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Inicio Enfermedades Infecciosas y Microbiología Clínica (English Edition) Comparative evaluation of assays for IgM detection of rubella and measles infect...
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Vol. 40. Issue 1.
Pages 22-27 (January 2022)
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Vol. 40. Issue 1.
Pages 22-27 (January 2022)
Original article
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Comparative evaluation of assays for IgM detection of rubella and measles infections
Evaluación comparativa de ensayos para la detección de IgM en infecciones por rubéola y sarampión
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Mayte Pérez Olmedaa, Pilar Balfagóna, Juan Camachoa, Desirée Dafouza, Jesús de la Fuentea, María Ángeles Murilloa, José Luis Muñoza, Aurora Fernández Garcíab,d, Juan Carlos Sanzc,d, Fernando de Orya,d,
Corresponding author
fernandodeorym@gmail.com

Corresponding author.
a Laboratorio de Serología, Centro Nacional de Microbiología, Instituto de Salud Carlos III, Majadahonda, Spain
b Laboratorio de Aislamiento Viral, Centro Nacional de Microbiología, Instituto de Salud Carlos III, Majadahonda, Spain
c Laboratorio Regional de Salud Pública de la Comunidad de Madrid, Madrid, Spain
d Centro de Investigación Biomédica en Red en Epidemiología y Salud Pública (CiberESP), Instituto de Salud Carlos III, Madrid, Spain
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Tables (5)
Table 1. List of assays analyzed.
Table 2. Comparison of rubella assays.
Table 3. Performance characteristics of rubella assays.a
Table 4. Comparison of measles assays.
Table 5. Performance characteristics of measles assaysa.
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Abstract
Background

Serological diagnosis of infections due to measles and rubella viruses is done by IgM detection. The aim of this study was to comparatively evaluate commercial systems for detecting IgM against both viruses, including those of ELISA, in indirect and capture formats, chemiluminescence and electrochemiluminescence.

Methods

Seven (for rubella) and six (for measles) assays were studied. One hundred and sixty two samples were included in the study (from 90 rubella and 72 measles cases), and all were analyzed in all the assays.

Results

The ranges of sensitivity, specificity and agreement for rubella were 94.8–100%, 52.4–100% and 75.5–98.1%, respectively. The corresponding ranges for measles assays were 87.0–100%, 53.3–100%, and 73.0–99.4%.

Conclusion

The best-performing assays were chemiluminescence (for measles and rubella IgM), and electrochemiluminescence (for rubella IgM).

Keywords:
Rubella virus
Measles virus
Enzyme immunoassay
Chemiluminescent immunoassay
Electrochemiluminescent immunoassay
Resumen
Introducción

El diagnóstico serológico de las infecciones por los virus de la rubéola y del sarampión se realiza por detección de IgM específica. El objetivo de este estudio fue evaluar comparativamente sistemas comerciales para la detección de IgM frente a ambos virus, incluyendo ensayos de ELISA, tanto con metodologías indirectas como de captura, así como quimioluminiscencia y electroquimioluminiscencia.

Métodos

Se estudiaron 7 ensayos para rubéola y 6 para sarampión. Se emplearon 162 muestras (de 90 casos de rubéola y de 72 de sarampión) que se analizaron en todos los ensayos.

Resultados

Los rangos de sensibilidad, especificidad y concordancia para los ensayos de rubéola fueron 94,8-100%, 52,4-100% y 75,5-98,1%, respectivamente. Los rangos correspondientes para los ensayos de sarampión fueron 87-100%, 53,3-100% y 73-99,4%, respectivamente.

Conclusión

Los mejores ensayos fueron quimioluminiscencia (para IgM frente a rubéola y a sarampión) y electroquimioluminiscencia (para IgM frente a rubéola).

