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Filter by:The French Public Health Council recommended pneumococcal vaccination combined strategy for all immunocompromised patients in 2012. This strategy consisted in conjugated 13-valent pneumococcal injection followed 2 months later by polysaccharide 23-valent vaccine injection. General practitioners are usually in charge of this vaccination. Conjugated pneumococcal vaccine enhances the immunogenicity of the polysaccharide vaccine. Acute leukemia and lymphoma are treated with multiple courses of chemotherapy, impairing the immune system and potentially the response to vaccination. These patients are more at risk for developing pneumococcal invasive diseases than the general population. However, efficacy of pneumococcal vaccination is poorly documented in this setting. We assume that 70% of the patients are non-responders to vaccination, according to their anti-pneumococcal immunoglobulin G titers and the opsonophagocytic activity. To assess the immunogenicity of the pneumococcal vaccination combined strategy in adult population of acute leukemia and lymphoma, the investigator will measure anti-pneumococcal serotype-specific immunoglobulin G titers and opsonophagocytic activity at different time-points after completion of the combined vaccine strategy. The primary objective is to assess the immunogenicity of pneumococcal vaccination combined strategy at 3 months after the 13-valent pneumococcal injection (corresponding to 1 month after the end of the combined strategy) using immunoglobulin G titers and opsonophagocytic activity. At different time points (day 0, 1 month after the 13-valent pneumococcal injection, the day of the injection of the polysaccharide 23-valent vaccine, one month after the injection of the polysaccharide 23-valent vaccine, 3-6 months after the polysaccharide 23-valent vaccine,9-12 months after the polysaccharide 23-valent vaccine), the immunological response to vaccination will be monitored using specific-serotype immunoglobulin G titers, opsonophagocytic activity, and total anti-pneumococcal Immunoglobulin. The investigator will determine predictive factors of non-response to vaccination by comparing demographic data, biological data and treatment received by both acute myeloblastic leukemia and lymphoma patients. The tolerance and safety of the vaccination strategy will also be assessed in this specific hematological population.
Taiwan is an endemic region for hepatitis B. Before the implementation of a nationwide vaccination program in 1984, the hepatitis B virus (HBV) carrier rate in the general population was 15 to 20%.1-2 The major impact of hepatitis B (HB) infection is its long-term sequelae which may include chronic hepatitis, liver cirrhosis, and hepatocellular carcinoma.3 Perinatal infection accounts for 40-50% of all hepatitis B infections and is responsible for the generation-to-generation transmission of HB virus.4 Hepatitis B vaccines, both plasma derived and recombinant, are highly immunogenic and efficacious.5-10 It has been reported that HB vaccine given soon after birth is able to protect infants from perinatal infection and HB infection became the first disease model to show that mother-to-neonate transmission can be interrupted by an effective vaccine.11 Taiwan started a national program of HB vaccination since 1984. This program resulted in a significant reduction of the HB carrier rate in children aged below 10 years from 9.8% before nationwide vaccination to 1.3% after the program.12 It also decreased the incidence of hepatocellular carcinoma in children aged 6 to 9 years from 0.52 to 0.13 per 100,000.13 However, the duration of protection provided by the HB vaccine and the proper timing of a booster dose remains unclear. Because the HB vaccine is a subunit protein vaccine, which contains only HBsAg, a limited duration of protection is anticipated. The results of several long-term follow-up studies of the protective efficacy of HB vaccination have been published. Soon after vaccination, protective levels of antibody (anti-HBs >10 mIU/mL) can be detected in the great majority (83-99%) of vaccinees.5-7 The proportion of vaccinees with protective anti-HBs levels decreases to 75-87% 5 years after vaccination and further drops to 50 to 70% 10-12 years after.10,11,14,15,19-21 Because of the progressive decline of anti-HBs and the associated increased likelihood of development of new HBV infections, some investigators advise the use of a booster vaccination.20,21 However, a preponderance of data indicates that the protective efficacy of the HB vaccine can last for at least 5 to 10 years and a booster before 5 years is not necessary.16-18,22,23 By demonstrating significant augmentation of cellular immunity and adequate induction of a protective level of antiHBs (>10 mIU/ml) in HBsAg and HBeAg-positive subjects 10 years after HB vaccination, we also proved that protection afforded by HB vaccination persisted for no less than 10 years in all vaccinees.R Nevertheless, the protective efficacy after the period of 10 years remains unknown. Knowledge of the duration of protection of HB vaccine and the optimal timing of booster vaccination remains crucial. In this study, we are going to examine the humoral and cellular immunity and monitored the antibody response following a booster dose of HB vaccine in a group of children whom had been vaccinated 14 years prior to this study.