A humanized mouse model to study mast cells mediated cutaneous adverse drug reactions.

Recently a G-protein-coupled receptor, MAS Related GPR Family Member X2 (MRGPRX2), was identified as a specific receptor on human mast cells responsible for IgE independent adverse drug reactions (ADR). Although a murine homologue, Mrgprb2, has been identified for this receptor, its affinity for many ADR-causing drugs is poor making it difficult to undertake in vivo studies to examine mechanisms of ADR and to develop therapeutic strategies. Here, we have created humanized mice capable of generating MRGPRX2-expressing human MCs allowing for the study of MRGPRX2 MCs-mediated ADR in vitro as well as in vivo. Humanized mice were generated by hydrodynamic-injection of plasmids expressing human GM-CSF and IL-3 into NOD-scid IL2R-γ-/- strain of mice that had been transplanted with human hematopoietic stem cells. These GM/IL-3 humice expressed high numbers of tissue human MCs but the MRGPRX2 receptor expressed in MCs were limited to few body sites including the skin. Importantly, large numbers of MRGPRX2-expressing human MCs could be cultured from the bone marrow of GM/IL-3 humice revealing these mice to be an important source of human MCs for in vitro studies of MRGPRX2-related MCs activities. When GM/IL-3 humice were exposed to known ADR causing contrast agents (meglumine and gadobutrol), the humice were found to experience anaphylaxis analogous to the clinical situation. Thus, GM/IL-3 humice represent a valuable model for investigating in vivo interactions of ADR-causing drugs and human MCs and their sequelae, and these mice are also a source of human MRGPRX2-expressing MCs for in vitro studies.

Impact of gadolinium-based contrast agents on the growth of fish cells lines.

The present study was the first approach conducted under environmental concentrations of Gd-DOTA and Gd-DTPA-BMA to assess cellular impacts of these compounds. Gd-DOTA (Gadoteric acid) is one of the most stable contrast agent, currently used as Dotarem® formulation during Magnetic Resonance Imaging exams. The study was mainly performed on a Zebra Fish cell line (ZF4; ATCC CRL-2050). At the concentrations of 0.127 nM and 63.59 nM (respectively 20 ng and 10 µg of Gd/L), we did not observed any toxicity of Dotarem® but a slowdown of the cell growth was clearly measured. The effect is independent of medium renewing during 6 days of cell culturing. The same effect was observed i-with Gd-DOTA on another fish cell line (RT W1 gills; ATCC CRL-2523) and ii-with another contrast agent (Gd-DTPA-BMA - Omniscan®) on ZF4 cells. On the ZF4 cell line, the diminution of the cell growth was of the same order during 20 days of exposure to a culture medium spiked with 63.59 nM of Dotarem® and was reversible within the following 8 days when Dotarem® was removed from the medium. As shown by using modified DOTA structure (Zn-DOTA), the effect may be due to the chelating structure of the contrast agent rather than to the Gd ion. Until now, the main attention concerning the impact of Gd-CA on living cells concerned the hazard due to Gd release. According to our results, quantifying the presence of Gd-CA chelating structures in aquatic environments must be also monitored.

Absence of potential gadolinium toxicity symptoms following 22,897 gadoteric acid (Dotarem®) examinations, including 3,209 performed on renally insufficient individuals.