Palabras clave:
Virus rubéola
Virus sarampión
Inmunoensayo enzimático
Inmunoensayo quimioluminiscente
Inmunoensayo electroquimioluminiscente
Full Text
Introduction

Rubella and measles infections are usually diagnosed in the laboratory by RT-PCR detection of the virus genomes during the first four days of the disease. However, samples taken at the appropriate time for making a direct diagnosis are not always available, so the detection of IgM-class antibodies is used as a fundamental tool for correct case characterization.1 Using a combination of the two approaches greatly improves the performance of measles2,3 and rubella2 diagnosis. In a situation of elimination, such as the current one, serological tests with good sensitivity and specificity characteristics are required. Siemens Healthcare Diagnostics (Marburg, Germany) (ELISA-Siemens) currently supplies the reference methods (ELISA assays, Enzygnost®) for determining IgM against rubella (RuV) and measles (MeV) viruses. The Enzygnost® kits have been used by a large number of network laboratories for many years.4,5 However, they will soon be withdrawn from the market, so the identification of alternative methods with acceptable performance characteristics is a challenge for clinical laboratories.

The aim of this study is to assess the operating characteristics of ELISA assays, based on indirect or μ chain capture methodologies, and chemiluminescence (CLIA) (capture), all for the purpose of determining the levels of IgM against RuV and MeV, and of electrochemiluminescence (ECLIA) (capture), for determining IgM versus RuV. Seven assays were compared for RuV IgM and six for MeV IgM.

Materials and methodsSerological methods

The following assays were studied (Table 1):

  • 1.

    Rubella assays

  • i.

    Enzygnost Rubella IgM, Siemens (Marburg, Germany) (RuV-ELISA-Siemens). The determinations were carried out in a Behring ELISA Processor III (BEPIII) (Siemens).

  • ii.

    Serion ELISA Classic Rubella IgM, Serion (Würzburg, Germany) (RuV-ELISA-Serion). The determinations were done in a BEPIII.

  • iii.

    Anti-Rubella IgM ELISA, EuroImmun (Lübeck, Germany) (RuV-ELISA-Euroimmun-1). The assay was done manually, and the plates were read in a BEPIII.

  • iv.

    Anti-Rubella IgM GP ELISA, EuroImmun (RuV-ELISA-Euroimmun-2). The tests were done manually, and the plates were read in a BEPIII.

  • v.

    Enzywell Rubella IgM, Diesse (Monteriggioni, Italy) (RuV-ELISA-Diesse). The tests were done manually, and the plates were read in a BEPIII.

  • vi.

    LIAISON® Rubella IgM, Diasorin (Saluggia, Italy) (RuV-CLIA). The determinations were done on a LIAISON® XL platform (Diasorin).

  • vii.

    ELECSYS® Rubella IgM, Roche Diagnostics (Penzberg, Germany) (RuV-ECLIA). The determinations were done in a Cobas e411 analyzer (Roche Diagnostics).

  • 2.

    Measles assays

  • i.

    Enzygnost Measles IgM, Siemens (MeV-ELISA-Siemens). The determinations were carried out in a BEPIII.

  • ii.

    Serion ELISA Classic Measles IgM, Serion (MeV-ELISA-Serion). The determinations were carried out in a BEPIII.

  • iii.

    Anti-Measles IgM ELISA, EuroImmun (MeV-ELISA-Euroimmun-1). The tests were done manually, and the plates were read in a BEPIII.

  • iv.

    Anti-Measles IgM NP ELISA, EuroImmun (MeV-ELISA-Euroimmun-2). Tests were done manually, and the plates were read in a BEPIII.

  • v.

    Enzywell Measles IgM, Diesse (MeV-ELISA-Diesse). Tests were done manually, and the plates were read in a BEPIII.

  • vi.

    LIAISON® Measles IgM (Diasorin) (MeV-CLIA). The determinations were done on a LIAISON® XL platform.

Table 1.

List of assays analyzed.

