Your search keyword '"Bruin, E. (Erwin) de"' showing total 9 results

1. Exploring novel sero-epidemiological tools—Effect of different storage conditions on longitudinal stability of microarray slides comprising influenza A-, measles- and Streptococcus pneumoniae antigens

Author

Freidl, G.S. (Gudrun), Bruin, E. (Erwin) de, Schipper, M. (Maarten), Koopmans D.V.M., M.P.G. (Marion), Freidl, G.S. (Gudrun), Bruin, E. (Erwin) de, Schipper, M. (Maarten), and Koopmans D.V.M., M.P.G. (Marion)

Abstract

In this study we evaluated the long-term stability of a microarray-based serological screening platform, containing antigens of influenza A, measles and Streptococcus pneumoniae, as part of a preparedness research program aiming to develop assays for syndromic disease detection. Spotted microarray slides were kept at four different storage regimes with varying temperature and humidity conditions. We showed that under the standard storage condition in a temperature-controlled (21 °C) and desiccated environment (0% relative humidity), microarray slides remained stable for at least 22 months without loss of antigen quality, whereas the other three conditions (37 °C, desiccated; Room temperature, non-desiccated; Frozen, desiccated) produced acceptable results for some antigens (influenza A, S.pneumoniae), but not for others (measles). We conclude that these arrays for multiplex antibody testing can be prepared and stored for prolonged periods of time, which aids laboratory-preparedness and facilitates sero-epidemiological studies.

Published

2017

2. Changes in heterosubtypic antibody responses during the first year of the 2009 A(H1N1) influenza pandemic.

Author

Freidl, G.S. (Gudrun), Ham, H.J. van den, Boni, M.F. (Maciej), Bruin, E. (Erwin) de, Koopmans D.V.M., M.P.G. (Marion), Freidl, G.S. (Gudrun), Ham, H.J. van den, Boni, M.F. (Maciej), Bruin, E. (Erwin) de, and Koopmans D.V.M., M.P.G. (Marion)

Abstract

Seropositivity to avian influenza (AI) via low-level antibody titers has been reported in the general population and poultry-exposed individuals, raising the question whether these findings reflect true infection with AI or cross-reactivity. Here we investigated serological profiles against human and avian influenza viruses in the general population using a protein microarray platform. We hypothesized that higher antibody diversity across recent H1 and H3 influenza viruses would be associated with heterosubtypic reactivity to older pandemic- and AI viruses. We found significant heterogeneity in antibody profiles. Increased antibody diversity to seasonal influenza viruses was associated with

Published

2016

3. MERS-CoV infection of alpaca in a region whereMERS-CoV is endemic

Author

Reusken, C.B.E.M. (Chantal), Schilp, C. (Chrispijn), Raj, V.S. (Stalin), Bruin, E. (Erwin) de, Kohl, R.H.G., Farag, E. (Elmoubasher), Haagmans, B.L. (Bart), Al Romaihi, H.E. (Hamad), Le Grange, F. (Francois), Bosch, B.J. (Berend Jan), Koopmans D.V.M., M.P.G. (Marion), Reusken, C.B.E.M. (Chantal), Schilp, C. (Chrispijn), Raj, V.S. (Stalin), Bruin, E. (Erwin) de, Kohl, R.H.G., Farag, E. (Elmoubasher), Haagmans, B.L. (Bart), Al Romaihi, H.E. (Hamad), Le Grange, F. (Francois), Bosch, B.J. (Berend Jan), and Koopmans D.V.M., M.P.G. (Marion)

Published

2016

4. Influenza at the animal-human interface: A review of the literature for virological evidence of human infection with swine or avian influenza viruses other than A(H5N1)

