Search Results (10,816)

While there is some agreement on estimating construction cost contingency for “known unknowns,” there is little consensus on estimating management reserves for “unknown unknowns.” Definitions of risk and uncertainty also differ between the economics and finance literature and the cost engineering literature. This paper examines how cost engineering guidance on estimating management reserves is applied in government-sponsored project cost estimates. This lack of consensus is evident in a specific program: the management, treatment, and disposal of 212,000 cubic meters of mixed radioactive and hazardous chemical waste generated by plutonium production at the Hanford Nuclear Site. Over $30 billion has been invested in treatment facilities, vitrification plants, and laboratories analyzing gases, liquids, sludges, and salt cake from 177 aging storage tanks. The remaining construction and operating costs are highly uncertain, with estimates ranging from $300 billion to $640 billion. Analyses of alternatives for constructing Hanford waste treatment facilities assume 15% contingencies and 40% management reserves. A method is presented to compute the implicit moments of Extreme Value distributions of cost estimates for different options, helping determine whether one alternative’s cost estimate stochastically dominates others. Adopting industry definitions of contingency and management reserves by federal government agencies could improve construction cost estimation in government-financed programs. Full article

Currently, gold nanoparticles are increasingly used in targeted drug delivery nanostructures. However, their intrinsic catalytic activity is often overlooked when using them as a carrier. In this study, the interaction between the sotalol drug from the beta-blocker family and gold nanoparticles was investigated using capillary electrophoresis and high-performance liquid chromatography. Both methods showed that sotalol undergoes catalytic oxidation on the surface of citrate-stabilized gold nanoparticles into three products. Together with a cleavage of the isopropyl group from the nitrogen atom, the oxidation at the hydroxyl group occurs with the formation of a ketone. Analysis of electropherograms showed 100% conversion of sotalol after 48 h of incubation at a surface coverage of 1.2 × 10¹⁹ molecules per m². To examine the role of reactive oxygen species, the experiments were performed in oxygen-saturated and oxygen-deficient gold nanoparticle dispersions. The effects of radical scavenger additives and pH of nanoparticle dispersion were also assessed. The influence of surface ligands on sotalol conversion was studied using gold nanoparticles coated with thiols, surfactants, and polyelectrolytes. Based on comprehensive data, the mechanism of gold-nanoparticle-assisted multicenter oxidation of sotalol is proposed. Full article

This work focuses on the production of biodiesel from Nannochloropsis sp. microalgae. The study compares the effectiveness of conventional methods, such as Soxhlet extraction and the Bligh and Dyer method with a non-conventional method that uses an ionic liquid as solvent for lipid extraction. The Bligh and Dyer method demonstrated superior efficiency with a lipid yield of 8.19% compared to Soxhlet extraction. Sample parameters were optimized in a maximum lipid yield of 18.29% at a sample volume of 91.9 mL, a duration of 7 min, and a power rate of 0.62 W. We further investigated the use of ionic liquids for lipid extraction from microalgae. We synthesized ionic liquids, and 1-(4 sulphonic acid) butyl-3-Methyl imidazolium hydrogen sulphate and 1-(4 sulphonic acid) butyl pyridinium hydrogen sulphate were characterized using FTIR, NMR and TGA. This method showed lipid extraction efficiency values of 10.7% and 0.402%. Subsequent transesterification of algal oil using 1-(4 sulphonic acid) butyl-3-Methyl imidazolium hydrogen sulphate yielded 19.82% biodiesel. FTIR analysis confirmed the presence of lipids and esters in the biodiesel, and the produced biodiesel met ASTM specifications, indicating its suitability for use as biofuel. Full article