OBJECTIVES: Recent safety concerns regarding gadolinium-based contrast agents (GdCAs) concluded with the suspension of some agents from the European market, yet a clinical consequence remains unknown. We used electronic health records to investigate the incidence of potential toxicity to gadoteric acid (Dotarem®) within our local population, including those with renal insufficiency (RI). METHODS: Data for patients who underwent contrast-enhanced MRI were identified, stratified by renal function at time of scan and retrospectively followed using routinely collected health data. Searches performed were: records of hypersensitivity reactions; diagnoses of nephrogenic systemic fibrosis (NSF); onset of chronic pain, a symptom that has been associated with NSF and the theorised gadolinium deposition disease (GDD); and post-contrast acute kidney injury (PC-AKI). Comparisons were made between patients and controls (those who underwent non-contrast scans) via chi-square and ANOVA statistical tests. RESULTS: Of the 22,897 contrast-enhanced MRI scans performed locally from 2004-2016 (adult, n = 22,325 and paediatric, n = 572), 14% were performed on patients with RI (30 ≤ eGFR < 60, n = 2,622; 15 ≤ eGFR < 30, n = 464; eGFR < 15, n = 123). Two adult patients (0.01%) suffered hypersensitivity reactions. Zero cases of NSF were reported, with an average follow-up time of 6.0 ± 2.5 years (range, 8 months-15 years). Analysis failed to highlight statistically higher rates of chronic pain onset post-MRI (adult: p = 0.777, paediatric: p = 0.578), or PC-AKI (adult: p = 0.566, paediatric: p = 0.841), in the patient groups compared to controls. CONCLUSIONS: These data indicate that administration of gadoteric acid to RI patients does not result in a higher rate of signs or symptoms that may be associated with gadolinium toxicity when compared to controls. KEY POINTS: • Following 22,897 administrations of gadoteric acid to a local population, there was no association with symptoms that may be associated with gadolinium toxicity. • Zero cases of nephrogenic systemic fibrosis were reported following 3,209 gadoteric acid administrations to a cohort of renally insufficient patients. • A low number of hypersensitivity reactions were observed (0.01%) and no higher rate of chronic pain or post-contrast acute kidney injury were noted when compared with a control cohort of non-contrast-enhanced examinations.

Embryonic toxico-pathological effects of meglumine antimoniate using a chick embryo model.

Leishmaniasis is one of the diverse and neglected tropical diseases. Embryo-toxicity of drugs has always been a major concern. Chick embryo is a preclinical model relevant in the assessment of adverse effects of drugs. The current study aimed to assess embryonic histopathological disorders and amniotic fluid biochemical changes following meglumine antimoniate treatment. The alteration of vascular branching pattern in the chick's extra-embryonic membrane and exploration of molecular cues to early embryonic vasculogenesis and angiogenesis were also quantified. Embryonated chicken eggs were treated with 75 or 150 mg/kg of meglumine antimoniate. Embryo malformations, growth retardation and haemorrhages on the external body surfaces were accompanied by histopathological lesions in the brain, kidney, liver and heart in a dose-dependent manner. Significant rise occurred in the biochemical indices of alkaline phosphatase, aspartate aminotransferase, alanine aminotransferase and amylase in the amniotic fluid. Quantification of the extra-embryonic membrane vasculature showed that the anti-angiogenic and anti-vasculogenic effects of the drug were revealed by a significant decrease in fractal dimension value and mean capillary area. The relative expression levels of vascular endothelial growth factor A and vascular endothelial growth factor receptor 2 mRNA also significantly reduced. Concerns of a probable teratogenicity of meglumine antimoniate were established by data presented in this study. It is concluded that tissue lesions, amniotic fluid disturbance, altered early extra-embryonic vascular development and gene expression as well as the consecutive cascade of events, might eventually lead to developmental defects in embryo following meglumine antimoniate treatment. Therefore, the use of meglumine antimoniate during pregnancy should be considered as potentially embryo-toxic. Hence, physicians should be aware of such teratogenic effects and limit the use of this drug during the growing period of the fetus, particularly in rural communities. Further pharmaceutical investigations are crucial for planning future strategies.

Non-clinical safety assessment of gadoterate meglumine (Dotarem(®)) in neonatal and juvenile rats.

The purpose of this study was to assess the safety of gadoterate meglumine, a gadolinium-based contrast agent used in magnetic resonance imaging, in neonatal and juvenile rats. Rats received a single intravenous administration on postnatal day (PND) 10 or 6 administrations (from PND 10 to 30), at doses of 0, 0.6, 1.25, and 2.5 mmol/kg/administration, i.e. equivalent to approximately 1, 2 and 4-times the usual human dose. The animals were sacrificed at the end of the treatment period or after a 60-day treatment-free period. No mortality and no significant treatment-related effect on clinical signs, macroscopic and histopathological findings, development, behavior, sexual maturation and hematology parameters were observed. Minor non-adverse changes were observed in clinical biochemistry and urinary parameters. Based on AUC0-t, gadoterate meglumine was more rapidly eliminated at PND 30 vs. PND 10, reflecting maturation of kidney function. At the end of the treatment period, Gd was measurable in all organs sampled after single or repeated dosing and levels were dose-dependent as expected, the highest ones being found in kidneys. The total Gd concentrations were similar in all the organs following a single or repeated dosing. At the end of the treatment-free period, only traces of gadolinium were quantifiable, almost exclusively in kidneys, reflecting the excretory function of this organ. In conclusion, single or repeated administration of gadoterate meglumine to juvenile rats was well tolerated.

