Search Results (21,249)

Mycotoxins are compounds produced by the secondary metabolism of certain fungi. These compounds contaminate foods worldwide and pose a severe threat to the health of humans and animals. They also cause huge economic losses. A plethora of methodologies, encompassing agricultural, biological, chemical, and physical approaches, have been devised to curtail the presence of mycotoxins in food commodities. Among the physical processes, cold plasma (CP) has emerged as a useful technique for controlling the presence of toxigenic fungi in foods and for degrading the mycotoxins occurring in them without significantly affecting the quality and organoleptic properties of the treated commodities. The present review endeavors to demonstrate the efficacy of CP as a method of eradicating or reducing both the toxigenic mycobiota and the mycotoxins present in the most contaminated foods, including nuts, dried fruits, and cereal grains. The mechanisms of toxin degradation proposed by the different researchers are also examined and compared. Furthermore, the impact of the CP effect on the quality, sensorial characteristics, and toxicological properties of the treated food is thoroughly examined. Full article

Essential oils have attracted increasing attention due to their bioactive properties. This review focuses on their anticonvulsant potential by exploring the relation between the chemical composition of essential oils and the mechanism of action underlying this effect. Evidence from in vivo and ex vivo studies is presented to identify structure–activity relations and to distinguish well-supported effects from preliminary findings. Moreover, as essential oil’s quality is vital to ensure safety and efficacy in pharmacotherapeutic approaches. For this reason, factors including extraction and analytical methods as well as authenticity assessment are discussed due to their impact on pharmacological consistency and reproducibility. Overall, this review highlights key compounds and mechanisms contributing to anticonvulsant activity, identifies current limitations in the literature, and outlines priorities for future research aimed at validating essential oils as potential complementary therapeutic agents in seizure management. Full article

The aim of the study was to investigate the effect of enriching carrot slices by NFC (not from concentrate) juices from chokeberry (CH), sea buckthorn (SB), cherry (CHE) and carrot (CA) before microwave-vacuum (MVD) and freeze-drying (FD) carrot on the physicochemical and thermal properties. While water activity (AW) was not dependent on enrichment treatment but only on drying method, NFC juices significantly enriched carrot slices with biocomponents. Freeze-dried samples, as a reference, had significantly lower AW than those dried by the MVD method. Both FD and MVD-dried samples had comparable polyphenol content and DPPH antioxidant activity (AA), but the MVD-dried samples exhibited higher ABTS antioxidant activity. Carrot enrichment in chokeberry and cherry juices resulted in up to six and 10 times higher TPC than in the raw material. In addition, samples enriched in these juices and dried with FD proved to be the most stable in terms of water state and glass transition temperature (61.4 and 69.6 °C) and water activity (approx. 0.10). In FTIR analysis, all samples exhibited similar spectral shapes, indicating similar chemical composition and functional group composition. Only in the spectral region below 900 cm⁻¹ were unique molecular vibrations induced by various organic compounds present. Enriching carrot in juices and MVD can lead to increased hardness (Fmax and breaking work), although this is associated with increased crispness, resulting from the microstructure with a large number of small pores, especially in MVD samples enriched with cherry, chokeberry, and carrot juices, with scores of 8.0–8.4 In this respect, the average crispness rating of the MVD samples (7.2) exceeded that of the FD samples (6.8). If there is a requirement for crunchiness in the future production of dried vegetables as snacks, changes in hardness should be prioritized, along with color and biocomponent content. Full article

Natural products are the fundamentals of drug discovery due to their exceptional structural diversity and biological activity’s evolutionary optimization. The review provides a critical and integrative analysis of natural products in pharmaceutical chemistry, highlighting their significance for current biomedicine and pharmacotherapy. The review is organized around a system that connects structure, function, and translation, focusing on structural analysis, scaffold design, and mechanistic understanding in major disease-relevant therapeutic areas. Investigations on representative compounds like paclitaxel, artemisinin, and curcumin are presented to explain the way molecular architecture regulates pharmacological activity, drug selectivity, and clinical performance. The review evaluates significant medicinal chemistry strategies, including semisynthetic modification, prodrug design, and scaffold optimization, and their crucial roles in enhancing potency, pharmacokinetics, and safety. We critically examine the latest advancements in drug delivery technologies, particularly those based on nanotechnology and carrier-free methods, regarding their translational potential and regulatory concern. Current challenges pertaining to pharmacokinetics and ADMET properties, as well as the standardization of analysis, are also examined, emphasizing their impact on reproducibility in research. Researchers investigate the role and limitations of emerging fields such as genome mining, synthetic biology, and network pharmacology in enhancing discovery pipelines. Thus, this review integrates chemical, pharmacological, and translational approaches and suggests an effective strategy to overcome challenges in the development of natural products as the next generation of precision medicine therapeutic agents. Full article

