Vaccination with complete adjuvant-added inactivated virus vaccine of Japanese encephalitis to swine, rabbits and chicks for preventing viremia (epidemiological study on Japanese encephalitis 25)

As a step towards the elimination of Japanese encephalitis virus in natural surroundings, we inoculated pigs, rabbits and chicks with inactivated Japanese encephalitis vaccine supplemented with complete or incomplete Freund's adjuvant twice at one-week interval. Subsequently, we compared HI antibody titers of the groups inoculated with vaccine containing complete Freund's adjuvant (pigs, rabbits, chicks), of the group inoculated with vaccine containing incomplete adjuvant (rabbits), ar;d of the groups inoculated with vaccine containing no adjuvant (pigs, rabbits, chicks), and also observations on changes in the antibody titers due to natural infection. In a certain portion of these animals neutralizing antibody titers were also determined. The results of this study are briefly summarized as follows. 1. In the groups of pigs and rabbits inoculated with vaccine containing complete Freund's adjuvant, titers of HI antibody and neutralizing antibody were higher than those inoculated with vaccine containing no adjuvant and their high titers persisted. Further, in the group of chicks inoculated with inactivated Japanese encephalitis vaccine containing complete Freund's adjuvant, HI antibody titers were higher and persistent as compared with the antibody titers in the chicks inoculated with inactivated Japanese encephalitis vaccine alone. 2. In the rabbits inoculated with inactivated Japanese encephalitis vaccine contammg incomplete adjuvant, HI antibody titers were lower than in those receiving the vaccine with complete adjuvant, but it has been demonstrated clearly that vaccination of inactivated Japanese encephalitis vaccine supplemented with incomplete adjuvant brings about less sideeffects. Hence such a method of vaccination can be applied as the vaccination with least side-effects. 3. With respect to natural infection of swine, on August 27 when the pigs were thought to have been infected, there was observed a rise in antibody titers. And on being infected with Japanese encephalitis, the antibodies formed in those pigs inoculated with inactivated Japanese ence- phalitis vaccine with or without complete adjuvant proved to be all 2-ME resistant type, whereas the antibodies produced in the control groups not receiving such a vaccination were 2-ME sensitive antibody.</p

Antibodies against prM protein distinguish between previous infection with dengue and Japanese encephalitis viruses.

BACKGROUND: In Southeast Asia, dengue viruses often co-circulate with other flaviviruses such as Japanese encephalitis virus, and due to the presence of shared antigenic epitopes it is often difficult to use serological methods to distinguish between previous infections by these flaviviruses. RESULTS: Convalescent sera from 69 individuals who were known to have had dengue or Japanese encephalitis virus infection were tested by western blotting against dengue, Japanese encephalitis and West Nile virus antigens. We determined that individuals who had been infected with dengue viruses had IgG responses against the premembrane protein of dengue viruses but not Japanese encephalitis, whereas individuals who had been infected with Japanese encephalitis had IgG specific for the premembrane protein of Japanese encephalitis virus but not the dengue viruses. None reacted with the premembrane protein of West Nile virus. Using the Pearson Chi Square test, it was determined that the difference between the two groups was highly significant with a p value of <0.001. CONCLUSION: The use of flavivirus premembrane protein in seroepidemiological studies will be useful in determining what flaviviruses have circulated in a community

Japanese Encephalitis Virus in Meningitis Patients, Japan

Cerebrospinal fluid specimens from 57 patients diagnosed with meningitis were tested for Japanese encephalitis virus. Total RNA was extracted from the specimens and amplified. Two products had highest homology with Nakayama strain and 2 with Ishikawa strain. Results suggest that Japanese encephalitis virus causes some aseptic meningitis in Japan

Acute encephalitis syndrome surveillance, Kushinagar district, Uttar Pradesh, India, 2011-2012

In India, quality surveillance for acute encephalitis syndrome (AES), including laboratory testing, is necessary for understanding the epidemiology and etiology of AES, planning interventions, and developing policy. We reviewed AES surveillance data for January 2011-June 2012 from Kushinagar District, Uttar Pradesh, India. Data were cleaned, incidence was determined, and demographic characteristics of cases and data quality were analyzed. A total of 812 AES case records were identified, of which 23\% had illogical entries. AES incidence was highest among boys<6 years of age, and cases peaked during monsoon season. Records for laboratory results (available for Japanese encephalitis but not AES) and vaccination history were largely incomplete, so inferences about the epidemiology and etiology of AES could not be made. The low-quality AES/Japanese encephalitis surveillance data in this area provide little evidence to support development of prevention and control measures, estimate the effect of interventions, and avoid the waste of public health resources