Assay  Manufacturer  Method  Platform/manually  Antigen  Format (no. samples)  Stability once opened  Samples tested (n
Rubella
Enzygnost Rubella IgMRuV-Siemens  Siemens  Indirect ELISA  BEPIII  Rubella-infected BHK21 cells  96  Expiry date  162 
ELISA Classic Rubella IgMRuV-Virion  Virion  Indirect ELISA  BEPIII  Rubella-infected cells (HPV-77)  96  Expiry date  162 
Anti-Rubella IgM ELISARuV-Euroimmun-1  Euroimmun  Indirect ELISA  Manually  Rubella-infected Vero cells (strain HPV-77)  96  Expiry date  162 
Anti-Rubella IgM GP ELISARuV-Euroimmun-2  Euroimmun 2  Indirect ELISA  Manually  Highly purified native GP (strain HPV-77, grown in Vero cells)  96  Expiry date  162 
Enzywell Rubella IgMRuV-Diesse  Diesse  Capture ELISA  Manually  Purified rubella virus  96  Expiry date  162 
LIAISON® Rubella IgMRuV-CLIA  Diasorin  Capture CLIA  LIAISON® XL  Rubella viral particle (strain HPV 77)  100  8 weeks  158 
Elecsys® Rubella IgMRuV-ECLIA  Roche  Capture ECLIA  Cobas e411  Rubella-like particles  100  14 days  160 
Measles
Enzygnost Measles IgMMeV-Siemens  Siemens  Indirect ELISA  BEPIII  Measles-infected Vero cells  96  Expiry date  162 
ELISA Classic Measles IgMMeV-Virion  Virion  Indirect ELISA  BEPIII  Measles-infected cells, strain Edmonston  96  Expiry date  162 
Anti-Measles IgM ELISAMeV-Euroimmun-1  Euroimmun  Indirect ELISA  Manually  Measles-infected cells, strain HNT-PI Vero cells  96  Expiry date  162 
Anti-Measles IgM NP ELISAMeV-Euroimmun-1  Euroimmun 2  Indirect ELISA  Manually  Recombinant NP expressed in eukaryotic cells  96  Expiry date  162 
Enzywell Measles IgMMeV-Diesse  Diesse  Capture ELISA  Manually  Purified measles virus  96  Expiry date  162 
LIAISON® Measles IgMMeV-CLIA  Diasorin  Capture CLIA  LIAISON® XL  Recombinant NP expressed in Baculovirus  50  8 weeks  158 

All the assays were carried out in strict accordance with the respective instructions for use. This includes the pretreatment with anti-human IgG to remove any interference from rheumatoid factors for the indirect methods.

Samples

A total of 162 samples from patients with exanthematic disease were included in the study; patients were diagnosed as having rubella or measles.

They were grouped into two panels.

  • -

    Panel 1. 90 samples from rubella cases from an outbreak that occurred in 1996.

  • -

    Panel 2. 72 samples from measles cases from an outbreak that occurred in 1991.

The samples were stored at −20°C until their use for this study.

All the samples were tested for both MeV- and RuV-IgM.

The samples were finally classified as positive or negative on the basis of the majority of results: in both cases, samples with four or more positive results were considered positive; samples with four or more negative results were considered negative. All other samples were considered indeterminate, and were excluded from subsequent analysis.

Ethical approval

This study was approved by the Ethical Committee of the Institute of Health Carlos III (approval number: CEI PI 81_2019-v2_Enmienda 2019).

ResultsRubella assays

Of the rubella samples, 74 were classified as positive (≥4 positive results), 15 as negative (≥4 negative results), and one as indeterminate (Table 2). Of the positive samples, 67 were positive in all the assays, and six of the negative samples were negative in all the assays.

Table 2.

Comparison of rubella assays.

  RuV-SiemensRuV-VirionRuV-Euroimmun-1
  Positive  Indeterminate  Negative  Positive  Indeterminate  Negative  Positive  Indeterminate  Negative 
Panel 1. Rubella samples (n=90)
Positive  72  74  71 
Indeterminate 
Negative  12  10  13 
Panel 2. Measles samples (n=72)
Positive 
Indeterminate 
Negative  60  14  21  33  65 
Total of samples (n=162)
Positive  74  77  73 
Indeterminate 
Negative  72  16  23  43  78 
  RuV-Euroimmun-2RuV-DiesseRuV-CLIAaRuV-ECLIAb
  Positive  Indeterminate  Negative  Positive  Indeterminate  Negative  Positive  Indeterminate  Negative  Positive  Indeterminate  Negative 
Panel 1. Rubella samples (n=90)
Positive  71  73  69  70 
Indeterminate 
Negative  12  10  14  14 
Panel 2. Measles samples (n=72)
Positive 
Indeterminate 
Negative  68  65  68  67 
Total of samples (n=162)
Positive  74  76  70  73 
Indeterminate 
Negative  80  75  82  81 
a

Results from 158 samples (86 rubella and 72 measles cases).

b

Results from 160 samples (88 rubella and 72 measles cases).