In-vitro sensitivity of Pakistani Leishmania tropica field isolate against buparvaquone in comparison to standard anti-leishmanial drugs.

In this study, in vitro anti-leishmanial activity of buparvaquone was evaluated against promastigotes and intracellular amastigotes of Pakistani Leishmania tropica isolate KWH23 in relation to the current standard chemotherapy for leishmaniasis (sodium stibogluconate, sodium stibogluconate, amphotericin B and miltefosine). For buparvaquone, mean % inhibition in intracellular amastigotes at four different concentrations (1.35 µM, 0.51 µM, 0.17 µM and 0.057 µM) was 78%, 44%, 20% and 14% respectively, whereas, against promastigotes it was 89%, 77%, 45% and 35% respectively. IC50 values calculated to estimate the anti-leishmanial activity of buparvaquone against intra-cellular amastigotes and promastigotes was 0.53 µM (95% C.I. = 0.32-0.89) and 0.15 µM (95% C.I. = 0.01-1.84) respectively. Amphotericin B was the most potent in-vitro drug tested, with an IC50 of 0.075 µM (95% C.I. = 0.006-0.907) against promastigotes, and 0.065 µM (95% C.I. = 0.048-0.089) against intra-cellular amastigotes. Amphotericin B was more cytotoxic against THP1 cells, with an IC50 of 0.15 µM (95% C.I. = 0.01-0.95) and an apparent in-vitro therapeutic index of 2.0, than was buparvaquone, with an IC50 of 12.03 µM (95% C.I. = 5.36-26.96) against THP1 cells and a therapeutic index of 80.2. The study proposes that buparvaquone may be further investigated as a candidate drug for treatment of cutaneous leishmaniasis.

Soy isoflavones have antimutagenic activity on DNA damage induced by the antileishmanial Glucantime (meglumine antimoniate).

Isoflavones are phytoestrogens reported to be potent antioxidant agents. In contrast, the antileishmanial meglumine antimoniate has mutagenic activities. This study evaluated the ability of soy isoflavones to reduce DNA damage induced by meglumine antimoniate. Antimutagenic effects (by micronucleus test) were tested using Swiss mice divided into seven groups treated with meglumine antimoniate (425 mg/kg bw pentavalent antimony); cyclophosphamide (50 mg/kg bw); water (negative control); single isoflavones dose (1.6 mg/kg bw), and three groups received one dose of isoflavones via gavage (0.4 mg/kg bw, 0.8 mg/kg bw or 1.6 mg/kg bw) plus meglumine antimoniate via intraperitoneal, simultaneously. To evaluate antigenotoxicity (by Comet assay), each group with 10 animals received the above-mentioned control doses; single dose of isoflavones 0.8 mg/kg bw, and three groups received isoflavones (0.8 mg/kg bw) by gavage along with intraperitoneal meglumine antimoniate, which were treated with isoflavones 24 h before or after receiving meglumine antimoniate (pre-treatment and post-treatment, respectively) or simultaneously. Cells were harvested 24 h after the treatment, and the data were evaluated by ANOVA followed by Tukey's test (p < 0.05). The data from the simultaneous treatment by micronucleus test revealed that isoflavones (0.4 and 0.8 mg/kg) were able to reverse the mutagenic effect of Glucantime. Moreover, all regimes of the treatment with 0.8 mg/kg bw dose were able to reduce the genotoxicity caused by meglumine antimoniate. It is suggested that the protective effect of isoflavones against DNA damage is related to their ability to reduce oxidative stress caused by the trivalent Sb(III) metabolite of meglumine antimoniate.

