based amplification. J. Clin. Microbiol. 36:1341-1346[Abstract/Free Full Text].

4. Boivin, G., J. Handfield, E. Toma, G. Murray, R. Lalonde, and M. G. Bergeron. 1998. Comparative evaluation of the cytomegalovirus DNA load in polymorphonuclear leukocytes and plasma of human immunodeficiency virus-infected subjects. J. Infect. Dis. 177:355-360[Medline].

5. Boom, R., C. J. Sol, M. M. M. Salimans, C. L. Jansen, P. M. Wertheim-van Dillen, and J. van der Noordaa. 1990. Rapid and simple method for purification of nucleic acids. J. Clin. Microbiol. 28:495-503[Abstract/Free Full Text].

6. Bowen, E. F., C. A. Sabin, P. Wilson, et al. 1997. Cytomegalovirus (CMV) viraemia detected by polymerase chain reaction identifies a group of HIV-positive patients at high risk of CMV disease. AIDS 11:889-893[CrossRef][Medline].

7. Bowen, E. F., P. Wilson, A. Cope, et al. 1996. Cytomegalovirus retinitis in AIDS patients: influence of cytomegaloviral load on response to ganciclovir, time to recurrence and survival. AIDS 10:1515-1520[Medline].

8. Compton, J. 1991. Nucleic acid sequence-based amplification. Nature 350:91-92[CrossRef][Medline].

9. Dodt, K. K., P. H. Jacobsen, B. Hofmann, et al. 1997. Development of cytomegalovirus (CMV) disease may be predicted in HIV-infected patients by CMV polymerase chain reaction and the antigenemia test. AIDS 11:F21-F28[CrossRef][Medline].

10. Doorenbal, P., G. Seerp Baarsma, W. G. V. Quint, A. Kijlstra, P. H. Rothbarth, and H. G. M. Niesters. 1996. Diagnostic assays in cytomegalovirus retinitis: detection of herpesvirus by simultaneous application of the polymerase chain reaction and local antibody analysis on ocular fluid. Br. J. Ophthalmol. 80:235-240[Abstract/Free Full Text].

11. Drew, W. L. 1992. Cytomegalovirus infection in patients with AIDS. Clin. Infect. Dis. 14:608-615[Medline].

12. Francisci, D., A. Tosti, F. Baldelli, G. Stagni, and S. Pauluzzi. 1997. The pp65 antigenemia test as a predictor of cytomegalovirus-induced end-organ disease in patients with AIDS. AIDS 11:1341-1345[CrossRef][Medline].

13. Gallant, J. E., R. D. Moore, D. D. Richman, J. Keruly, R. E. Chaisson, and The Zidovudine Epidemiology Study Group. 1992. Incidence and natural history of cytomegalovirus disease in patients with advanced human immunodeficiency virus disease treated with zidovudine. J. Infect. Dis. 166:1223-1227[Medline].

14. Gozlan, J., J. M. Salord, C. Chouaïd, C. Duvivier, O. Picard, M. C. Meyohas, and J. C. Petit. 1993. Human cytomegalovirus (HCMV) late-mRNA detection in peripheral blood of AIDS patients: diagnostic value for HCMV disease compared with those of viral culture and HCMV DNA detection. J. Clin. Microbiol. 31:1943-1945[Abstract/Free Full Text].

15. Gozlan, J., J. P. Laporte, S. Lesage, M. Labopin, A. Najman, N. C. Gorin, and J. C. Petit. 1996. Monitoring of cytomegalovirus infection and disease in bone marrow recipients by reverse transcription-PCR and comparison with PCR and blood and urine cultures. J. Clin. Microbiol. 34:2085-2088[Abstract].

16. Griffiths, P. D., J. E. Feinberg, J. Fry, et al. 1998. The effect of valaciclovir on cytomegalovirus viremia and viruria detected by polymerase chain reaction in patients with advanced human immunodeficiency virus disease. J. Infect. Dis. 177:57-64[Medline].

17. Hammer, S. M., K. E. Squires, M. D. Hughes, et al. 1997. A controlled trial of two nucleoside analogues plus indinavir in persons with human immunodeficiency virus infection and CD4 cell counts of 200 per cubic millimeter or less. N. Engl. J. Med. 337:725-733[Abstract/Free Full Text].

18. Hansen, K. K., A. Ricksten, B. Hofmann, B. Norrild, S. Olofsson, and L. Mathiesen. 1994. Detection of cytomegalovirus DNA in serum correlates with clinical cytomegalovirus retinitis in AIDS. J. Infect. Dis. 170:1271-1274[Medline].

19. Ljungman, P., and S. A. Plotkin. 1995. Workshop on CMV disease: definition, clinical severity scores and new syndromes. Scand. J. Infect. Dis. 99:87-89.

