Search Results (1,564)

Iron deficiency anemia remains a global nutritional challenge due to the low bioavailability and side effects of conventional inorganic iron supplements. A novel organic iron supplement, oyster peptide ferrous chelate (OP-Fe), was prepared using oyster peptides as ligands. Its preparation process was optimized via single-factor experiments and statistical methods with the optimal conditions identified as 1% peptide concentration, 35 °C chelation temperature, 3.91:1 peptide-to-iron ratio, 1.49% ascorbic acid concentration and pH 6.05. Under these conditions, the chelate’s iron content reached 15.44 ± 0.18 g/kg. Multi-dimensional characterization confirmed that Fe²⁺ formed stable complexes with oyster peptides through carboxyl, amino, and imidazole groups. In vitro Caco-2 cell experiments showed OP-Fe achieved a maximum iron absorption rate of 76.07%, significantly higher than ferrous sulfate (52.39%). In vivo pharmacokinetic studies in mice demonstrated higher iron accumulation in serum and small intestine for OP-Fe. Key iron transport-related genes (PEPT1, TFR1, DMT1) were upregulated, contributing to enhanced absorption. OP-Fe exhibits favorable structural stability and bioavailability, holding potential as an efficient iron supplement. Full article

To achieve the high-value utilization of pine nut resources, a novel zinc supplement was developed in this study. Pine nut protein was enzymatically hydrolyzed to prepare pine nut peptides (PP), which were subsequently chelated with zinc ions to form pine nut peptide–zinc chelate (PZn). Under optimized conditions, the zinc chelation rate of PZn reached 60.18 ± 1.77%. Peptidomic analysis revealed that PZn is composed of a select group of peptides predominantly characterized by low molecular weight (80.65 ± 1.47% < 1 kDa) and enrichment in aspartic acid, glutamic acid, and cysteine, indicating a self-selective chelation process. Comprehensive characterization via multiple techniques confirmed that zinc ions coordinate with carboxyl, hydroxyl, and thiol groups on these peptides, leading to charge neutralization, disruption of hydrogen-bonding networks, and peptide aggregation. Furthermore, bioactivity prediction of the PZn-constituting peptides revealed high intrinsic antioxidant potential, which corroborated the experimental results, showing that PZn exhibited significantly enhanced radical scavenging capacity compared to PP. These findings demonstrate that PZn possesses excellent zinc-binding capability and antioxidant activity, suggesting its potential as a novel zinc supplement, with its efficacy rooted in its specific molecular composition. Full article

Irrigation plays a crucial role in the success of root canal treatment; however, currently, no standardized irrigation protocols exist, particularly regarding the optimal sequence for smear layer removal. This systematic review aimed to determine which irrigation protocol achieves superior smear layer removal: traditional sequential irrigation with sodium hypochlorite (NaOCl) followed by ethylenediaminetetraacetic acid (EDTA), or irrigation with etidronic acid, either combined with NaOCl in continuous chelation or used as a final irrigant. Continuous chelation with etidronic acid may be clinically advantageous in daily practice, as it would facilitate workflow by using a single irrigating solution without compromising the efficacy of the irrigation process. A comprehensive electronic search was conducted in Medline, Embase, Cochrane, Scopus, and Web of Science, last updated in August 2025. In vitro studies were selected according to predefined PICO-based criteria. Two reviewers independently screened the studies and extracted data, with an inter-rater agreement of 0.92 using the Kappa index. Risk of bias was evaluated using a modified CONSORT checklist for in vitro studies on dental materials. The average item compliance of the included studies was 58%. The maximum score was 73% and the minimum was 47%. Twenty studies met the inclusion criteria. Etidronic acid used in continuous chelation showed equal or superior smear layer removal compared with sequential irrigation in nine of ten studies. Conversely, when used as a final irrigant, etidronic acid demonstrated inferior performance in more than half of the studies, particularly in the apical third. Based on the available evidence, etidronic acid in continuous chelation appears as effective as, or more effective than, traditional NaOCl–EDTA sequential irrigation. Full article