Introduction: Post-infectious bronchiolitis obliterans (PIBO) is a rare and severe chronic lung disease. Our goal was to characterize respiratory epithelium in children with PIBO, which remains unexplored, using an ex vivo model culture. Methods: Proximal bronchial biopsies from children with PIBO and reconstituted bronchial epithelium from PIBO patients (n = 3) and controls (n = 17) were analyzed using an air–liquid interface culture model. Epithelial cell composition, barrier integrity, and mediator production, including mucins, inflammatory and antiviral responses, were assessed in this pathological and functional approach. Results: Epithelial thickness was assessed in PIBO biopsies. Ex vivo reconstituted PIBO epithelia appeared to exhibit comparable cohesion and cell composition to controls. Mucin expression and secretion were likewise similar between groups. PIBO epithelial might have displayed reduced IL-33 transcript levels and decreased TSLP secretion, whereas IFN-λ1, IFN-λ2-3 and IFN-β secretion could have been elevated. No differences were detected in remodeling markers (MMP-9 and YKL-40). Conclusions: In summary, ex vivo model of PIBO epithelia suggested that the epithelium may preserve structural characteristics and mucin production, without evidence of remodeling. However, PIBO epithelial cells may have a distinct immune profile, with lower alarmin expression and higher interferon secretion. This could indicate a tendency toward enhanced antiviral response rather than structural changes. These preliminary results need to be confirmed in larger cohorts. Full article

Rapeseed press cake (RPC), the protein-rich residue from edible oil production, is currently underutilized and is primarily used as animal feed. This study aimed to investigate pressurized liquid extraction (PLE) for protein recovery from RPC using response surface methodology (RSM) with precipitation yield (PY) as the response variable. Following alkaline extraction, proteins were precipitated at their isoelectric point, and solid residues were freeze-dried to obtain protein powders. Conventional extraction (CE) under magnetic stirring at room temperature was used as a reference. The results demonstrated that increasing pH from 8 to 11 significantly enhanced protein extraction efficiency for both methods. PLE exhibited superior performance, achieving higher PY compared to CE while drastically reducing extraction time from 120 min (CE) to 6 min (PLE). Optimal conditions were identified at a solid-to-liquid ratio of 0.10 g/mL, 150 °C, and 6 min, yielding a PY of 14.9%, protein recovery in extract (PR_E) of 43.8%, and protein recovery in precipitated mass (PR_P) of 20.0%, with a protein content (PC_P) of 647.2 mg albumin eq./g. RSM analysis identified extraction temperature as the most critical parameter for PLE, highlighting its dominant role in mass transfer. Finally, amino acid (AA) analysis revealed that protein powders were rich in essential AAs, with glutamic and aspartic acids being the most abundant. Additionally, PLE-derived protein powders exhibited enhanced solubility. This study confirms PLE as a highly promising and time-efficient technique for protein recovery from RPC, supporting the potential of sustainable valorization of agro-industrial by-products and promoting a circular economy model within the food industry. Full article

The discovery of melatonin as a multifunctional free radical scavenger and its possible synthesis in the mitochondrial matrix of peripheral eukaryotic somatic cells highlights a critical new perspective on the importance of this indole. Experimental evidence supporting these findings is substantial, but there are still lingering questions whether melatonin is a direct radical scavenger in vivo and whether it is synthesized in the mitochondrial matrix. We systematically analyze the innovative experimental approaches that support melatonin’s radical scavenging actions and assess the compelling data supporting its production in mitochondria. Melatonin concentrations are reportedly higher in this organelle than in other cellular compartments. Proteins for the enzymes required to convert serotonin to melatonin are present in the mitochondrial matrix and purified mitochondria synthesize melatonin. In the mitochondrial matrix, melatonin is likely located within the “damage radius” of highly reactive oxygen species. We also summarize novel actions of melatonin associated with its regulation of membrane fluidity, determine the molecular composition of membrane lipid rafts, and modulate liquid–liquid phase separation and biomolecular condensates intracellularly. If the findings discussed herein continue to be validated, melatonin would be in an optimal position to function as an antioxidant and may be a key driver in the context of preserving mitochondrial redox homeostasis and disease mitigation. Full article

Oil enterprises face the challenge of reconciling escalating energy conservation targets with persistent production requirements, necessitating sophisticated electricity management solutions. The conventional ton-per-kWh allocation approach, often manually adjusted based on historical production and planning data, lacks a scientific basis and fails to accurately identify efficiency differences or assess energy-saving potential, making it difficult to convince participating units. To address this, we propose a dynamic spatiotemporal allocation scheme and develop a multi-objective optimization model that integrates electricity efficiency, operational stability, and production priority. The model incorporates nonlinear efficiency terms, stability components, and priority-weighted items, with constraints including total balance, monthly adjustment limits, and key area protection. Central to the efficiency term is the accurate prediction of liquid production from electricity consumption. We decompose electricity use into three components—core production electricity, auxiliary production electricity, and product transportation electricity—and derive their proportional coefficients through regression of historical data, enabling high-precision liquid production prediction via machine learning using the Light Gradient Boosting Machine (LGBM). The resulting constrained optimization problem is solved using the Sequential Least Squares Programming (SLSQP) algorithm. Validation using both simulated data and Daqing Oilfield field data demonstrates that the scheme effectively achieves electricity reduction targets while significantly mitigating associated liquid production loss, reducing it by 18.0% in simulated experiments and 32.5% in field validation compared to the conventional ton-per-kWh method. This offers a scientific and adaptive electricity management framework that supports refined energy control and facilitates the petroleum industry’s green and low-carbon transformation. Full article

