Detection of measles,mumps, and rubella antibodies in saliva using antibody capture radioimmunoassay

Antibody capture radioimmunoassays were developed for detecting virus specific IgM (MAC-RIA) and IgG (GACRIA) to measles, mumps, and rubella and used to investigate saliva as an alternative specimen to serum for diagnosis. Saliva was collected from 63 patients with measles, 19 with mumps, and 150 with rubella, which were all clinically diagnosed and serologically confirmed. Virus specific IgM was detected in 92% of measles, 75% of mumps, and 100% of rubella saliva samples collected during the first week of illness. Between 1 and 5 weeks after onset virus specific IgM was detected in 100% of saliva specimens. After the 5th week the proportion of reactive specimens declined. The specificity of the MACRIA tests was established by testing saliva samples collected from blood donors for measles (88), mumps (88), and rubella IgM (91). All of the saliva specimens tested for measles and rubella specific IgM were unreactive, 1/88 specimens tested for mumps specific IgM contained significant reactivity. Saliva specimens collected from acute cases of MMR were tested in all 3 MACRIAs. A small proportion of saliva samples contained detectable IgM of more than one virus infection. Rubella and measles specific IgG was detected in the saliva of all cases from the 4th or 5th day of illness, respectively. Detection of mumps specific IgG was less successful. We have demonstrated that virus specific IgM can be reliably detected in saliva samples collected from acute cases of measles, mumps, and rubella and identified 1–5 weeks after onset of illness as the optimum time for collection of samples. © 1993 Wiley-Liss, Inc.     

Storage of bovine viral diarrhoea virus samples on filter paper and detection of viral RNA by a RT-PCR method

Of four solid carriers tested, Whatman paper No 1 was the best for storing blood and serum samples for the diagnosis of bovine viral diarrhoea (BVD) by means of viral RNA detection. The filter papers were impregnated with 10 microl of blood or serum, followed by air drying. Samples collected in this way from persistently infected animals had lost infectivity within a few days, but viral RNA could still be detected by RT-PCR for up to 6 months. When investigated by RT-PCR, 12 blood and 10 serum samples selected at random from animals persistently infected with BVD virus showed the same results whether samples had been spotted onto filters or examined directly from the liquid state. The filters spotted with blood or serum are convenient for storage and transport of samples to a diagnostic laboratory without the need for cooling. Sequencing of amplified RNA can be used subsequently for genetic typing.     

Detection of measles virus RNA in whole blood stored on filter paper

The purpose of this study was to evaluate the use of dried blood spots stored on filter paper as a means to provide specimens for virologic surveillance for measles virus (MV) in situations when the reverse cold chain is not available. Two single-step RT-PCR assays were evaluated for sensitivity of detection of MV nucleoprotein gene RNA. The more sensitive assay was then used to assess the stability of MV RNA in dried whole blood stored on filter paper. MV RNA was found to be stable in dried blood spots for up to 2 months at room temperature or 1 month at 37 degrees C. As few as 100 infected human peripheral blood mononuclear cells (PBMC) per blood spot could be detected using a single-step RT-PCR reaction and ethidium bromide detection. MV RNA was also detected in dried blood spots obtained from rhesus macaques after challenge with wild-type MV. In the rhesus samples, the single-step RT-PCR reaction could detect approximately 10(3) TCID(50) per blood spot, while nested PCR detected 3 TCID(50) per blood spot. The results of this laboratory-based study suggest that the use of dried blood spots stored on filter has the potential to improve virologic surveillance for MV in some areas, and they emphasize the need for continued testing under field conditions.     

