Photoacoustic study of percutaneous absorption of Carbopol and transdermic gels for topic use in skin

Topical medicine application has been used to treat a good number of pathological processes. Its efficacy is associated to an efficient penetration of the drug in the internal skin layers, promoting systemic effects and excluding the possibility of drug degradation by the digestive tract and hepatic elimination. This work analyzes the penetration kinetics of two soluble bases employed as vehicles for topic application: superficial gel (Carbopol 940) and transdermic (transdermal) gel. Analysis was performed with the photoacoustic technique, based upon the absorption of modulated light by a sample with subsequent conversion of the absorbed energy in heat, generating acoustic waves in the air layer adjacent to the sample. Each of the two vehicles was evaluated through in vivo (human skin) and in vitro application. Measurements in vitro employed samples of VitroSkin (synthetic material with properties similar to those of real skin, employed in the pharmaceutical industry research). Results show that the permeation was faster for the transdermal gel, both for in vivo and in vitro measurements, indicating that in vitro measurements may be utilized in qualitative, comparative permeation studies.     

A colourful bond between art and chemistry

How can a work of art give us clues about scientific aspects? How can chemistry help a painter enhance his creativity and, above all, preserve the original characteristics of his work? Does an artist require scientific knowledge to innovate or, at least, not to be faked? Other symbiotic fields between art and science are: tattoos, as body art with physical and chemical consequences; pigments, as basic materials with interesting historiographical preparations; spectroscopy diagnosis, as very broad and thorough method of analysis (but also specific and non-intrusive); biosensors, as one of the applications of new pigments. Note also the interconnection between the several possible paths of science and art, which reflect new challenges with enormous potential investigated through a literature review and the application as a case study in an educational inquiry module.     

The relationship between the antimicrobial activity of eugenol and the LPETG peptide structure and associated analysis for docking purposes

Sortase A is responsible for the virulence of Gram-positive pathogens, including staphylococci and streptococci. The LPETG is the peptide surface anchor signal for Sortase A. The inhibitors of this enzyme shared similar binding pattern with substrate LPETG. Eugenol and its derivatives may act as sortase A inhibitor. The antimicrobial activity of eugenol and its derivatives was tested in vitro against bacterial strains: Staphylococcus aureus, Streptococcus mutans and Escherichia coli. All the tested derivatives demonstrated antimicrobial activity. Differences between derivatives in terms of in vitro activity and interactions between the amino acid residues were correlated in the docking analysis for the same derivatives. According to the relationship observed in this study between the antimicrobial activity of eugenol and the LPETG peptide structure, some of the eugenol derivatives proved to be more active inhibiting sortase A than eugenol against microorganisms when tested at the same concentrations.     

Self-Assembled Functionalized Graphene Nanoribbons from Carbon Nanotubes

Graphene nanoribbons (GNR) were generated in ethanol solution by unzipping pyrrolidine-functionalized carbon nanotubes under mild conditions. Evaporation of the solvent resulted in regular few-layer stacks of graphene nanoribbons observed by transmission electron microscopy (TEM) and X-ray diffraction. The experimental interlayer distance (0.49–0.56 nm) was confirmed by computer modelling (0.51 nm). Computer modelling showed that the large interlayer spacing (compared with graphite) is due to the presence of the functional groups and depends on their concentration. Stacked nanoribbons were observed to redissolve upon solvent addition. This preparation method could allow the fine-tuning of the interlayer distances by controlling the number and/or the nature of the chemical groups in between the graphene layers.     

