Search Results (489)

Shale gas extraction releases significant quantities of organic iodides of “unknown origin”, which generally pose high ecological and health risks, yet their toxic mechanisms remain unclear. In this study, the human hepatocellular carcinoma (HepG2) cell line was employed as an in vitro cell model to assess the cytotoxic effects of three typical organic iodides (1,2-diiodoethane, 1,3-diiodopropane, and 1,4-diiodobutane) identified in shale gas extraction wastewater from Chongqing, China. The results demonstrated that all three diiodoalkanes exhibited significant toxic effects on HepG2 cells at a concentration of 25 µM, and this effect demonstrated a dose-dependent pattern. As the concentration of diiodoalkanes increased, the viability of HepG2 cells decreased significantly, while cell mortality increased markedly. The transcriptomic analysis indicated that exposure to these three diiodoalkanes induced abnormal expression of genes associated with the extracellular space, extracellular matrix (ECM), and endoplasmic reticulum (ER) in HepG2 cells, which was presumed to be linked to the disruption of the intracellular redox-antioxidant system homeostasis by the diiodoalkanes. Furthermore, assays of intracellular reactive oxygen species (ROS) and antioxidant enzyme/molecule levels suggested that diiodoalkane exposure triggered excessive intracellular ROS production, induced oxidative stress, and ultimately resulted in cell death. Full article

Objective: To determine the association of body composition (BC) in smoldering multiple myeloma (SMM) with time to progression (TTP) to MM. Methods: The quantity and quality of adipose and muscle tissue were retrospectively derived from 63 whole-body low-dose computed tomography (WBLDCT) scans between 2017 and 2021. BC was analyzed by segmenting a single axial image at the level of the fourth lumbar vertebrae. Subjects were grouped into below vs. above the sex-specific median for BC metrics. Clinical information including TTP and progression risk factors were recorded. Cox proportional hazard models were used to determine the association between BC metrics and TTP. BC groups were compared using the Wilcoxon rank sum test and Fisher’s exact test. Results: Thirty subjects progressed over a median follow-up of 49.2 months. For subjects with a subcutaneous adipose tissue (SAT) cross-sectional area (CSA) below vs. above the median, TTP was 24.8 vs. not reached (p = 0.02). Similarly, TTP was 20.7 vs. not reached (p = 0.01) for those with SAT CSA indexed to height below vs. above the median. High SAT CSA (hazard ratio [HR]: 0.42 [95%CI: 0.20–0.90], p = 0.03) and high SAT index (HR: 0.39 [95%CI: 0.18–0.83], p = 0.01) were both associated with a lower progression risk. High SAT index remained significantly associated with reduced progression risk in multivariate analysis (p = 0.03). There was no association between TTP and obesity (BMI ≥ 30 kg/m²) or muscle metrics. High SAT CSA and index were associated with younger age and higher hemoglobin levels. Conclusions: SAT quantity might serve as a prognostic marker for progression in SMM. Full article

Insects present extraordinary potential for obtaining recombinant proteins, both in terms of the quantity and quality of the synthesized product. This work proposes the use of artificial diets including pDNA as an oral transfection system for the Lepidoptera Spodoptera exigua. It is hypothesized that oral transfection can lead to the effective expression of the reporter genes carried in plasmids. Prior to their incorporation into the artificial diet, plasmids (pCMVβ and pEGFP-N2) were protected from inactivation in the digestive tract by chitosan nanoparticulation. The survival of plasmids and their oral uptake by larvae was evaluated, as well as the persistence of pDNA in larvae throughout their ontogeny. The results confirmed that transfection occurred and that pDNA persisted during the ontogeny, even after discontinuing plasmid administration. The transcription of reporter genes was quantified by qRT-PCR, and the results indicate a dose-dependent synthesis of mRNA as the inclusion level of pDNA in diets increased. Moreover, the measurement of the biological activity of the recombinant proteins (β-galactosidase activity and green fluorescence) paralleled the results obtained for gene transcription, also dose-dependently. Therefore, effective oral transfection is feasible in S. exigua, provided that pDNA is protected against gut inactivation prior to its incorporation in artificial diets. Full article

