Your search keyword '"Vilas-Boas C"' showing total 10 results

1. Oxidation of metal thin films by atomic oxygen: A low energy ion scattering study.

Author

Stilhano Vilas Boas, C. R., Sturm, J. M., and Bijkerk, F.

Subjects

*ION scattering, *OXYGEN, *METALLIC films, *THIN films, *ION energy, *TANTALUM

Abstract

In this study, we combine low-energy ion scattering (LEIS) static and sputter depth profiles for characterization of the oxidation kinetics on Zr, Mo, Ru, and Ta films of various thicknesses, followed by exposure to atomic oxygen at room temperature (∼20 °C). A method for nondestructive determination of the oxide growth rate via LEIS static depth profiling (static DP) is presented in detail. This method shows high sensitivity to the oxide thickness formed, and the results are in agreement with those obtained by X-ray reflectometry and sputter depth profiling (sputter DP). Sequential exposures of oxygen isotopes in combination with LEIS sputter DP are applied to elucidate the growth mechanism of the oxide films. The results indicate that the oxidation kinetics at the applied experimental conditions is directly influenced by the metal work function, characterizing a Cabrera-Mott growth type. The maximum thickness of the formed oxide and oxide growth rate are in the order Zr ≈ Ta > Mo > Ru. The combining of analysis by LEIS static DP and isotope tracing sputter DP is decisive in the characterization of oxidation kinetics in the room temperature regime. [ABSTRACT FROM AUTHOR]

Published

2019

2. Safyre: A versatile self-anchoring re-adjustable sling

Author

Palma, P., primary, Riccetto, C., additional, Dambros, M., additional, Thiel, M., additional, Fraga, R., additional, Vilas-Boas, C., additional, and Netto, N., additional

Published

2003

3. Preliminary hazard assessment of a new nature-inspired antifouling (NIAF) agent.

Author

Vilas-Boas C, Sousa J, Lima E, Running L, Resende D, Ribeiro ARL, Sousa E, Santos MM, Aga DS, Tiritan ME, Ruivo R, Atilla-Gokcumen GE, and Correia-da-Silva M

Subjects

Animals, Water Pollutants, Chemical toxicity, Aliivibrio fischeri drug effects, Xanthones toxicity, Mytilus drug effects, Mytilus physiology, Diatoms drug effects, Humans, Daphnia drug effects, Daphnia physiology, Artemia drug effects, Biofouling prevention & control

Abstract

A recently synthesized aminated 3,4-dioxygenated xanthone (Xantifoul2) was found to have promising antifouling (AF) effects against the settlement of the macrofouler Mytilus galloprovincialis larvae. Preliminary assessment indicated that Xantifoul2 has reduced ecotoxicological impacts: e.g., being non-toxic to the marine crustacea Artemia salina (<10 % mortality at 50 μM) and showing low bioconcentration factor in marine organisms. In order to meet the EU Biocidal Product Regulation, a preliminary hazard assessment of this new nature-inspired antifouling (NIAF) agent was conducted in this work. Xantifoul2 did not affect the swimming ability of the planktonic crustacean Daphnia magna, the growth of the diatom Phaeodactylum tricornutum, and the cellular respiration of luminescent Gram-negative bacteria Vibrio fischeri, supporting the low toxicity towards several non-target marine species. Regarding human cytotoxicity, Xantifoul2 did not affect the cell viability of retinal human cells (hTERT-RPE-1) and lipidomic studies revealed depletion of lipids involved in cell death, membrane modeling, lipid storage, and oxidative stress only at a high concentration (10 μM). Accelerated degradation studies in water were conducted under simulated sunlight to allow the understanding of putative transformation products (TPs) that could be generated in the aquatic ecosystems. Both Xantifoul2 and photolytic-treated Xantifoul2 in the aqueous matrix were therefore evaluated on several nuclear receptors (NRs). The results of this preliminary hazard assessment of Xantifoul2, combined with the high degradation rates in water, provide strong evidence of the safety of this AF agent under the evaluated conditions, and provide the support for future validation studies before this compound can be introduced in the market., Competing Interests: Declaration of competing interest Marta Correia-da-Silva has patent Xanthonic compounds and their use as antifouling agents issued to CN113226035. Emilia Sousa has patent Xanthonic compounds and their use as antifouling agents issued to CN113226035. If there are other authors, they declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2024

4. 3,4-Dioxygenated xanthones as antifouling additives for marine coatings: in silico studies, seawater solubility, degradability, leaching, and antifouling performance.