广州市海珠区76例婴儿麻疹病例分析

目的对广州市海珠区76例婴儿麻疹病例进行分析,以了解其不断增多的原因,制定防制策略。方法将国家疾病监测信息报告管理系统中上报的该区婴儿麻疹病例采集静脉血测麻疹IgM抗体,并问卷调查,然后进行分析。结果76例病例中,有55例麻疹抗体阳性,21例抗体阴性。阳性病例中,小于8月龄26例（47．3％）,而≥8月龄（麻疹免初月龄）的29例病例中有麻疹疫苗（MV）接种史的占31．0％,其中本地病例接种率为63．6％,外地病例为11．1％,差异有统计学意义（χ^2=6．518,P〈0．05）。病例调查前后的诊断一致率为81．6％（χ^2=25．47,P〈0．05）;医院未抽血检验的达19例（25．0％）,其误诊率达31．6％。结论抽血送检率低、误诊率较高、外地儿童增多且其MV及时接种率低、存在免疫失败、母传抗体低使未到MV初免月龄的婴儿发病增多等是导致该区婴儿麻疹病例不断增多的原因。     

Acute infectious mononucleosis and coincidental measles virus infection.

BACKGROUND: Both Epstein-Barr and measles viruses (MV) cause immune suppression, and the association of the two viruses is evaluated as life threatening. The cell immune impairment caused by simultaneous Epstein-Barr and measles viral infections was responsible for the complicated course of the disease in all described previously reports and for unfavorable outcomes in most of the cases. Timely diagnosis of coincidental viral infections could be a useful predictor for the clinical course and complications. Diagnosis must be based on an accurate assessment of clinical, hematologic, serologic manifestations and supported by appropriate laboratory methods. Recognizing the infectious etiology of concomitant infections is important for both clinicians and epidemiologists. OBJECTIVE: To describe a case report of a 20-year-old woman previously vaccinated against measles infected with acute mononucleosis and coincidental measles virus infection. STUDY DESIGN: The clinical, routine laboratory, as well as serological and virologic findings of this patient were scrutinized. Special emphasis was placed on the use of RT-PCR/PCR for confirming the involvement of both measles virus and Epstein-Barr virus (EBV) in this patient's illness. RESULTS: Infectious mononucleosis was not suspected at admission to the hospital. The final diagnosis of a concomitant measles virus infection and acute infectious mononucleosis was facilitated using viral serology to detect virus-specific IgG and IgM antibodies and by RT-PCR for the detection of measles virus RNA and EBV DNA from peripheral blood monocyte cells (PBMC). CONCLUSION: The present report highlights the difficulty of diagnosing two coincidental virus infections on clinical grounds. Serological and molecular laboratory methods, specifically the PCR (RT-PCR) analysis, are found to be useful for confirming the concomitant viral infections and proper identification of the infecting pathogens.     

PCR detection of dengue virus using dried whole blood spotted on filter paper

Whole blood dried onto filter paper constitutes a potentially useful material for molecular testing of viruses, including dengue. In order to assess the stability of viral RNA, we carried out dengue-RNA detection in whole blood infected with dengue virus that had been previously spotted onto filter paper. Filter papers were stored at room temperature, 4 and -70 degrees C and processed for PCR assay at intervals of 2, 4, 6 and 9 weeks. Our results demonstrated that dengue-RNA was stable in filter paper for 9 weeks at all tested temperatures. Furthermore, we evaluated these conditions using frozen sera and dried blood samples onto filter paper from 52 patients with confirmed clinical diagnosis of dengue infection. PCR results showed a 100% specificity and 93% sensitivity for dried blood samples. This storage method facilitates the transportation and analysis by nucleic acid amplification techniques even when freezing conditions are not available.     

Comparative detection of measles and rubella IgM and IgG derived from filter paper blood and serum samples.