The role of medicinal plants in primary healthcare and livelihoods around the world is both ancient and well-documented. Agathosma betulina (P.J. Bergius) Pillans, commonly known as ‘buchu’, has long been utilised in traditional medicine as a household remedy for various ailments and is also valued for its essential oils in the cosmetics and pharmaceutical industries. This study aimed to profile and quantify the secondary metabolites in buchu using ultra-performance liquid chromatography quadrupole time-of-flight combined with mass spectrometry (UPLC-QTOF-MS) techniques, whereby plant material from three distinct locations in the Western Cape Province, Groot Winterhoek, Citrusdal, and Cederberg, was collected. A total of 32 maker compounds were identified from buchu leaves. The results revealed a significant location-dependent variation in the accumulation of multiple classes of phytochemicals, including phenolic acids, flavonoids, saponins, terpenoids, oligosaccharides, vitamins, and steroids. Citrusdal samples had the most bioactive compounds compared to the Cederberg and Groot Winterhoek. Citrusdal had the highest flavonoid levels, while Cederberg samples were the richest in phenolic acids and Groot Winterhoek was dominant in iridoid glycoside levels. Principal component analysis (PCA) revealed distinct clusters corresponding to the three different regions, confirming chemical differences. Elucidating the distribution of secondary metabolites in this species may provide new information for possible medicinal and pharmacological uses, such as the creation of novel and enhanced organic medications and food products. These results will aid in selecting a buchu chemotype with optimal attributes for the intended therapeutic application, helping to protect wild populations from over-exploitation through cultivation. Full article

Soybean (Glycine max [L.] Merr.) seed hardness is a critical physical trait that dictates processing efficiency and end-product quality, yet the underlying genetic and metabolic regulatory networks remain poorly elucidated. To systematically decipher the mechanisms governing this complex quantitative trait, a multi-omics approach integrating a genome-wide association study (GWAS), transcriptomics, and metabolomics was conducted on a panel of 162 soybean germplasm accessions from Northeast China. Four significant quantitative trait nucleotides (QTNs) on chromosomes 15 and 19 were identified by GWAS. Subsequent RNA-seq and liquid chromatography–mass spectrometry (LC-MS) analyses comparing extreme phenotypes identified 573 differentially expressed genes (DEGs) and 784 differentially accumulated metabolites (DAMs). Joint multi-omics analysis revealed 14 consistently enriched pathways, highlighting the crucial role of secondary metabolite biosynthesis. Notably, Glyma.19G030500, which encodes an isoflavone malonyltransferase, was identified as the primary hub gene. These findings offer valuable genomic targets for the marker-assisted breeding of soybean varieties with optimized processing qualities. Full article

Invasive alien plants seriously threaten native plant biodiversity and agricultural production. The development of environmentally friendly agriculture requires sustainable weed control techniques to manage these invasive alien weeds. This study evaluated the allelopathic effects of ethanol extract from Artemisia frigida against five invasive alien plants (Ageratum conyzoides, Bidens pilosa, Ipomoea purpurea, Eclipta prostrata, and Amaranthus retroflexus). The main components in the extract were identified using high-performance liquid chromatography–tandem mass spectrometry (LC-MS/MS), and we assessed their allelopathic effects on seed germination of the five species. The results showed that the ethanol extract of A. frigida completely inhibited seed germination of all five invasive plants at 5 g·L⁻¹. Thirteen components were identified, among which 4-ethyloctanoic acid, cis-jasmone, and p-anisic acid exhibited significant inhibitory effects. Notably, 4-ethyloctanoic acid demonstrated broad-spectrum herbicidal activity. At 50 mg·L⁻¹, it completely inhibited B. pilosa growth and had the strongest inhibitory effects on A. conyzoides and E. prostrata. This compound disrupted redox homeostasis and induced oxidative stress by modulating antioxidant enzyme activities, including superoxide dismutase (SOD), peroxidase (POD), and catalase (CAT). These findings indicate that 4-ethyloctanoic acid is the main allelochemical with herbicidal potential in A. frigida, providing a theoretical basis for developing novel herbicides and environmentally friendly control techniques for invasive alien plants. Full article