Effects of in utero and lactational exposure to SbV on rat neurobehavioral development and fertility.

Meglumine antimoniate (MA) is a pentavalent antimony drug used to treat leishmaniases. We investigated the neurobehavioral development, sexual maturation and fertility of the offspring of MA-treated rats. Dams were administered MA (0, 75, 150, 300 mg Sb(V)/kg body wt/d, sc) from gestation day 0, throughout parturition and lactation, until weaning. At the highest dose, MA reduced the birth weight and the number of viable newborns. In the male offspring, MA did not impair development (somatic, reflex maturation, weight gain, puberty onset, open field test), sperm count, or reproductive performance. Except for a minor effect on body weight gain and vertical exploration in the open field, MA also did not affect the development of female offspring. Measurements of the Sb levels (ICP-MS) in the blood of MA-treated female rats and their offspring demonstrated that Sb is transferred to the fetuses via the placenta and to the suckling pups via milk.

Association of water extract of green propolis and liposomal meglumine antimoniate in the treatment of experimental visceral leishmaniasis.

This work investigated the use of water extract of green propolis (WEP) and its association with free or liposomal meglumine antimoniate (MA) for the treatment of murine visceral leishmaniasis. Mice infected with Leishmania infantum were treated with oral doses of WEP associated or not with a single dose of liposomal MA by intraperitoneal route. Parasite burden was assessed in the liver and spleen by limiting dilution assay, and alterations in the spleen cellular phenotype were evaluated by flow cytometry. Tissue damage was assessed by determination of biochemical markers of the liver, heart, and kidney function and histopathological analysis of the liver and spleen. Our data showed that treatment with WEP was able to reduce parasite load in the liver but not in the spleen. On the other hand, liposomal MA reduced parasite load in both organs. Unexpectedly, there was no synergism with the combination of WEP and liposomal MA in reducing the parasite load. The histopathological analysis showed that administration of WEP, liposomal MA, or their association was able to protect the liver and spleen from lesions caused by infection. No alteration in the profile of spleen cells by flow cytometry or in the liver, heart, and kidney functions by biochemical markers due to any of the treatments was observed. These results demonstrate that although WEP was able to significantly reduce the liver parasite load, its association with liposomal MA did not lead to significant improvement in reducing parasite load. On the other hand, treatment with WEP and/or liposomal MA protected the liver and spleen from lesions caused by the infection.

Neolignan Licarin A presents effect against Leishmania (Leishmania) major associated with immunomodulation in vitro.

Leishmaniasis' treatment is based mostly on pentavalent antimonials or amphotericin B long-term administration, expensive drugs associated with severe side effects. Considering these aforementioned, the search for alternative effective and safe leishmaniasis treatments is a necessity. This work evaluated a neolignan, licarin A anti-leishmanial activity chemically synthesized by our study group. It was observed that licarin A effectively inhibited Leishmania (Leishmania) major promastigotes (IC50 of 9.59 ± 0.94 µg/mL) growth, by inducing in these parasites genomic DNA fragmentation in a typical death pattern by apoptosis. Additionally, the neolignan proved to be even more active against intracellular amastigotes of the parasite (EC50 of 4.71 ± 0.29 µg/mL), and significantly more effective than meglumine antimoniate (EC50 of 216.2 ± 76.7 µg/mL) used as reference drug. The antiamastigote activity is associated with an immunomodulatory activity, since treatment with licarin A of the infected macrophages induced a decrease in the interleukin (IL)-6 and IL-10 production. This study demonstrates for the first time the antileishmanial activity of licarin A and suggests that the compound may be a promising in the development of a new leishmanicidal agent.

Skin gadolinium following use of MR contrast agents in a rat model of nephrogenic systemic fibrosis.