When analyzing the measles samples, three were identified as positive for RuV-IgM (confirmed as double infections) and one as indeterminate for rubella IgM, in a MeV IgM-positive case. Thirty-two samples were negative in all assays; the majority of discrepant results were obtained in RuV-Virion (14 positive and 21 indeterminate). The results from the RuV-IgM assays compared with the reference criterion are shown in Tables 2 and 3.

Table 3.

Performance characteristics of rubella assays.a

RuV-SiemensRuV-VirionRuV-Euroimmun-1
Sensitivity  Specificity  Agreement  Sensitivity  Specificity  Agreement  Sensitivity  Specificity  Agreement 
96.1 (88.3–99.0)  87.8 (78.3–93.7)  91.8 (86.1–95.4)  100 (94.1–99.0)  52.4 (41.2–63.5)  75.5 (67.9–81.8)  94.8 (86.5–98.3)  95.1 (87.3–98.4)  95 (90–97.) 
RuV-Euroimmun-2RuV-DiesseRuV-CLIAbRuV-ECLIAc
Sensitivity  Specificity  Agreement  Sensitivity  Specificity  Agreement  Sensitivity  Specificity  Agreement  Sensitivity  Specificity  Agreement 
96.1 (88.3–99)  97.6 (90.6–99.6)  96.9 (92.4–98.8)  98.7 (92–99.9)  91.5 (82.7–96.2)  95 (90–97.6)  95.9 (87.7–98.9)  100 (94.4–99.9)  98.1 (94–99.5)  97.3 (89.8–99.5)  98.8 (92.5–99.9)  98.1 (94.1–99.5) 
a

The values showed for sensitivity, specificity and agreement are percent and 95% confidence interval (95% CI).

b

Results from 158 samples (86 rubella and 72 measles cases).

c

Results from 160 samples (88 rubella and 72 measles cases).

The best performances were obtained by RuV-CLIA (agreement: 98.1% [95% confidence interval (95% CI): 94.0–99.5%]; sensitivity: 95.9% [95% CI: 87.7–98.9%]; and specificity: 100% [95% CI: 94.4–99.9%]) and RuV-ECLIA (respectively, 98.1% [95% CI: 94.1–99.5%]; 97.3% [95% CI: 89.8–99.5%] and 98.8% [95% CI: 92.5–99.9%]). With the ELISA methods, the figures for agreement, sensitivity and specificity ranged from 96.9% [95% CI: 92.4–98.8%] (RuV-Euroimmun-2) to 75.5% [95% CI: 67.9–81.8%] (RuV-Virion); 100% [95% CI: 94.1–99.0%] (RuV-Virion) to 94.8% [95% CI: 86.5–98.3%] (RuV-Euroimmun-1); and 97.6% [95% CI: 90.6–99.6%] (RuV-Euroimmun-2) to 52.4% [95% CI: 41.2–63.5%] (RuV-Virion), respectively (Table 3).

Measles assays

69 samples from measles cases were classified as positive (≥4 positive results), and three as indeterminate. Amongst the positive cases, 57 samples gave positive result in all the assays.

Discrepant results were obtained mainly in MeV-Euroimmun-1 (5 samples with an indeterminate result) and MeV-Euroimmun-2 (7 indeterminate and 2 negative samples) (Table 4).

Table 4.

Comparison of measles assays.

