Hospital Infection is a major health problem and affects around 1.5 million people annually around the world. The Amazon region has a wide diversity of native palm trees that have fruits and oilseeds. Astrocaryum vulgare, commonly known as Tucumã in Brazil, belongs to the family Arecaceae. This palm has orange, fleshy, single-egg-shaped fruits that are used for therapeutic purposes in diseases of the eyes and skin due to the high content of carotenoids, oil is used in cooking, health treatment and massage. This study evaluated the antimicrobial activity of the Tucumã oil against 18 microorganisms. The antimicrobial activity of Tucumã was measured through the determination of the Minimum Inhibitory Concentration (MIC), as well as the determination of the Minimum Microbicidal Concentration (CMM) aiming to contribute to the discovery of new antimicrobials against pathogenic microorganisms’ human health and may contribute to the treatment of nosocomial infections. The results showed that the oil of Tucumã presented antimicrobial activity against five important bacteria, four Gram - positive bacteria (Enterococcus faecalis, Enterococcus faecium, Staphylococcus epidermidis and Streptococcus agalactiae) and one Gram - negative (Acinetobacter baumannii).
The aim of this study was to evaluate the toxicity of tucumã oil nanocapsules from the Amazon region in silver catfish, Rhamdia quelen. Fish were exposed to water treated with different concentrations of tucumã nanocapsules, white, solubilized oil and surfactant vehicles. After three days of exposure, fish were euthanized and liver, gills and brain removed for analysis of the dichlorofluorescein, nitric oxide and PicoGreen ® assays. Plasma was collected for assay of hepatic transaminases. The nanocapsules had a diameter of 221±1.27 nm, confirmed by atomic force microscopy. The oil nanocapsules were not toxic to this species of fish, but white nanocapsules and surfactant increased the levels of reactive oxygen species. Thus, nanocapsules are promising for the transport of tucumã oil. In view of the anti-inflammatory properties of this oil, it is possible to envisage its application in skin diseases for example, since they present essentially inflammatory conditions.
The chemotherapeutic all-trans retinoic acid (ATRA) used in the treatment of Acute Promyelocytic Leukemia has adverse effects on its oral administration, with which we incorporated a system of drugs, the nanocapsules, in order to have a possible improvement in solubility, photosensitivity, lower toxicity, generating pharmacological efficacy. The objective was to evaluate and compare the hemolytic and coagulation activity of the free drug (AL), nanoencapsulated (NA) and the white nanocapsules (NB) by analyzing the results of hemolysis, Prothrombin Time (PT) and Activated Partial Thromboplastin Time (APTT). We developed a prospective study of treatments at different concentrations of 0.25; 0.5; 1.0; 1.5; 2.0; 2.5 μg/mL. For the first test, all concentrations showed hemolytic activity, but when compared to NA with ATRA it is observed that these carriers induced lower hemolytic toxicity. In the PT test the nanoparticles at the two lowest concentrations remained in the physiological range (12 - 15 seconds). For the APTT test the three lowest concentrations remained within the control (25 - 35 seconds). Thus, we believe there is a promising benefit of using these nanoparticles developed and no doubt further studies will be performed to confirm the responses obtained here.
Microalgae are rapidly being employed in carbon fixation due to their benefits over other crops for energy needs, such as high photosynthetic efficiency, massive biomass production and rapid development. Spirulina maxima is a microalgae whose production is based on cultivation with favorable growing conditions. Within the Life Cycle Analysis, the steps that fed into the Impact 2002 system included assembly and cultivation, production and characterization of nanochitosan, flocculation of biomass with nanochitosan, filtration, drying, production and characterization of the nanosphere, and obtaining the microalgae filter. The production stages were evaluated regarding the environmental impacts that could be caused. To evaluate these processes, Life Cycle Analysis (LCA) was applied using SimaPro software version 8.5 and Ecoinvent 3 database with the "Impact 2002+" impact method from the Swiss Federal Institute of Technology. Characterization and normalization data were considered. The impact categories that stood out the most in relation to the release of particulates into the atmosphere by carrying out the steps are carcinogenic, non-carcinogenic, inorganic breathables, depletion of the ozone layer, organic breathables, global warming, non-renewable energy. Within the category of carcinogens (Kg C 2 H 3 Cl eq), there is a total of 1.81 kg C 2 H 3 Cl eq of released particulates, for non-carcinogens a total of 3.91 Kg C 2 H 3 Cl eq of released particulates, inorganic breathables have a total of 0 0418 kg of particulates released during the stages, for the category of damage and destruction of the ozone layer, expressed there is a total of 1.35 E-6 divided between the stages, the organic breathables totaled 0.00771, for the global warming category expressed in kg CO 2 eq we have a total of 24.1 and within the non-renewable energy category we have a total of 352 MJ. As a final result, after evaluating the main categories of risks present during the LCA process, the main category of environmental impact was "Damage to human health". The result obtained is due to the high consumption of electricity.
To present a possible new alternative for wound treatment, this work evaluated the biological safety and therapeutic efficacy of graphene oxide (GO) and reduced graphene oxide (rGO) nanoparticles (NPs). First, the nanostructures were studied in silico and showed to be able to inhibit the production of some pro-inflammatory cytokines and stimulate the production of the anti-inflammatory cytokine IL-10, especially rGO. The results of the morphological and structural characterization of GO NPs synthesized from the Hummers method and reduced by ascorbic acid, were consistent with the literature, confirming their achievement. In the broth microdilution assay, GO and rGO showed antimicrobial activity against the clinical isolate of Streptococcus agalactiae (S. agalactiae) at a minimum inhibitory concentration (MIC) of 625 µg/mL for GO and 312.5 µg/mL for rGO. In addition, the nanostructure of rGO was able to inhibit, in subinhibitory concentration, the formation of S. agalactiae biofilm by up to 77% when compared to the positive control. Both NPs, in all tested concentrations, did not cause hemolysis, and alterations in coagulation in vitro assays. However, in the safety tests, it was evidenced that only the MIC of 312, µg/mL for rGO was biologically safe and presented anti-inflammatory and healing behavior in vitro. In general, the present work confirmed rGO's potential in the treatment of chronic wounds, since in silico showed anti-inflammatory behavior and in vitro showed therapeutic efficacy at low concentrations, prevented biofilm formation, and showed no significant toxic effects.
The search for new drugs can be accelerated by in silico methods, i.e., fully computational methods known for their speed and low cost, allowing the analysis of a large amount of data, e.g., thousands of possible antimicrobials, in a few weeks. Molecular docking and first-principles calculations are great allies in this quest. They enable the assessment of protein-ligand interactions and can predict interactions between NPs and macromolecules to provide more information about the interactions and dynamics of NPs in biological systems. In this context, this work aims to use in silico methods to detect the formation of biogenic metallic nanoparticles from functional microalgal biomolecules of the genus Chlorella, which have chelation of metal ions as a fundamental property, and to verify the possible antibacterial biofilm efficacy using computational tools such as molecular docking. In a first analysis, it was found that the iron salt FeSO4 was the most suitable to bind the microalgal enzyme and produce its phytochelatin protein. Following this result, an analysis of the electronic structure of the phytochelatin complex with the iron salt was carried out, proving its structural modification at the nanometric level, after which an analysis of its therapeutic effect on antibiofilm activity was performed. S. aureus, a bacterium known for its multiresistant to antibiotics, these results demonstrate, through alternative in silico methods, the physiological role of phytochelatin from microalgae in the detoxification and bioremediation of metallic contaminants.
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