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A study on the clinical application of a rapid diagnostic reagent for measles

Year 2012, Volume: 9 Issue: 1, 39 - 44, 01.03.2012

Abstract

References

  • Numazaki K. Current problems of measles control in Japan and Western Pacific region. Vaccine 2007;25:3101–4.
  • Centers for Disease Control and Prevention (CDC). Progress in global measles control and mortality reduc- tion, 2000–2006. Morb Mortal Wkly Rep 2007;56:1237–41.
  • Paunio M, Peltola H, Valle M, Davidkin I, Virtanen M, Heinonen OP. Explosive school-based measles outbreak intense exposure may have resulted in high risk, even among revaccinees. Am J Epidemiol 1998;148:1103–10.
  • Helfand RF, Kim DK, Gary HE Jr, et al. Nonclassic measles infections in an immune population exposed to measles during a college bus trip. J Med Virol 1998;56:337-41
  • Ong G, Rasidah N, Wan S, and Cutter J. Outbreak of mea- sles in primary school students with high first dose MMR vaccination coverage. Singapore Med J 2007;48:656–61.
  • Cisse B, Aaby P, Simondon F, Samb B, Soumaré M, Whittle H. Role of schools in the transmission of measles in rural Senegal: implications for measles control in developing countries. Am J Epidemiol 1999;149:295-301.
  • Morita Y, Suzuki T, Shiono M, et al. Sequence and phylo- genetic analysis of the nucleoprotein (N) gene in measles viruses prevalent in Gunma Japan in 2007. Jpn J Infect Dis 2007;60:402–4.
  • Mubarak HS, Van De Bildt MW, Mustafa OA, et al. Serological and virological characterization of clinically diagnosed cases of measles in suburban Khartoum. J Clin Microbiol 2000;38:987–91.
  • Solange AO, Luiz ABC, Antonio CMP, et al. Assessment of the performance of a definition of a suspected measles case: implications for measles surveillance. Rev Panam Salud 2006;19: 229–35.
  • Van Binnendijk RS, van den Hof S, van den Kerkhof H, et al. Evaluation of serological and viological tests in the diagnosis of clinical and subclinical measles virus infec- tions during an outbreak of measles in The Netherlands. J Infect Dis 2003;188:898–903.
  • Nerbrand C, Jasir A, Schalén C. Are current rapid de- tection tests for Group A streptococci sensitive enough? Evaluation of 2 commercial kits. Scand J Infect Dis 2002;34:797–9.
  • Fujimoto T, Okafuji T, Okafuji T, et al. Evaluation of a bedside immunochromatographic test for detection of adenovirus in respiratory samples, by comparison to virus isolation, PCR and real-time-PCR. J Clin Microbiol 2004; 42: 5489-92
  • Hurta AC, Alexanderc R, Hibbert J, Deeda N, Barra IG. Performance of six influenza rapid tests in detect- ing human influenza in clinical specimens. J Clin Virol 2007;39:132–5.
  • Santibanez S, Tischer A, Heider A, Siedler A, Hengel H. Rapid replacement of endemic measles virus genotypes. J Med Virol 2002;83:2699–708.
  • Riddell MA, Rota JS, Rota PA. Review of the temporal and geographical distribution of measles virus genotypes in the prevaccine and postvaccine eras. Virol J 2005;2:1–9.
  • Okafuji T, Okafuji T, Fujino M, Nakayama T. Current sta- tus of measles in Japan: molecular and seroepi-demiolog- ical studies. J Infect Chemother 2006;12:343–8.
  • Ono N, Tatsuo H, Hidaka Y, Aoki T, Minagawa H, Yanagi Y. Measles viruses on throat swabs from measles patients use signaling lymphocytic activation molecule (CDw150) but not CD46 as a cellular receptor. J Virol 2001;75:4399–401.
  • Hasegawa T, Asaeda A, Hamaguchi Y, Numazaki K. Development of rapid diagnostic reagent for measles. Hybridoma 2009;28:241-9
  • Sato TA, Fukuda A, Sugiura A. Characterization of major structural proteins of measles virus with monoclonal an- tibodies. J Gen Virol 1985;66:1397–409.
  • Erdman DD, Anderson LJ, Adams DR, Stewart JA, Markowitz LE, Bellini WJ. Evaluation of monoclonal anti- body-based capture enzyme immunoassays for detection of specific antibodies to measles virus. J Clin Microbiol 1991;29:1466-71.
  • Viola B, Viktoria G, Tatsuya S, Yaeta E, Tamas M. A set of ligation-independent in vitro translation vectors for eu- karyotic protein production. BMC Biotechnol 2008;8:32.
  • Graves MC. Measles virus polypeptide in infected cell studied by immune precipitation and one-dimensional peptide mapping. J Virol 1981;38:224-30
  • Hummel KB, Lowe L, Bellini WJ, Rota PA. Development of quantitative gene-specific real-time RT-PCR assays for the detection of measles virus in clinical specimens. J Virol Methods 2005;132:166-73.
  • Jin L, Feng Y, Parry R, Cui A, Lu Y. Real-time PCR and its application to mumps rapid diagnosis. J Med Virol 2007;70:1761–7.
  • Ratnam S, Tipples G, Head C, Fauvel M, Fearon M, Ward BJ. Performance of indirect immunoglobulinM (IgM) serol- ogy tests and IgM capture assays for laboratory laboratory diagnosis of measles. J Clin Microbiol 2000;38:99–104.
  • Tipples GA, Hamkar R, Mohktari-Azad T, Gray M, Parkyn G, Head C, Ratnam S. Assessment of immunoglobulinM enzyme immunoassays for diagnosis of measles. J Clin Microbiol 2003;41:4790–2.
  • El Mubarak HS, Ibrahim SA, Vos HW, et al. Measles virus protein-specific IgM, IgA, and IgG subclass responses dur- ing the acute and convalescent phase of infection. J Med Virol 2004; 72:290-8.
  • Owens GP, Shearer AJ, Yu X, et al. Screening random pep- tide libraries with subacute sclerosing panencephalitis brain-derived recombinant antibodies identifies multiple epitopes in the C-terminal region of the measles virus nucleocapsid. Protein 2006;80:12121–30.
  • Longhi S, Receveur-Bre´chot V, Karlin D, et al. The C terminal domain of the measles virus nucleoprotein is intrinsically disordered and folds upon binding to the C terminal moiety of the phosphoprotein. J Biol Chem 2003;278:18638–48.
  • Fujino M, Yoshida N, Yamaguchi S, et al. A simple meth- od for the detection of measles virus genome by loop- mediated isothermal amplification (LAMP). J Med Virol 2005;76:406-13.
  • Kikuta H, Ebihara T, Endo R, et al. Development of a rapid chromatographic immunoassay for detection of Human metapneumovirus using monoclonal antibodies against nucleoprotein of hMPV. Hybridoma 2007;26:17–21.