  MeV-SiemensMeV-VirionMeV-Euroimmun-1
  Positive  Indeterminate  Negative  Positive  Indeterminate  Negative  Positive  Indeterminate  Negative 
Panel 2. Measles samples (n=72)
Positive  66  69  64 
Indeterminate 
Negative 
Panel 1. Rubella samples (n=90)
Positive 
Indeterminate 
Negative  90  78  89 
Total of samples (n=162)
Positive  66  69  64 
Indeterminate 
Negative  90  78  89 
  MeV-Euroimmun-2MeV-DiesseMeV-CLIAa
  Positive  Indeterminate  Negative  Positive  Indeterminate  Negative  Positive  Indeterminate  Negative 
Panel 2. Measles samples (n=72)
Positive  60  68  67 
Indeterminate 
Negative 
Panel 1. Rubella samples (n=90)
Positive 
Indeterminate 
Negative  90  33  48  87 
Total of samples (n=162)
Positive  60  68  67 
Indeterminate 
Negative  90  33  48  87 
a

Results from 158 samples (71 measles and 87 rubella).

All samples from the rubella cases were identified as negative according to the final classification. No positive results were obtained in MeV-Siemens, MeV-EuroImmun-2 or MeV-CLIA.

The results obtained in the compared assays are shown in Table 5. The best performances were obtained by MeV-CLIA (agreement: 99.4% [95%CI: 95.9–100%]; sensitivity: 98.5% [95% CI: 91.0–99.9%], and specificity: 100% [95% CI: 94.7–99.9%]). With the ELISA methods, the figures for agreement, sensitivity and specificity ranged from 98.1% [95% CI: 94.2–99.5%] (MeV-Siemens) to 73% [95% CI: 65.2–79.5%] (MeV-Diesse); 100% [95% CI: 93.4–99.9%] (MeV-Virion) to 87% [95% CI: 76.2–93.5%] (MeV-EuroImmun-2); and 100% [95% CI: 94.9–99.9%] (MeV-Siemens and MeV-EuroImmun-2) to 53.3% (MeV-Diesse) [95% CI: 42.6–63.8%], respectively.

Table 5.

Performance characteristics of measles assaysa.

MeV-SiemensMeV-VirionMeV-Euroimmun-1
Sensitivity  Specificity  Agreement  Sensitivity  Specificity  Agreement  Sensitivity  Specificity  Agreement 
95.7 (87–98.9)  100 (94.9–99.9)  98.1 (94.2–99.5)  100 (93.4–99.9)  86.7 (77.5–92.6)  92.5 (86.9–95.9)  92.8 (83.2–97.3)  98.9 (93.1–99.9)  96.2 (91.6–98.5) 
MeV-Euroimmun-2MeV-DiesseMeV-CLIAb
Sensitivity  Specificity  Agreement  Sensitivity  Specificity  Agreement  Sensitivity  Specificity  Agreement 
87 (76.2–93.5)  100 (94.9–99.9)  94.3 (89.2–97.2)  98.6 (91.1–99.9)  53.3 (42.6–63.8)  73 (65.2–79.5)  98.5 (91–99.9)  100 (94.7–99.9)  99.4 (95.9–100) 
a

The values showed for sensitivity, specificity and agreement are percent and 95% confidence interval (95% CI).

b

Results from 158 samples (71 measles and 87 rubella).

Discussion

In 2018, measles and rubella were eliminated in 35 (66%) and 39 (73%) of the Member States of the WHO European Region.6 This was made possible by adequate vaccine coverage and surveillance systems, and the availability of sensitive and specific diagnostic methods, using both direct detection by PCR and serological determination of specific IgMs. In recent years, the most commonly used methods for determining specific IgMs against RuV and MeV have been those of Enzygnost® Siemens. These methods have been used as reference.5 However, the company has ceased the production of these reagents, so the need to identify suitable alternative, sensitive and specific methods has become an important matter. Here, we compared seven methods for determining IgM against RuV and six methods for determining MeV-IgM, including Enzygnost® assays. Despite the consideration of the Siemens assays as reference5 we have used a consensus criterion for classification of the samples, due to the assay from Siemens may show negative results in very early samples at least for measles, as previously reported.7 Thus, we think that by using a consensus criterion, the case classification is strongly improved.