20. MacGregor, R. R., S. J. Pakola, A. L. Graziani, et al. 1995. Evidence of active cytomegalovirus infection in clinically stable HIV-infected individuals with CD4⁺ lymphocyte counts below 100/µl of blood: features and relation to risk of subsequent CMV retinitis. J. Acquir. Immune. Defic. Syndr. Hum. Retrovirol. 10:324-330[Medline].

21. Mazzulli, T., R. H. Rubin, M. J. Ferraro, R. T. D'Aquila, S. A. Doveikis, B. R. Smith, T. H. The, and M. S. Hirsch. 1993. Cytomegalovirus antigenemia: clinical correlations in transplant recipients and in persons with AIDS. J. Clin. Microbiol. 31:2824-2827[Abstract/Free Full Text].

22. Pertel, P., R. Hirschtick, J. Phair, J. Chmiel, L. Poggensee, and R. Murphy. 1992. Risk of developing cytomegalovirus retinitis in persons infected with the human immunodeficiency virus. J. Acquir. Immune. Defic. Syndr. Hum. Retrovirol. 5:1069-1074.

23. Podzamcer, D., E. Ferrer, A. Garcia, et al. 1997. PP65 antigenemia as a marker of future CMV disease and mortality in HIV-infected patients. Scand. J. Infect. Dis. 29:223-227[Medline].

24. Rasmussen, L., S. Morris, D. Zipeto, et al. 1995. Quantitation of human cytomegalovirus DNA from peripheral blood cells of human immunodeficiency virus-infected patients could predict cytomegalovirus retinitis. J. Infect. Dis. 171:177-182[Medline].

25. Roseff, S. D., M. Rockis, J. F. Keiser, et al. 1993. Optimization for detection of cytomegalovirus by the polymerase chain reaction (PCR) in clinical samples. J. Virol. Methods 42:137-146[CrossRef][Medline].

26. Saillour, F., N. Bernard, L. Dequae-Merchadou, et al. 1998. Predictive factors of occurrence of cytomegalovirus disease and impact on survival in the Aquitaine cohort in France, 1985 to 1994. J. Acquir. Immune. Defic. Syndr. Hum. Retrovirol. 17:171-178[Medline].

27. Shinkai, M., S. A. Bozette, W. Powderly, P. Frame, and S. A. Spector. 1997. Utility of urine and leukocyte cultures and plasma DNA polymerase chain reaction for identification of AIDS patients at risk for developing human cytomegalovirus disease. J. Infect. Dis. 175:302-308[Medline].

28. Spector, S. A., G. F. McKinley, J. P. Lalezari, et al. 1996. Oral ganciclovir for the prevention of cytomegalovirus disease in persons with AIDS. N. Engl. J. Med. 334:1491-1497[Abstract/Free Full Text].

29. Spector, S. A., R. Wong, K. Hsia, M. Pilcher, and M. J. Stempien. 1998. Plasma cytomegalovirus (CMV) DNA load predicts CMV disease and survival in AIDS patients. J. Clin. Invest. 101:497-502[Medline].

30. The, T., M. van der Ploeg, A. P. van den Berg, A. M. Vlieger, M. van der Giessen, and W. J. van Son. 1992. Direct detection of cytomegalovirus in peripheral blood leukocytes $---$ a review of the antigenemia assay and polymerase chain reaction. Transplantation 54:193-198[Medline].

31. Van der Bij, W., R. Torensma, W. J. van Son, et al. 1988. Rapid immunodiagnosis of active cytomegalovirus infection by monoclonal antibody staining of blood leukocytes. J. Med. Virol. 25:179-188[Medline].

32. Van der Vliet, G. M. E., R. A. F. Schukkink, B. van Gemen, P. Schepers, and P. R. Klatser. 1993. Nucleic acid sequence-based amplification (NASBA) for the identification of mycobacteria. J. Gen. Microbiol. 139:2423-2429[Medline].

33. Zegans, M. E., R. C. Walton, G. N. Holland, J. J. O'Donnell, M. A. Jacobson, and T. P. Margolis. 1998. Transient vitreous inflammatory reactions associated with combination antiretroviral therapy in patients with AIDS and cytomegalovirus retinitis. Am. J. Ophthalmol. 125:292-300[CrossRef][Medline].

