ELISA Based Anthrax Antibody Titer in Cattle Induced by Locally Prepared Anthrax Vaccine Originated from Sterne F-24 Strain in Bangladesh

Vaccination is usually practiced to prevent and control anthrax in Bangladesh. For this purpose, vaccine prepared from Sterne F-24 strain ofBacillus anthracisby Livestock Research Institute (LRI), Mohakhali, Dhakahas long been used in this country. However, in some cases anthrax occurred in vaccinated animals in Bangladesh. A total of 100 cattle at LalTeer Livestock Research and Development Farm, LalTeerLivestock Limited, Bangladesh, aging between 3-6 years and weighing between 250-400 kg were randomly selected for vaccination purpose. Blood samples (n=100) were collected before the vaccination for collecting pre-vaccination serum, andthe animals were vaccinated (at 1 mL/animal; 1x107 spores/mL) with the anthrax vaccine produced by LRI. All blood samples from the vaccinated animals were collected on day 7, 28, 60, 90, 120, 150, 180, 240, 270, 300, 330, and 360 of post-vaccination, and serum samples were prepared. The antibody levels in the serum samples against anthrax were monitored using an Enzyme-Linked Immunosorbent Assay (ELISA). Over the course of 12 months, the antibody titers were found at the level higher than the reference value. Though there were reports on anthrax suspected cases in this farm, no such cases were reported during the study period. Thus, the vaccine appears to induce adequate antibody response against anthrax in Bangladesh.Microbes and Health, January 2015. 4(1): 36-38

Persistent Impairments in Humoral and Cellular Immunity in Patients with Immune Thrombocytopenia Treated with Rituximab: A Sub-Study of a Randomized Controlled Trial

Abstract 492 Background: The anti-CD20 antibody, rituximab, is increasingly being used as a treatment for immune thrombocytopenia (ITP). The concern about rare occurrences of progressive multifocal leukoencephalopathy in this population and the reliance on vaccine responses in patients who ultimately require splenectomy calls for additional studies into the integrity of the immune system after rituximab treatment. The objective of this study was to evaluate both the antibody and cellular responses to the Streptococcus pneumoniae polysaccharide vaccine and to the Haemophilus influenza type b (Hib) conjugate vaccine in rituximab-treated patients with ITP. Methods: Adults with primary ITP and a platelet count below 30 x109/L who had participated in a randomized trial of rituximab or placebo were eligible for this prospective sub-study. Six months after the study intervention, patients were given the S. pneumoniae polysaccharide vaccine (Pneumovax-23®, Merck) and the Hib conjugate vaccine (ActHIB®, Aventis). Antibodies against the pneumococcal capsular polysaccharide (anti-PCP) and Hib polyribosyl-ribitol phosphate (anti-PRP) were measured by EIA. A bactericidal assay was used to measure the ability to eradicate Hib in culture. An adequate antibody response was defined as a 4-fold increase in antibody concentration from baseline in the first month post vaccination. IgG anti-PRP ≥ 1 μg/mL was considered protective. For the bactericidal assay, a 4-fold increase from baseline was considered positive. CD3+ T-cells and total (CD19+), naïve (CD19+, CD27−), memory (CD19+, CD27+, CD38−) and pre-plasma (CD19low, CD27hi, CD38hi) B-cells were determined by flow cytometry before and after vaccinations. Interferon-γ (IFN-γ) secreting T-cells were measured by elispot. Results: Patients who had been randomized to receive rituximab (n=14) or placebo (n=6) participated in this prospective study. Compared with placebo, fewer patients in the rituximab group achieved an adequate antibody response to S. pneumonia vaccine (21.4% versus 66.7%) or the Hib vaccine (28.6% versus 83.3%). These results correlated with a reduced bactericidal effect of anti-PRP antibodies observed in patients treated with rituximab compared with placebo (14.2% versus 83.3%). Two patients in the rituximab group demonstrated an adequate rise in antibody titer but with no functional bactericidal activity. In addition, 3 patients who did not mount an adequate antibody response, had IgG anti-PRP titers below protective levels and did not demonstrate bactericidal activity in vitro were considered Hib vaccine failures. There were no Hib vaccine failures in the placebo group. In the rituximab group, total number of B-cells declined rapidly after treatment (1.895 × 104/mL) relative to the placebo group (5.65 × 104/mL) and never fully recovered even 1 year post-treatment. Resting memory B-cells were significantly reduced after rituximab and remained at low levels even up to 1 year. Conversely, naïve B-cells recovered to near normal levels within 6 months of treatment. Activated pre-plasma B-cells increased following vaccination in the placebo group; yet, this response was variable in patients who had received rituximab. CD3+ T-cell numbers were unaffected by rituximab and vaccination; however, the number of IFN-γ- secreting T-cells were lower in the rituximab group. Conclusions: Rituximab treatment was associated with an impaired antibody response to vaccination, which in some patients was only demonstrated by impaired bactericidal activity. The expected increase in B-cell subsets was not observed following vaccination in the rituximab group, and T-cells, while normal in number, demonstrated functional impairments. Our findings characterize subtle defects in immunity which may persist after rituximab treatment. Disclosures: Off Label Use: Rituximab is not licensed for use with ITP patient. Kelton:Amgen: Membership on an entity's Board of Directors or advisory committees, Research Funding; GlaxoSmithKline: Membership on an entity's Board of Directors or advisory committees, Research Funding; Hoffman-LaRoche: Research Funding. Arnold:Amgen: Membership on an entity's Board of Directors or advisory committees, Research Funding; GlaxoSmithKline: Membership on an entity's Board of Directors or advisory committees, Research Funding; Hoffman-LaRoche: Research Funding.

Immunological products and vaccines

9.1 Active immunity, 416 9.2 Passive immunity, 418 9.3 Specific vaccines and preparations, 418 9.4 Immunoglobulins (Ig), 421 Vaccines stimulate production of antibodies and other components of the immune mechanism. • Inactivated ▪ Heat/chemically inactivated virulent microorganism (virus or bacteria). ▪ May require a primary series of injections of vaccine to produce an adequate antibody response, and in most cases booster (reinforcing) injections are required; the duration of immunity varies from months to many years. Some inactivated vaccines are adsorbed onto an adjuvant (such as aluminium hydroxide) to enhance the antibody response....