Author

Freidl, G.S. (Gudrun), Meijer, A. (Adam), Bruin, E. (Erwin) de, de Nardi, M. (Marco), Munoz, O. (Olga), Capua, I. (Ilaria), Breed, A.C., Harris, K. (Kate), Hill, A. (Andrew), Kosmider, R. (Rowena), Banks, J. (Jill), von Dobschuetz, S. (Sophie), Stärk, K.D.C. (Katharina D. C.), Wieland, B., Stevens, K., Werf, S. (Sylvie) van der, Enouf, V. (Vincent), van der Meulen, K. (Karen), Reeth, K. van, Dauphin, G. (Gwenaelle), Koopmans D.V.M., M.P.G. (Marion), Freidl, G.S. (Gudrun), Meijer, A. (Adam), Bruin, E. (Erwin) de, de Nardi, M. (Marco), Munoz, O. (Olga), Capua, I. (Ilaria), Breed, A.C., Harris, K. (Kate), Hill, A. (Andrew), Kosmider, R. (Rowena), Banks, J. (Jill), von Dobschuetz, S. (Sophie), Stärk, K.D.C. (Katharina D. C.), Wieland, B., Stevens, K., Werf, S. (Sylvie) van der, Enouf, V. (Vincent), van der Meulen, K. (Karen), Reeth, K. van, Dauphin, G. (Gwenaelle), and Koopmans D.V.M., M.P.G. (Marion)

Abstract

Factors that trigger human infection with animal influenza virus progressing into a pandemic are poorly understood. Within a project developing an evidence-based risk assessment framework for influenza viruses in animals, we conducted a review of the literature for evidence of human infection with animal influenza viruses by diagnostic methods used. The review covering Medline, Embase, SciSearch and CabAbstracts yielded 6,955 articles, of which we retained 89; for influenza A(H5N1) and A(H7N9), the official case counts of the World Health Organization were used. An additional 30 studies were included by scanning the reference lists. Here, we present the findings for confirmed infections with virological evidence. We found reports of 1,419 naturally infected human cases, of which 648 were associated with avian influenza virus (AIV) A(H5N1), 375 with other AIV subtypes, and 396 with swine influenza virus (SIV). Human cases naturally infected with AIV spanned haemagglutinin subtypes H5, H6, H7, H9 and H10. SIV cases were associated with endemic SIV of H1 and H3 subtype de

Published

2014

5. Influenza at the animal-human interface: A review of the literature for virological evidence of human infection with swine or avian influenza viruses other than A(H5N1)

Author

Freidl, G.S. (Gudrun), Meijer, A. (Adam), Bruin, E. (Erwin) de, de Nardi, M. (Marco), Munoz, O. (Olga), Capua, I. (Ilaria), Breed, A.C., Harris, K. (Kate), Hill, A. (Andrew), Kosmider, R. (Rowena), Banks, J. (Jill), von Dobschuetz, S. (Sophie), Stärk, K.D.C. (Katharina D. C.), Wieland, B., Stevens, K., Werf, S. (Sylvie) van der, Enouf, V. (Vincent), van der Meulen, K. (Karen), Reeth, K. van, Dauphin, G. (Gwenaelle), Koopmans D.V.M., M.P.G. (Marion), Freidl, G.S. (Gudrun), Meijer, A. (Adam), Bruin, E. (Erwin) de, de Nardi, M. (Marco), Munoz, O. (Olga), Capua, I. (Ilaria), Breed, A.C., Harris, K. (Kate), Hill, A. (Andrew), Kosmider, R. (Rowena), Banks, J. (Jill), von Dobschuetz, S. (Sophie), Stärk, K.D.C. (Katharina D. C.), Wieland, B., Stevens, K., Werf, S. (Sylvie) van der, Enouf, V. (Vincent), van der Meulen, K. (Karen), Reeth, K. van, Dauphin, G. (Gwenaelle), and Koopmans D.V.M., M.P.G. (Marion)