PURPOSE: To detect the ultrastructural site of gadolinium retention in skin by using an animal model of nephrogenic systemic fibrosis and compare a linear, low-stability gadolinium chelate (formulated gadodiamide) with a macrocylic, high-stability gadolinium chelate (gadoterate meglumine). MATERIALS AND METHODS: Experimental procedures were performed according to rules and regulations laid down by the UK Home Office (Animal Procedures Act of 1986). Male Wistar rats were subjected to 5/6 subtotal nephrectomy (creatinine clearance, 25% normal). Gadolinium-based contrast agents, formulated gadodiamide (n = 9) and gadoterate meglumine (n = 11), were administered intravenously (2.5 mmol/kg for 5 days). After 28 days, skin was analyzed by means of morphometric and immunohistochemical techniques and electron microscopy. Data were compared with the Student t test. Skin gadolinium was located by means of energy-filtered transmission electron microscopy. RESULTS: Formulated gadodiamide produced a 40-fold greater increase in gadolinium in skin than did gadoterate meglumine. An electron-dense filamentous material, detected within extracellular matrix, displayed a "halo" appearance, associated with collagen fibrils and electron-dense intracellular fragments of collagen fibrils within activated fibroblasts. Both electron-dense features demonstrated the presence of gadolinium but were much less apparent following gadoterate meglumine administration, where the presence of gadolinium was not detected. Formulated gadodiamide increased dermal cell count, dermal thickness, and collagen bundle density with enhanced immunostain for CD34, fibroblast-specific protein 1,4-hydroxy-prolyl-hydroxylase, and factor XIIIa. Circular staining for α-smooth muscle actin indicated new blood vessel formation. Skin of rats receiving gadoterate meglumine remained unchanged. CONCLUSION: Gadolinium retention in skin following formulated gadodiamide administration was located to the collagen fibril, in both the extracellular matrix and within activated fibroblasts.

An experimental approach to studying the effectiveness and safety of meglumine antimoniate formulations.

Among the problems associated to leishmaniasis, the two most outstanding ones are the lack of a vaccine and the adverse effects caused by drugs use for its control. Meglumine antimoniate compounds are the first-line drugs in the treatment for cutaneous leishmaniasis (the most prevalent form of the disease in Colombia); nevertheless, they are far from being ideal drugs due to their toxicity (not to mention the emergence of drug-resistant parasites), all of which has prompted current search for new strategies to improve their safety. This work assesses the effectiveness and safety (toxicity including new aspects related with immunotoxicity not reported previously) of two different meglumine antimoniate formulations using an in vitro and in vivo murine model. The results evidence that although both injectable formulations induce an equally efficient (clearance of intracellular parasites), both give rise to adverse effects, including a preferential immunomodulation on Balb/c mice and in a lesser proportion on ICR mice. These results are comparable to human trials reporting variable reactions when following the same treatment regimen. The model presented herein is proposed as a tool for evaluating the effectiveness and safety of meglumine antimoniate-based antileishmanial formulations.

Genotoxic effects of the antileishmanial drug Glucantime.

Leishmaniasis is caused by species of the protozoan parasite Leishmania. It is the third most important vector-borne disease and is widely distributed throughout the world. The World Health Organization recommends pentavalent antimonials as drugs of first choice in its treatment. Although Glucantime has traditionally been used to treat leishmaniasis, there are still many questions about its structure, mechanisms of action and ability to induce damage in DNA. In this study, the genotoxic activity of this drug was evaluated in vitro using human lymphocytes treated for 3 and 24 h (comet assay) and 48 h (apoptosis assay) with 3.25, 7.5 and 15 mg/ml of Glucantime, respectively, corresponding to 1.06, 2.12 and 4.25 mg/ml of pentavalent antimony. In the in vivo tests, Swiss mice received acute treatment with three doses (212.5, 425 and 850 mg/kg) of pentavalent antimony. All the treatments were administered intraperitoneally in the volumes of 0.1 ml/10 g of body weight, adapting human exposure to murine conditions. The animals were treated for 3 h in the comet assay using resident peritoneal exudate macrophages, for 24 h in the comet assay using peripheral blood leukocytes and for 24 h in the bone marrow erythrocyte micronucleus test. While no genotoxic effect was observed in the in vitro tests, the in vivo tests showed that Glucantime induces DNA damage. These findings indicate that Glucantime is a promutagenic compound that causes damage to DNA after reduction of pentavalent antimony (SbV) into the more toxic trivalent antimony (SbIII) in the antimonial drug meglumine antimoniate.