For thousands of years glass packaging for wine has traditionally been associated with quality and remains used today as an inert and recyclable container. However, alternative containers such as aluminum cans and polyethylene terephthalate (PET) bottles have been gaining traction over the last several years because of their lower cost, increased recyclability, and increasing consumer acceptance. Advancements in can-liner technology further support aluminum cans as a realistic option for wineries; however, data on how different packaging types influence the quality of packaged wine remains sparse. This study evaluated the physiochemical properties of carbonated blueberry wine stored in glass bottles, aluminum cans, and polyethylene terephthalate (PET) bottles under accelerated conditions (35 °C). Across the three packaging types, the wine quality parameters of total acidity, sugar, and pH did not differ significantly. There were, however, measurable statistical differences that emerged in color, anthocyanin content, and volatile organic compound (VOC) profiles. Pearson’s correlation analysis revealed a strong linear relationship between the degradation of color (intensity and hue) and anthocyanin concentration over time for all packaging types, with the loss being dependent upon packaging type. These findings indicate that while certain quality attributes vary with container, the overall chemical changes in blueberry wine are comparable across glass, aluminum, and PET bottles. Consequently, aluminum can packaging stands as a viable, cost-effective alternative packaging for blueberry wine producers. Full article

Geroprotective molecules are currently being actively investigated for the prevention of skin aging. An overview of geroprotectors in dermatology encompasses agents such as antioxidants, ultraviolet (UV) photoprotective agents, chemical peels, and carbon dioxide (CO₂) lasers, each with inherent limitations, including poor tolerability in individuals with sensitive skin. Regarding biostimulators, high-molecular-weight peptides (exceeding 500 kDa) exhibit limited cutaneous bioavailability, underscoring the need for low-molecular-weight geroprotective compounds. One such candidate is dehydroepiandrosterone DHEA, a neurosteroid with anti-aging and anti-stress properties, which also serves as a precursor to sex steroids. Although topical hormone replacement therapy with estrogens and androgens is being utilized, it remains confined to formal hormone replacement regimens and is associated with a significant adverse effect profile. The aim of this review was to analyze the key molecular mechanisms underlying the effects of DHEA on the skin, with particular emphasis on its metabolism and sex- and age-dependent mechanisms of action. Additionally, this review seeks to elucidate the factors contributing to the absence of approved topical DHEA formulations and to outline the potential of DHEA as an anti-aging agent in dermatological applications. DHEA has demonstrated significant skin-improving effects in several studies; its investigation has been predominantly confined to postmenopausal women. Furthermore, the outcome measures employed in these studies lacked specificity. DHEA is not permitted for use in cosmetic products within the European Union due to its hormonal activity. Its use is only allowed as an extemporaneous formulation under the established regulatory frameworks of individual countries. The indications for its use and the appropriate dosage for men and women must be clearly defined based on the results of future clinical studies. Promising research directions include the pharmacogenetic characterization of steroidogenic enzymes and sex hormone receptors, as well as the evaluation of DHEA in both sexes, specifically in premenopausal women and in men presenting with late-onset hypogonadism. Additionally, the biological effects of the primary metabolites of DHEA, androstenedione, and 5-androstenediol, on the cutaneous function remain unexplored, including their potential anti-aging activity mediated through retinoid receptor activation. Full article