We compared the use of serum and filter paper blood spots as specimen sources for the detection of measles- and rubella-specific IgM and IgG. We collected capillary blood into microtainer tubes and onto filter paper spots from 60 children and 60 healthy adults. The blood was collected from 12-15-month-old children approximately 3 weeks after primary vaccination with measles, mumps, rubella vaccine, and the sample-pairs were tested for measles-specific IgM and IgG antibodies by using a capture antibody EIA and an indirect EIA, respectively. We tested sample-pairs from a subset of participants for rubella- specific IgM and IgG antibodies by using commercially available capture IgM (Captia) and indirect IgG (Wampole) assays. The concordance of results from serum and filter paper blood spots was high for all assays: 98% for measles IgM, 93% for measles IgG, 94% for rubella IgM, and 93% for rubella IgG, and increased to between 96-100% for all four assays when indeterminate samples were excluded. The correlation coefficients for EIA signals were 0.99 and 0.77 for measles IgM and IgG, respectively, and 0.92 and 0.94 for rubella IgM and IgG, respectively. The cut-off values used for filter paper samples were the same as those used for serum samples for all tests except for the rubella IgM assay. The use of filter paper blood spots is a promising future option for the detection of measles- and rubella-specific antibodies.     

Detection of Puumala and Rift Valley Fever virus by quantitative RT-PCR and virus viability tests in samples of blood dried and stored on filter paper

Haemorrhagic fever viruses cause emerging infections worldwide, and blood or serum is the main sample used for diagnosis. However, storage and transportation of such samples from remote areas to regional laboratories may be complicated and expensive. In this study, a novel approach was evaluated for the detection of Puumala hantavirus (PUUV) RNA and Rift Valley fever virus (RVFV) RNA. Whole-blood samples spiked with viable virus particles were tested in parallel with clinical samples from patients with acute haemorrhagic fever with renal syndrome (nephropathia epidemica). Individual blood samples were spotted on filter paper, dried, and used for RNA extraction at later time points. PUUV RNA was detected by RT-PCR after storage at room temperature for up to six weeks. In contrast, only low copy numbers of RVFV RNA were detected after 1-2 days even though viable RVFV was eluted from the dried filter papers after the same time. The use of filter paper to collect and store blood samples for PUUV RNA detection is therefore a simple and reliable procedure. This approach might facilitate sampling and analysis of other RNA viruses from human or animal sources and could be used for field studies in remote areas or in developing countries.     

Measles virus-specific cellular immunity in patients with vaccine failure.

The cytotoxic T-lymphocyte (CTL) response to measles virus (MV) was studied in blood samples from 13 acute- and early convalescent-phase patients with measles infection despite previous vaccination with the live-MV vaccine. MV CTL responses were also measured in six healthy peer controls who had live-MV vaccination during childhood and in five healthy adults who had a remote history of natural measles. All patients recovered from illness without complication. Acute MV infection was diagnosed on the basis of the Centers for Disease Control criteria and by measuring MV-specific immunoglobulin G (IgG) and IgM antibodies. Elevated IgG titers occurred in 80% of the patients at 1 to 2 weeks and in 100% at 4 weeks postinfection. IgM antibodies were detectable in all patient tested and were elevated in 60% of the patients at 1 to 2 weeks postinfection. The MV-specific CTL response was enhanced in 10 of the 13 patients tested, with a mean maximal lysis of 48.5% +/- 13.3%, compared with that of healthy peer controls who had had live-MV vaccinations during childhood (mean lysis, 14.6% +/- 12.9%; n = 6) and healthy adults with a remote history of natural measles (mean, 30.8% +/- 12.2%; n = 5). Three patients had low MV CTL levels at two time points following measles, with a mean lysis of 12% +/- 1.7%. It is concluded that while there is no evidence for a deficiency in the generation of cellular immunity to MV in the majority of patients with MV vaccine failure, a small number of individuals may fail to develop an enhanced T-cell response following infection.     

Decline of Measles-Specific Immunoglobulin M Antibodies after Primary Measles, Mumps, and Rubella Vaccination