Blood-sucking organisms produce various anticoagulant proteins that prevent blood clotting in their prey. Even in well-studied species like Hirudo medicinalis, many such proteins remain unidentified. We previously described a novel cysteine-rich anticoagulant (CRA), a distant homolog of antistasin. Later, we discovered another, much larger homolog in the medicinal leech. Its amino acid sequence is also highly cysteine-rich. Analysis of cysteine patterns showed four antistasin-like domain motifs, with one of them strongly disrupted. Since both antistasin and CRA contain two such domains, the new protein represents a duplicated antistasin-like structure. We cloned its cDNA, expressed the recombinant protein in Escherichia coli, purified it by metal-chelate chromatography, refolded it, and tested its anticoagulant properties. Using standard clinical assays—activated partial thromboplastin time, prothrombin time, and thrombin time—we found that the protein inhibited coagulation in all tests, though to varying degrees. These findings suggest that different antistasin-like anticoagulants in the leech enable it to block both intrinsic and extrinsic coagulation pathways, while hirudin inhibits the final step of clot formation. The combination of different anticoagulant proteins allows the leech to effectively prevent the prey’s blood from clotting during feeding. Full article

Soil co-contamination with cadmium (Cd) and zinc (Zn) poses serious threats to environmental safety and public health. This study investigates the enhancement effect and underlying mechanism of the biodegradable chelator Ethylenediamine-N,N′-disuccinic acid (EDDS) on phytoremediation of Cd-Zn contaminated soil using Sedum lineare. The results demonstrate that EDDS application (3.65 g·L⁻¹) effectively alleviated metal-induced phytotoxicity by enhancing chlorophyll synthesis, activating antioxidant enzymes (catalase and dismutase), regulating S-nitrosoglutathione reductase activity, and promoting leaf protein synthesis, thereby improving photosynthetic performance and cellular integrity. The combined treatment significantly increased the bioavailability of Cd and Zn in soil, promoted their transformation into exchangeable fraction, and resulted in removal rates of 30.8% and 28.9%, respectively. EDDS also modified the interaction patterns between heavy metals and essential nutrients, particularly the competitive relationships through selective chelation between Cd/Zn and Fe/Mn during plant uptake. Soil health was substantially improved, as evidenced by reduced electrical conductivity, enhanced cation exchange capacity, and enriched beneficial microbial communities including Sphingomonadaceae. Based on the observed ion antagonism during metal uptake and translocation, this study proposes a novel “Nutrient Regulation Assisted Remediation” strategy to optimize heavy metal accumulation and improve remediation efficiency through rhizosphere nutrient management. These findings confirm the EDDS–S. lineare system as an efficient and sustainable solution for remediation of Cd–Zn co-contaminated soils. Full article

Titanium oxide (TiO₂) is of great interest in solar cell manufacturing, hydrogen production, and organic compound photodegradation. The synthesis variables and methodology affect the morphology, texture, crystalline structure, and phase mixtures of TiO₂, which, in turn, affect the optical and catalytic properties of TiO₂. In this work, the effect of acetic acid as a catalyst and chelating agent on the morphology, texture, crystal structure, optical properties, and photocatalytic activity of TiO₂ samples obtained using the sol–gel method with sodium dodecyl sulfate (SDS) as a template was investigated. The results indicated that acetic acid not only catalyzes the hydrolysis of the TiO₂ precursor but also acts as a chelating agent, causing a decrease in crystallite size from 18.643 nm (T7 sample, pH = 6.8, without addition of acetic acid) to 16.536 nm (T2 sample, pH = 2). At pH 2 and 3, only the anatase phase was formed (T2 and T3 samples), whereas at pH 5 and 6.8, in addition to the anatase phase, the brookite phase (11.4% and 15.61% for samples T5 and T7, respectively) was formed. The band-gap value of TiO₂ decreased with decreasing pH during synthesis. Although the T2 sample had the highest specific surface area and pore volume (232.02 m²g⁻¹ and 0.46 gcm⁻³, respectively), the T3 sample had better efficiency in methylene blue dye photodegradation because its bird-nest-like morphology improved photon absorption, promoting better photocatalytic performance. Full article

