Search Results (642)

Anemia is a major global public health problem and is most commonly associated with iron deficiency; however, deficiencies in other micronutrients, including vitamin B₁₂, may also contribute to its development. Increasing evidence suggests that Helicobacter pylori infection may influence the occurrence of anemia through several mechanisms related to alterations in the gastric environment. Chronic gastric inflammation and increased gastric pH associated with H. pylori infection may impair the absorption of non-heme iron and reduce the concentration of vitamin C in gastric juice. Since vitamin C enhances iron bioavailability by reducing ferric iron (Fe³⁺) to the more absorbable ferrous form (Fe²⁺), decreased levels of this vitamin may further limit iron absorption. At the same time, the increase in gastric pH may hinder the release of vitamin B₁₂ from food proteins, potentially contributing to disturbances in its absorption. This review aimed to present an integrated overview of the relationships between H. pylori infection, alterations in the gastric environment, and mechanisms that may contribute to the development of anemia, including disturbances in vitamin B₁₂ absorption, with particular emphasis on the potential role of vitamin C. Full article

The Vehicle-to-Grid (V2G) technology is considered one of the best solutions for integrating renewable energy systems; however, most literature reports favorable economic results using synthetic data, without accounting for seasonal or market limitations. The current research presents the results of the MATLAB R2023b (Version 23.2, MathWorks, Natick, MA, USA) simulation of the 100-household energy community in Debrecen, Hungary, with 30 electric vehicles (EVs) using entirely simulation-based Lithium Iron Phosphate (LiFePO4) batteries, a simulation-based 150 kW solar photovoltaic (PV) system, and a simulation-based 200 kW wind power system, using real meteorological data for January 2024. The optimization of charging/discharging for electric vehicles was performed using a multi-objective genetic algorithm (GA) over 30 days at a 15 min time resolution, accounting for stochastic loads and temperature effects on battery degradation, with a sensitivity analysis of key parameters. The results of the optimized solution for the electric vehicle charging/discharging were unexpected: the total energy cost increased by 68.9% ($4337.65 to $7327.54), the peak demand increased by 266.2% (31.9 to 116.9 kW), the degradation cost was $479.63, the load factor was reduced from 0.847 to 0.722, and the SOC constraint was violated for 0.758% of measurements. The V2G is not economically viable under current Hungarian pricing and Central Europe winter conditions. Results are robust for varying parameters using sensitivity analysis and Pareto front tracing. The break-even point is achieved when ratios of peak-to-off-peak prices are above 3.5:1. Seasonal policies and market reforms are critical for V2G viability. Importantly, the influence of inherent design deficiencies in the optimization model on the reported results cannot be ruled out. Full article

Phosphorus (P) availability is currently a limiting factor for agricultural production, especially in tropical soils, and its interaction with cationic micronutrients can significantly affect physiological efficiency and nutrient uptake by plants. Therefore, this study aimed to evaluate the uptake kinetic parameters described by the Michaelis–Menten model (Vmax, Km, and Cmin) for P as a function of the supply of Cu, Fe, Mn, and Zn, as well as the kinetic parameters of Cu, Fe, Mn, and Zn as a function of P supply in cotton (Gossypium hirsutum L.). The experiment was conducted in a greenhouse at the experimental unit of CENA, in Piracicaba, São Paulo, Brazil, using individual pots. Phosphorus concentration and accumulation were reduced only under Fe and Zn deficiency, with reductions of up to 60% in the shoots and 85% in the roots. Zn deficiency caused a drastic reduction in P uptake capacity, with Vmax decreasing from 590 to 50.85 µmol g⁻¹ h⁻¹ (approximately a 12-fold reduction), accompanied by an increase in Cmin (from 269 to 1508 µmol L⁻¹). In terms of micronutrient kinetics, P omission reduced plant growth and affected only Fe and Zn uptake. For Fe, Km increased from 12.82 to 27.31 µmol L⁻¹ and Cmin from 1.03 to 20.51 µmol L⁻¹. For Zn, and Vmax decreased from 0.16 to 0.02 µmol g⁻¹ h⁻¹ (approximately 8-fold), while Cmin increased from 0.08 to 1.56 µmol L⁻¹. These results demonstrate a strong interaction between P, Fe, and Zn, highlighting their regulatory roles in nutrient uptake and providing mechanistic insights into plant nutritional efficiency. Full article