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1.	Bitsch, A., H. Kirchner, R. Dupke, and G. Bein. 1993. Cytomegalovirus transcripts in peripheral blood leukocytes of actively infected transplant patients detected by reverse transcription-polymerase chain reaction. J. Infect. Dis. 167:740-743[Medline].
2.	Blok, M. J., M. H. Christiaans, V. J. Goossens, J. P. van Hooff, B. Top, J. M. Middeldorp, and C. A. Bruggeman. 1998. Evaluation of a new method for early detection of active cytomegalovirus infections. A study in kidney transplant recipients. Transpl. Int. 11(Suppl. 1):S107-S109.
3.	Blok, M. J., V. J. Goossens, S. J. V. Vanherle, B. Top, N. Tacken, J. M. Middeldorp, M. H. Christiaans, J. P. van Hooff, and C. A. Bruggeman. 1998. Diagnostic value of monitoring human cytomegalovirus late pp67 mRNA expression in renal allograft recipients by nucleic acid sequence-based amplification. J. Clin. Microbiol. 36:1341-1346[Abstract/Free Full Text].
4.	Boivin, G., J. Handfield, E. Toma, G. Murray, R. Lalonde, and M. G. Bergeron. 1998. Comparative evaluation of the cytomegalovirus DNA load in polymorphonuclear leukocytes and plasma of human immunodeficiency virus-infected subjects. J. Infect. Dis. 177:355-360[Medline].
5.	Boom, R., C. J. Sol, M. M. M. Salimans, C. L. Jansen, P. M. Wertheim-van Dillen, and J. van der Noordaa. 1990. Rapid and simple method for purification of nucleic acids. J. Clin. Microbiol. 28:495-503[Abstract/Free Full Text].
6.	Bowen, E. F., C. A. Sabin, P. Wilson, et al. 1997. Cytomegalovirus (CMV) viraemia detected by polymerase chain reaction identifies a group of HIV-positive patients at high risk of CMV disease. AIDS 11:889-893[CrossRef][Medline].
7.	Bowen, E. F., P. Wilson, A. Cope, et al. 1996. Cytomegalovirus retinitis in AIDS patients: influence of cytomegaloviral load on response to ganciclovir, time to recurrence and survival. AIDS 10:1515-1520[Medline].
8.	Compton, J. 1991. Nucleic acid sequence-based amplification. Nature 350:91-92[CrossRef][Medline].
9.	Dodt, K. K., P. H. Jacobsen, B. Hofmann, et al. 1997. Development of cytomegalovirus (CMV) disease may be predicted in HIV-infected patients by CMV polymerase chain reaction and the antigenemia test. AIDS 11:F21-F28[CrossRef][Medline].
10.	Doorenbal, P., G. Seerp Baarsma, W. G. V. Quint, A. Kijlstra, P. H. Rothbarth, and H. G. M. Niesters. 1996. Diagnostic assays in cytomegalovirus retinitis: detection of herpesvirus by simultaneous application of the polymerase chain reaction and local antibody analysis on ocular fluid. Br. J. Ophthalmol. 80:235-240[Abstract/Free Full Text].
11.	Drew, W. L. 1992. Cytomegalovirus infection in patients with AIDS. Clin. Infect. Dis. 14:608-615[Medline].
12.	Francisci, D., A. Tosti, F. Baldelli, G. Stagni, and S. Pauluzzi. 1997. The pp65 antigenemia test as a predictor of cytomegalovirus-induced end-organ disease in patients with AIDS. AIDS 11:1341-1345[CrossRef][Medline].
13.	Gallant, J. E., R. D. Moore, D. D. Richman, J. Keruly, R. E. Chaisson, and The Zidovudine Epidemiology Study Group. 1992. Incidence and natural history of cytomegalovirus disease in patients with advanced human immunodeficiency virus disease treated with zidovudine. J. Infect. Dis. 166:1223-1227[Medline].
14.	Gozlan, J., J. M. Salord, C. Chouaïd, C. Duvivier, O. Picard, M. C. Meyohas, and J. C. Petit. 1993. Human cytomegalovirus (HCMV) late-mRNA detection in peripheral blood of AIDS patients: diagnostic value for HCMV disease compared with those of viral culture and HCMV DNA detection. J. Clin. Microbiol. 31:1943-1945[Abstract/Free Full Text].
15.	Gozlan, J., J. P. Laporte, S. Lesage, M. Labopin, A. Najman, N. C. Gorin, and J. C. Petit. 1996. Monitoring of cytomegalovirus infection and disease in bone marrow recipients by reverse transcription-PCR and comparison with PCR and blood and urine cultures. J. Clin. Microbiol. 34:2085-2088[Abstract].
16.	Griffiths, P. D., J. E. Feinberg, J. Fry, et al. 1998. The effect of valaciclovir on cytomegalovirus viremia and viruria detected by polymerase chain reaction in patients with advanced human immunodeficiency virus disease. J. Infect. Dis. 177:57-64[Medline].