Administration of miltefosine and meglumine antimoniate in healthy dogs: clinicopathological evaluation of the impact on the kidneys.

In canine leishmaniosis (CanL), kidneys are affected in virtually all dogs. Treatment of CanL is limited in Europe to meglumine antimoniate and miltefosine. This study evaluated the pharmacological, toxicological, and pathological effects of both drugs in healthy beagle dogs. Four male and four female dogs were divided into two groups. The animals in Group 1 were administered an oral solution of 2% of miltefosine at 2 mg/kg b.w. once a day, for twenty-eight days. The animals in Group 2 were administered a preparation of meglumine antimoniate at 100 mg/kg b.w. subcutaneously once a day for twenty-eight days. After treatment, all dogs were followed-up for a further twenty-eight days. Dogs were observed daily and clinically examined ten times throughout the study. On days -1 and 55 a renal biopsy was performed on all dogs and analyzed by light microscopy, immunofluorescence, and electron microscopy. All the examinations failed to demonstrate any lesions in the miltefosine-treated dogs. Conversely, all the meglumine antimoniate-treated dogs demonstrated severe tubular damage, characterized by tubular cell necrosis and apoptosis. In conclusion, although no clinical signs of renal disease were evident, the use of meglumine antimoniate in the pharmacological treatment approach of CanL-affected dogs should be carefully considered.

Reduced tissue parasitic load and infectivity to sand flies in dogs naturally infected by Leishmania (Leishmania) chagasi following treatment with a liposome formulation of meglumine antimoniate.

The toxicity and antileishmanial effectiveness of a novel liposome formulation of meglumine antimoniate in mongrel dogs with visceral leishmaniasis (VL) obtained from a region where VL is endemic in Brazil have been investigated. Groups of 12 animals received by the intravenous route four doses (with 4-day intervals) of either liposomal meglumine antimoniate (group I [GI], 6.5 mg Sb/kg of body weight/dose), empty liposomes (GII), or isotonic saline (GIII). Evaluation of markers of hematopoietic, hepatic, and renal functions before and just after treatment showed no significant change. On the other hand, transitory adverse reactions, including prostration, defecation, tachypnea, and sialorrhea, were observed during the first 15 min after injections in GI and GII. Parasitological evaluation of sternal bone marrow 4 days after the last dose showed a significant reduction of parasite burden in GI, compared to the other groups. Immunocytochemical evaluations of the skin, bone marrow, cervical lymph nodes, livers, and spleens of dogs for parasites, 150 days after treatment, indicated significant parasite suppression (higher than 95.7%) in the lymph nodes, livers, and spleens of GI, compared to control groups. Feeding of Lutzomyia longipalpis phlebotomines on dogs from GI, 150 days after treatment, resulted in a significant reduction of sand fly infection efficiency, compared to feeding on animals from GII and GIII. This is the first report of both long-term parasite suppression and reduction of infectivity to sand flies in naturally infected dogs following treatment with a liposome-encapsulated drug. Importantly, this was achieved using a 20-fold-lower cumulative dose of Sb than is used for conventional antimonial treatment.

[Evaluation of the cumulative effect of meglumine antimoniate on the progeny of swiss mice: biologic assay]. / Avaliação do efeito cumulativo do antimoniato de meglumina sobre a prole de camundongos swiss: ensaio biológico.

OBJECTIVES: Evaluate the effect of Meglumine Antimoniate on maternal-fetal transference in F1 generations (offspring of dams exposed to the drug), and embryotoxicity in F2 generations. METHODS: Female Swiss mice were treated with daily s.c. injection of Meglumine Antimoniate (100mgSb v/kg bw/day) from day 7 until day 12 of pregnancy. The control group received only the vehicle (distilled water). After birth of offspring (F1 generation), 59 females were examined daily for determination of the estral cycle. When the cycle estrus was determined, males were mated with 18 females of the same lineage. On day 18 of pregnancy, females were euthanasied in a chamber of CO2 and after incision of the abdomen, the uterus was exposed. Then, resorptions as well as living and dead fetuses were evaluated, also the number of embryo/fetal implantation sites. Fetuses and their placenta were weighted to calculate the placental index. Three placentas of each litter were separated for microscopic analysis. RESULTS: Administration of the Meglumine Antimoniate did not interfere in the estral cycle of the treated group, since it did not alter the precoital interval and fertility index. Placenta alterations were not observed in the F2 generations. CONCLUSION: Meglumine Antimoniate did not interfere in the reproductive performance, after chronic exposition of dams. Data suggest that there is a gradual elimination of Meglumine Antimoniate by the maternal organism without damaging the future offspring.