This study evaluated the iron-chelating capacity (ICC) of Lupinus mutabilis protein hydrolysate (LMPH) and its peptide fractions obtained through ultrafiltration and purification by immobilized metal ion affinity chromatography (IMAC) and gel filtration chromatography (GFC). Peptides were identified by LC-MS/MS, and their interactions with Fe²⁺ were analysed using molecular docking. LMPH was produced by enzymatic hydrolysis with Alcalase and subsequently subjected to ultrafiltration to concentrate peptides smaller than 2 kDa. This fraction exhibited higher ICC (35.1 mg Fe²⁺·g⁻¹) than the hydrolysate (22.75 mg Fe²⁺·g⁻¹). Sequential purification by IMAC and GFC yielded peptide fractions with enhanced ICC values (45.20 and 13.51 mg Fe²⁺·g⁻¹). A total of 176 peptides were identified by de novo LC-MS/MS sequencing, from which nine were selected based on favourable structure–ICC relationships and absence of predicted toxicity. Molecular docking analysis suggested spatial proximity between Fe²⁺ and the selected peptides. Although stable multi-site binding was not predicted under the applied computational model, the results support the potential of these sequences to interact with Fe²⁺. These findings provide molecular and chemical insights supporting the iron-binding potential of LMPH-derived peptides and highlight their future potential as functional ingredients for preventing and managing iron deficiency. Full article

Background/Objectives: The co-occurrence of asthma and obesity presents a significant clinical challenge, but the underlying mechanisms remain unclear. Reduced adiponectin and vitamin D levels have been associated with both conditions, suggesting that their potential modulatory roles warrant further investigation. This study aimed to evaluate whether vitamin D and adiponectin levels differ among pediatric groups defined by their asthma and obesity status, to better characterize the metabolic and inflammatory profile of the obesityasthma phenotype. Methods: A total of 120 participants aged 6–18 were enrolled and categorized into four groups: Asthma (n = 30), Obesity (n = 30), Asthma + Obesity (n = 30), and Control group (n = 30). All participants underwent lung function testing, anthropometric assessment and measurement of fraction of exhaled nitric oxide (FeNO). Participants were further categorized according to BMI percentiles. Adiponectin levels were measured using ELISA, while vitamin D levels were detected using HPLC. Results: Vitamin D levels and lung function parameters did not differ across groups, although deficiency was most prevalent in the obesity group. FeNO was elevated in asthmatics relative to obese children (p = 0.038) and in obese asthmatics compared with both controls (p = 0.040) and obese children (p = 0.021). Adiponectin levels were lower in obese asthmatic children compared to the controls (p = 0.024). A similar difference was observed between the controls and obese asthmatics among children with low vitamin D levels (p = 0.014). Conclusions: The dominant mechanisms underlying the obesity–asthma phenotype remain unclear; however, our findings indicate a link between adiponectin dysregulation and heightened airway inflammation, as evidenced by increased FeNO levels, though the precise pathways involved are still not well-understood. The role of vitamin D appears less consistent. These results highlight the need for further research to clarify the interplay between metabolic and inflammatory pathways and to support more personalized management strategies in children with obesity-related asthma. Full article