A study on the clinical application of a rapid diagnostic reagent for measles

Year 2012, Volume: 9 Issue: 1, 39 - 44, 01.03.2012

Abstract

-

References

  • Numazaki K. Current problems of measles control in Japan and Western Pacific region. Vaccine 2007;25:3101–4.
  • Centers for Disease Control and Prevention (CDC). Progress in global measles control and mortality reduc- tion, 2000–2006. Morb Mortal Wkly Rep 2007;56:1237–41.
  • Paunio M, Peltola H, Valle M, Davidkin I, Virtanen M, Heinonen OP. Explosive school-based measles outbreak intense exposure may have resulted in high risk, even among revaccinees. Am J Epidemiol 1998;148:1103–10.
  • Helfand RF, Kim DK, Gary HE Jr, et al. Nonclassic measles infections in an immune population exposed to measles during a college bus trip. J Med Virol 1998;56:337-41
  • Ong G, Rasidah N, Wan S, and Cutter J. Outbreak of mea- sles in primary school students with high first dose MMR vaccination coverage. Singapore Med J 2007;48:656–61.
  • Cisse B, Aaby P, Simondon F, Samb B, Soumaré M, Whittle H. Role of schools in the transmission of measles in rural Senegal: implications for measles control in developing countries. Am J Epidemiol 1999;149:295-301.
  • Morita Y, Suzuki T, Shiono M, et al. Sequence and phylo- genetic analysis of the nucleoprotein (N) gene in measles viruses prevalent in Gunma Japan in 2007. Jpn J Infect Dis 2007;60:402–4.
  • Mubarak HS, Van De Bildt MW, Mustafa OA, et al. Serological and virological characterization of clinically diagnosed cases of measles in suburban Khartoum. J Clin Microbiol 2000;38:987–91.
  • Solange AO, Luiz ABC, Antonio CMP, et al. Assessment of the performance of a definition of a suspected measles case: implications for measles surveillance. Rev Panam Salud 2006;19: 229–35.
  • Van Binnendijk RS, van den Hof S, van den Kerkhof H, et al. Evaluation of serological and viological tests in the diagnosis of clinical and subclinical measles virus infec- tions during an outbreak of measles in The Netherlands. J Infect Dis 2003;188:898–903.
  • Nerbrand C, Jasir A, Schalén C. Are current rapid de- tection tests for Group A streptococci sensitive enough? Evaluation of 2 commercial kits. Scand J Infect Dis 2002;34:797–9.
  • Fujimoto T, Okafuji T, Okafuji T, et al. Evaluation of a bedside immunochromatographic test for detection of adenovirus in respiratory samples, by comparison to virus isolation, PCR and real-time-PCR. J Clin Microbiol 2004; 42: 5489-92
  • Hurta AC, Alexanderc R, Hibbert J, Deeda N, Barra IG. Performance of six influenza rapid tests in detect- ing human influenza in clinical specimens. J Clin Virol 2007;39:132–5.
  • Santibanez S, Tischer A, Heider A, Siedler A, Hengel H. Rapid replacement of endemic measles virus genotypes. J Med Virol 2002;83:2699–708.
  • Riddell MA, Rota JS, Rota PA. Review of the temporal and geographical distribution of measles virus genotypes in the prevaccine and postvaccine eras. Virol J 2005;2:1–9.