Vegetables constitute an essential component of the daily diet in Albania; however, they also represent a major pathway of human exposure to pesticide residues. This study investigates the presence of pesticide residues in widely used vegetables, including leafy, fruity, root, and bulb types, and evaluates the potential dietary health risks associated with their consumption. Vegetable samples were analyzed using gas chromatography–tandem mass spectrometry (GC-MS/MS) and liquid chromatography–tandem mass spectrometry (LC-MS/MS), for the presence of 417 pesticide analytes, ensuring high analytical sensitivity and reliability. Pesticide residues were present, with 42 distinct compounds, including metabolites, found in all the analyzed samples. Notably, some of the detected substances are not currently authorized for use as plant protection products, suggesting either environmental persistence or regulatory non-compliance. Exceedances of European Union maximum residue limits (MRLs) were most frequently detected in leafy vegetables (42.31%), followed by fruity vegetables (18.75%), whereas no MRL exceedances were observed in root and bulb vegetables. According to the dietary exposure assessment conducted using European Food Safety Authority Pesticide Residue Intake Model (EFSA PRIMo model v.3.1), chronic dietary exposure to pesticide residues was below the acceptable daily intake (ADI). According to this assessment, the acute exposure exceeded the acute reference dose (ARfD) for several pesticide–vegetable combinations, particularly among children. This highlights the need for ongoing monitoring and better agricultural management techniques to reduce potential health risks related to pesticide residues in vegetables. The study results indicate the need to strengthen national monitoring programs, enforce pesticide regulations more strictly, and promote the wider adoption of integrated pest management strategies to reduce dietary pesticide exposure and protect public health in Albania. Full article

Goose blood has anticancer properties and was recorded in ancient China, but the specific molecular mechanisms underlying this effect still require further exploration. In this study, SW1990 cells were treated with goose serum or plasma, and transcriptome analysis was performed to explore the function of goose blood on cancer cells. Metabolomic profiling was also performed on goose serum, goose plasma, chicken serum, and chicken plasma to identify the bioactive substances responsible for the anticancer effect. The study examined the effects of goose plasma and serum on SW1990 cells and compared the metabolites between goose and chicken blood. Wound scratch, CCK-8, and Annexin V-PI assays showed that goose plasma and serum inhibited SW1990 cell proliferation at 24 and 48 h. Both treatments reduced cell viability, with serum inducing early and late apoptosis and plasma inducing late apoptosis. RNA sequencing (RNA-seq) identified 2259 (1418 upregulated, 841 downregulated) and 2731 (1844 upregulated, 887 downregulated) differentially expressed genes (DEGs) in the plasma and serum groups versus the negative control (NC), respectively, and 689 DEGs between the plasma and serum groups. Gene Ontology (GO) and KEGG pathway analyses revealed that the DEGs were enriched in processes such as lipid metabolism, JAK-STAT, and IL-17 pathways. Untargeted liquid chromatography–tandem mass spectrometry (LC-MS/MS) analysis identified distinct metabolites in goose and chicken blood, with unique metabolites and differential ones between groups. In SW1990 cells, four metabolite subclusters matched the plasma and serum effects. In summary, goose blood can suppress cancer cells by regulating gene expression to affect the key signaling pathways involved in cancer cell apoptosis and autophagy. Certain metabolites present at high concentrations in goose blood, such as cucurbitacin D and Oleoyl-L-carnitine, may also contribute to the inhibition of cancer cell proliferation and migration. These findings suggest that goose blood holds broad application prospects as a future auxiliary drug for cancer treatment, and this study provides a theoretical basis for the further application of goose products. Full article