In emphysema, the alveolar septal structure is progressively destroyed, which is believed to be irreversible. However, as it has recently been linked to vascular endothelial growth factor (VEGF) deficiency, we hypothesized that VEGF stimulation can promote lung cell proliferation/migration to reverse emphysema. Our sulfated caffeic acid dehydropolymer, CDSO3, was thus examined in vitro and in vivo, given its VEGF-stimulating activity via ferrous ion (Fe²⁺) chelation-mediated stabilization of hypoxia-inducible factor-1α (HIF-1α). In lung epithelial/endothelial cells, CDSO3 promoted proliferation and wound closure by 1.6–3.0-fold at 10 μM; however, these effects were negated by excess FeSO₄ or an HIF-1α inhibitor, indicating an Fe²⁺- and HIF-1α-dependent mechanism. In rat models of established emphysema induced by cigarette smoke extract or the VEGF receptor antagonist SU5416, two-week lung administration of CDSO3 at 60 μg/kg from day 21 enabled: 68–79% recovery of exercise endurance and airspace enlargement/destruction; a 1.8-fold increase in proliferating cell nuclear antigen above healthy levels; normalization of cleaved caspase-3; restoration of HIF-1α; and a 1.3-fold increase in VEGF above healthy levels. In contrast, CDSO3 pre-chelated with Fe²⁺ was ineffective. In conclusion, Fe²⁺ chelation-mediated HIF-1α stabilization and VEGF stimulation via local lung delivery of CDSO3 can reverse established emphysema by promoting cell growth and survival. Full article

Frataxin is a conserved mitochondrial protein essential for cellular iron–sulfur (Fe–S) cluster biogenesis and oxidative balance, with its deficiency causing Friedreich’s ataxia in humans. The hypomagnetic field (HMF), an environmental stressor known to influence oxidative stress and neurodevelopment, may interact with such inherent metabolic vulnerabilities. This study investigated whether HMF exposure exacerbates Fe–S homeostasis and oxidative disruption in a Drosophila melanogaster model of frataxin deficiency. Using synchrotron radiation-based X-ray fluorescence (SR-XRF) spectroscopy for in situ elemental analysis in live tissues, we found that HMF significantly altered iron distribution and content in a tissue-specific manner. In frataxin-silenced brains, HMF decreased iron distribution but increased total iron content, whereas in eyes it reduced iron content. Sulfur content decreased in frataxin-deficient eyes but increased in brains under HMF, though its spatial distribution was unchanged. Critically, HMF elevated reactive oxygen species (ROS) in frataxin-deficient brains. Transcriptomic analysis identified 202 differentially expressed genes under HMF in frataxin-silenced flies, including key regulators of iron metabolism and oxidative stress pathways. These findings demonstrate that HMF disrupts tissue-specific iron and sulfur homeostasis and intensifies oxidative stress in a frataxin-deficient insect system, underscoring its role as an environmental factor capable of aggravating metabolic fragility. Full article

Background: Iron deficiency remains a major nutritional challenge, partly due to the limited stability and bioavailability of conventional iron formulations in foods and during digestion. In this study, iron–protein microparticles (IP-MPs) based on bovine serum albumin (IA-MPs) and hemp protein (IH-MPs) were developed via coprecipitation and evaluated as food-compatible iron delivery systems. Methods: Iron–protein microparticles (IP-MPs) were fabricated by a coprecipitation technique. The stability of IP-MPs was investigated in a three-phase digestion model. The uptake of IP-MPs by Caco-2 cells as well as the Ferritin concentration in Caco-2 cells were investigated. Results: Particle morphology and size distribution were strongly dependent on the protein matrix, with hemp protein microparticles exhibiting greater size uniformity and higher stability under simulated gastric conditions. In a standardized in vitro gastrointestinal digestion model, both IP-MP formulations preserved iron predominantly in the bioactive Fe(II) state and remained sufficiently intact to reach the intestinal phase. Biocompatibility and iron uptake were assessed using Caco-2 cell monolayers. Neither formulation induced cytotoxic effects, while iron delivered via IP-MPs showed enhanced cellular uptake compared to a commercial iron supplement and ferrous sulfate. The amount of Fe(II) detected in the basolateral compartment of IH-MP and IA-MP samples (1.4 µg and 1.3 µg, respectively) was higher than that observed for Floradix^® samples (approximately 0.7 µg) and corresponded to about 25% of the total iron applied. Functional iron bioavailability, assessed by ferritin formation, was significantly higher for IP-MPs, with hemp protein microparticles yielding the strongest ferritin response. Conclusions: These results demonstrate that iron–protein microparticles, particularly those based on hemp protein, effectively improve iron stability during digestion and enhance cellular iron bioavailability, highlighting their potential for application in iron fortification and functional food systems. Full article