  • Okafuji T, Okafuji T, Fujino M, Nakayama T. Current sta- tus of measles in Japan: molecular and seroepi-demiolog- ical studies. J Infect Chemother 2006;12:343–8.
  • Ono N, Tatsuo H, Hidaka Y, Aoki T, Minagawa H, Yanagi Y. Measles viruses on throat swabs from measles patients use signaling lymphocytic activation molecule (CDw150) but not CD46 as a cellular receptor. J Virol 2001;75:4399–401.
  • Hasegawa T, Asaeda A, Hamaguchi Y, Numazaki K. Development of rapid diagnostic reagent for measles. Hybridoma 2009;28:241-9
  • Sato TA, Fukuda A, Sugiura A. Characterization of major structural proteins of measles virus with monoclonal an- tibodies. J Gen Virol 1985;66:1397–409.
  • Erdman DD, Anderson LJ, Adams DR, Stewart JA, Markowitz LE, Bellini WJ. Evaluation of monoclonal anti- body-based capture enzyme immunoassays for detection of specific antibodies to measles virus. J Clin Microbiol 1991;29:1466-71.
  • Viola B, Viktoria G, Tatsuya S, Yaeta E, Tamas M. A set of ligation-independent in vitro translation vectors for eu- karyotic protein production. BMC Biotechnol 2008;8:32.
  • Graves MC. Measles virus polypeptide in infected cell studied by immune precipitation and one-dimensional peptide mapping. J Virol 1981;38:224-30
  • Hummel KB, Lowe L, Bellini WJ, Rota PA. Development of quantitative gene-specific real-time RT-PCR assays for the detection of measles virus in clinical specimens. J Virol Methods 2005;132:166-73.
  • Jin L, Feng Y, Parry R, Cui A, Lu Y. Real-time PCR and its application to mumps rapid diagnosis. J Med Virol 2007;70:1761–7.
  • Ratnam S, Tipples G, Head C, Fauvel M, Fearon M, Ward BJ. Performance of indirect immunoglobulinM (IgM) serol- ogy tests and IgM capture assays for laboratory laboratory diagnosis of measles. J Clin Microbiol 2000;38:99–104.
  • Tipples GA, Hamkar R, Mohktari-Azad T, Gray M, Parkyn G, Head C, Ratnam S. Assessment of immunoglobulinM enzyme immunoassays for diagnosis of measles. J Clin Microbiol 2003;41:4790–2.
  • El Mubarak HS, Ibrahim SA, Vos HW, et al. Measles virus protein-specific IgM, IgA, and IgG subclass responses dur- ing the acute and convalescent phase of infection. J Med Virol 2004; 72:290-8.
  • Owens GP, Shearer AJ, Yu X, et al. Screening random pep- tide libraries with subacute sclerosing panencephalitis brain-derived recombinant antibodies identifies multiple epitopes in the C-terminal region of the measles virus nucleocapsid. Protein 2006;80:12121–30.
  • Longhi S, Receveur-Bre´chot V, Karlin D, et al. The C terminal domain of the measles virus nucleoprotein is intrinsically disordered and folds upon binding to the C terminal moiety of the phosphoprotein. J Biol Chem 2003;278:18638–48.
  • Fujino M, Yoshida N, Yamaguchi S, et al. A simple meth- od for the detection of measles virus genome by loop- mediated isothermal amplification (LAMP). J Med Virol 2005;76:406-13.
  • Kikuta H, Ebihara T, Endo R, et al. Development of a rapid chromatographic immunoassay for detection of Human metapneumovirus using monoclonal antibodies against nucleoprotein of hMPV. Hybridoma 2007;26:17–21.
There are 31 citations in total.

