Vaccination coverage and immunity against hepatitis B among HIV-infected patients in South Brazil

Evidence-based strategies to improve the hepatitis B virus (HBV) vaccination coverage rates might help to reduce the burden caused by co-infection with HBV and human immuno-deficiency virus (HIV). In this study, the aim was to evaluate the vaccination coverage and immunity against HBV among HIV-infected individuals in South Brazil, and identify factors that are associated with compliance patterns and antibody reactivity. Three hundred HIV-infected men and women were included in this survey. The patients answered a standardized questionnaire, and vaccination cards were checked in order to assess hepatitis B vaccine status. A blood sample was collected for quantitative determination of antibody to hepatitis B virus surface antigen (anti-HBs). Participants were also evaluated for their CD4 cell count and HIV viral load. The overall vaccination coverage of HBV vaccination found in this study (57.4%) was lower than that was previously reported in South Brazil. Anti-HBs levels >10 IU/L were observed in 47.0% of the studied population. A significant inequality in the coverage rates and antibody reactivity was found in favor of patients with better economic status. In conclusion, the results indicate the need for improvement in the HBV vaccination coverage among HIV carriers, in particular focusing on low-income individuals.

The prevalence of hepatitis B virus infection markers and socio-demographic risk factors in HIV-infected patients in Southern Brazil

Introduction Hepatitis B virus (HBV) and human immunodeficiency virus (HIV) infections are two of the world's most important infectious diseases. Our objective was to determine the hepatitis B surface antigen (HBsAg) and hepatitis B core antibody (anti-HBc) prevalences among adult HIV-infected patients and identify the associations between socio-demographic variables and these HBV infection markers. Methods This study was performed from October 2012 to March 2013. Three hundred HIV-seropositive patients were monitored by the Clinical Analysis Laboratory of Professor Polydoro Ernani de São Thiago University Hospital, Santa Catarina, Brazil. The blood tests included HBsAg, anti-HBc immunoglobulin M (IgM) and total anti-HBc. Patients reported their HIV viral loads and CD4+ T-cell counts using a questionnaire designed to collect sociodemographic data. Results The mean patient age was 44.6 years, the mean CD4 T-cell count was 525/mm3, the mean time since beginning antiretroviral therapy was 7.6 years, and the mean time since HIV diagnosis was 9.6 years. The overall prevalences of HBsAg and total anti-HBc were 2.3% and 29.3%, respectively. Among the individuals analyzed, 0.3% were positive for HBsAg, 27.3% were positive for total anti-HBc, and 2.0% were positive either for HBsAg or total anti-HBc and were classified as chronically HBV-infected. Furthermore, 70.3% of the patients were classified as never having been infected. Male gender, age >40 years and Caucasian ethnicity were associated with an anti-HBc positive test. Conclusions The results showed an intermediate prevalence of HBsAg among the studied patients. Moreover, the associations between the anti-HBc marker and socio-demographic factors suggest a need for HBV immunization among these HIV-positive individuals, who are likely to have HIV/HBV coinfection. .

Uso combinado de sinvastatina e paclitaxel associado à nanoemulsão lipídica no tratamento do câncer / Combined use of simvastatin and paclitaxel associated to a lipidic nanoemulsion in cancer treatment