Background/Objectives: Monoclonal antibody (mAb) stability is critical not only during manufacturing but also at the point of clinical administration. For therapies like tislelizumab (Tevimbra), a programmed death-1 (PD-1) targeting IgG mAb, delays in dosing often result in prepared infusions being discarded, contributing to substantial drug waste despite being engineered for improved stability. Methods: To evaluate the physicochemical in-use stability of tislelizumab in a ready-to-administer format, we mapped degradation pathways, including post-translational modifications (PTMs); peptide alterations; pH and solution characteristics—under 12-month storage (ultra-long), under 1-month storage (0, 7, 14, 21, 28 and 31 days), and under exposure-related forced degradation conditions including room temperature, elevated temperature, pH (acidic/basic), oxidation and UV exposure. Structural analysis was contextualised to the known PD-1 binding site, making stability assessment relevant to tislelizumab’s mechanism-of-action in blocking PD-1. To assess solution stability, a validated size-exclusion chromatography (SEC) assay was applied to all conditions. Results: Aggregation was identified as the primary degradation pathway during ultra-long-term storage. SEC and chemical assessment revealed no measurable changes in protein quantity, aggregation, peptide integrity, or PTM profile over 31 days at 2–8 °C in polyolefin intravenous bags (1.6 mg/mL). Conclusions: These results support the structural and physicochemical stability of tislelizumab under refrigerated conditions. Full article

Urbanization generates large quantities of arsenic-contaminated excavated soils that pose environmental risks due to arsenic volatilization during high-temperature sintering processes. While these soils have potential for recycling into construction materials, their reuse is hindered by arsenic release. This study demonstrated calcium hydroxide (Ca(OH)₂) as a highly effective additive for suppressing arsenic volatilization during soil sintering, while simultaneously improving material properties. Through comprehensive characterization using inductively coupled plasma-mass spectrometry (ICP-MS), scanning electron microscopy (SEM) and X-ray microtomography (μCT), energy dispersive spectroscopy (EDS), X-ray diffraction (XRD), Fourier Transform Infrared Spectroscopy (FTIR) and X-ray photoelectron spectroscopy (XPS), results demonstrated that Ca(OH)₂ addition (0.5–2 wt.%) reduces arsenic volatilization by 57% through formation of thermally stable calcium arsenate (Ca₃(AsO₄)₂). Ca(OH)₂ acted via two mechanisms: (a) chemical immobilization through Ca-As-O compound formation, (b) physical encapsulation in a calcium-aluminosilicate matrix during liquid-phase sintering, and (c) pH buffering that maintains arsenic in less volatile forms. Optimal performance was achieved at 0.5% Ca(OH)₂, yielding 9.14 MPa compressive strength (29% increase) with minimal arsenic leaching (<110 ppb). Microstructural analysis showed Ca(OH)₂ promoted densification while higher doses increased porosity. This work provides a practical solution for safe reuse of arsenic-contaminated soils, addressing both environmental concerns and material performance requirements for construction applications. Full article

The excessive use of fossil fuels and the increasing generation of solid waste, driven by population growth, industrialization, and economic development, have led to serious environmental, energy, and public health issues. In light of this problem, it is crucial to adopt sustainable solutions that promote the transition to renewable energy sources, such as biogas. Although progress has been made in optimizing biogas production, there is still no adaptable model for various environments that allows for the determination of optimal quantities of different organic wastes, simultaneously considering their composition, moisture content, and control of critical factors for biogas production, as well as the biodigester’s capacity and other relevant elements. In practice, the dosing of waste is conducted empirically, leading to inefficiencies that limit the potential for biogas production in real scenarios. The objective of this article is to propose a linear optimization model with nonlinear constraints that maximizes biogas production, considering fundamental parameters such as the moisture percentage, pH, carbon/nitrogen ratio (C/N), substrate volume, organic matter, volatile solids (VS), and biogas production potential from different wastes. The model estimates the optimal waste composition based on the biodigester capacity to ensure balanced substrates. The results for the proposed scenarios demonstrate its effectiveness: Scenario 1 achieved 3.42 m³ (3418.67 L) of biogas, while Scenario 2, with a greater diversity of waste, reached 8.06 m³ (8061.43 L). The model maintained pH (6.49–6.50), C/N ratio (20.00), and moisture (60.00%) within optimal ranges. Additionally, a Monte Carlo sensitivity analysis (1000 simulations) validated its robustness with a 95% confidence level. This model provides an efficient tool for optimizing biogas production and waste dosing in rural contexts, promoting clean and sustainable technologies for renewable energy generation. Full article

