View clinical trials related to Encephalitis, Tick-borne.
Filter by:The main purpose of this study is to provide safety and immunogenicity data in Japanese participants.
In Europe, tick-borne encephalitis (TBE) virus causing TBE is transmitted by the bite of Ixodes ricinus tick, which can also transmit Lyme borreliae , the causative agent of Lyme borreliosis (LB). Since TBE and LB are both endemic with high incidence rates in Slovenia, we should be attentive to the possibility of double infections. Double infections with TBE virus and Lyme borreliae were reported to occur rarely even in endemic countries, however reliable data on coinfection rates are rather limited. Microbiological diagnosis of TBE virus infection is quite straightforward, and there is no specific therapy for TBE available so far. This markedly differs from borrelial infection, in which case interpretation of serological test results demands more caution, but there is highly efficient antibiotic treatment available for LB. This may lead to over prescribing of antibiotics to TBE patients with documented borrelial antibodies in serum indicating possible coinfection with Lyme borreliae, but missing clinical or microbiological criteria for proven borrelial coinfection. Approximately 10% of patients who had been treated appropriately for LB and about one third of patients after TBE report nonspecific subjective complaints, such as fatigue, headache, arthralgia, and myalgia, termed post-Lyme and post-encephalitic symptoms, respectively. These may not be differentiated clearly from nonspecific symptoms occurring with a rather substantial incidence also in the general population. A trend of ascribing medically unexplained nonspecific subjective symptoms to LB in subjects with positive borrelial antibodies in serum puzzles the situation further. The aim of this prospective observational study was to assess the proportion and clinical implication of proven and possible coinfection with Lyme borreliae in patients with TBE, and to evaluate the association between anti-borrelial antibiotic therapy and clinical outcome in the subgroup of patients with possible coinfection.
Allergic patients especially those undergoing de-sensitization treatment have an altered immune responsiveness. The investigators aim to find out whether this influences immune responses to primary and booster vaccinations.
The risk for tick borne encephalitis increases in Sweden. Together with an increased awareness of the possibility to acquire protection by vaccination, this has led to an increase in the number of doses of the vaccine distributed in Sweden each year - now being approximately 400.000. The first year, two doses with an interval of 1 month is recommended for the general population, followed by a third dose approximately one year later and an additional booster dose three years after the third. Preliminary results from a previous study showed a higher percentage protected (=titer at least 10) after 3 doses than after 2 doses (Rombo et al. EUDRA CT 2011 001348-31, unpublished information). In the same study, there were no differences between those who were vaccinated 0+7+21 compared to 0+30+90. The investigators were surprised to find marked differences between 2 and 3 doses also in the younger control group. The investigators therefore aim to confirm results in a new study and to add a group with a double dose at day 0 and then a single dose at day 30 and 360
Patients undergoing allogeneic blood and marrow transplantation (HSCT) experience a prolonged period of dysfunctional immunity. Systematic reimmunization is necessary at appropriate time intervals following transplantation to re-establish immunity. Vaccination practices after HSCT remain varied and data sparse. Tick-borne encephalitis (TBE) is one of the most severe infections of the central nervous system caused by a tick-borne flavivirus. There is no specific treatment, and prevention with the vaccine is the only intervention available. To assess the efficacy of TBE vaccination in adult allogeneic HSCT recipients compared to an age-matched and sex-matched control group of healthy volunteers without previous TBE vaccination, a prospective open-label phase II pilot study on humoral and cellular immune responses after use of TBE vaccine (FSME Immun) will be performed. As primary end point the outcome of the neutralization test (NT) against TBE will be assessed in a total of 26 HSCT patients one year after HSCT and in 26 healthy volunteers, namely four weeks after the second vaccination. Therefore, the number of subjects with NT titres against TBE virus >10, assumed to be the threshold for antibody-mediated protection will be evaluated. As secondary endpoints, antibody concentrations of TBE enzyme-linked immunosorbent assay before and four weeks after the second and third vaccination and antibody concentrations of NT against TBE four weeks after primary immunization. To evaluate cellular immune responses, lymphocyte proliferations assays and cytokine detection assays will be performed. In a subgroup analysis, these secondary endpoints will be compared between healthy volunteers, HSCT patients without immunosuppressive treatment and HSCT patients receiving immunosuppressive agents. Additionally, immune reconstitution by analysis of peripheral blood lymphocyte subsets and serum immunoglobulin levels will be evaluated prior to vaccination, after twelve weeks and prior to the third vaccination in HSCT patients only.
Many viral infections of global importance, including HIV, are transmitted across the mucosal surface of the genital tract. As immunity against these infections is likely to be primarily mediated by antibodies in mucosal secretions, developing techniques to increase the levels and persistence of antiviral antibody on mucosal surfaces may enhance the protection against a number of important infections. Preclinical studies have anatomically targeted vaccine antigens to sites where genital tract immunity is induced. This response is likely due to the ability of regional lymph Preclinical studies have anatomically targeted vaccine antigens to sites where genital tract immunity is induced. This response is likely due to the ability of regional lymph nodes to "pattern" the cell surface markers of responding vaccine specific lymphocytes with homing markers. In contrast, injecting a distant muscle (such as in the arm) which shares no anatomical relationship with the vagina, may not pattern cells with homing markers for the genital tract. Direct injection of inguinal lymph nodes is impractical in humans but intramuscular injection into the thigh will target antigens to the deep inguinal lymph nodes shared in common with the cervix/vagina. This study will be a Phase IV randomised, single centre, open label, laboratory assessment blinded exploratory trial to assess mucosal immunogenicity following three targeted intramuscular immunisations with TicoVac vaccine. 20 subjects will be randomised to each of2 groups immunised in right deltoid or right anterolateral thigh. Following an initial screening visit subjects will be immunised at 0, 1 and 6 months. There will be follow up visits 5 days after each immunisation and a final visit at 7 months. Blood samples and cervicovaginal secretions will be taken prior to each immunisation for immunological measures. In addition, blood samples will be taken at each immunisation and follow up visit for measurement of peripheral blood mononuclear cells. The study is funded by ADITEC, which is a collaborative research programme that aims to accelerate the development of novel and powerful immunisation technologies for the next generation of human vaccines.
The purpose of this study is to evaluate TBE antibody persistence from 7 to 10 years after the first booster TBE vaccination with FSME-IMMUN 0.5ml.
The aim of this study is to investigate the immunogenicity response in adults up to 10 years after one booster dose. Data collected from this study will allow for greater information to prescribers who administer TBE vaccine, so that they can appropriately time the administration of booster vaccinations to individuals who received different vaccination schedules and who live in tick borne encephalitis endemic regions.
Antibody titers after tick-borne encephalitis (TBE) vaccination are less in elderly and vaccination breakthroughs are more common in this age group. This has prompted Swedish authorities to recommend an additional dose in the initial vaccination schedule (= 0+30+90 days instead of the usually recommended 0+30 days. The investigators intend to evaluate this regime.
This study will evaluate the durability of antibody responses in children and adolescents after primary immunization with TBE vaccine