In vitro evaluation of the effectiveness and cytotoxicity of meglumine antimoniate microspheres produced by spray drying against Leishmania infantum.

The aim of the present study was to evaluate the in vitro activity and cytotoxicity of meglumine antimoniate microspheres produced by spray drying on Leishmania infantum and the effect of the excipients used in them. The parasite strain shows sensitivity to the meglumine antimoniate microspheres prepared. All the antimony IC50 values from encapsulated meglumine antimoniate (3.80 +/- 0.34 to 9.53 +/- 0.70 microg SbV/ml for promastigotes assay) are considerably lower compared to the mean value of IC50 in Glucantime solution (112 +/- 12.74 microg SbV/ml). Interesting IC50 values for the excipient chitosan (112.64 +/- 0.53 mg/ml for promastigotes and 100.81 +/- 26.45 mg/ml for amastigotes) were obtained (without cytotoxic activity), whereas the rest of the excipients did not show any activity. This new delivery system could offer a new pharmacological tool for the treatment of leishmaniosis that reduces the doses required, lowering toxic side effects because of meglumine antimoniate.

Avaliação do efeito cumulativo do antimoniato de meglumina sobre a prole de camundongos swiss: ensaio biológico / Evaluate the cumulative effect of meglumine antimoniate on the progeny of swiss mice: biologic assay

OBJETIVOS: Avaliar o efeito do antimoniato de meglumina na transferência materno-fetal na geração F1 (prole de matrizes expostas ao composto), e conseqüências em progênies F2. MÉTODOS: Camundongos fêmeas Swiss foram tratados com antimoniato de meglumina, via subcutânea, com administração diária, do sétimo ao 12º dia de gestação (ddg), na dose equivalente a 100mgSb v/kg peso/dia. O grupo controle recebeu apenas o veículo (água destilada). Após o nascimento da prole (geração F1), 59 fêmeas foram examinadas diariamente para determinação do ciclo estral. Quando determinado o ciclo estro, acasalou-se 18 fêmeas com machos da mesma linhagem. No 18º ddg, as fêmeas foram eutanasiadas por câmara de CO2, o abdômen incisado e o útero exposto, quando avaliou-se os sítios de desenvolvimento embrionário e fetal quanto ao número de reabsorções, fetos vivos e mortos. Todos os fetos e placentas foram pesados para calcular o índice placentário. Três placentas de cada ninhada foram separadas para análise microscópica. RESULTADOS: A exposição ao antimoniato de meglumina não interferiu no ciclo estral dos animais tratados, pelo fato de não alterar o intervalo precoital e o índice de fertilidade. Não foram observadas alterações placentárias em progênies F2. CONCLUSÃO: O antimoniato de meglumina não altera a performance reprodutiva das mães expostas cronicamente. Estes dados sugerem que ocorre uma gradual eliminação do antimoniato de meglumina no organismo materno, sem acarretar danos a proles futuras.

