Search Results (117)

Anthocyanin-rich purple fruits and vegetables—such as blackcurrants, blueberries, purple sweet potatoes, and red cabbage—are increasingly recognized for their health-promoting properties. These natural pigments exert antioxidant and anti-inflammatory effects, making them relevant to both chronic disease prevention and exercise recovery. This review critically examines current evidence on the redox-modulating mechanisms of anthocyanins, including their interactions with key signaling pathways such as Nrf2 and NF-κB, and their effects on oxidative stress, mitochondrial function, vascular homeostasis, and post-exercise adaptation. Particular attention is given to their bioavailability and the challenges associated with their chemical stability, metabolism, and food matrix interactions. In light of these factors, dietary strategies and technological innovations to improve anthocyanin absorption are also discussed. The synthesis of preclinical and clinical findings supports the potential of anthocyanin-rich foods as functional components in health optimization, athletic performance, and recovery strategies. Full article

This study examines Poland’s agricultural land market between 2009 and 2023 through fixed effects and spatial econometric models, highlighting economic and spatial determinants of land prices. Key results show that GDP per capita strongly increases land values (β = +0.699, p < 0.001), while agricultural gross value added (–2.698, p = 0.009), soil quality (–6.241, p < 0.001), and land turnover (–0.395, p < 0.001) are associated with lower prices. Spatial dependence is confirmed (λ = 0.74), revealing strong regional spillovers. The volume of state-owned WRSP land sales declined from 37.4 thousand hectares in 2015 to 3.1 thousand hectares in 2023, while non-market transfers, such as donations, exceeded 49,000 annually. Although these trends support farmland protection and family farms, they also reduce market mobility and hinder generational renewal. The findings call for more flexible, sustainability-oriented land governance that combines ecological performance, regional equity, and improved access for young farmers. Full article

Cotton, commonly used in wound care, has limitations such as quick saturation and wound adhesion, prompting surface modifications. In our studies, iron, which promotes platelet aggregation and coagulation, was deposited onto cotton via direct current (DC) magnetron sputtering. Thus, the biochemical properties of cotton fabrics were enhanced. Microscopic analyses revealed uniform iron coating on the fibers, and biochemical tests, such as activated partial thromboplastin time (aPTT) and prothrombin time (PT), showed that the modification did not affect the material’s coagulation activity. Measurements with the thiobarbituric acid (TBA) method (TBARS) showed that iron-modified cotton had antioxidant activity by lowering lipid peroxidation, which can be beneficial for better wound healing and lower infection risk. Moreover, our analysis showed the absence of cyto- and genotoxic properties against normal peripheral blood mononuclear cells (PBM cells). It was found that tested fabrics did not directly interact with DNA. Full article

Urinary tract infections (UTI) are among the most frequent bacterial infections in children, representing a significant cause of morbidity with potential long-term complications, including renal scarring and chronic kidney disease. This review explores the multifaceted roles of vitamins A, D, E, and C in the prevention and management of pediatric UTI. Vitamin A supports mucosal barrier integrity and immune modulation, reducing pathogen adhesion and colonization. Vitamin C exhibits antioxidant and antimicrobial properties, acidifying urine to inhibit bacterial growth and enhancing the efficacy of antibiotics. Vitamin D strengthens innate immunity by promoting antimicrobial peptide production, such as cathelicidins, and improves epithelial barrier function, while vitamin E mitigates oxidative stress, reducing renal inflammation and tissue damage. The interplay between oxidative stress, immune response, and nutritional factors is emphasized, highlighting the potential of these vitamins to restore antioxidant balance and prevent renal injury. Complementary strategies, including probiotics and phytotherapeutic agents, further enhance therapeutic outcomes by addressing microbiome diversity and providing additional antimicrobial effects. While these approaches show promise in mitigating UTI recurrence and reducing dependence on antibiotics, evidence gaps remain regarding optimal dosing, long-term outcomes, and their integration into pediatric care. By adopting a holistic approach incorporating vitamin supplementation and conventional therapies, clinicians can achieve improved clinical outcomes, support antibiotic stewardship, and reduce the risk of renal complications in children with UTI. Full article