Mushrooms like Inonotus obliquus and Ganoderma lucidum show significant pharmacological promise. This review analyzes fungi as sources of natural inhibitors against Advanced Glycation End-products (AGEs)—key drivers of diabetes and neurodegeneration. We highlight that extracts from Lignosus rhinocerus and Auricularia auricula exhibit antiglycation potency (IC₅₀ as low as 0.001 mg/mL) superior to aminoguanidine. Inhibitory effects are attributed to bioactive fractions including FYGL proteoglycans, uronic acid-rich polysaccharides, and fungal-specific metabolites like ergothioneine. These compounds act through multi-target mechanisms across the glycation cascade: competitive inhibition of Schiff base formation, trapping reactive dicarbonyls (e.g., methylglyoxal), transition metal chelation, and direct scavenging of reactive oxygen species (ROS). Furthermore, the review addresses the transition from in vitro potency to in vivo efficacy (RAGE pathway modulation), stability during food processing (UV-B irradiation), and critical safety issues regarding heavy metal bioaccumulation. Mushroom-derived inhibitors represent a sustainable therapeutic alternative to synthetic agents, offering broader protection against glycative stress. This synthesis provides a foundation for developing standardized mushroom-based nutraceuticals for managing AGE-related chronic disorders. Full article

Background: Plant citrate synthase (CSY) is involved in the iron deficiency (−Fe) response and aluminum (Al) detoxification. However, knowledge of CSY function in responding to excess iron (+Fe) or Al stress (+Al) is still limited. Methods: The CDS and promoter of GmCSY3 were isolated from soybean and bioinformatically analyzed. The GmCSY3 expression was detected by qRT-PCR and GUS assay. The growth of GmCSY3 recombinant yeast under +Fe or +Al was detected. The phenotype, CSY activity, citric acid concentration, chlorophyll content, MDA, H₂O₂, O₂⁻ contents, GST, CAT, SOD, and POD activities were examined in GmCSY3 overexpressed and RNAi-suppressed soybean chimeras under +Fe or +Al. Perls and Hematoxylin stained the roots, and the FCR activity was determined. Results: GmCSY3 was induced by +Fe or +Al, but not by −Fe. GmCSY3 enhanced yeast’s acid production and resistance to +Fe or +Al. GmCSY3 overexpression in soybean significantly enhanced CSY activity, promoted growth, alleviated oxidative damage caused by +Fe or +Al, with less free Fe³⁺ and Al³⁺, and reduced FCR activity, while GmCSY3 RNAi-suppressed showed the opposite effect. Conclusions: GmCSY3 promotes the process of citrate synthesis, chelates Fe³⁺ and Al³⁺, alleviates oxidative damage caused by +Fe or +Al, and modulates iron absorption in plants. Full article

Water-soluble poly-β-cyclodextrins (PCDs), crosslinked with ethylenediaminetetraacetic acid dianhydride (EDTADA), were synthesized at varying β-CD:EDTADA molar ratios (1:6, 1:9, 1:12, 1:15) to develop multifunctional nanocarriers with the ability to complex drugs, polymers, and ions. All PCDs exhibited nanometric particle sizes (14 to 28 nm), negative zeta potential (−18 to −27 mV), and adjustable content of free carboxyl groups controlled by crosslinker ratio. Functional evaluations demonstrated effective Ca²⁺ chelation and a linear inclusion complexation profile with acyclovir, but not with naproxen, highlighting pH-dependent solubility effects. Additionally, PCDs successfully formed polyelectrolyte complexes with poly-L-lysine, indicating their potential as components of advanced drug delivery systems. Among the analyzed variants, PCD 1:6 showed reduced yields, fewer reactive groups, and diminished ion-binding capacity compared to formulations with higher crosslinker content. These findings underscore the importance of crosslinking density in modulating physicochemical and functional properties and support the potential of EDTA-crosslinked PCDs as versatile platforms for advanced, ion-sensitive biomedical applications. Full article