Increasing regulatory demands for high-quality plastic recycling create a strong need for novel tracer systems that enable reliable polymer identification and sorting. This feasibility study evaluates germanium nanocrystals (GeNCs) as Raman-detectable tracer materials in polypropylene (PP). The synthesis of GeNC/PP composite materials possessing various GeNC contents via a solvent-based intercalation process followed by compounding and injection molding is reported. Hydride-terminated GeNCs were synthesized and subsequently functionalized with dodecyl ligands to ensure chemical stability, compatibility with the polymer matrix, and processability under conventional melt-processing conditions. The dodecyl-functionalized GeNCs were successfully stabilized and homogeneously integrated into the PP matrix. Raman spectroscopy demonstrates the clear detection of GeNCs within the composites through a characteristic Ge–Ge optical phonon mode at 296 cm⁻¹, which is well separated from the intrinsic Raman bands of polypropylene. The Raman signal intensity increases systematically with increasing GeNC concentration. Raman mapping reveals an overall homogeneous distribution of the nanocrystals within the polymer, while a slight tendency toward agglomeration is observed at higher loadings. These results demonstrate that GeNCs are well suited as optically detectable tracers for polypropylene and can be reliably identified using Raman spectroscopy, highlighting their potential for tracer-based sorting concepts in advanced recycling and digital material passport applications. Full article

Context/Objective: Fungi of the genus Tolypocladium are known for their diverse metabolic capabilities and medicinal potential. Indole diterpenoids (IDTs) represent a structurally unique class of fungal metabolites. Beyond their established roles as mycotoxins, these compounds have recently shown promise for neuroprotective effects. The objective of this study was to isolate and characterize novel IDTs from Tolypocladium album DWS131 and evaluate their neuroprotective activities and underlying mechanisms. Methods: IDTs were isolated through comprehensive chromatographic techniques. Their structures were elucidated using HRESIMS data, 1D/2D NMR spectra, and quantum chemical calculations. Neuroprotective effects were evaluated using glutamate (Glu)-induced R28 cells in vitro and N-methyl-D-aspartic acid-induced mouse models in vivo. A total of 48 mice were utilized for in vivo evaluations, divided into two separate experimental cohorts. In each cohort, mice were randomly assigned to four groups (n = 6 per group). Post-intravitreal injection, retinal survival and visual function were assessed via Brn3a-stained flat-mounts, H&E staining, f-VEP, f-ERG, and OptoDrum. Mechanisms involving the SLC7A11/GPX4/ACSL4 axis were investigated by Western blotting and immunofluorescence. Results: Seven previously undescribed paxilline-type IDTs, tolypindoles A–G (1–7), and two known analogues (8–9) were identified. Compounds 8 and 9 exhibited significant neuroprotection closely associated with the attenuation of oxidative stress and the modulation of ferroptosis-related pathways in Glu-induced R28 cells. In vivo, they preserved retinal ganglion cells, maintained retinal structure, and protected visual function, with compound 8 demonstrating superior efficacy. Mechanistic investigations revealed that both compounds modulate the SLC7A11/GPX4/ACSL4 signaling axis. Conclusions: This study expands the chemical diversity of T. album DWS131. Compounds 8 and 9, characterized by isopentenyl moieties, highlight a promising therapeutic potential for retinal neurodegenerative diseases such as glaucoma. Full article

Verbascum species have long been recognized for their medicinal properties; however, detailed studies on the endemic species Verbascum wiedemannianum Fisch. & C.A. Mey. remain limited. The purpose of this study is to evaluate the antioxidant and anti-tyrosinase activities of essential oil (EO) and methanol extract (ME) derived from V. wiedemannianum, an endemic species from Türkiye. The EO was obtained by hydrodistillation, and its chemical composition was characterized using GC-FID and GC/MS. The principal constituents of the EO were palmitic acid (27.3%), myristic acid (11.9%), 1-octadecanol (13.0%), and pentacosane (6.6%). LC-MS/MS analysis of the ME identified luteolin and chrysoeriol derivatives as the predominant compounds. The antioxidant potential of both the EO and ME was evaluated using three assay systems based on electron transfer reactions: the Folin–Ciocalteu reagent, the Trolox equivalent antioxidant capacity assay, and the cupric ion (Cu²⁺) reducing antioxidant capacity assay. The potential skin care effects of the EO and ME were further evaluated using a tyrosinase inhibition assay. Across all the assays, the ME consistently showed notable activities, whereas the activity of the EO was less clearly defined. These findings indicate that the ME of V. wiedemannianum contains bioactive compounds with potential applications in natural antioxidant and skin care formulations. Further studies are warranted to clarify its therapeutic uses. Full article