OBJECTIVES: Evaluate the effect of Meglumine Antimoniate on maternal-fetal transference in F1 generations (offspring of dams exposed to the drug), and embryotoxicity in F2 generations. METHODS: Female Swiss mice were treated with daily s.c. injection of Meglumine Antimoniate (100mgSb v/kg bw/day) from day 7 until day 12 of pregnancy. The control group received only the vehicle (distilled water). After birth of offspring (F1 generation), 59 females were examined daily for determination of the estral cycle. When the cycle estrus was determined, males were mated with 18 females of the same lineage. On day 18 of pregnancy, females were euthanasied in a chamber of CO2 and after incision of the abdomen, the uterus was exposed. Then, resorptions as well as living and dead fetuses were evaluated, also the number of embryo/fetal implantation sites. Fetuses and their placenta were weighted to calculate the placental index. Three placentas of each litter were separated for microscopic analysis. RESULTS: Administration of the Meglumine Antimoniate did not interfere in the estral cycle of the treated group, since it did not alter the precoital interval and fertility index. Placenta alterations were not observed in the F2 generations. CONCLUSION: Meglumine Antimoniate did not interfere in the reproductive performance, after chronic exposition of dams. Data suggest that there is a gradual elimination of Meglumine Antimoniate by the maternal organism without damaging the future offspring.

Pentoxifylline prevents the meglumine antimonate-induced renal toxicity in rats, but not that induced by the inorganic antimony pentachloride.

Tumor necrosis factor-alpha (TNF-alpha) is a mediator of inflammation and has an important role in human and experimental renal diseases. Pentoxifylline (PTX) has been shown to inhibit cytokine synthesis, including TNF-alpha. The aim of the present study was to examine the effect of PTX on meglumine antimonate (Sb(V)) and antimony pentachloride (SbCl(5))-induced renal toxicity in rats. Sixty Wistar rats were divided into six groups according to the treatment employed over the period of 7 days: group I-saline (NaCl 0.9%); group II-PTX plus saline; group III-meglumine antimonate (Sb(V)) plus saline; group IV-meglumine antimonate (Sb(V)) plus PTX; group V-SbCl(5) plus saline; group VI-SbCl(5) with PTX. The animals' urinary concentration ability was evaluated before and after the end of the treatment. Urine and blood osmolality, sodium and creatinine concentration, and urine volume per minute (V) were determined. Creatinine clearance (CrCl), fractional sodium excretion (FE(Na)), and urine to plasma osmolality ratio (U/P osm) were calculated. TNF-alpha concentration in blood was assessed. On the seventh day, the animals were sacrificed and their kidneys were submitted to histological analysis. The meglumine antimonate (Sb(V))-treated animals showed an impaired renal capacity to concentrate urine, with low values of the ratio U/P osm, reduction in CrCl, and an increment in TNF-alpha serum levels. PTX associated with meglumine antimonate (Sb(V)) reduced TNF-alpha serum levels and was effective in preventing renal functional alterations. Rats treated with SbCl(5) showed functional and histopathologic alterations compatible with acute tubular necrosis, and treatment with PTX did not prevent SbCl(5)-induced nephrotoxicity. PTX was effective in preventing renal functional alterations induced by meglumine antimonate (Sb(V)) in rats.

Toxicological assessment of gadolinium release from contrast media.

In vivo gadolinium release was evaluated for MultiHance, Omniscan and Gadovist estimating gadolinium content in liver, kidneys, spleen, femur and brain after single or repeated intravenous administrations to rats at 1 mmol/kg. Gadolinium acetate (GdAc) at a daily dose of 0.03 mmol/kg and physiological saline were used as positive and negative controls, respectively. No changes in blood chemistry, haematology nor histopathology were seen with any of the tested contrast media, whereas an increase in white blood cell count and in serum cholesterol were found after GdAc at 0.18 mmol/kg cumulative dose. Analogously, gadolinium content in target organs (as % of injected dose) after any of contrast media was 100-200 times lower than after GdAc, either after single or repeated administrations. Under these experimental conditions, the rank of residual gadolinium found in these organs was GdAcOmniscan >Gadovist >MultiHance. Depopulation of lymphocytes in periarteriolar lymphatic sheaths (PALS) areas of the spleen was noted in rats treated with a single dose of GdAc sacrificed 24h post-dosing, but not in repeated dose rats sacrificed 48 h after last dosing. It was, therefore, concluded that this was a transient phenomenon and that PALS are rapidly repopulated with lymphocytes. With all contrast media, gadolinium content after a 2-day washout following a 3-week repeated administration period was lower than the amount found 24h after a single administration. Accordingly, the observed gadolinium content in organs should actually be in a complexed form (possibly the injected complex) which is subjected to elimination.