17.	Hammer, S. M., K. E. Squires, M. D. Hughes, et al. 1997. A controlled trial of two nucleoside analogues plus indinavir in persons with human immunodeficiency virus infection and CD4 cell counts of 200 per cubic millimeter or less. N. Engl. J. Med. 337:725-733[Abstract/Free Full Text].
18.	Hansen, K. K., A. Ricksten, B. Hofmann, B. Norrild, S. Olofsson, and L. Mathiesen. 1994. Detection of cytomegalovirus DNA in serum correlates with clinical cytomegalovirus retinitis in AIDS. J. Infect. Dis. 170:1271-1274[Medline].
19.	Ljungman, P., and S. A. Plotkin. 1995. Workshop on CMV disease: definition, clinical severity scores and new syndromes. Scand. J. Infect. Dis. 99:87-89.
20.	MacGregor, R. R., S. J. Pakola, A. L. Graziani, et al. 1995. Evidence of active cytomegalovirus infection in clinically stable HIV-infected individuals with CD4⁺ lymphocyte counts below 100/µl of blood: features and relation to risk of subsequent CMV retinitis. J. Acquir. Immune. Defic. Syndr. Hum. Retrovirol. 10:324-330[Medline].
21.	Mazzulli, T., R. H. Rubin, M. J. Ferraro, R. T. D'Aquila, S. A. Doveikis, B. R. Smith, T. H. The, and M. S. Hirsch. 1993. Cytomegalovirus antigenemia: clinical correlations in transplant recipients and in persons with AIDS. J. Clin. Microbiol. 31:2824-2827[Abstract/Free Full Text].
22.	Pertel, P., R. Hirschtick, J. Phair, J. Chmiel, L. Poggensee, and R. Murphy. 1992. Risk of developing cytomegalovirus retinitis in persons infected with the human immunodeficiency virus. J. Acquir. Immune. Defic. Syndr. Hum. Retrovirol. 5:1069-1074.
23.	Podzamcer, D., E. Ferrer, A. Garcia, et al. 1997. PP65 antigenemia as a marker of future CMV disease and mortality in HIV-infected patients. Scand. J. Infect. Dis. 29:223-227[Medline].
24.	Rasmussen, L., S. Morris, D. Zipeto, et al. 1995. Quantitation of human cytomegalovirus DNA from peripheral blood cells of human immunodeficiency virus-infected patients could predict cytomegalovirus retinitis. J. Infect. Dis. 171:177-182[Medline].
25.	Roseff, S. D., M. Rockis, J. F. Keiser, et al. 1993. Optimization for detection of cytomegalovirus by the polymerase chain reaction (PCR) in clinical samples. J. Virol. Methods 42:137-146[CrossRef][Medline].
26.	Saillour, F., N. Bernard, L. Dequae-Merchadou, et al. 1998. Predictive factors of occurrence of cytomegalovirus disease and impact on survival in the Aquitaine cohort in France, 1985 to 1994. J. Acquir. Immune. Defic. Syndr. Hum. Retrovirol. 17:171-178[Medline].
27.	Shinkai, M., S. A. Bozette, W. Powderly, P. Frame, and S. A. Spector. 1997. Utility of urine and leukocyte cultures and plasma DNA polymerase chain reaction for identification of AIDS patients at risk for developing human cytomegalovirus disease. J. Infect. Dis. 175:302-308[Medline].
28.	Spector, S. A., G. F. McKinley, J. P. Lalezari, et al. 1996. Oral ganciclovir for the prevention of cytomegalovirus disease in persons with AIDS. N. Engl. J. Med. 334:1491-1497[Abstract/Free Full Text].
29.	Spector, S. A., R. Wong, K. Hsia, M. Pilcher, and M. J. Stempien. 1998. Plasma cytomegalovirus (CMV) DNA load predicts CMV disease and survival in AIDS patients. J. Clin. Invest. 101:497-502[Medline].
30.	The, T., M. van der Ploeg, A. P. van den Berg, A. M. Vlieger, M. van der Giessen, and W. J. van Son. 1992. Direct detection of cytomegalovirus in peripheral blood leukocytes $---$ a review of the antigenemia assay and polymerase chain reaction. Transplantation 54:193-198[Medline].
31.	Van der Bij, W., R. Torensma, W. J. van Son, et al. 1988. Rapid immunodiagnosis of active cytomegalovirus infection by monoclonal antibody staining of blood leukocytes. J. Med. Virol. 25:179-188[Medline].
32.	Van der Vliet, G. M. E., R. A. F. Schukkink, B. van Gemen, P. Schepers, and P. R. Klatser. 1993. Nucleic acid sequence-based amplification (NASBA) for the identification of mycobacteria. J. Gen. Microbiol. 139:2423-2429[Medline].
33.	Zegans, M. E., R. C. Walton, G. N. Holland, J. J. O'Donnell, M. A. Jacobson, and T. P. Margolis. 1998. Transient vitreous inflammatory reactions associated with combination antiretroviral therapy in patients with AIDS and cytomegalovirus retinitis. Am. J. Ophthalmol. 125:292-300[CrossRef][Medline].