Background/Objectives: WenTong HuoXue Cream (WTHXC) plays a significant role in the treatment of diabetic peripheral neuropathy (DPN). However, the material basis and quality control methods for this formulation remain largely unexplored. Methods: In this study, UPLC-HRMS/MS combined with standard reference substances was employed to comprehensively identify and confirm the chemical constituents of WTHXC. Furthermore, a rapid and sensitive UPLC-MS/MS method based on multiple reaction monitoring (MRM) mode was developed and validated for the simultaneous quantification of the marker components. Results: Nine compounds were unambiguous characterized, including Di-hydrocapsaicin (DHC), Oxypeucedanin hydrate (OPH), Imperatorin (IMP), Isoimperatorin (IIMP), Xanthotoxin (XAN), Hydroxysafflor yellow A (HSYA), Chlorogenic acid (CGA), Ferulic Acid (FA) and Ligustilide (LIG). The results of method validation denotes that all the analytes showed good linearity between concentration and peak area in the tested ranges, with correlation coefficients (r) not less than 0.9990. The relative standard deviation (RSD) of precision was in the range of 0.57–7.11%. The accuracy of the method, verified by recovery experiments at three concentration levels, ranged from 96.51% to 101.04% for all analytes. Transdermal behavior determination results demonstrate that OPH, HYSA, CGA, FA and LIG exhibited favorable skin permeability and may serve as the key active components of WTHXC. Conclusions: This study elucidates the material basis of WTHXC, providing a scientific foundation for the development of quality control methods and facilitating its broader clinical application. Full article

Silk fabrics and caftans preserved in the Topkapı Palace Museum collection constitute a distinguished group of cultural heritage objects reflecting the advanced weaving technologies, refined metal-thread use, and sophisticated natural dyeing practices of Ottoman court textile production. In this study, selected ceremonial caftans attributed to five Ottoman sultans were examined through a multidisciplinary and multi-analytical approach to characterize their structural, chromatic, and chemical properties. Color characteristics were evaluated in the CIE L*a*b* color space, while yarn properties, weave structures, and production techniques were investigated by optical microscopy. The morphology and elemental composition of the metal threads were analyzed using scanning electron microscopy coupled with energy-dispersive X-ray spectroscopy (SEM–EDX), and dyestuffs were identified by high-performance liquid chromatography with diode-array detection (HPLC–DAD). The results show that compound silk weaving structures were widely used in Ottoman court textiles, metal threads were predominantly silver-based and often gold-gilded, and dyestuffs with high fastness properties were preferentially selected. The revised manuscript situates these findings within a broader international literature on historical textile analysis and natural dye characterization, while using only a limited number of directly relevant studies from the authors’ previous work. The present study therefore provides new, object-specific and comparable data for the scientific documentation, material characterization, and conservation-oriented understanding of Ottoman textile heritage. Full article

Stabilizing weak soils is a well-known pavement and geotechnical engineering technique. This technique involves introducing minimal cementitious materials to improve the soil’s geotechnical characteristics. This paper investigates the use of recycled industrial polymer waste (IPW) as a reinforcement material in the presence of cementitious binders to stabilize weak silty sand soil (SM), supporting sustainable engineering practices. The randomly distributed IPW were added as percentages of 0%, 5%, and 10% to a mixture of lime soil and cement soil, with varying amounts of 0% to 6% of lime (L) and 0% to 6% of ordinary Portland cement (OPC), respectively. The laboratory experiments were conducted on natural and stabilized samples in wet (unsoaked) and submerged (soaked) conditions. The experimental program included Proctor compaction, California bearing ratio (CBR), unconfined compressive strength (UCS), durability tests, scanning electron microscopy (SEM), energy dispersive spectroscopy (EDS), and X-ray diffraction analyses. The resilient modulus (Mr) was estimated using an empirical equation. The outcomes of this experimental study show that adding a combination of IPW shreds with a small amount of L and/or OPC to the SM soil provides a significant increase in the UCS, CBR, durability and Mr values compared with case of SM with only L, which allows for superior characteristics and increases strength and stiffness parameters throughout any phase of earthwork construction design, resulting in stronger and stiffer subgrades. These results were reinforced by microstructural observations from SEM, EDS, and DRX, confirming the formation of cementitious gels and chemical compounds, consistent with the macro-scale mechanical improvements. The expected practical outcomes include potential reductions in pavement thickness, which can help lower pavement stabilization costs and extend its service life. Additionally, the use of waste materials to replace raw materials contributes to decreased energy consumption and emissions, although detailed assessments are needed to quantify these effects. Full article