The paper presents the design of iterative learning control for a class of mobile robots. This control strategy allows driving the considered system, which executes the same control task in trials, to the predefined reference within the consecutive iterations by improving the control signal gradually. The control problem being stated concerns a mobile robot, and hence, its kinematic model is presented. The considered model is nonlinear as it is related to the robot orientation angle. Thus, the linearization strategy is introduced by dividing the range of possible orientation angles to four quarters and then deriving a linear parameter-varying system. As a distinct research topic, the feasible/optimal number selection of polytope vertices of each LPV submodel are considered. Next, for the resulting bank of models, the switched iterative control scheme is transformed into closed-loop differential linear repetitive processes. Subsequently, based on the fact that ensuring the so-called stability along the trial is equivalent to the convergence of the original model output to the predefined reference, an appropriate stabilization condition is applied in order to compute the feedback controller gains. The overall effectiveness and performance of the proposed methodology are evaluated through comprehensive simulation examples. Full article

The advancement of Transformer models in computer vision has rapidly spurred numerous Transformer-based object detection approaches, such as DEtection TRansformer. Although DETR’s self-attention mechanism effectively captures the global context, it struggles with fine-grained detail detection, limiting its efficacy in small object detection where noise can easily obscure or confuse small targets. To address these issues, we propose Fuzzy System DNN-DETR involving two key modules: Fuzzy Adapter Transformer Encoder and Fuzzy Denoising Transformer Decoder. The fuzzy Adapter Transformer Encoder utilizes adaptive fuzzy membership functions and rule-based smoothing to preserve critical details, such as edges and textures, while mitigating the loss of fine details in global feature processing. Meanwhile, the Fuzzy Denoising Transformer Decoder effectively reduces noise interference and enhances fine-grained feature capture, eliminating redundant computations in irrelevant regions. This approach achieves a balance between computational efficiency for medium-resolution images and the accuracy required for small object detection. Our architecture also employs adapter modules to reduce re-training costs, and a two-stage fine-tuning strategy adapts fuzzy modules to specific domains before harmonizing the model with task-specific adjustments. Experiments on the COCO and AI-TOD-V2 datasets show that FSDN-DETR achieves an approximately 20% improvement in average precision for very small objects, surpassing state-of-the-art models and demonstrating robustness and reliability for small object detection in complex environments. Full article

This research examined the biochemical and microbiological characteristics of linen–copper (LI-Cu) composite materials, which were synthesized using magnetronsputtering techniques. The LI-Cu composites underwent comprehensive physicochemical and biological analyses. Physicochemical evaluations included elemental analysis (C, O, Cu), microscopic examination, and assessments of surface properties such as specific surface area and total pore volume. Biological evaluations encompassed microbiological tests and biochemical–hematological assessments, including the activated partial thromboplastin time (aPTT) and prothrombin time (PT). We determined the effect of LI-Cu materials on the viability and DNA damage in peripheral blood mononuclear (PBM) cells. Moreover, we studied the interactions of LI-Cu materials with plasmid DNA using a plasmid relaxation assay. The antimicrobial activity of LI-Cu composites was assessed using methodologies consistent with the EN ISO 20645:2006 and EN 14119:2005 standards. Specimens of the tested material were placed on inoculated agar plates containing representative microorganisms, and the extent of growth inhibition zones was measured. The results demonstrated that the modified materials exhibited antimicrobial activity against representative strains of Gram-positive and Gram-negative bacteria, as well as fungi. The results showed the cyto- and genotoxic properties of LI-Cu against PBM cells in a time- and power-dependent manner. Furthermore, the LI-Cu composite exhibited the potential for direct interaction with plasmid DNA. Full article