Given the lack of a gold standard, the criterion of the majority of results obtained in the compared assays was taken as the reference for classifying our results. For rubella, the best agreement, sensitivity and specificity figures were obtained by the RuV-CLIA and RuV-ECLIA methods, both of which are based on μ chain capture methods. Three of the ELISAs (RuV-Euroimmun-1, RuV-Euroimmun-2 and RuV-Diesse) yielded better values than those obtained by RuV-Siemens, the best of these being RuV-Euroimmun-2, which uses GP as the antigen, thereby making it a suitable alternative for detecting RuV IgM.

Several comparative studies have been published in recent years, some of which have involved the methods examined here. The RuV-ECLIA assay (Elecsys, Roche) shows good agreement (98.0%) with another CLIA (Architect, Abbott).8 RuV-EuroImmun-1 shows good comparability with RuV-Siemens in the diagnosis of suspected cases of congenital rubella syndrome, with an agreement of 94.7%.9 The RuV-ECLIA showed a sensitivity of 79.8–96.0% in a multicenter study, which is a lower range than that noted in the present study, with high specificity (98.7–99.0%).10

The best specificity values obtained in this study were those of RuV-CLIA and RuV-ECLIA. Moreover, RuV-EuroImmun-2 has been shown to be the most specific of the ELISA-based methods when compared with an ELISA method using whole-virus antigen.11 The majority of the discrepancies occurred in the RuV-Virion assay when measles samples were tested (35/72, 48%), resulting in a very low specificity for this method.

In relation to measles assays, the best values of sensitivity, specificity, and agreement were obtained with MeV-CLIA (98.5%, 100% and 99.4%, respectively). The only assay that produced low values for agreement and specificity (73.0% and 53.3%) was MeV-Diesse; the remaining assays yielded acceptable (MeV-Virion and MeV-Euroimmun-2) or excellent (MeV-Siemens and MeV-Euroimmun-2) overall values. The assays with more discrepant results were MeV-Diesse (33 indeterminate and 9 positive samples) and MeV-Virion (8 indeterminate and 4 positive samples) (Table 4), resulting in a very low value of specificity in both assays.

Recently published information is available from measles IgM assays. In general, capture ELISA methods are more sensitive than indirect ones.12

The MeV-CLIA method has been compared with the MeV-Siemens method in some reports, in which it showed sensitivity and specificity of 94.0% and 100%,13 and 93.8% and 98.8%,14 respectively. Compared with capture ELISA (Microimmune), MeV-CLIA showed 92.0% sensitivity and 100% specificity, with a small proportion of indeterminate results.15 In an additional report, MeV-CLIA showed improved corresponding values of a different CLIA (Vircell), although the difference was not statistically significant.16

Most assays for MeV IgM, except MeV-Diesse and, to a lesser extent, MeV-Virion, gave excellent specificity values. Therefore, it does not appear that the specificity of the assays is related to the antigen used (NP in the cases of MeV-Euroimmun-2 and MeV-CLIA, and extract from infected cells in the cases of MeV-Siemens and MeV-Euroimmun-1). In the current situation of elimination of measles and rubella, when the number of cases is declining, the positive predictive value of IgM determination decreases, so confirmatory methods are necessary. Detection of seroconversion or a significant increase in antibody titer in two paired samples indicates an acute infection.1 On the other hand, IgG avidity assays allow primary and secondary infections to be differentiated, this being applicable to measles cases in which the characterization of vaccine failure is possible,17 and to rubella,9 mainly to rule out primary infection in pregnancy, of devastating teratogenic effect. Commercial methods for characterizing IgG avidity against both viruses are available, including ELISA and CLIA.8,11,17,18 However, in the current circumstances, comparative elimination studies are necessary to ensure the quality of the serological methods used in clinical laboratories.5,19

Although the simultaneous reactivity against measles and rubella seems not be frequent,20 it can occur in subjects recently immunized by using measles-mumps-rubella (MMR) vaccine. In the present study no data about antecedents of recent vaccination was recorded. This situation could explain the finding of positive IgM to both viruses. According to our experience, in the context of measles and rubella outbreaks, MMR vaccination is implemented, as a Public Health measure. That is the reason why, in such situations, a number of vaccine related cases could be expected. To further explore this point, we have tested for mumps IgM the three samples classified as double infections, trying to confirm a recent MMR vaccination. One of them showed a positive result in the mumps IgM assay, confirming a recent vaccination, the remaining two being negative (results not shown).