Abstract

Factors that trigger human infection with animal influenza virus progressing into a pandemic are poorly understood. Within a project developing an evidence-based risk assessment framework for influenza viruses in animals, we conducted a review of the literature for evidence of human infection with animal influenza viruses by diagnostic methods used. The review covering Medline, Embase, SciSearch and CabAbstracts yielded 6,955 articles, of which we retained 89; for influenza A(H5N1) and A(H7N9), the official case counts of the World Health Organization were used. An additional 30 studies were included by scanning the reference lists. Here, we present the findings for confirmed infections with virological evidence. We found reports of 1,419 naturally infected human cases, of which 648 were associated with avian influenza virus (AIV) A(H5N1), 375 with other AIV subtypes, and 396 with swine influenza virus (SIV). Human cases naturally infected with AIV spanned haemagglutinin subtypes H5, H6, H7, H9 and H10. SIV cases were associated with endemic SIV of H1 and H3 subtype de

Published

2014

6. Discrimination of influenza infection (A/2009 H1N1) from prior exposure by antibody protein microarray analysis

Author

Beest, D.E. (Dennis) te, Bruin, E. (Erwin) de, Imholz, S. (Sandra), Wallinga, J. (Jacco), Teunis, P.F.M. (Peter), Koopmans D.V.M., M.P.G. (Marion), Boven, M. (Michiel) van, Beest, D.E. (Dennis) te, Bruin, E. (Erwin) de, Imholz, S. (Sandra), Wallinga, J. (Jacco), Teunis, P.F.M. (Peter), Koopmans D.V.M., M.P.G. (Marion), and Boven, M. (Michiel) van

Abstract

Reliable discrimination of recent influenza A infection from previous exposure using hemagglutination inhibition (HI) or virus neutralization tests is current

Published

2014

7. Profiling of Humoral Response to Influenza A(H1N1)pdm09 Infection and Vaccination Measured by a Protein Microarray in Persons with and without History of Seasonal Vaccination

Author

Huijskens, E. (Elisabeth), Reimerink, J.H.J. (Johan), Mulder, P.G.H. (Paul), Beek, J.J. (Hans) van, Meijer, A.C. (Sander), Bruin, E. (Erwin) de, Friesema, I.H.M., Jong, M.D. (Menno) de, Rimmelzwaan, G.F. (Guus), Peeters, M. (Marcel), Rossen, J.W. (John), Koopmans D.V.M., M.P.G. (Marion), Huijskens, E. (Elisabeth), Reimerink, J.H.J. (Johan), Mulder, P.G.H. (Paul), Beek, J.J. (Hans) van, Meijer, A.C. (Sander), Bruin, E. (Erwin) de, Friesema, I.H.M., Jong, M.D. (Menno) de, Rimmelzwaan, G.F. (Guus), Peeters, M. (Marcel), Rossen, J.W. (John), and Koopmans D.V.M., M.P.G. (Marion)

Abstract

Background: The influence of prior seasonal influenza vaccination on the antibody response produced by natural infection or vaccination is not well understood. Methods: We compared the profiles of antibody responses of 32 naturally infected subjects and 98 subjects vaccinated with a 2009 influenza A(H1N1) monovalent MF59-adjuvanted vaccine (Focetria®, Novartis), with and without a history of seasonal influenza vaccination. Antibodies were measured by hemagglutination inhibition (HI) assay for influenza A(H1N1)pdm09 and by protein microarray (PA) using the HA1 subunit for seven recent and historic H1, H2 and H3 influenza viruses, and three avian influenza viruses. Serum samples for the infection group were taken at the moment of collection of the diagnostic sample, 10 days and 30 days after onset of influenza symptoms. For the vaccination group, samples were drawn at baseline, 3 weeks after the first vaccination and 5 weeks after the second vaccination. Results: We showed that subjects with a history of seasonal vaccination generally exhibited higher baseline titers for the various HA1 antigens than subjects without a seasonal vaccination history. Infection and pandemic influenza vaccination responses in persons with a history of seasonal vaccination were skewed towards historic antigens. Conclusions: Seasonal vaccination is of significant influence on the antibody response to subsequent infection and vaccination, and further research is needed to understand the effect of annual vaccination on protective immunity.