Microplastic and nanoplastic (MNP) particles have been observed in various human organs. However, polypropylene (PP), one of the top three most commonly detected types of MNPs in terms of quantity, is also present in injections given for the infusion treatment of diseases, and there is a considerable knowledge gap concerning its adverse effects on the human cardiovascular system. In this study, we used commercial PP particles (500 nm), similar in size to nanoplastics (NPs) present in injections and greater than or equal in concentration to NPs in the blood of healthy individuals, as the experimental dose to study their toxicological effects on human umbilical vein endothelial cells. The results revealed that PP particles at 35 μg/mL, equivalent to 20 times the concentration of blood, reduced cell viability, induced oxidative stress, caused cytomembrane damage, increased the inflammatory response, promoted apoptosis, and inhibited cell migration and wound tissue healing. In addition, a NP concentration of up to 210 μg/mL decreased the level of zonula occludens-1. In conclusion, since we used spherical particles, a type of nanoplastic present in plastic-bottle injections in clinical treatment that induces toxicological effects, this study provides cellular-level insights into the ecological risks of NP exposure in the human body. Full article

Basic substances of plant or animal origin are permitted for use in the protection of organic crops. Experiments were performed under laboratory, greenhouse, and field conditions using emulsified sunflower oil solution at 10%, water onion extract (Allium cepa L.) at 25%, chitosan at 2%, two commercial strains of Saccharomyces cerevisiae (US 05 and Coobra), and a low dose of copper (2 kg/ha) to inhibit the growth of Phytophthora infestans, to contribute to the extension of the vegetation period, and to maintain the photosynthetic capacity responsible for the quantity of yield. Potato varieties with different levels of resistance to the pathogen were planted, and preventive treatments were performed. In the greenhouse experiment, inoculation of potato plants with the pathogen was carried out. The aim of the study was to develop strategies for the combined or alternating use of basic substances and copper in order to delay the appearance of potato late blight symptoms and keep them below the level of economic damage. The main factor determining the effectiveness of the tested strategies was the yield. Protective treatments contributed to an increase in yield compared with untreated plants. Strategies combining copper with sunflower oil, onion extract, or chitosan reduced late blight symptoms; however, the final effect on plant health and yields depended on the susceptibility of the variety to the pathogen. Strategies based solely on basic substances were effective in protecting potato varieties that were less susceptible to P. infestans (e.g., Red Sonya, Lilly, Tajfun). For more-susceptible varieties (e.g., Vineta, Satina, Lord) copper pesticide must be included in the treatment strategy; however, copper can be applied either as the first four foliar sprays followed by two treatments with basic substances or, alternately, with them. Full article

To optimize the quality and quantity of basil cultivars, this study investigated four varieties of nutrient-rich growing media compared with chemical fertilizers at the recommended dose in the soil-grown system, and commercial growing media (control) for producing holy basil and Genovese basil under greenhouse conditions. The experiment used a completely randomized design (CRD) with six treatments and five replications. With greater levels of chlorophyll, T3 and T4 growing media, consisting of top soil, filter cake, long-term/short-term composted chicken manure, coconut coir dust, and rice husk ash at a ratio of 3:2:2:1.5:1.5 v/v, produced the largest fresh yield when used for holy basil and Genovese basil productions, respectively. However, the net profit margin showed no discernible variations from T3–T5 and T2–T6 growing media, respectively. Nevertheless, T3 or T4 and T4 growing media were recommended for holy basil and Genovese basil production, respectively, based on highest productivity and intricacy of preparation, while also ensuring that the product retains its quality in terms of antioxidant bioactive components. In addition to maintaining the biomass of basil plants’ productivity even when they are cultivated in appropriate growing media, Genovese basil needs to be fertilized with organic fertilizer, like chicken manure, following the fifth or sixth harvesting period. Holy basil should be harvested after the fourth harvest period. Full article