The study has some weaknesses. First, samples were taken in 1991 and 1996, in an epidemic context. Although the medical doctors who sent the samples clinically characterized the patients, no additional information was available about the time of bleeding after the appearance of the exanthema. This information is important for the correct interpretation of discrepant results, which are mainly false negatives. Second, we tried to establish the performance characteristics of assays for RuV- and MeV-IgM, using samples from both diseases. However, samples of other infections that may cause differential diagnostic problems, mainly human parvovirus B19 (HPVB19), as well as cytomegalovirus and Epstein Barr virus, should also been included. This aspect is of great interest in the context of the elimination of measles and rubella, as is consistently evident for both RuV and MeV.1,21 The same occurs in travelers with cases acquired in countries with endemic circulation of arboviruses (Zika virus [ZikV], dengue and chikungunya). A certain degree of false-positive heterologous reactivity has recently been described, whereby the LIAISON assay for ZikV in cases of measles and HPVB19 gave positive results that were not confirmed in immunofluorescence assays.22 Finally, positive heterologous results due to polyclonal stimulation of B lymphocytes in both rubella and measles cases could not be excluded, which could compromise the specificity of measles and rubella assays. For these reasons, further studies are required to determine the importance of this phenomenon.

In conclusion, the information reported here will help clinical laboratories to improve the serological diagnosis of measles and rubella infections.

Conflict of interest

The authors declare that they have no conflict of interest.

Acknowledgements

This work was supported by the Fondo de Investigación Sanitaria (grant number FIS PI15CIII/00023).

