Comparing the efficacy of nutmeg essential oil and a chemical pesticide against Musca domestica and Chrysomya albiceps for selecting a new insecticide agent against synantropic vectors.

The insecticidal activity of Myristica fragrans (Houtt) essential seed oil, (Nutmeg) was evaluated against Musca domestica (Linnaeus) and Chrysomya albiceps (Wiedemann); both important infectious pathogenic disease vectors. The oil was extracted by distillation, and 21 components were identified during chemical analysis; principally ß-pinene (26%), α-pinene (10.5%), Sabinene (9.1%) and γ-terpinen (8.5%). Insecticidal properties were identified through larvicide and adulticide tests. Using the immersion method, the oil at 5% was found to be very effective (90 ± 1%) against M. domestica larvae. The results for adulticide activity varied by fly species, dosage, time, and method of exposure. Topical application (on the insect thorax) was more toxic to C. albiceps, where the lethal concentration at 50% (LC50) was 2.02 ± 0.56, and 8.57 ± 2.41 for the common flies. When the insects were exposed to oil impregnated paper, the results were similar for M. domestica and C. albiceps adults with respective LC50 values of 2.74 ± 0.24, and 3.65 ± 0.48. Thus, the results demonstrated that M. fragrans oil presents insecticidal activity and can be used for control of Musca domestica and Chrysomya albiceps.

Trypanosoma evansi impacts on embryonic neural progenitor cell functions.

Trypanosoma evansi appears to have a significant tropism for brain tissue in its chronic and acute phases. The most common symptoms of this brain infection are motor incoordination, meningoencephalitis, demyelination, and anemia. There have only been few studies of the effects of T. evansi infection on neuronal differentiation and brain plasticity. Here, we investigated the impact of the congenital T. evansi infection on brain development in mice. We collected telencephalon-derived neural progenitor cells (NPCs) from T. evansi uninfected and infected mice, and cultivated them into neurospheres. We found that T. evansi significantly decreased the number of cells during development of neurospheres. Analysis of neurosphere differentiation revealed that T. evansi infection significantly increased neural migration. We also observed that T. evansi promoted expression of glial fibrillary acidic protein (GFAP) in infected cells. These data suggest that congenital T. evansi infection may affect embryonic brain development.

Disturbance of energetic homeostasis and oxidative damage provoked by trichlorfon as relevant toxicological mechanisms using silver catfish as experimental model.

Recent evidences have suggested the involvement of phosphoryl transfer, catalyzed by creatine kinase (CK), adenylate kinase (AK) and pyruvate kinase (PK), to metabolic alterations and impairment of bioenergetics homeostasis linked to adenosine triphosphate (ATP) production, and utilization during exposure to pesticides. It is recognized that sublethal concentrations of trichlorfon alter hepatic and branchial metabolism, but the pathways involved in this process remains unknown. Thus, the aim of this study was to evaluate whether phosphoryl transfer network can be a pathway involved in the hepatic and branchial metabolic alterations during exposure to sublethal concentrations of trichlorfon using silver catfish Rhamdia quelen as experimental model. Hepatic and branchial CK (cytosolic and mitochondrial isoforms) and PK activities were inhibited after 48 h of exposure to 11 and 22 mg/L trichlorfon compared to control group, while AK activity did not differ between groups. In addition, sodium-potassium pump (Na+, K+-ATPase) activity was lower after 48 h of exposure to 22 mg/L trichlorfon compared to control group. Thiobarbituric acid reactive substances (TBARS) were higher in liver samples after 24 h of exposure to 22 mg/L trichlorfon compared to control group, as well as after 48 h of exposure to 11 and 22 mg/L trichlorfon in liver and gills. Finally, hepatic and branchial non-protein thiol (NPSH) levels were lower after 48 h of exposure to 11 and 22 mg/L trichlorfon. All evaluated parameters did not recover after 48 h in clean water. Based on these evidence, the impairment of phosphoryl transfer network can be considered a pathway involved in the hepatic and branchial metabolic alterations during exposure to sublethal concentrations of trichlorfon. Moreover, alterations on CK and PK activities provoke an impairment on Na+, K+-ATPase activity, which can be mediated by lipid oxidative damage and reduction of NPSH content.