Effect of complete adjuvant on vaccination of live attenuated Japanese encephalitis vaccine to swine for preventing viremia. 39. Epidemiological studies of J.E

In an attempt to eliminate Japanese encephalitis virus in natural surroundings, pigs having maternal antibody were given inoculation of live-attenuated Japanese encephalitis vaccine and injection of Freund's complete adjuvant simultaneously. Titer of hemoagglutination inhibiting antibodies of pigs inoculated with live attenuated vaccine and complete adjuvant, was higher than that inoculated with vaccine alone and its titer persisted.</p

Japanese Encephalitis

Japanese encephalitis is a vector-borne disease caused by a virus. The disease is common in children andcan cause inflammation of the brain. In Indonesia the disease is consider as a neglected disease, although somestudies suggest Japanese encephalitis infections in both animals and humans in some regions. Transmission cycleactually happens between mosquitoes with the host such as pigs or birds. Transmission to humans occurs onlyincidentally. Disease diagnosis in humans can be done by rapid test, ELISA, or PCR. While control using avaccine is not a program yet in Indonesi

Transformation of antibody of Japanese encephalitis from IGM to IGG in experimental infected hen and transmission of IGG from hen to chicks. (epidemiological study on Japanese encephalitis. 37)

Transformation of Japanese encephalitis antibody from IgM to IgG in the sera of the experimental infected chicks with Japanese encephalitis virus and transmission of IgM or IgG from hen to chicks were examined by the gel filtration on Sephadex G-200 column. The following results were obtained. 1. Titer of hemoagglutination inhibiting antibody rose on seven days after inoculation of mouse brain homogenate infected with Japanese encephalitis, and that increased rapidly after the second inoculation of Japanese encephalitis. The maximum peak of antibody titer attained on 35 days after the first inoculation, on 7 days after the second inoculation and it maintained for a period of 2 months then decreased. Viremia was detected till 6 hours after the first inoculation. 2. IgM antibody by gel filtration appeared on 7 days after the first inoculation, kept on rising, reached the peak on 35 days after the first inoculation, then decreased, and disappeared on 120 days. IgG antibody appeared about 2 weeks after the IgM antibody appearance, and the titer of IgG antibody became higher than that of IgM antibody on 35 days after the first inoculation, then decreased gradually, and showed 1 : 16 of titer of peak on 150 days by gel filtration. 3. We could obtain the chicks by fertilization from experimentally infected hen, having IgM and IgG of hemoagglutination inhibiting antibody of Japanese encephalitis. And the localization of antibodies in the sera of its chicks was determined by Sephadex G-200 gel filtration. And IgG antibody was detected in chick serum, though IgM antibody was not detected by this method.</p

Phylogeography of Japanese encephalitis virus:genotype is associated with climate

The circulation of vector-borne zoonotic viruses is largely determined by the overlap in the geographical distributions of virus-competent vectors and reservoir hosts. What is less clear are the factors influencing the distribution of virus-specific lineages. Japanese encephalitis virus (JEV) is the most important etiologic agent of epidemic encephalitis worldwide, and is primarily maintained between vertebrate reservoir hosts (avian and swine) and culicine mosquitoes. There are five genotypes of JEV: GI-V. In recent years, GI has displaced GIII as the dominant JEV genotype and GV has re-emerged after almost 60 years of undetected virus circulation. JEV is found throughout most of Asia, extending from maritime Siberia in the north to Australia in the south, and as far as Pakistan to the west and Saipan to the east. Transmission of JEV in temperate zones is epidemic with the majority of cases occurring in summer months, while transmission in tropical zones is endemic and occurs year-round at lower rates. To test the hypothesis that viruses circulating in these two geographical zones are genetically distinct, we applied Bayesian phylogeographic, categorical data analysis and phylogeny-trait association test techniques to the largest JEV dataset compiled to date, representing the envelope (E) gene of 487 isolates collected from 12 countries over 75 years. We demonstrated that GIII and the recently emerged GI-b are temperate genotypes likely maintained year-round in northern latitudes, while GI-a and GII are tropical genotypes likely maintained primarily through mosquito-avian and mosquito-swine transmission cycles. This study represents a new paradigm directly linking viral molecular evolution and climate

JAPANESE ENCEPHALITIS

Japanese encephalitis is a vector-borne disease caused by a virus. The disease is common in children and can cause inflammation of the brain. In Indonesia the disease is consider as a neglected disease, although some studies suggest Japanese encephalitis infections in both animals and humans in some regions. Transmission cycle actually happens between mosquitoes with the host such as pigs or birds. Transmission to humans occurs only incidentally. Disease diagnosis in humans can be done by rapid test, ELISA, or PCR. While control using a vaccine is not a program yet in Indonesi