Background/Objectives: 22q11.2 microdeletion syndrome (22q11DS) is a genetic disease caused by aberration of chromosome 22 that results in some phenotypic features and developmental disorders. This paper presents a cross-sectional study on speech and communication of Polish children with 22q11DS. Methods: Individuals affected with 22q11DS may show difficulties in functioning, including speech and hearing. Therefore, we prepared a speech development questionnaire and employed it to obtain data from parents (or legal guardians) of 54 children with 22q11DS. The questionnaire covered the following speech and communication development stages: babbling, using first words, first sentences, verbal and non-verbal communication, speech disfluencies, hearing loss, speech intelligibility, difficulties in interpersonal contact, and participation in speech therapy. The obtained answers underwent statistical analysis to verify relationships between the stages of personal development and selected dysfunctions and disorders. Results: In the study group we observed delays in achieving subsequent speech developmental stages and that hearing loss was associated with delays in producing first words. Hearing loss was reported in about a quarter of cases, but a significant proportion of children (55.56%) reported speech disfluencies, which had not been emphasized in previous works, where hearing loss is considered a common co-occurring disorder. Conclusions: Our findings suggest that this may represent a phenomenon associated with 22q11DS that warrants further investigation using standardized tests for assessing disfluencies. Additionally, we observed that speech therapists and caregivers were perceived as not fully aware of the speech development impairments caused by 22q11DS. These preliminary observations point to the need for future studies and increased awareness efforts in this area. Full article

This study introduces a novel approach for enhancing the functional properties of cotton fibers through complexation of copper sulfate, and subsequent combination with chitosan (COT-CuSO₄-CTS). Our preliminary investigations focused on the development composites as candidate materials for functional coatings with antimicrobial properties. The materials were thoroughly characterized via scanning electron microscopy (SEM) and optical microscopy, providing insights into their structural features and composition. The findings show that the modified cotton materials exhibit potent antimicrobial activity. Specifically, the COT-CuSO₄ and COT-CuSO₄-CTS samples demonstrated zones of inhibition against both Gram-positive Staphylococcus aureus and Gram-negative Escherichia coli, confirming their ability to reduce microbial growth significantly. The incorporation of a chitosan layer significantly enhanced the Ultraviolet Protection Factor (UPF) of the cotton fabric from 3.37 to over 50, indicating exceptional UV shielding capabilities, while copper(II) oxide treatment provided a moderate UPF value of 14.56. Blood compatibility studies further revealed that COT-CuSO₄ and COT-CuSO₄-CTS fabrics influence coagulation parameters, with a marked prolongation in activated partial thromboplastin time (aPTT) and prothrombin time (PT) compared to untreated cotton. This anticoagulant effect is primarily linked to the presence of copper, although the addition of chitosan modulates this response, slightly reducing clotting times compared to COT-CuSO₄ alone. Cytotoxicity and genotoxicity assessments using Peripheral Blood Mononuclear (PBM) cells indicated that untreated cotton was non-toxic and non-genotoxic. However, COT-CuSO₄ and COT-CuSO₄-CTS fabrics displayed a reduction in cell viability and induced DNA damage, highlighting their potential cytotoxic and genotoxic effects. Notably, COT-CuSO₄-CTS showed lower cytotoxicity and genotoxicity than COT-CuSO₄-CTS, suggesting that chitosan reduces the overall cytotoxic and genotoxic potential of the composite. Furthermore, plasmid DNA relaxation assays indicated that COT-CuSO₄ and COT-CuSO₄-CTS interact with DNA, with COT-CuSO₄ exhibiting a stronger interaction than COT-CuSO₄-CTS, consistent with the findings on PBM cells. Full article

Oxidative stress, characterized by an overproduction of reactive oxygen species that overwhelm the body’s physiological defense mechanisms, is a key factor in the progression of parasitic diseases in both humans and animals. Scabies, a highly contagious dermatological condition caused by the mite Sarcoptes scabiei var. hominis, affects millions globally, particularly in developing regions. The infestation leads to severe itching and skin rashes, triggered by allergic reactions to the mites, their eggs, and feces. Conventional scabies treatments typically involve the use of scabicidal agents, which, although effective, are often associated with adverse side effects and the increasing threat of resistance. In light of these limitations, there is growing interest in the use of medicinal plants as alternative therapeutic options. Medicinal plants, rich in bioactive compounds with antioxidant properties, offer a promising, safer, and potentially more effective approach to treatment. This review explores the role of oxidative stress in scabies pathogenesis and highlights how medicinal plants can mitigate this by reducing inflammation and oxidative damage, thereby alleviating symptoms and improving patient outcomes. Through their natural antioxidant potential, these plants may serve as viable alternatives or complementary therapies in the management of scabies, especially in cases where resistance to conventional treatments is emerging. Full article