Details

Primary Language English
Journal Section Original Articles
Authors

Kei Numazaki This is me

Publication Date March 1, 2012
Published in Issue Year 2012 Volume: 9 Issue: 1

Cite

APA Numazaki, K. (2012). A study on the clinical application of a rapid diagnostic reagent for measles. European Journal of General Medicine, 9(1), 39-44.
AMA Numazaki K. A study on the clinical application of a rapid diagnostic reagent for measles. European Journal of General Medicine. March 2012;9(1):39-44.
Chicago Numazaki, Kei. “A Study on the Clinical Application of a Rapid Diagnostic Reagent for Measles”. European Journal of General Medicine 9, no. 1 (March 2012): 39-44.
EndNote Numazaki K (March 1, 2012) A study on the clinical application of a rapid diagnostic reagent for measles. European Journal of General Medicine 9 1 39–44.
IEEE K. Numazaki, “A study on the clinical application of a rapid diagnostic reagent for measles”, European Journal of General Medicine, vol. 9, no. 1, pp. 39–44, 2012.
ISNAD Numazaki, Kei. “A Study on the Clinical Application of a Rapid Diagnostic Reagent for Measles”. European Journal of General Medicine 9/1 (March 2012), 39-44.
JAMA Numazaki K. A study on the clinical application of a rapid diagnostic reagent for measles. European Journal of General Medicine. 2012;9:39–44.
MLA Numazaki, Kei. “A Study on the Clinical Application of a Rapid Diagnostic Reagent for Measles”. European Journal of General Medicine, vol. 9, no. 1, 2012, pp. 39-44.
Vancouver Numazaki K. A study on the clinical application of a rapid diagnostic reagent for measles. European Journal of General Medicine. 2012;9(1):39-44.