The valorization of dairy by-products, particularly whey, represents a key challenge and opportunity in sustainable food systems. This study aimed to evaluate the physicochemical and amino acid composition of milk and whey-derived products and to identify optimal whey–milk mixtures using integrated multivariate and desirability-based approaches. Ten model systems (M1–M10) were prepared with increasing whey content (7.5–75%), and their composition was analyzed using infrared spectroscopy and high-performance liquid chromatography. Multivariate analysis, including PCA and correlation heatmaps, revealed that protein, casein, TS, SNF, and amino acid fractions (ΣEAA and ΣBCAA) were the primary drivers of compositional variability, whereas lactose and acidity-related parameters contributed to secondary differentiation. Desirability function analysis was applied by integrating nutritional quality, functional balance, and sustainability score into a composite index. The results demonstrated that intermediate formulations achieved a more balanced profile compared with extreme compositions. Among all mixtures, the formulation containing 30% whey (M5) showed the highest overall desirability within the evaluated parameters, reflecting a favorable balance between compositional quality and whey utilization. These findings highlight the potential of integrated analytical approaches for the development of nutritionally optimized and resource-efficient dairy systems. Full article

This study investigates the environmental and health impacts of potentially toxic elements (PTEs) in solid and liquid wastes from phosphate beneficiation and fertilizer production in the Mdhilla area, Gafsa Basin, Tunisia. Solid wastes, including phosphate tailings (PTs) and phosphogypsum (PG), and associated industrial effluents from phosphate beneficiation (PBE) and fertilizer production (PFE), were characterized using physicochemical analysis, ICP-MS, SEM–EDX, and ion chromatography. Single and integrated pollution indices, along with conservative human health risk assessments, were applied to evaluate cumulative contamination and potential risks. PT exhibited near-neutral pH (7.64) and high PTE enrichment (Zn 350 mg kg⁻¹, Cr 329 mg kg⁻¹, Cd 38.8 mg kg⁻¹), whereas PG was strongly acidic (pH 3.13) and comparatively depleted in metals, reflecting process-dependent partitioning. Despite neutral pH, PBEs contained markedly higher metal concentrations than PFEs, with Fe (163 mg L⁻¹), Cr (3.09 mg L⁻¹), Cd (0.49 mg L⁻¹), and Pb (0.71 mg L⁻¹) exceeding discharge limits. Pollution indices indicated severe to extreme contamination, with PBE showing an exceptionally high contamination degree (C_deg = 63,659) compared to PFE (C_deg = 12,815), and elevated Toxic Element Pollution Index (PTEPI) values confirmed stronger cumulative pollution in PBE. Potential ecological risk indices (PERI > 600) revealed very high ecological risk for both effluents, primarily driven by Cd, Co, and Tl. Although dermal contact may represent the most frequent exposure route, risk assessment results indicated that accidental oral ingestion is the dominant pathway contributing to both non-carcinogenic and carcinogenic risks, with children being particularly vulnerable. Non-carcinogenic risk thresholds (HQ > 1) were exceeded for PBE, while total carcinogenic risks approached or exceeded regulatory limits (10⁻⁶–10⁻⁴), mainly due to Cd and Cr. Overall, phosphate beneficiation was the primary source of cumulative metal loading and associated ecological and health risks, while fertilizer production partially reduced contamination. These findings underscore the urgent need for improved management and mitigation of phosphate-processing wastes in industrial regions. Full article

Bongkrekic acid (BKA) is a potent respiratory toxin produced by Pseudomonas cocovenenans. This toxin is commonly found in spoiled fermented rice- and wheat-based products, snow fungus, and black fungus and can cause severe foodborne illness. The development of a rapid onsite detection method can effectively prevent food poisoning incidents and ensure food safety. In this study, a highly specific anti-BKA monoclonal antibody was prepared, the reaction conditions were optimized, and an indirect competitive chemiluminescent enzyme-linked immunoassay (ic-CLEIA) system was developed for high-throughput screening of BKA in food. The results showed that the ic-CLEIA had good linearity in the range of 7.3–106.6 pg/mL, a limit of detection of 4.7 pg/mL, a limit of quantification of 7.3 pg/mL, a half-maximal inhibition concentration of 28.2 pg/mL, a spike recovery of 86.6–94.1%, a coefficient of variation of less than 10%, and no cross-reactivity with structural analogs. There was no significant difference between the detection results obtained with ic-CLEIA and ultraperformance liquid chromatography–tandem mass spectrometry for the samples. This method provides reliable technical support for food safety monitoring, especially for grassroots laboratories and large-scale sample screening. Full article