Micronutrient deficiencies in human diets, often exacerbated by soil degradation, pose a significant global health challenge. Glacial flour, fine sediments produced by glacial erosion, may offer a sustainable, low-cost solution to improve soil fertility and enhance micronutrient availability in crops. This study evaluates the potential of glacial flour soil amendments from glaciers with two contrasting lithologies—basaltic Sólheimajökull (Iceland) and metasedimentary Chhota Shigri (Himalaya)—to enrich soybeans (Glycine max var. Black Jet) with essential nutrients while assessing the risk associated with potentially toxic elements. In a controlled glasshouse experiment, soybeans were grown in artificial soils amended with five doses of glacial flour (0.5–20 T ha⁻¹) and analysed for 18 elements. Results demonstrated enhanced uptake of key nutrients such as Zn, Fe, Mo, and Se, particularly in Icelandic glacial flour treatments, supporting the potential for crop biofortification. However, Himalayan flour led to arsenic (As) accumulation at higher doses, exceeding food safety limits. Multivariate clustering revealed two distinct element uptake behaviours: oxyanion-mediated and mimicking elements (Mo, Se, Sr, As) and those driven by plant demand (macronutrients, Fe, Mn, Zn). These findings highlight glacial flour’s potential for nutrient enrichment but also of potentially toxic elements, underscoring the need for source-specific screening to ensure safe agricultural application in deglaciating regions. Full article

Triphenyl phosphate (TPHP), a typical organophosphate flame retardant, has been listed as an emerging pollutant, yet its biodegradation remains poorly studied. Herein, an efficient TPHP-degrading marine bacterium, Pseudomonas abyssi RL-WG04, was isolated from mangrove sediments, which could degrade 95.22% of 100 mg/L TPHP within 120 h. RL-WG04 exhibited good tolerance to varied environmental conditions, maintaining over 70% TPHP degradation percentages (100 mg/L, 7 d) across 20–50 °C, pH 7.0–9.0, and salinity 2.0–4.0% (NaCl, w/v). Organic solvents (p-xylene, biphenyl, toluene and ethyl acetate, 0.5% v/v) had a negligible impact, whereas metal ions (Mn²⁺, Fe³⁺, Ca²⁺, Cu²⁺, Mg²⁺, Zn²⁺, and Co²⁺) strongly inhibited degradation, especially at 1 mM. Under optimized conditions, TPHP degradation by RL-WG04 followed the improved Gompertz model (R² = 0.99927). Metabolite identification indicated that RL-WG04 transformed TPHP into phenol but failed to utilize phenol for growth because of the phenol 2-monooxygenase deficiency. Nevertheless, the constructed consortia of RL-WG04 and Pseudomonas sp. RL-LY03 (phenol-degrading bacterium) achieved complete TPHP degradation and cell proliferation. Additionally, RL-WG04 could efficiently remove TPHP (25 mg/kg) from clay and sandy mangrove sediments with 100% and 90.04% removal percentages, respectively. Overall, this work provides novel insights into the fate of TPHP and a potential approach for its remediation. Full article