Author

Vilas-Boas C, Silva ER, Resende D, Pereira B, Sousa G, Pinto M, Almeida JR, Correia-da-Silva M, and Sousa E

Subjects

Ecosystem, Solubility, Seawater, Biofouling prevention & control, Disinfectants toxicity

Abstract

Marine biofouling pollution is a process that impacts ecosystems and the global economy. On the other hand, traditional antifouling (AF) marine coatings release persistent and toxic biocides that accumulate in sediments and aquatic organisms. To understand the putative impact on marine ecosystems of recently described and patented AF xanthones (xanthones 1 and 2), able to inhibit mussel settlement without acting as biocides, several in silico environmental fate predictions (bioaccumulation, biodegradation, and soil absorption) were calculated in this work. Subsequently, a degradation assay using treated seawater at different temperatures and light exposures was conducted for a period of 2 months to calculate their half-life (DT 50 ). Xanthone 2 was found to be non-persistent (DT 50  < 60 days) at 50 μM, contrary to xanthone 1 (DT 50  > 60 days). To evaluate the efficacy of both xanthones as AF agents, they were blended into four polymeric-based coating systems: polyurethane- and polydimethylsiloxane (PDMS)-based marine paints, as well as room-temperature-vulcanizing PDMS- and acrylic-based coatings. Despite their low water solubility, xanthones 1 and 2 demonstrated suitable leaching behaviors after 45 days. Overall, the generated xanthone-based coatings were able to decrease the attachment of the Mytilus galloprovincialis larvae after 40 h. This proof-of-concept and environmental impact evaluation will contribute to the search for truly environmental-friendly AF alternatives., (© 2023. The Author(s).)

Published

2023

5. Gallic acid derivatives as inhibitors of mussel (Mytilus galloprovincialis) larval settlement: Lead optimization, biological evaluation and use in antifouling coatings.

Author

Rita Neves A, Vilas Boas C, Gonçalves C, Vasconcelos V, Pinto M, Silva ER, Sousa E, Almeida JR, and Correia-da-Silva M

Subjects

Animals, Ecosystem, Gallic Acid pharmacology, Larva, Biofouling prevention & control, Disinfectants pharmacology, Mytilus

Abstract

The addition of biocides to marine coatings has been the most used solution to avoid marine biofouling, however they are persistent, bioaccumulative, and toxic (PBT) to marine ecosystems. The development of natural products or Nature-inspired synthetic compounds to replace these harmfull biocides has been pursued as one of the most promising antifouling (AF) alternatives. Following a bioprospection strategy, we have previously reported the AF activity of gallic acid persulfate (1) against the settlement of Mytilus galloprovincialis larvae (EC 50  = 18 µM and LC 50 /EC 50  = 27) without exhibiting ecotoxicity to Artemia salina. In this work, a lead optimization strategy was applied to compound 1 in order to improve potency while maintaining a low ecotoxicity profile. In this direction, twenty-seven compounds were synthesized, from which eighteen were obtained for the first time. An AF screening was performed against the settlement of mussel M. galloprovincialis larvae and derivative 26, 2-(3,4,5-trihydroxybenzamido)ethan-1-aminium bromide, was found to be more potent (EC 50  = 3 µM and LC 50 /EC 50  = 73) than compound 1 and the biocide Econea® (EC 50  = 4 µM). The potential impact on neurotransmission, and ecotoxicity against two non-target marine organisms was also evaluated. Marine polyurethane (PU)-based coatings containing compound 26 were prepared and lower adherence of mussel larvae was observed compared to compound 26 free PU-coatings. Studies concerning the leaching of compound 26 from the prepared coating were also conducted, and < 10% of this compound was detected after 45 days of submersion in water. Overall, we have optimized the potency against the settlement of mussels of our initial lead compound, not compromising the toxicity and compatibility with PU-based coatings., (Copyright © 2022 Elsevier Inc. All rights reserved.)