Plant-derived bioactive metabolites have emerged as promising modulators of oxidative stress and inflammation, two interconnected processes involved in the pathogenesis of numerous chronic diseases. Arid ecosystems, particularly the Sonoran Desert, constitute an underexplored source of structurally diverse phytochemicals with significant pharmacological potential. This review provides a comprehensive overview of major classes of plant-derived bioactives, including polyphenols, flavonoids, terpenoids, and alkaloids, with emphasis on their molecular mechanisms of antioxidant and anti-inflammatory action. These compounds exert cytoprotective effects through direct reactive oxygen species (ROS) scavenging and indirect regulation of endogenous defense systems, primarily via activation of the Nrf2/Keap1 pathway and suppression of NF-κB signaling. Additional pathways, including MAPK, PI3K/Akt, AMPK, and mitochondrial regulatory networks, are discussed as critical mediators of redox balance and inflammatory control. Particular attention is given to Sonoran Desert plant species such as Bucida buceras, Phoradendron californicum, Larrea tridentata, Opuntia spp., and Agave deserti, all of which demonstrate promising biological activities associated with enhanced adaptation to environmental stress. Experimental approaches used to evaluate phytochemical bioactivity, including chemical assays, cellular models, omics technologies, and translational strategies, are also examined. Furthermore, this review discusses current limitations related to bioavailability, phytochemical variability, and clinical validation, highlighting emerging nanodelivery systems and precision medicine approaches as potential solutions. Collectively, the evidence supports the therapeutic relevance of Sonoran Desert plant bioactives as multi-target agents for modulating oxidative stress, inflammation, and chronic disease progression Full article

Emerging contaminants (ECs) encompass a wide spectrum of pollutants, from endocrine disruptors and persistent organic pollutants to microplastics and pharmaceutical residues. These contaminants often exhibit distinct chemical and physical properties compared with traditional pollutants and potentially pose risks to human health, especially as they have become pervasive in environmental and biological systems. ECs can also pose a significant threat to cardiovascular health, as they may target the ion channels that are critical to regulating cardiac excitability and contraction. However, the impact of ECs on the cardiovascular system, particularly on cardiac ion channels, remains elusive. In this review, we aim to provide an overview of the knowledge base concerning the impact of emerging contaminants on cardiac ion channels, with an emphasis on the effects of these compounds on cardiac excitability, contractility, and overall cardiovascular function. We first outline the structural and functional characteristics of ion channels, along with how these transmembrane proteins regulate cardiac physiology. Subsequently, we detail how typical ECs directly or indirectly interact with various ion channels—including sodium, calcium, potassium channels, as well as ion transporters and exchangers. Special attention is given to studies that have demonstrated cell-level responses or examined how pollutant concentration and chemical structure affect the modulation of ion channels. This review compiles recent research reports to elucidate the mechanisms by which EC exposure disrupts cardiac ion channels, potentially leading to cardiotoxicity. Moreover, the insights gathered herein illuminate critical research gaps and outline essential directions for future investigations. Full article

The increasing prevalence of drug-resistant microorganisms has prompted research into novel antimicrobial compounds, with 2-thiophene carboxylic acid thiourea derivatives showing promise for future therapeutic applications. However, the poor water solubility of these compounds limits their practical use. This study investigates the formation and characterization of inclusion complexes between 2-hydroxypropyl-β-cyclodextrin (HPβCD) and 2-thiophene carboxylic acid-halogenated (chlorine-, bromine-, and iodine-) thiourea derivatives, seeking to improve their physicochemical properties. The dynamic light scattering (DLS) measurements and UV-Vis spectroscopy provided information related to thiourea–HPβCD aggregates and stoichiometry. Solid-state inclusion compounds and physical mixtures were prepared in two different molar ratios (thioureas:HPβCD = 1:1 and 1:2), and the morphology of the resulting powders was observed by scanning electron microscopy (SEM). Thermogravimetry (TG) and differential scanning calorimetry (DSC) (TG-DSC) coupled analysis were used to analyze thermal profiles in the temperature range of 25 °C to 600 °C, while the spectral data obtained by Fourier transform infrared spectroscopy (FTIR) provided the characteristic vibrational bands of the pure guest molecules and data corresponding to the structural and chemical changes in the host–guest systems. The structural and thermal analyses revealed significant interactions between the host and thioureas molecules, with evidence of possible interactions involving two cyclodextrin molecules. The results demonstrate the presence of intermediate stoichiometry in the inclusion compounds, with possible enhancement of the therapeutic potential of these thiourea derivatives. Full article