Aluminum (Al), an element that has no biological function described in plants, is commonly found in acidic soils, reducing plant growth, despite some beneficial effects reported in the literature. Iron (Fe) is an essential nutrient for plants, and Fe deficiency causes leaf interveinal chlorosis. Remarkably, rice (Oryza sativa), a C₃ crop considered tolerant to Al, shows alleviation of Fe deficiency chlorosis when exposed to Al, suggesting that Al can positively impact Fe homeostasis. However, whether this effect is observed only in rice or is common to other plant species is unknown. The rice wild progenitor Oryza rufipogon is closely related to the domesticated species, sharing several traits such as a semi-aquatic habit and use of the combined strategy for Fe uptake. Maize (Zea mays), on the other hand, is a C₄ plant, adapted to well-aerated soils, and uses a classic chelation-based strategy for Fe uptake. Here we used these two Poaceae representatives to determine whether Al excess could alleviate Fe deficiency chlorosis in species other than rice. Although Al caused toxicity irrespective of Fe levels, its addition essentially abolished chlorosis in Fe-deficient plants. The expression of Fe deficiency-induced marker genes was reduced to control levels in both species, suggesting that the Al alleviation effect leads to systemic signaling and down-regulation of Fe uptake mechanisms. Al alleviation partially rescued photosynthetic machinery inhibited by Fe deficiency, suggesting that leaves are maintaining photosynthetic activity when Al is present even under low Fe conditions. Taken together, our data show that the Al alleviation effect is shared by two other Poaceae species in addition to O. sativa and suggest that it might not be directly linked to domestication, changes in C₃/C₄ metabolism, or Al tolerance levels found in different species. Full article

This study investigates the accumulation potential of Brassica napus L. and Zea mays L. cultivated on soils contaminated with Zn, Cd, Cu and Pb, using HEDTA—Hydroxyethyl Ethylenediamine Triacetic Acid—to enhance metal mobility. The research addresses a gap in the literature regarding the dual-purpose use of energy crops for assisted phytoextraction and bioenergy recovery. Two pot experiments were conducted on soils of different textures, with HEDTA applied at 2.5 and 5 mmol·kg⁻¹. Metal concentrations in soil and plant tissues were measured, and indices such as the geoaccumulation index (Igeo), bioconcentration factors (BCF), translocation factor (TF), metal tolerance index (MTI), crop growth rate (CGR) and higher heating value (HHV) were calculated. Results showed that HEDTA significantly increased Cd and Zn mobility, leading to higher accumulation in rapeseed shoots. Maize demonstrated phytostabilization by retaining metals in roots. Rapeseed biomass exhibited a higher HHV (up to 20.6 MJ·kg⁻¹) and greater carbon and hydrogen content, indicating suitability for thermochemical conversion. Maize, with lower ash content, showed potential for bioethanol production. The findings support the integration of chelate-assisted phytoextraction with energy recovery from biomass. Full article

Chrysanthemums are appreciated not only for their ornamental and medicinal attributes but also as edible plants long incorporated into teas, infusions, and culinary traditions. Yet, hybrid cultivars specifically adapted to European growing conditions remain poorly characterized with respect to their medicinal potential. In this study, we investigated the phytochemical composition, antioxidant properties, and enzyme-inhibitory activities of inflorescences of four field-grown Chrysanthemum × morifolium ‘Donna’ × C. rubellum ‘Clara Curtis’ hybrids of European origin (CD 7, DC 19, DC 26, CD 46). Their profiles were compared with those of a Chinese tea cultivar (C. morifolium CHR18) and a commercial herbal product (CH B). Chemical constituents were analyzed using GC–MS and LC–MS, while antioxidant activity was evaluated by FRAP, CUPRAC, DPPH, ABTS, and iron-chelating assays; hyaluronidase (HYAL) and butyrylcholinesterase (BChE) inhibition were also assessed. A total of 61 volatile compounds were identified, with several terpenoids—such as chrysanthenone and verbenone—occurring exclusively in the European hybrids. CHR 18 possessed the highest flavonoid and phenolic acid levels, whereas hybrid CD 46 exhibited the most pronounced overall antioxidant performance. Hyaluronidase inhibition was strongest in DC 26 and CD 46 (60–62%), surpassing both reference samples, while BChE inhibition remained generally low. Overall, the results highlight that C. morifolium × C. rubellum hybrids developed for cultivation in the temperate European climate offer a unique combination of phytochemical richness, robust antioxidant activity, and noteworthy enzyme inhibition. These traits underscore their promise as emerging functional chrysanthemum resources and support future applications in European herbal products, nutraceutical development, and region-specific functional food innovation. Full article