Published

2013

8. Prevalence of human parechovirus in The Netherlands in 2000 to 2007

Author

Sanden, S.M.G. (Sabine) van der, Bruin, E. (Erwin) de, Vennema, H. (Harry), Swanink, C. (Caroline), Koopmans D.V.M., M.P.G. (Marion), Avoort, H.G.A.M. (Harrie) van der, Sanden, S.M.G. (Sabine) van der, Bruin, E. (Erwin) de, Vennema, H. (Harry), Swanink, C. (Caroline), Koopmans D.V.M., M.P.G. (Marion), and Avoort, H.G.A.M. (Harrie) van der

Abstract

Infection with human parechovirus 3 (HPeV3) was described for the first time in Japan in 2004 and reportedly is more often associated with severe disease than infection with HPeV1 or HPeV2. In 2004, infections with HPeV3 were observed for the first time in The Netherlands. Genetic analysis showed several different lineages, suggesting endemic circulation. We analyzed 163 cell culture isolates from the same number of patients tested in routine virological laboratories as part of the national enterovirus surveillance program. Isolates were collected between 2000 and 2007 and could not be characterized by routine methods. In total, 155 isolates (95%) were found positive for HPeV by a reverse transcription-PCR assay targeting the 5′ untranslated region, explaining the majority of the diagnostic deficit in enterovirus surveillance for these years. Typing of the isolates by use of partial genome sequencing of the VP1/2A region revealed the presence of 55 HPeV1, 2 HPeV2, 89 HPeV3, 1 HPeV4, and 8 HPeV5 isolates. We compared isolation dates, age groups affected, and clinical pictures, which were reported as part of the routine surveillance. Clear differences in epidemiology were observed, with HPeV3 occurring at intervals of 2 years and in the spring-summer season, whereas HPeV1 was observed in small numbers throughout each year, with a low in the summer months. HPeV3 infection affected younger children than HPeV1 infection and was significantly more often associated with fever, meningitis, and viremia. Copyright

Published

2008

9. Epochal evolution of GGII.4 norovirus capsid proteins from 1995 to 2006

Author

Siebenga, J.J. (Joukje), Vennema, H. (Harry), Renckens, B. (Bernadet), Bruin, E. (Erwin) de, Veer, B. (Bas) van der, Siezen, R.J. (Roland), Koopmans D.V.M., M.P.G. (Marion), Siebenga, J.J. (Joukje), Vennema, H. (Harry), Renckens, B. (Bernadet), Bruin, E. (Erwin) de, Veer, B. (Bas) van der, Siezen, R.J. (Roland), and Koopmans D.V.M., M.P.G. (Marion)

Abstract

Noroviruses are the causative agents of the majority of viral gastroenteritis outbreaks in humans. During the past 15 years, noroviruses of genotype GGII.4 have caused four epidemic seasons of viral gastroenteritis, during which four novel variants (termed epidemic variants) emerged and displaced the resident viruses. In order to understand the mechanisms and biological advantages of these epidemic variants, we studied the genetic changes in the capsid proteins of GGII.4 strains over this period. A representative sample was drawn from 574 GGII.4 outbreak strains collected over 15 years of systematic surveillance in The Netherlands, and capsid genes were sequenced for a total of 26 strains. The three-dimensional structure was predicted by homology modeling, using the Norwalk virus (Hu/NoV/GGI.1/Norwalk/1968/US) capsid as a reference. The highly significant preferential accumulation and fixation of mutations (nucleotide and amino acid) in the protruding part of the capsid protein provided strong evidence for the occurrence of genetic drift and selection. Although subsequent new epidemic variants differed by up to 25 amino acid mutations, consistent changes were observed in only five positions. Phylogenetic analyses showed that each variant descended from its chronologic predecessor, with the exception of the 2006b variant, which is more closely related to the 2002 variant than to the 2004 variant. The consistent association between the observed genetic findings and changes in epidemiology leads to the conclusion that population immunity plays a role in the epochal evolution of GGII.4 norovirus strains. Copyright

Published

2007