References
[1]
J.M. Hübschen, S.M. Bork, K.E. Brown, A. Mankertz, S. Santibanez, M. Ben Mamou, et al.
Challenges of measles and rubella laboratory diagnostic in the era of elimination.
Clin Microbiol Infect, 23 (2017), pp. 511-515
[2]
J.C. Sanz, M. Mosquera, B. Ramos, R. Ramírez, F. de Ory, J.E. Echevarria.
Assessment of RNA amplification by multiplex RT-PCR and IgM detection by indirect and capture ELISAs for the diagnosis of measles and rubella.
[3]
Y. Cosgun, D. Guldemir, A. Coskun, S. Yolbakan, A.T. Kalaycioglu, G. Korukluoglu, et al.
The importance of serological and molecular analyses for the diagnosis of measles cases and for meeting elimination targets in Turkey from 2007 to 2015.
Epidemiol Infect, 146 (2018), pp. 735-740
[4]
World Health Organization. Manual for the laboratory-based surveillance of measles, rubella, and congenital rubella syndrome. Available from: https://www.who.int/immunization/monitoring_surveillance/burden/laboratory/manual_section4.1/en/.
[5]
V. Stambos, J. Leydon, M. Riddell, H. Clothier, M. Catton, D. Featherstone, et al.
Evaluation of the World Health Organization global measles and rubella quality assurance program, 2001–2008.
J Infect Dis, 204Suppl1 (2011), pp. S499-S505
[7]
J.C. Sanz, M. Mosquera, B. Ramos, R. Ramírez, F. de Ory, J.E. Echevarría.
Assessment of RNA amplification by multiplex RT-PCR and IgM detection by indirect and capture ELISAs for the diagnosis of measles and rubella.
[8]
F. Genco, A. Sarasini, M. Parea, M. Prestia, L. Scudeller, V. Meroni.
Comparison of the LIAISON®XL and ARCHITECT IgG IgM, and IgG avidity assays for the diagnosis of Toxoplasma, cytomegalovirus, and rubella virus infections.
New Microbiol, 42 (2019), pp. 88-93
[9]
R. Viswanathan, S. George, M.V. Murhekar, A.M. Abraham, M.P. Singh, S.M. Jadhav, et al.
Comparison of two commercial ELISA kits for detection of rubella specific IgM in suspected congenital rubella syndrome cases and rubella IgG antibodies in a serosurvey of pregnant women.
Diagn Microbiol Infect Dis, 94 (2019), pp. 243-247
[10]
J. van Helden, L. Grangeot-Keros, C. Vauloup-Fellous, R. Vleminckx, F. Masset, M.G. Revello.
Evaluation of fully automated assays for the detection of Rubella IgM and IgG antibodies by the ELECSYS® immunoassay system.
J Virol Methods, 199 (2014), pp. 108-115
[11]
K.P. Wandinger, S. Saschenbrecker, K. Steinhagen, T. Scheper, W. Meyer, U. Bartelt, et al.
Diagnosis of recent primary rubella virus infections: significance of glycoprotein-based IgM serology IgG avidity and immunoblot analysis.
J Virol Methods, 174 (2011), pp. 85-93
[12]
T.A. Mamaeva, M.A. Naumova, N.V. Zheleznova, G.I. Lipskaia, M. Mulders, D.A. Featherstone.
Evaluation of the commercial ELISA test-systems of different formats to detect specific IgM and IgG in measles patient sera.
Vopr Virusol, 58 (2013), pp. 43-48
[13]
F. de Ory, T. Minguito, P. Balfagón, J.C. Sanz.
Comparison of chemiluminescent immunoassay and ELISA for measles IgG and IgM.
APMIS, 123 (2015), pp. 648-651
[14]
A. Sampedro, J. Rodríguez-Granger, C. Gómez, A. Lara, J. Gutierrez, A. Otero.
Comparative evaluation of a new chemiluminescent assay and an ELISA for the detection of IgM against measles.
J Clin Lab Anal, 27 (2013), pp. 477-480
[15]
B. Haywood, M. Patel, S. Hurday, R. Copping, D. Webster, D. Irish, et al.
Comparison of automated chemiluminescence immunoassays with capture enzyme immunoassays for the detection of measles and mumps IgM antibodies in serum.
J Virol Methods, 196 (2014), pp. 15-17
[16]
C. Gómez-Camarasa, A. Lara-Oya, F. Cobo, A. Sampedro-Martínez, J. Rodríguez-Granger, J. Gutierrez-Fernández, et al.
Comparison of two chemiluminescent immunoassays in the detection of measles IgM antibodies.
J Virol Methods, 237 (2016), pp. 38-39
[17]
S. Mercader, P. Garcia, W.J. Bellini.
Measles virus IgG avidity assay for use in classification of measles vaccine failure in measles elimination settings.
Clin Vaccine Immunol, 19 (2012), pp. 1810-1817
[18]
J. Dina, C. Creveuil, S. Gouarin, F. Viron, A. Hebert, F. Freymuth, et al.
Performance evaluation of the VIDAS® measles IgG assay and its diagnostic value for measuring IgG antibody avidity in measles virus infection.
Viruses, 8 (2016), pp. 234
[19]
F. de Ory, J.C. Sanz, J.E. Echevarría, M.M. Mosquera, M.E. Guisasola, Red de Laboratorios Autonómicos para el Plan de Eliminación del Sarampión.
Comparison of serological procedures used for the diagnosis of viral exanthema in laboratories participating in the measles elimination plan.
Enferm Infecc Microbiol Clin, 22 (2004), pp. 319-322
[20]
H.I. Thomas, E. Barrett, L.M. Hesketh, A. Wynne, P. Morgan-Capner.
Simultaneous IgM reactivity by EIA against more than one virus in measles, parvovirus B19 and rubella infection.
J Clin Virol, 14 (1999), pp. 107-118
[21]
M. de Los Ángeles Ribas, Y. Tejero, Y. Cordero, D. Pérez, A. Sausy, C.P. Muller, et al.
Identification of human parvovirus B19 among measles and rubella suspected patients from Cuba.
J Med Virol, 91 (2019), pp. 1351-1354
[22]
M. Pérez-Olmeda, M.P. Sánchez-Seco, A. Vázquez, P. Balfagón, J. de la Fuente, M.A. Murillo, et al.
Evaluation of the LIAISON® XL Zika capture IgM II for the diagnosis of Zika virus infections.
Viruses, 12 (2020), pp. 69
Copyright © 2020. Sociedad Española de Enfermedades Infecciosas y Microbiología Clínica
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