Medicinal and aromatic plants contain valuable natural compounds widely used in health, food, and cosmetics. This study compares the antioxidant capacities and phenolic compositions of tea and ethanol extracts from eight species naturally growing in Fethiye, Muğla, Türkiye. Antioxidant activity was assessed using the β-carotene bleaching method, 2,2-diphenyl-1-picrylhydrazyl (DPPH), 2,2′-azino-bis (3-ethylbenzothiazoline-6-sulfonic acid) (ABTS⁺), cupric reducing antioxidant capacity (CUPRAC), and metal chelating activity. Herbal teas generally showed stronger antioxidant activity than ethanol extracts. Rosemary tea had the highest activity (2.90 µg/mL), followed by lavender (11.30 µg/mL). In metal chelating, rosemary tea exhibited a half-maximal inhibitory concentration (IC₅₀) of 9.22 µg/mL, close to ethylenediaminetetraacetic acid (EDTA). Phenolic profiling showed rosemary tea contained 30.74 mg/g rosmarinic acid and 0.74 mg/g quercetin. These results support the traditional use of southwestern Türkiye’s medicinal plants and emphasize the antioxidant potential of herbal teas. Integrating ethnobotanical knowledge with phytochemical data provides a basis for functional food development, crop improvement, and conservation of local plant genetic resources. Unlike previous studies focusing on single species or limited solvent comparisons, this research simultaneously evaluates both herbal tea and ethanol extracts of eight locally grown medicinal plants, offering a unique perspective on their comparative antioxidant and phenolic diversity. Full article

Eu³⁺ is a fluorescent and paramagnetic ion whose emission intensity increases when chelated with enhancers such as tetracycline (TC). In this study, Eu³⁺ was conjugated with citric acid (CA) to form magnetic fluorescent probes capable of capturing trace TC from solutions. The probes were rapidly prepared (~2.25 min) and trapped TC within ~2.5 min under microwave heating. The method enabled sensitive detection of TC, oxytetracycline, and chlortetracycline with detection limits of ~3–7 nM by fluorescence spectroscopy. It was successfully applied to real food samples, including fresh chicken broth and commercial broth cubes, achieving high accuracy (93.7% and 96.6%). This dual-functional probe offers a rapid and sensitive approach for detecting TC residues in complex food matrices, demonstrating strong potential for food-safety monitoring. Full article

Contamination of agricultural soils with heavy metals, such as zinc (Zn), copper (Cu) and lead (Pb), is a major problem for food safety and environmental sustainability. The present study aimed to evaluate the efficiency of phytoremediation induced with Brassica juncea (Indian mustard) and ethylenediaminetetraacetic acid (EDTA) in reducing the content of heavy metals in contaminated soils. The experiment was carried out in a greenhouse, using soil polluted with Zn, Cu and Pb, to which different treatments were applied, using: the biological method (Indian mustard only), the chemical method (EDTA in three concentrations: 0.5–1.0–2.0 mmol·kg⁻¹) and the mixed method (Indian mustard and EDTA in three concentrations: 0.5–1.0–2.0 mmol·kg⁻¹). The determinations included the analysis of the residual metal content by atomic absorption spectroscopy, as well as the evaluation of the physiological parameters of the plants (biomass, chlorophyll content in leaves, humidity, height). The results of unifactorial and bifactorial ANOVA revealed highly significant differences (p < 0.001) between the treatments and the types of metals, confirming the synergistic interaction between the chelation and phytoextraction processes. The combined treatments Indian mustard and EDTA in concentrations of 1.0 mmol·kg⁻¹ and 2.0 mmol·kg⁻¹, ensured the highest decontamination efficiency, with reductions of 51.5% for Zn, 36.3% for Pb and 27.5% for Cu. In conclusion, the mixed method represents a viable, ecological and reproducible strategy for the remediation of soils contaminated with heavy metals. Full article