ABSTRACT
Antimoniais pentavalentes são considerados medicamentos de primeira linha no tratamento das diferentes formas de leishmaniose. O perfil de segurança dos medicamentos à base de antimônio (Sb), entretanto, ainda não foi completamente elucidado. O objetivo deste conjunto de estudos que constam desta tese foi fornecer informações adicionais sobre a segurança de um curso de tratamento com o antimoniato de meglumina (AM). O primeiro estudo investigou o acúmulo e eliminação do Sb do sangue e órgãos de ratos machos adultos tratados com uma dose diária de AM, por um período de 21 dias consecutivos. Foi observado que o antimônio é lentamente eliminado. O segundo estudo avaliou o desenvolvimento pós-natal da prole nascida e amamentada por ratas tratadas na gestação e lactação até o desmame com AM. A transferência de Sb através da placenta e via leite materno para a prole foi determinada. Os resultados mostraram, em geral, que o desenvolvimento pós-natal e a fertilidade dos ratos expostos não foram alterados. Os dados também sugerem que o Sb passa facilmente para o leite e está presente nesta matriz biológica em uma forma química que o torna bem absorvido pelos lactentes. Além disso, nós também investigamos se as atividades das enzimas citocromo P450 hepáticas (CYP), que participam do metabolismo de endo- e xenobióticos, foram alteradas pelo tratamento. Os resultados mostraram que um curso de tratamento de 24 dias com AM causou um consistente declínio das atividades de CYP1A no fígado de camundongos SW e DBA-2, e uma diminuição nas atividades de CYP2B9/10 nas fêmeas de SW, mas não em DBA-2 de ambos os sexos...
Pentavalent antimony compounds are considered as first choice drugs to treat different clinical manifestations of leishmaniasis. The safety profile of antimony-based anti-leishmanial drugs, however, has not been entirely elucidated so far. The objective of the set of experimental studies presented in this thesis was to provide additional information on the safety of a course of treatment with meglumine antimoniate (MA). The first study was an investigation of the accumulation and clearance of antimony (Sb) in the blood and organs of adult male rats treated with a 21-day course of MA. It was observed that residual Sb is slowly eliminated from rats organs and blood. The second study evaluated the postnatal development of the offspring born to and nursed by rats treated during gestation and lactation until weaning with MA. The transfer of Sb via placenta and mothers milk to the offspring was determined as well. Results showed that offspring postnatal development and fertility remained virtually unaltered after treatment with MA. Data suggested that Sb is transferred into breast milk and is present there in a chemical form that makes this metalloid bioavailable to suckling pups. Furthermore, we investigated whether activities of liver cytochrome P450 enzymes that take part in the metabolism of endogenous and exogenous substances were altered after a course of treatment with MA. It was found that a 24-d course of treatment with MA caused a consistent decline in CYP1A activity in the mouse liver. A decrease of CYP2B9/10 activity was noted in SW females but not in SW males and in DBA-2 of either sex...
Subject(s)
Animals , Antimony/therapeutic use , Leishmaniasis/therapy , Metalloids , Meglumine/therapeutic use , /toxicity , RodentiaABSTRACT
Meglumine antimoniate (MA) and sodium stibogluconate are pentavalent antimony (SbV) drugs used since the mid-1940s. Notwithstanding the fact that they are first-choice drugs for the treatment of leishmaniases, there are gaps in our knowledge of their toxicological profile, mode of action and kinetics. Little is known about the distribution of antimony in tissues after SbV administration. In this study, we evaluated the Sb content of tissues from male rats 24 h and three weeks after a 21-day course of treatment with MA (300 mg SbV/kg body wt/d, subcutaneous). Sb concentrations in the blood and organs were determined by inductively coupled plasma-mass spectrometry. In rats, as with in humans, the Sb blood levels after MA dosing can be described by a two-compartment model with a fast (t1/2 = 0.6 h) and a slow (t1/2 >> 24 h) elimination phase. The spleen was the organ that accumulated the highest amount of Sb, while bone and thyroid ranked second in descending order of tissues according to Sb levels (spleen >> bone, thyroid, kidneys > liver, epididymis, lungs, adrenals > prostate > thymus, pancreas, heart, small intestines > skeletal muscle, testes, stomach > brain). The pathophysiological consequences of Sb accumulation in the thyroid and Sb speciation in the liver, thyroid, spleen and bone warrant further studies.
Subject(s)
Antimony/analysis , Antiprotozoal Agents/pharmacokinetics , Meglumine/pharmacokinetics , Organometallic Compounds/pharmacokinetics , Animals , Antiprotozoal Agents/administration & dosage , Dose-Response Relationship, Drug , Male , Meglumine/administration & dosage , Meglumine Antimoniate , Organometallic Compounds/administration & dosage , Rats, Wistar , Time Factors , Tissue DistributionABSTRACT
Meglumine antimoniate (MA) and sodium stibogluconate are pentavalent antimony (SbV) drugs used since the mid-1940s. Notwithstanding the fact that they are first-choice drugs for the treatment of leishmaniases, there are gaps in our knowledge of their toxicological profile, mode of action and kinetics. Little is known about the distribution of antimony in tissues after SbV administration. In this study, we evaluated the Sb content of tissues from male rats 24 h and three weeks after a 21-day course of treatment with MA (300 mg SbV/kg body wt/d, subcutaneous). Sb concentrations in the blood and organs were determined by inductively coupled plasma-mass spectrometry. In rats, as with in humans, the Sb blood levels after MA dosing can be described by a two-compartment model with a fast (t1/2 = 0.6 h) and a slow (t1/2 >> 24 h) elimination phase. The spleen was the organ that accumulated the highest amount of Sb, while bone and thyroid ranked second in descending order of tissues according to Sb levels (spleen >> bone, thyroid, kidneys > liver, epididymis, lungs, adrenals > prostate > thymus, pancreas, heart, small intestines > skeletal muscle, testes, stomach > brain). The pathophysiological consequences of Sb accumulation in the thyroid and Sb speciation in the liver, thyroid, spleen and bone warrant further studies.