Published

2022

6. Quantification of a Sulfated Marine-Inspired Antifouling Compound in Several Aqueous Matrices: Biodegradation Studies and Leaching Assays from Polydimethylsiloxane Coatings.

Author

Vilas-Boas C, Gonçalves V, Marco P, Sousa E, Pinto M, Silva ER, Tiritan ME, and Correia-da-Silva M

Subjects

Dimethylpolysiloxanes, Gallic Acid, Seawater chemistry, Sulfates, Sulfur, Water, Biofouling prevention & control

Abstract

The development of marine-inspired compounds as non-toxic antifouling (AF) agents has been pursued in the last years. Sulfur is the third most common element in seawater. Sulfur is present in oxygenated seawater as sulfate anion (SO 4 2- ), which is the most stable combination of sulfur in seawater, and several promising AF secondary metabolites with sulfate groups have been described. However, sulfated compounds proved to be an analytical challenge to quantify by HPLC. Taking these facts into consideration, this work presents the development and validation of a method for the quantification of gallic acid persulfate (GAP) in seawater and ultrapure water matrix, based on hydrophilic interaction liquid chromatography (HILIC). This method was used to evaluate GAP stability following several abiotic and biotic degradation assays, and to quantify its release in seawater from room-temperature-vulcanizing polydimethylsiloxane commercial coating. GAP was very stable in several water matrices, even at different pH values and in the presence/absence of marine microorganisms and presented a leaching value lower than 0.5%. This work discloses HILIC as an analytical method to overcome the difficulties in quantifying sulfated compounds in water matrices and highlights the potential of GAP as a promising long-lasting coating.

Published

2022

7. Impact of Tralopyril and Triazolyl Glycosylated Chalcone in Human Retinal Cells' Lipidome.

Author

Vilas-Boas C, Running L, Pereira D, Cidade H, Correia-da-Silva M, Atilla-Gokcumen GE, and Aga DS

Subjects

Humans, Lipidomics, Lipids, Pyrroles, Chalcone analysis, Chalcone pharmacology, Chalcones analysis, Disinfectants toxicity, Water Pollutants, Chemical chemistry

Abstract

Antifouling (AF) coatings containing booster biocides are used worldwide as one of the most cost-effective ways to prevent the attachment of marine organisms to submerged structures. Nevertheless, many of the commercial biocides, such as Econea ® (tralopyril), are toxic in marine environments. For that reason, it is of extreme importance that new efficient AF compounds that do not cause any harm to non-target organisms and humans are designed. In this study, we measured the half-maximal inhibitory concentration (IC 50 ) of a promising nature-inspired AF compound, a triazolyl glycosylated chalcone (compound 1 ), in an immortalized human retinal pigment epithelial cell line (hTERT-RPE-1) and compared the results with the commercial biocide Econea ® . We also investigated the effects of these biocides on the cellular lipidome following an acute (24 h) exposure using liquid chromatography quadrupole time-of-flight mass spectrometry (LC-Q-TOF/MS). Our results showed that compound 1 did not affect viability in hTERT-RPE-1 cells at low concentrations (1 μM), in contrast to Econea ® , which caused a 40% reduction in cell viability. In total, 71 lipids were found to be regulated upon exposure to 10 µM of both compounds. Interestingly, both compounds induced changes in lipids involved in cell death, membrane modeling, lipid storage, and oxidative stress, but often in opposing directions. In general, Econea ® exposure was associated with an increase in lipid concentrations, while compound 1 exposure resulted in lipid depletion. Our study showed that exposure to human cells at sublethal Econea ® concentrations results in the modulation of several lipids that are linked to cell death and survival.

Published

2022

8. Multidimensional characterization of a new antifouling xanthone: Structure-activity relationship, environmental compatibility, and immobilization in marine coatings.