The control of oxygen stoichiometry via topochemical reduction offers a powerful route to manipulate the functional properties of complex oxides. Here, we investigate the chemical and structural evolution of epitaxial BiFeO₃ (BFO) thin films under CaH₂ treatment in a sealed tube, using a representative reduction condition of 365 °C for 2 h and a temperature window of 345 to 380 °C to probe the reduction dependent evolution. The inherent sensitivity of BFO’s multiferroic properties to oxygen vacancy formation and cation valence states makes it an ideal platform to probe reduction pathways. The aim of this work is to elucidate the detailed reduction pathway, including phase stability, valence changes in Bi and Fe, and the morphological consequences of oxygen extraction. Using a combination of spectroscopic, diffraction, and microscopic techniques, it was demonstrated that CaH₂ annealing does not yield a homogeneous oxygen-deficient perovskite. Instead, it triggers a decomposition into Bi₂O₃, metallic Bi, and FeO_x secondary phases, accompanied by severe surface roughening. This chemical reconstruction leads to a strong suppression of the ferromagnetic-like response and a redshift in the optical absorption edge. Full article

Micronutrient deficiencies and low nutrient-use efficiency remain critical constraints to sustainable crop production. This study tested the hypothesis that Zn- and Cu-doped MnFe₂O₄ spinel ferrite nanoparticles can function as an efficient multinutrient nanofertilizer to enhance fenugreek (Trigonella foenum-graecum L.) growth and physiological performance. Zn- and Cu-doped MnFe₂O₄ nanoparticles were synthesized via a sol–gel method and characterized using X-ray diffraction (XRD), scanning electron microscopy (SEM), and energy-dispersive X-ray spectroscopy (EDS). The nanoparticles exhibited a cubic spinel structure with an average crystallite size of 27 nm and uniform incorporation of Zn and Cu within the MnFe₂O₄ lattice. Foliar application at different concentrations (100–500 mg/L) significantly improved seed germination, seed vigor, plant height, leaf number, stem thickness, biomass accumulation, and chlorophyll content compared with the untreated control. The 300 mg/L treatment consistently produced the greatest improvements, increasing plant height, biomass, and total chlorophyll content by more than 25–40% relative to control plants. Higher concentrations of T₅ resulted in diminished benefits, indicating a concentration-dependent response. These findings demonstrate that Zn- and Cu-doped MnFe₂O₄ nanofertilizer provides a balanced and bioavailable source of essential micronutrients, offering a promising nano-enabled strategy for improving nutrient use efficiency and sustainable fenugreek production. Full article

The Jiaodong gold-mineralized area is one of the most significant gold districts in China. The newly discovered Moshan gold deposit is hosted in the Late Jurassic Queshan granite, previously considered a prospecting blind zone. In this study, pyrite from the Moshan gold deposit is examined as the primary research subject. To elucidate the ore-forming processes and genetic mechanisms of this deposit, we conducted a comprehensive mineralogical and geochemical study on pyrite, the principal gold-bearing mineral. EPMA and LA-MC-ICP-MS analyses reveal that the pyrite is slightly sulfur-deficient (average S/Fe ratio of 1.976) and exhibits trace element variations (As, Co, and Ni) strongly correlated with distinct metallogenic stages. Gold occurs in various forms, including visible inclusion gold, fracture gold, and invisible nano-particulate gold (Au⁰). The in situ sulfur isotope δ³⁴S values range from 7.11‰ to 9.40‰ (average 8.00‰), displaying high homogeneity and a positive deviation from the troilite in the Canyon Diablo iron meteorite. By integrating pyrite S-Fe relationships, Co-Ni-As systematics, and sulfur isotope characteristics, the study indicates that the Moshan gold deposit originates from a magmatic-hydrothermal source. The ore-forming materials predominantly derive from Mesozoic granite-derived magmatic-hydrothermal fluids, with a minor contribution from crustal basement materials. The depth of mineralization is interpreted as mid-shallow. These findings not only highlight the metallogenic potential of the Queshan granite and clarify the genetic relationship between the Moshan gold deposit and other regional gold deposits but also provide a novel theoretical foundation and technical support for deep gold exploration in the Jiaodong region. Full article