Background: Daratumumab (Dara) is the first monoclonal antibody introduced into clinical practice to treat multiple myeloma (MM). It currently forms the backbone of therapy regimens in both newly diagnosed (ND) and relapsed/refractory (RR) patients. However, previous reports indicated an increased risk of infectious complications (ICs) during Dara-based treatment. In this study, we aimed to determine the profile of ICs in MM patients treated with Dara-based regimens and establish predictors of their occurrence. Methods: This retrospective, real-life study included MM patients treated with Dara-based regimens between July 2019 and March 2024 at our institution. Infectious events were evaluated using the Terminology Criteria for Adverse Events (CTCAE) version 5.0. Results: The study group consisted of a total of 139 patients, including 49 NDMM and 90 RRMM. In the RR setting, the majority (60.0%) of patients received the Dara, bortezomib, and dexamethasone (DVd) regimen, whereas ND patients were predominantly (98%) treated with the Dara, bortezomib, thalidomide, and dexamethasone (DVTd) regimen. Overall, 55 patients (39.6%) experienced ICs. The most common IC was pneumonia (37.5%), followed by upper respiratory tract infections (26.8%). Finally, twenty-five patients had severe ICs (grade ≥ 3) and required hospitalization, and eight patients died due to ICs. In the final multivariable model adjusted for setting (ND/RR) and age, hemoglobin level (OR 0.77, 95% CI: 0.61–0.96, p = 0.0037), and Eastern Cooperative Oncology Group (ECOG) >1 (OR 4.46, 95% CI: 1.63–12.26, p = 0.0037) were significant factors influencing severe IC occurrence. Additionally, we developed predictive models using the J48 decision tree, gradient boosting, and random forest algorithms. After conducting 10-fold cross-validation, these models demonstrated strong performance in predicting the occurrence of pneumonia during treatment with daratumumab-based regimens. Conclusions: Simple clinical and laboratory assessments, including hemoglobin level and ECOG scale, can be valuable in identifying patients vulnerable to infections during Dara-based regimens, facilitating personalized prophylactic strategies. Full article

Oxidative stress plays a crucial role in the pathogenesis of various ocular degenerative diseases, leading to structural and functional changes in eye tissues. This imbalance between reactive oxygen species (ROS) and antioxidants significantly contributes to conditions such as age-related macular degeneration, diabetic retinopathy, cataracts, and glaucoma. Both enzymatic and nonenzymatic antioxidants are vital for maintaining ocular health by neutralizing ROS and restoring cellular redox balance. Essential trace elements, including iron, zinc, copper, and selenium, are fundamental for the proper functioning of these antioxidant systems. Iron is indispensable for enzymatic activity and cellular energy production, zinc supports numerous proteins involved in visual functions and antioxidant defense, copper is essential for various enzymatic reactions preventing oxidative stress, and selenium is critical for the activity of antioxidant enzymes such as glutathione peroxidase (GPX) and thioredoxin reductase (TrxR). This review summarizes current research on the complex interactions between oxidative stress and trace elements in ocular diseases, highlighting the therapeutic potential of antioxidant supplementation to mitigate oxidative damage and improve eye health. By integrating insights from studies on oxidative stress, trace elements, and eye physiology, this article underscores new diagnostic and therapeutic strategies that could lead to more effective prevention and treatment of ocular diseases, aiming to enhance clinical outcomes and guide future research in optimizing therapeutic strategies for eye health. Full article

Plants are able to produce various types of crystals through metabolic processes, serving functions ranging from herbivore deterrence to photosynthetic efficiency. However, the structural analysis of these crystals has remained challenging due to their small and often imperfect nature, which renders traditional X-ray diffraction techniques unsuitable. This study explores the use of Microcrystal Electron Diffraction (microED) as a novel method for the structural analysis of plant-derived microcrystals, focusing on Armeria maritima (Milld.), a halophytic plant known for its biomineralisation capabilities. In this study, A. maritima plants were cultivated under controlled laboratory conditions with exposure to cadmium and thallium to induce the formation of crystalline deposits on their leaf surfaces. These deposits were analysed using microED, revealing the presence of sodium chloride (halite), sodium sulphate (thénardite), and calcium sulphate dihydrate (gypsum). Our findings highlight the potential of microED as a versatile tool in plant science, capable of providing detailed structural insights into biomineralisation processes, even from minimal and imperfect crystalline samples. The application of microED in this context not only advances the present understanding of A. maritima’s adaptation to saline environments but also opens new avenues for exploring the structural chemistry of biomineralisation in other plant species. Our study advocates for the broader adoption of microED in botanical research, especially when dealing with challenging crystallographic problems. Full article