Author

Vilas-Boas C, Neves AR, Carvalhal F, Pereira S, Calhorda MJ, Vasconcelos V, Pinto M, Sousa E, Almeida JR, Silva ER, and Correia-da-Silva M

Abstract

The accumulation of marine biofouling on ship hulls causes material damage, the spread of invasive species, and, indirectly, an increase in full consumption and subsequent pollutant gas emissions. Most efficient antifouling (AF) strategies rely on the conventional release of persistent, bioaccumulative, and toxic biocides incorporated in marine coatings. A simple oxygenated xanthone, 3,4-dihydroxyxanthone (1), was previously reported as a promising AF agent toward the settlement of Mytilus galloprovincialis larvae, with a therapeutic ratio higher than the commercial biocide Econea®. In this work, a structure-AF activity relationship study, an evaluation of environmental fate, and an AF efficiency in marine coatings were performed with compound 1. Hydroxy or methoxy groups at 3 and 4 positions in compound 1 favored AF activity, and groups with higher steric hindrances were detrimental. Compound 1 demonstrated low water-solubility and a short half-life in natural seawater, contrary to Econea®. In silico environmental fate predictions showed that compound 1 does not bioaccumulate in organism tissues, in contrast to other current emerging biocides, has a moderate affinity for sediments and slow migrates to ground water. No toxicity was observed against Vibrio fischeri and Phaeodactylum tricornutum. Polyurethane-based marine coatings containing compound 1 prepared through an innovative non-release-strategy were as efficient as those containing Econea® with low releases to water after 45 days. This proof-of-concept helped to establish compound 1 as a promising eco-friendly AF agent., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2021

9. One Step Forward towards the Development of Eco-Friendly Antifouling Coatings: Immobilization of a Sulfated Marine-Inspired Compound.

Author

Vilas-Boas C, Carvalhal F, Pereira B, Carvalho S, Sousa E, Pinto MMM, Calhorda MJ, Vasconcelos V, Almeida JR, Silva ER, and Correia-da-Silva M

Subjects

Animals, Dimethylpolysiloxanes chemistry, Half-Life, Mytilus growth & development, Polyurethanes chemistry, Seawater, Solubility, Sulfates chemistry, Time Factors, Biofouling prevention & control, Gallic Acid chemistry, Polymers chemistry

Abstract

Marine biofouling represents a global economic and ecological challenge and few eco-friendly antifouling agents are available. The aim of this work was to establish the proof of concept that a recently synthesized nature-inspired compound (gallic acid persulfate, GAP) can act as an eco-friendly and effective antifoulant when immobilized in coatings through a non-release strategy, promoting a long-lasting antifouling effect. The synthesis of GAP was optimized to provide quantitative yields. GAP water solubility was assessed, showing values higher than 1000 mg/mL. GAP was found to be stable in sterilized natural seawater with a half-life (DT 50 ) of 7 months. GAP was immobilized into several commercial coatings, exhibiting high compatibility with different polymeric matrices. Leaching assays of polydimethylsiloxane and polyurethane-based marine coatings containing GAP confirmed that the chemical immobilization of GAP was successful, since releases up to fivefold lower than the conventional releasing systems of polyurethane-based marine coatings were observed. Furthermore, coatings containing immobilized GAP exhibited the most auspicious anti-settlement effect against Mytilus galloprovincialis larvae for the maximum exposure period (40 h) in laboratory trials. Overall, GAP promises to be an agent capable of improving the antifouling activity of several commercial marine coatings with desirable environmental properties.

Published

2020

10. An antifouling model from the sea: a review of 25 years of zosteric acid studies.

Author

Vilas-Boas C, Sousa E, Pinto M, and Correia-da-Silva M

Subjects

Cinnamates chemistry, Conservation of Natural Resources, Environmental Pollution, Solubility, Sulfates, Sulfuric Acid Esters chemistry, Zosteraceae metabolism, Biofouling prevention & control, Biological Products pharmacology, Cinnamates pharmacology, Sulfuric Acid Esters pharmacology

Abstract

Many studies have shown that natural marine compounds can prevent biofouling by a broad spectrum of organisms without toxic effects, encouraging their use in antifouling (AF) coatings. Studies over the past 25 years of the natural product zosteric acid (ZA) are systematically organized in this review. ZA is a sulfated phenolic acid produced by the seagrass Zostera marina that has very promising AF potential against several micro- and macrofouling organisms. ZA was shown to have appropriate environmental fate parameters such as high water solubility, a low log P, low bioaccumulation, and no ecotoxicity, which demonstrated the potential of ZA as a safe AF agent. This review also highlights that ZA has been successfully incorporated into several types of coatings. The synthesis of analogs is also considered in this review, and it has allowed a better understanding of ZA structure-AF activity relationships and clarified the mechanism of action of ZA.

Published

2017