Background/Objectives: Fungotherapy has long been recognized as a therapeutic approach for treating and preventing various diseases. As an important representative of the so-called functional mushrooms, Chaga plays a crucial role in this system. Since this species is of limited distribution in Bulgaria, we are interested in studying a related but different species, Inonotus nidus-pici Pilát, with potential benefits for human health. Methods: The phytochemical composition of phenolic compounds in the studied species was analyzed using spectrophotometric methods and high-performance liquid chromatography (HPLC). Additionally, antioxidant activity was assessed using various assays, and the gastroprotective effect was evaluated in experimental rat models with indomethacin-induced gastric damage. Results: The quantities of the main classes of phenolic compounds in the studied object were determined, and an enriched phenolic extract (EPE) was obtained. The amount of phenolic compounds, in decreasing order, is as follows: tannins (1.67 ± 0.02%), phenolic acids (1.50 ± 0.09%), and flavonoids (1.24 ± 0.04%). Quercetin was the most present flavonoid (15.95 ± 0.05 mg/g DWE), followed by (+)-catechin (9.86 ± 0.15 mg/g DWE) and kaempferol (1.67 ± 0.09 mg/g DWE) in the enriched phenolic extract. The quantity of other established compounds was significantly lower. Of all ten phenolic acids identified in the same extract, the highest concentration was found only for rosmarinic acid (6.41 ± 0.08 mg/g DWE) and somewhat for p-coumaric acid (2.13 ± 0.12 mg/g DWE). Among all the applied methods regarding antioxidant activity, the highest potential of the extract for reducing copper ions was the most pronounced (1506.93 μM TE/g DWE), and the ability of the extract to reduce iron ions was almost the same (1354.05 μM TE/g DWE). In the experimental indomethacin-induced gastric ulcer rat model, EPE (25 mg/kg and 10 mg/kg) demonstrated a dose-dependent gastroprotective effect. Conclusions: The results of the experiments confirm the potential of the wood fungus species as a source of valuable biologically active compounds with beneficial and pharmacological effects. However, further studies are needed to fully determine its chemical composition and the biological activities related to it. Full article

The bacterial diversity of soils cultivated with avocado (Persea americana M.) is influenced by different factors, perhaps the most decisive being the type of agronomic management used by farmers. In conventional agronomic management (CM), high doses of agrochemicals are applied, in contrast to organic agronomic management (OM), where organic fertilizers are used. This alters the diversity and abundance of soil microorganism populations, which in turn affects crop health. This study aimed to isolate and morphologically characterize rhizospheric bacteria from avocado trees under different agronomic management systems (CM and OM). For the bacterial isolates, their ability to promote plant growth in vitro was determined through biochemical tests for phosphorus and calcium solubilization and nitrogen fixation. In addition, their in vivo effect on tomato (S. lycopersicum) growth was evaluated, and their antagonistic capacity against Fusarium sp. was assessed. The results showed differences in the quantity, diversity, and morphologies of bacterial isolates depending on the type of agronomic management. A higher Shannon diversity index was found in OM (2.44) compared to CM (1.75). A total of 35 bacterial isolates were obtained from both management types. A greater number of isolates from OM soils exhibited in vitro PGP activity; notably, eight isolates from OM plots showed phosphate-solubilizing activity, compared to only one from CM plots. Furthermore, although all isolates demonstrated nitrogen fixing capacity, those from OM orchards produced significantly higher nitrate levels than the control (Azospirillum vinelandii). On the other hand, inoculation of tomato plants with bacterial isolates from OM soils increased plant height, root length, and total fresh and dry biomass compared to isolates from CM soils. Likewise, OM isolates exhibited greater antagonistic activity against Fusarium sp. These findings demonstrate the impact of agronomic management on soil bacterial populations and its effect on plant growth and protection against pathogens. Full article

The soil nitrification rate is significantly affected by plant species, and it is also modulated by different nitrogen levels in the soil. There are a wide range of plant species with the capacity to produce biological nitrification inhibitors (hereafter referred to as BNI species). The preliminary results of this study report the influence of three different plant species on the nitrification rates under soil supply with three (0 mM, 3.5 mM, and 7.0 mM) nitrogen levels. The aim was to evaluate the potential of hemp, ryegrass, and sorghum in mitigating nitrification, in order to define a sustainable strategy for improving the nitrogen use efficiency by crops and to limit the nitrogen loss from agroecosystems. Leaf gas exchange measurements were also carried out in this study. Photosynthesis was only affected by nitrogen supply in hemp, resulting in a reduction in CO₂ assimilation at nitrogen doses higher than the plant’s requirements. Ryegrass devotes more reductive power towards leaf nitrogen assimilation than sorghum and hemp do. The greatest variation in nitrification rate in response to N was observed in soil cultivated with hemp (which also showed the highest potential nitrification rate), followed by sorghum and ryegrass. We speculate that this occurred because the greater seed sowing density for ryegrass ensured a greater quantity in the soil of molecules acting on nitrification compared to sorghum and hemp, with these latter being sown at lower densities. Our results suggest that sorghum and ryegrass might directly affect nitrification by BNI molecules, whereas hemp might indirectly mitigate nitrification through the nitrogen uptake. However, further research is needed to evaluate the effects exerted by the studied plant species on nitrification rates. Full article