Detection of measles-specific immunoglobulin M (IgM) has become the standard diagnostic method for laboratory confirmation of measles. In outbreaks, the interpretation of an IgM-positive result can be complicated when persons with suspected measles receive a dose of measles vaccine as part of outbreak control measures. This investigation evaluated the decay of measles-specific IgM antibodies 1 to 4 months after primary vaccination with measles, mumps, and rubella vaccine (MMRII). Serum samples were obtained from 536 infants vaccinated when they were 15 months old as part of a study to assess primary and secondary measles vaccine failure. Sixty serum specimens per week were selected from specimens collected between 4 and 9 weeks after MMRII vaccination; all 176 available serum specimens collected between 10 and ≥16 weeks were included. Specimens were tested for the presence of measles-specific IgM by an antibody-capture enzyme immunoassay. The proportion of IgM-positive specimens dropped from 73% at 4 weeks after vaccination to 52% at 5 weeks after vaccination and then declined to 7% by 8 weeks after vaccination. Less than 10% of children remained IgM positive between 9 and 11 weeks. An IgM-negative result helps rule out the diagnosis of measles in a person with suspected infection and a history of recent vaccination. The interpretation of a positive IgM result from a person with a clinically suspected case of measles and a recent history of measles vaccination (especially within 8 weeks) is problematic, and the diagnosis of measles should be based on epidemiologic linkage to a confirmed case or on detection of wild-type measles virus.     

The use of serum spotted onto filter paper for diagnosing and monitoring Chikungunya virus infection

BackgroundThe recent emergence of Chikungunya Virus (CHIKV) in the Americas constitutes a major public health problem on this continent, where the mosquito vector is widespread. The rapid diagnosis of suspected cases is essential for the monitoring and control of this ongoing outbreak. However, this requires reliable tools that are difficult to establish in areas without specialized laboratories.ObjectivesThe aim was to evaluate the performances of serum samples spotted onto filter paper for molecular and serological diagnosis of Chikungunya infection.Study designAnalyses were performed from frozen sera and serum spotted onto filter paper provided from 121 Chikungunya suspected cases collected at a biological laboratory on Saint-Martin Island.ResultsThis approach performed well in comparisons with standard methods, with a sensitivity of 100% and a specificity of 93.6% for the combined technical approaches (RT-PCR and serological results). Comparisons of serum samples spotted onto filter paper and frozen samples showed a concordance rate of 94.8% in molecular tests and 98.2% in serological tests.ConclusionsThis simple sampling technique could overcome the problems of the lack of efficient CHIKV diagnosis tools in remote regions, providing good results regardless of the molecular or serological approach used. This simple filter paper-based method can be used to diagnose both chikungunya and dengue infections, as previously demonstrated following transport at ambient temperature to specialized laboratories. Given the set-up costs and high performance of this method, it could be recommended for the monitoring and control of Chikungunya virus expansion in the Americas and in other affected regions.     

Laboratory investigations are indispensable to monitor the progress of measles elimination--results of the German Measles Sentinel 1999-2003.

BACKGROUND: The elimination of measles is a goal set by the World Health Organisation to be reached by 2010 in the European region. OBJECTIVES: To enhance the measles surveillance in Germany, a country-wide laboratory supported a sentinel was established. STUDY DESIGN: A network of >1200 representatively distributed practitioners reported detailed data on all clinically diagnosed cases and provided specimens for laboratory diagnosis. RESULTS: A total of 3225 suspected cases were reported between October 1999 and December 2003. The incidence in Western Germany decreased from >15 cases per 100,000 population to one case in 2003, while in Eastern Germany <1 case per 100,000 population was observed during these years. Laboratory investigations were undertaken in 40% of cases in 2000/2001. This rate increased to 79% in 2003. Simultaneously, the rate of confirmed cases dropped from 60% in the former years to 23% in 2003. Measles virus (MV) detection by serology and by PCR revealed concordant results in 92%. Most suspected cases (85%) were unvaccinated with 66% being laboratory confirmed. Only 10% of suspected cases occurred in vaccinated individuals and very few (22%) could be confirmed. Analyses of confirmed measles in vaccinated patients (n = 49) revealed 24.5% primary vaccine failures, 24.5% reinfections after successful vaccination and 31% MV infection before or shortly after vaccination. The genetic characterisation of 389 MV isolates identified eight genotypes: B3, C2, D4, D5, D6, D7, G2 and H1. Only the C2, D6 and D7 MV genotypes circulated endemically in Western Germany. The newly emerged MV D7 almost completely replaced the pre-existing C2 and D6 MVs in 2001. The few measles cases detected in Eastern Germany were mostly caused by imported MVs. CONCLUSION: The data demonstrate that laboratory investigations including molecular methods are an indispensable tool for surveillance in all countries advanced in measles elimination.     