The effects of Fe non-stoichiometry on crystal structure, microstructural evolution, and thermoelectric transport properties were systematically investigated in bornite (Cu₅Fe_1+yS₄; −0.06 ≤ y ≤ 0.06) synthesized by mechanical alloying followed by hot pressing. X-ray diffraction analysis confirmed the formation of a single-phase orthorhombic bornite structure over the entire composition range. Anisotropic lattice distortion was observed with increasing Fe non-stoichiometry, manifested as contraction along the a-axis and expansion along the b- and c-axes, with a non-linear dependence on composition. Crystallite sizes estimated from Lorentzian peak fitting increased from 64.1 nm for the stoichiometric composition to 70.6–76.3 nm for Fe-deficient samples and 73.2–90.9 nm for Fe-excess samples. Hall-effect measurements revealed p-type semiconducting behavior for the stoichiometric composition, degenerate p-type transport with increased hole concentration under Fe-deficient conditions, and a transition to n-type behavior with reduced carrier mobility under Fe-excess conditions. While Fe-deficient samples retained high electrical conductivity and positive Seebeck coefficients, Fe-excess samples exhibited negative Seebeck coefficients at low temperatures with sign reversal at elevated temperatures. As a consequence, the power factor of Fe-deficient samples was enhanced by approximately 20–30% relative to the stoichiometric composition. In addition, the total thermal conductivity remained below 0.8 W·m⁻¹·K⁻¹ for all samples, and Fe non-stoichiometry effectively suppressed lattice thermal conductivity. Consequently, the Cu₅Fe_0.94S₄ composition achieved a maximum dimensionless figure of merit of ZT = 0.61 at 673 K, representing a performance enhancement of approximately 30–70% compared with the stoichiometric composition (ZT = 0.36 at 673 K and 0.47 at 723 K). Full article

Background/Objectives: Iron deficiency anemia (IDA) is a widespread nutritional disorder characterized by impaired iron absorption, inflammation-associated iron restriction, and disrupted iron homeostasis. Increasing evidence suggests that gut microbiota play an important role in iron metabolism; however, the mechanisms underlying probiotic-assisted iron supplementation remain unclear. Our research group previously conducted in vitro fermentation screening experiments and obtained a bacterial strain, B. lactis Ca360, which possesses iron absorption-enhancing activity. Methods: In this study, an IDA mouse model induced by a low-iron diet was used to investigate whether B. lactis Ca360 could synergistically improve iron metabolism when combined with iron supplementation. Mice were treated with FeSO₄ alone or FeSO₄ combined with B. lactis Ca360, and hematological parameters, organ indices, serum iron-related markers, histopathological changes, duodenal iron metabolism-related gene expression, hepatic inflammatory responses, gut microbiota composition, short-chain fatty acid (SCFA) levels, and correlation networks were analyzed. Results: Iron deficiency induced typical anemia phenotypes, multi-organ dysfunction, intestinal iron absorption dysregulation, hepatic inflammation, and gut microbiota dysbiosis. Compared with FeSO₄ alone, the combined intervention more effectively improved hematological parameters, reduced organ indices, restored liver and spleen histological integrity, normalized intestinal iron metabolism-related gene expression, and alleviated hepatic inflammation. In addition, B. lactis Ca360 markedly reshaped gut microbiota composition, enriching SCFA-producing anaerobic genera, including Ruminococcus, Roseburia, Acetatifactor, Intestinimonas, Eubacterium_coprostanoligenes_group_unclassified, and Oscillibacter, accompanied by increased acetate, propionate, and butyrate levels. Spearman correlation analysis further revealed close associations between gut microbiota remodeling, improved iron metabolism, reduced inflammatory status, and recovery of anemia-related phenotypes. Conclusions: Overall, these findings demonstrate that B. lactis Ca360 enhances the efficacy of iron supplementation by modulating SCFA-producing and anti-inflammatory gut microbiota, thereby coordinately regulating intestinal iron absorption, inflammation, and systemic iron homeostasis, supporting probiotic-assisted iron supplementation as a promising nutritional strategy for IDA management. Full article