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Purpose: This work aims to evaluate the effects of the different meshes constructed in MIKE 3 software on the simulation and calibration results of the model. Theoretical framework: 3D hydrodynamic models, such as MIKE 3, provide the closest representation of reality by simulating the gradients in the three spatial dimensions and solutioning the Navier-Stokes equations. In these models, meshes are used to represent complex geometries. An efficient computational mesh is required to allow convergence and stability of the solution of the equations and, furthermore, of the modelling result. Method/design/approach: Simulation of four meshes with distinct discretization, calibration, comparison, and assessment of the model performance for these four conceptual models considering: mesh’s number of elements, simulation time, mean absolute error (MAE), coefficient of determination (R2), and relative difference. Results and conclusions: For the meshes adopted for comparison, refinement only in the “throat” (region near the dam) did not show significant influences on the results that would justify its use, considering the high computational cost. Therefore, in this case, a sparse mesh and without refinement can be used in detriment of a mesh with refinement only in the “throat”. Research implication: Understand how different meshes discretization can significantly alter simulation time and highlight that optimized simulation requires an equilibrium between simulation time and mesh discretization to maintain model’s performance. Originality/value: Understanding and quantifying the influence of the discretization of the model's mesh on the simulation time and the performance of the model allows the optimization of the modeling, considering the cost-effectiveness of different discretizations leading to smaller simulation time with similar performance.
Purpose: This work aims to evaluate the effects of the different meshes constructed in MIKE 3 software on the simulation and calibration results of the model. Theoretical framework: 3D hydrodynamic models, such as MIKE 3, provide the closest representation of reality by simulating the gradients in the three spatial dimensions and solutioning the Navier-Stokes equations. In these models, meshes are used to represent complex geometries. An efficient computational mesh is required to allow convergence and stability of the solution of the equations and, furthermore, of the modelling result. Method/design/approach: Simulation of four meshes with distinct discretization, calibration, comparison, and assessment of the model performance for these four conceptual models considering: mesh’s number of elements, simulation time, mean absolute error (MAE), coefficient of determination (R2), and relative difference. Results and conclusions: For the meshes adopted for comparison, refinement only in the “throat” (region near the dam) did not show significant influences on the results that would justify its use, considering the high computational cost. Therefore, in this case, a sparse mesh and without refinement can be used in detriment of a mesh with refinement only in the “throat”. Research implication: Understand how different meshes discretization can significantly alter simulation time and highlight that optimized simulation requires an equilibrium between simulation time and mesh discretization to maintain model’s performance. Originality/value: Understanding and quantifying the influence of the discretization of the model's mesh on the simulation time and the performance of the model allows the optimization of the modeling, considering the cost-effectiveness of different discretizations leading to smaller simulation time with similar performance.
Objective: This study aims to present an assessment of the potential for reusing effluents from domestic sewage treatment plants in the Hydrographic Basin of the Ipojuca River. Theoretical Framework: In regions facing water scarcity, effluent reuse emerges as an alternative to alleviate pressures and reduce contamination of water sources. In this regard, the choice of the Ipojuca River Watershed is justified due to the susceptibility of its constituent municipalities to water scarcity and pollution, as well as the fact that the Ipojuca River has been classified as the third most polluted in the country. Methodology: The methodology involved basin characterization, data collection from the sanitation services provider to perform quantitative and qualitative evaluation of reclaimed water supply, identification of demands based on consumptive uses (industry and irrigation), existing water use permits, and the provider's customer database. Additionally, georeferenced maps were generated for spatial analysis of the water balance. Results and Conclusion: Twelve Sewage Treatment Plants were identified, four of which are still under construction, with nominal treatment capacities exceeding the identified irrigation and industrial demands, except for two of them. In terms of quality, for the analyzed parameters, the treatment plants demonstrated satisfactory performance, suggesting that the effluent could be utilized for restricted purposes without the need for further treatment. Lastly, geospatially, the demands are located within a radius of 10km from the analyzed plants, in most cases. Research Implications: It can be inferred that the basin holds a significant reuse potential to be explored as an alternative for enhancing water availability and reducing effluent discharge into the Ipojuca River. Originality/Value: The results obtained through this unprecedented analysis in the watershed serve as a reference for policymakers and implementers of water resources management policies, as well as an encouragement for potential producers and consumers of reclaimed water.
Filamentous fungi are a rich source of bioactive compounds, which make them a promising resource for the discovery of new drugs. Objective: The objective of this study was to systematically review research data on bioactive compounds of filamentous fungi with biological activity. Theoretical Frame: This study used, as a theoretical basis, the literature published in the Medline, Web of Science and Science Direct databases in the period from 2012 to 2021, with the main citations: Main Items for Reporting Systematic Reviews and Meta-analyses (PRISMA) and Meta-Analysis of Statistics Assessment and Review Instrument (MASTARI). Method: A systematic electronic search was conducted in the Medline (PubMed), Web of Science (WoS) and Science Direct databases, using the descriptors “Filamentous fungi” AND “Bioactive compounds”, in order to identify articles related to the selected topic. The articles were selected by three independent reviewers among those published in English in the last 10 years. Results and Conclusions: The search resulted in 151 articles, of which 8 met the inclusion criteria and were eligible for bias risk assessment using six quality criteria. Filamentous fungi are a large and promising source of bioactive compounds due to various biological activities such as strong inhibition of phosphodiesterase 4B, cytotoxicity against cancer cells, and antimicrobial, immunosuppressive, antibacterial, antifungal, antiviral and anti-inflammatory activities. In view of the results, further efforts are hoped to discover new drugs from filamentous fungi. Currently, several studies are being developed with different strains of filamentous fungi collected in different environments, such as forests, sea, icy regions and soil. Aspergillus and Penicillium are among the most studied genera. These fungi produce several bioactive compounds, some already reported and others recently discovered. In vitro and in silico studies are being used to test the different biological activities provided by bioactive compounds; therefore, the results of these researches are very promising for the discovery of new drugs. Additionally, further studies are needed to test these activities in in vivo models. The results obtained are of great relevance for medicine and the pharmaceutical industry, as they bring an update of the main bioactive compounds and their biological activities from biodiversity, which can be used in the development of new drugs capable of fighting different diseases. Still, they can help the academic and scientific community about what has been studied and what remains to be researched. In the future, other species and strains of fungi can be studied, aiming to discover new bioactive compounds with biological activity; for this, fungi can be collected from different environments, such as forests, sea and soil microbiota, or isolated from plants, extreme and remote environments. In this way, it would be possible to make better use of the world's biodiversity, use molecular-based approaches and tools and produce resources capable of improving the quality of human life. Implications of the research: This study is highly relevant for the purposes of the Programa de Pós-Graduação em Saúde e Desenvolvimento Socioambiental da Universidade de Pernambuco, Campus Garanhuns, as well as for the entire academic, scientific and pharmaceutical community interested in discovering new bioactive compounds with biological activity. Originality and value: The study sought to present to the academic, scientific and pharmaceutical community what is currently being researched on bioactive compounds of filamentous fungi with biological activity, providing current information and main researchers, indicating what remains to be investigated and collaborating for the environmental and social management of the sector of health.
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