Serological and molecular epidemiology of measles virus outbreaks reported in Ethiopia during 2000-2004

Twenty-eight outbreaks in six regions and two major cities in Ethiopia from 2000 to 2004 were investigated, with the collection of 207 venous blood and/or oral fluid samples. Measles diagnosis was confirmed by detection of measles-specific IgM and/or detection of measles virus by polymerase chain reaction (PCR). Of 176 suspected cases tested for specific measles IgM, 142 (81%) were IgM positive. Suspected cases in vaccinated children were much less likely to be laboratory confirmed than in unvaccinated children (42% vs. 83%, P < 0.0001). Of 197 samples analyzed by RT-PCR measles virus genome was detected in 84 (43%). A total of 58 wild-type measles viruses were characterized by nucleic acid sequence analysis of the nucleoprotein (N) and hemagglutinin (H) genes. Two recognized genotypes (D4 and B3) were identified. Each outbreak comprised only a single genotype and outbreaks of each genotype tended to occur in distinct geographical locations. B3 was first observed in 2002, and has now been the cause of three documented outbreaks near to the border of Sudan. D4 genotype was previously observed in an outbreak in 1999 and occurs in more diverse locations throughout the country. These data yield insights into geographical and age-related sources of continued transmission. Refinement of measles control measures might include targeting older age groups (5-14 years) and strengthening routine immunization particularly where importation of cases is a concern.     

Development of quantitative gene-specific real-time RT-PCR assays for the detection of measles virus in clinical specimens

Real-time RT-PCR assays targeting sequences in the measles virus (MV) nucleoprotein (N), fusion (F), and hemagglutinin (H) genes were developed for the detection of MV RNA in clinical specimens. Four primer and probe sets each for the N, F, and H genes were evaluated and reaction conditions optimized. Using dilution series of synthetic RNAs, the limits of detection were determined to be approximately 10 copies for each target RNA/reaction. The relationship between C(t) values and RNA concentration was linear within a range of 10-10(6) RNA copies/reaction, and intra- and inter-assay variability was low. The N gene-specific real-time assay detected MV RNA in 100% of clinical samples from confirmed measles cases compared to 41% by standard RT-PCR. The MV H and F gene-specific real-time assays detected MV RNA in 93% and 82% of these specimens, respectively. Real-time assays could detect RNA from strains representing each active genotype of MV and were also highly specific, as no false positives were identified when samples known to contain other respiratory viruses were tested. Real-time RT-PCR assays will be available to support routine measles laboratory surveillance, to facilitate research projects on pathogenesis that require sensitive and quantitative detection of MV RNA, and to aid in the investigation of serious disease sequelae resulting from natural measles infection or vaccination with measles-containing vaccines.     

Inter-test comparison between filter paper absorbed blood eluate and serum for malaria serology by enzyme immunoassay: an operational feasibility

Antimalarial IgG and IgM were detected by enzyme immunoassay in finger-stick blood samples collected in capillary tubes and also spotted onto Whatman filter paper. Assay was performed in 92 blood samples obtained from 53 falciparum malaria patients, representing 23 fever cases (malaria negative) and 16 healthy individuals. A simple indirect ELISA was done using Plasmodium falciparum lysate and MSP1(19) peptide as antigens. Total IgG and IgM contents were also estimated in individual sera and filter paper eluate by single radial immunodiffusion (SRID). Assay results of both serum and filter paper eluates were compared. The sensitivity and specificity of the assays for IgG measurement were comparable between serum and filter paper eluates (P < 0.001), whereas, in case of IgM, detection level was poor in filter paper eluates as observed by ELISA and SRID. The filter paper eluates may serve the purpose of antigen-specific IgG detection in seroepidemiological surveys.