Background: One defining feature of various aggressive cancers, including glioblastoma multiforme (GBM), is glycolysis upregulation, making its inhibition a promising therapeutic approach. One promising compound is 2-deoxy-d-glucose (2-DG), a d-glucose analog with high clinical potential due to its ability to inhibit glycolysis. Upon uptake, 2-DG is phosphorylated by hexokinase to 2-DG-6-phosphate, which inhibits hexokinase and downstream glycolytic enzymes. Unfortunately, therapeutic use of 2-DG is limited by poor pharmacokinetics, suppressing its efficacy. Methods: To address these issues, we synthesized novel halogenated 2-DG analogs (2-FG, 2,2-diFG, 2-CG, and 2-BG) and evaluated their glycolytic inhibition in GBM cells. Our in vitro and computational studies suggest that these derivatives modulate hexokinase activity differently. Results: Fluorinated compounds show the most potent cytotoxic effects, indicated by the lowest IC₅₀ values. These effects were more pronounced in hypoxic conditions. ¹⁹F NMR experiments and molecular docking confirmed that fluorinated derivatives bind hexokinase comparably to glucose. Enzymatic assays demonstrated that all halogenated derivatives are more effective HKII inhibitors than 2-DG, particularly through their 6-phosphates. By modifying the C-2 position with halogens, these compounds may overcome the poor pharmacokinetics of 2-DG. The modifications seem to enhance the stability and uptake of the compounds, making them effective at lower doses and over prolonged periods. Conclusions: This research has the potential to reshape the treatment landscape for GBM and possibly other cancers by offering a more targeted, effective, and metabolically focused therapeutic approach. The application of halogenated 2-DG analogs represents a promising advancement in cancer metabolism-targeted therapies, with the potential to overcome current treatment limitations. Full article

Alginate-based materials have gained significant recognition in the medical industry due to their favorable biochemical properties. As a continuation of our previous studies, we have introduced a new composite consisting of cellulose nonwoven fabric charged with a metallic copper core (CNW-Cu⁰) covered with a calcium alginate (ALG⁻Ca²⁺) layer. The preparation process for these materials involved three main steps: coating the cellulose nonwoven fabric with copper via magnetron sputtering (CNW → CNW-Cu⁰), subsequent deposition with sodium alginate (CNW-Cu⁰ → CNW-Cu⁰/ALG⁻Na⁺), followed by cross-linking the alginate chains with calcium ions (CNW-Cu⁰/ALG⁻Na⁺ → CNW-Cu⁰/ALG⁻Ca²⁺). The primary objective of the work was to supply these composites with such biological attributes as antibacterial and hemostatic activity. Namely, equipping the antibacterial materials (copper action on representative Gram-positive and Gram-negative bacteria and fungal strains) with induction of blood plasma clotting processes (activated partial thromboplastin time (aPTT) and prothrombin time (PT)). We determined the effect of CNW-Cu⁰/ALG⁻Ca²⁺ materials on the viability of Peripheral blood mononuclear (PBM) cells. Moreover, we studied the interactions of CNW-Cu⁰/ALG⁻Ca²⁺ materials with DNA using the relaxation plasmid assay. However, results showed CNW-Cu⁰/ALG⁻Ca²⁺’s cytotoxic properties against PBM cells in a time-dependent manner. Furthermore, the CNW-Cu⁰/ALG⁻Ca²⁺ composite exhibited the potential to interact directly with DNA. The results demonstrated that the CNW-Cu⁰/ALG⁻Ca²⁺ composites synthesized show promising potential for wound dressing applications. Full article