Uma nova alternativa para o tratamento do câncer foi proposta em estudos anteriores, consistindo no uso de uma nanoemulsão lipídica como transportadora de agentes quimioterápicos às células neoplásicas. A redução da toxicidade da quimioterapia promovida pelo direcionamento específico de quimioterápicos às células tumorais nos levou a testar o potencial de aplicação do sistema de nanopartículas lipídicas na terapêutica combinada do paclitaxel com a sinvastatina, um agente hipolipemiante que pode ser empregado como coadjuvante no tratamento do câncer. Nos dias 11, 14 e 19 após a inoculação de células de melanoma B16F10, camundongos C57BL/6J receberam pela via intraperitoneal soluções de oleato de paclitaxel associado à nanoemulsão lipídica 17,5µmol/kg (Nano-paclitaxel), formulação comercial do paclitaxel 17,5µmol/kg, nanoemulsão lipídica (Nanoemulsão) e solução salina (Controle). A sinvastatina 50mg/kg/dia foi administrada por gavagem do 11° ao 19° dia após a inoculação do tumor em um dos grupos de animais tratados com o Nano-paclitaxel (Nano-paclitaxel + Sinva), no grupo tratado com a formulação comercial do paclitaxel (Paclitaxel + Sinva) e como monoterapia (Sinva). Camundongos Balb-c saudáveis receberam os mesmos tratamentos para avaliação dos possíveis efeitos tóxicos dos diferentes tratamentos. A terapia combinada Nano-paclitaxel + Sinva apresentou toxicidade negligível em comparação com a terapia combinada Paclitaxel + Sinva que provocou perda de peso e mielossupressão nos animais. Nos animais portadores de tumor, o tratamento Nano-paclitaxel + Sinva inibiu 95% do crescimento tumoral, comparado à inibição de 44% promovida pelo tratamento Paclitaxel + Sinva. Além disso, apenas 37% dos animais portadores de melanoma submetidos ao tratamento com Nano-paclitaxel + Sinva apresentaram metástases, em contraste com 90% dos tratados com Paclitaxel + Sinva. A probabilidade de sobrevida também foi maior nos camundongos tratados com o Nano-paclitaxel + Sinva em comparação aos tratados com Paclitaxel + Sinva. A análise de amostras de tumores por citometria de fluxo mostrou que somente nos grupos de animais tratados com Sinva, Nano-paclitaxel ou com a combinação Nano-paclitaxel + Sinva houve aumento na expressão de p21 em comparação ao grupo Controle. Da mesma forma, apenas nos grupos Sinva e Nano-paclitaxel + Sinva houve redução na expressão de ciclina D1 em comparação ao grupo Controle. O teste de viabilidade celular com rodamina 123 mostrou despolarização da membrana mitocondrial com redução no número de células tumorais viáveis em todos os grupos de tratamentos em comparação aos grupos Nanoemulsão e Controle. A avaliação histológica dos tumores demonstrou que os grupos Nanoemulsão e Controle apresentaram alta densidade de células tumorais, diferentemente dos demais grupos de tratamento e que apenas os tumores do grupo Nano-paclitaxel + Sinva apresentaram aumento na presença de fibras de colágeno tipo I e III. Em comparação ao grupo Controle, os tumores dos grupos Sinva, Paclitaxel + Sinva, Nano-paclitaxel e Nano-paclitaxel + Sinva apresentaram redução na expressão imunohistoquímica de ICAM, MCP-1 e MMP-9 sendo que o grupo Nano-paclitaxel + Sinva apresentou a menor porcentagem de área marcada positivamente para a MMP-9. A terapia combinada com Nano-paclitaxel + Sinva é menos tóxica e mais efetiva na inibição do crescimento tumoral do que a mesma terapia com a formulação comercial do paclitaxel

In previous studies we have proposed a novel approach for cancer treatment consisting of the use of a lipid nanoemulsion as a vehicle to direct chemotherapeutic agents to neoplastic cells. Reduction of chemotherapy toxicity promoted by specific targeting of antineoplastic agents to tumor cells led us to test the application of the lipidic nanoparticle system in combined treatment with paclitaxel and simvastatin, a cholesterol-lowering drug that can be used as coadjuvant in cancer treatment. On days 11, 14 and 19 after B16F10 melanoma cells inoculation, C57BL/6J mice were intraperitoneally injected with paclitaxel oleate associated to the lipidic nanoemulsion 17.5 µmol/kg (Nano-paclitaxel), commercial formulation of paclitaxel 17.5 µmol/kg, lipidic nanoemulsion (Nanoemulsion) or saline solution (Control). Simvastatin 50 mg/kg/day was administered by gavage from days 11 to 19 after tumor inoculation in one group of animals treated with Nano-paclitaxel (Nano-paclitaxel + Simva), in the group treated with commercial formulation of paclitaxel (Paclitaxel + Simva) and as monotherapy (Simva). Evaluation of possible toxic effects of the treatments was accessed in healthy Balb-c mice. Combined therapy with Nano-paclitaxel + Simva showed negligible toxicity as compared with the combination of Paclitaxel + Simva which resulted in animal weight loss and myelosuppression. In tumor-bearing animals, treatment with Nano-paclitaxel + Simva resulted in a remarkable tumor growth inhibition rate of 95%, compared to a 44% inhibition rate promoted by treatment with Paclitaxel + Simva. Moreover, only 37% of melanoma bearing animals treated with Nano-paclitaxel + Simva developed metastasis, in contrast to 90% of those treated with Paclitaxel + Simva. Survival rates were also higher in mice treated with Nano-paclitaxel + Simva in comparison to Paclitaxel + Simva treated animals. Analysis of tumor samples by flow cytometry showed that only animals treated with Simva, Nano-paclitaxel or Nano-paclitaxel + Simva increased the expression of p21 in comparison to Control group. Also, tumors from animals treated with Simva or Nano-paclitaxel + Simva presented a decrease in the expression of cyclin D1 in comparison to Control group. Cell viability test with rhodamine 123 showed mitochondrial membrane depolarization with reduction of tumor viable cells in all treatment groups in comparison to Nanoemulsion and Control groups. The histological study revealed that in contrast to drugs treated groups, tumors from Nanoemulsion and Control groups presented high tumor cell density and only Nano-paclitaxel + Simva treated animals presented tumors with increased presence of collagen fibers I and III. In comparison to Control group, tumors from groups Simva, Paclitaxel + Simva, Nano-paclitaxel and Nano-paclitaxel + Simva showed a reduction in immunohistochemical expression of ICAM, MCP-1 and MMP-9 and the group Nano-paclitaxel + Simva presented the lowest percentage of area positively stained for MMP-9. Combined therapy with Nano-paclitaxel + Simva was less toxic and more effective in promoting tumor growth inhibiton than the same combined therapy with the commercial formulation of paclitaxel