Thermochemical Liquefaction as a Cleaner and Efficient Route for Valuing Pinewood Residues from Forest Fires

Biomass thermochemical liquefaction is a chemical process with multifunctional bio-oil as its main product. Under this process, the complex structure of lignocellulosic components can be hydrolysed into smaller molecules at atmospheric pressure. This work demonstrates that the liquefaction of burned pinewood from forest fires delivers similar conversion rates into bio-oil as non-burned wood does. The bio-oils from four burned biomass fractions (heartwood, sapwood, branches, and bark) showed lower moisture content and higher HHV (ranging between 32.96 and 35.85 MJ/kg) than the initial biomasses. The increased HHV resulted from the loss of oxygen, whereas the carbon and hydrogen mass fractions increased. The highest conversion of bark and heartwood was achieved after 60 min of liquefaction. Sapwood, pinewood, and branches reached a slightly higher conversion, with yields about 8% greater, but with longer liquefaction time resulting in higher energy consumption. Additionally, the van Krevelen diagram indicated that the produced bio-oils were closer and chemically more compatible (in terms of hydrogen and oxygen content) to the hydrocarbon fuels than the initial biomass counterparts. In addition, bio-oil from burned pinewood was shown to be a viable alternative biofuel for heavy industrial applications. Overall, biomass from forest fires can be used for the liquefaction process without compromising its efficiency and performance. By doing so, it recovers part of the lost value caused by wildfires, mitigating their negative effects.     

Entropy Boundary Conditions in the Theory of Sedimentation of Ideal Suspensions

We study a non-linear generalized initial–boundary value problem of a scalar conservation law which models the sedimentation of an ideal suspension.     

Oligochitosan Synthesized by Cunninghamella elegans,a Fungus from Caatinga (The Brazilian Savanna) Is a Better Antioxidant than Animal Chitosan

Animal chitosan (Chit-A) is gaining more acceptance in daily activities. It is used in a range of products from food supplements for weight loss to even raw materials for producing nanoparticles and hydrogel drug carriers; however, it has low antioxidant activity. Fungal oligochitosan (OChit-F) was identified as a potential substitute for Chit-A. Cunninghamella elegans is a fungus found in the Brazilian savanna (Caatinga) that produces OligoChit-F, which is a relatively poorly studied compound. In this study, 4 kDa OChit-F with a 76% deacetylation degree was extracted from C. elegans. OChit-F showed antioxidant activity similar to that of Chit-A in only one in vitro test (copper chelation) but exhibited higher activity than that of Chit-A in three other tests (reducing power, hydroxyl radical scavenging, and iron chelation). These results indicate that OChit-F is a better antioxidant than Chit-A. In addition, Chit-A significantly increased the formation of calcium oxalate crystals in vitro, particularly those of the monohydrate (COM) type; however, OChit-F had no effect on this process in vitro. In summary, OChit-F had higher antioxidant activity than Chit-A and did not induce the formation of CaOx crystals. Thus, OChit-F can be used as a Chit-A substitute in applications affected by oxidative stress.     

Thermal decomposition and spectral characterization of di[carbonatotetraamminecobalt(III)] sulfate trihydrate and the nature of its thermal decomposition products

Journal of Thermal Analysis and Calorimetry - Detailed vibrational (IR, Raman, far-IR) and thermal (TGA, TG–MS, DSC) analysis has been performed on...     

Non-edible babassu oil as a new source for energy production–a feasibility transesterification survey assisted by ultrasound

Ethyl esters of babassu oil were synthesized by alkaline catalysis to make the green production of biodiesel feasible with simple methods and available technology. Babassu oil is a transparent, light yellow oil extracted from the seeds of the babassu palm (Orbinya sp), and due to its high saturated fatty acid composition (83%), it is considered a non-inedible oil. Transesterification using ethanol represents a valid alternative to using methanol because of ethanol’s lower toxicity and the higher yield on weight compared to methanol. Statistical methodology was applied to optimize the transesterification reaction, which was promoted by ultrasonic waves and mechanical agitation. Nuclear magnetic resonance spectroscopy was used to quantify the conversion attained. Alkaline transesterification assisted by ultrasound produced the best results with respect to reaction time and the phase separation step. The model obtained showed that conversions higher than 97% may be achieved in 10 min with correct tuning of the process variables.