Ionizing radiation (IR) as a stress inducer has a significant impact on various normal stem cells differentiation through activation of various signaling pathways. Low levels of oxidative stress of IR may preserve or even enhance cell differentiation. In response to IR, reactive oxygen species (ROS) can activate various signaling pathways that promote cell differentiation, notably through the involvement of nuclear factor erythroid 2–related factor 2 (NRF2). NRF2 interacts with multiple pathways, including Wnt/β-catenin (osteogenesis), PPARγ (adipogenesis), and BDNF/TrkB (neurogenesis). This response is dose-dependent: low doses of IR activate NRF2 and support differentiation, while high doses can overwhelm the antioxidant system, resulting in cell death. However, the quality of various types of IR, such as proton and carbon ion radiation, may have a varied impact on stem cells (SCs) differentiation compared to X-rays. Hence, activation of the NRF2 signaling pathway in SCs and cell differentiation depends on the level of stress and the quality and quantity of IR. This review is an update to explore how IR modulates SCs fate toward osteogenic, adipogenic, and neurogenic lineages through the NRF2 signaling pathway. We highlight mechanistic insights, dose-dependent effects, and therapeutic implications, bridging gaps between experimental models and clinical translation. Full article

Reducing post-harvest losses of cereal crops is a key challenge for ensuring global food security amid the limited arable land and growing population. This study investigates the effectiveness of electron beam irradiation (5 MeV, ILU-10 accelerator) as a physical decontamination method for various cereal crops cultivated in Kazakhstan. Samples were irradiated at doses ranging from 1 to 5 kGy, and microbiological indicators—including Quantity of Mesophilic Aerobic and Facultative Anaerobic Microorganisms (QMAFAnM), yeasts, and molds—were quantified according to national standards. Experimental results demonstrated an exponential decline in microbial contamination, with a >99% reduction achieved at doses of 4–5 kGy. The modeled inactivation kinetics showed strong agreement with the experimental data: R² = 0.995 for QMAFAnM and R² = 0.948 for mold, confirming the reliability of the exponential decay models. Additionally, key quality parameters—including protein content, moisture, and gluten—were evaluated post-irradiation. The results showed that protein levels remained largely stable across all doses, while slight but statistically insignificant fluctuations were observed in moisture and gluten contents. Principal component analysis and scatterplot matrix visualization confirmed clustering patterns related to radiation dose and crop type. The findings substantiate the feasibility of electron beam treatment as a scalable and safe technology for improving the microbiological quality and storage stability of cereal crops. Full article

In the context of the valorization of agri-food by-products, tomato (Solanum lycopersicum L.) seeds represent a protein-rich matrix containing potential bioactives. The aim of the present work is to develop a biochemical pipeline for (i) achieving high protein recovery from tomato seed, (ii) optimizing the hydrolysis with different proteases, and (iii) characterizing the resulting peptides. This approach was instrumental for obtaining and selecting the most promising peptide mixture to test for antifungal activity. To this purpose, proteins from an alkaline extraction were treated with bromelain, papain, and pancreatin, and the resulting hydrolysates were assessed for their protein/peptide profiles via SDS-PAGE, SEC-HPLC, and RP-HPLC. Bromelain hydrolysate was selected for antifungal tests due to its greater quantity of peptides, in a broader spectrum of molecular weights and polarity/hydrophobicity profiles, and higher DPPH radical scavenging activity, although all hydrolysates exhibited antioxidant properties. In vitro assays demonstrated that the bromelain-digested proteins inhibited the growth of Fusarium graminearum and F. oxysporum f.sp. lycopersici in a dose-dependent manner, with a greater effect at a concentration of 0.1 mg/mL. The findings highlight that the enzymatic hydrolysis of tomato seed protein represents a promising strategy for converting food by-products into bioactive agents with agronomic applications, supporting sustainable biotechnology and circular economy strategies. Full article