Search Results (581)

Polyvinyl alcohol (PVA)-based films are promising biodegradable alternatives to petroleum-derived plastics; however, their high rigidity and moisture sensitivity limit practical applications. In this study, PVA/carnauba wax (CW) films were prepared via solution casting and systematically modified using four plasticizers: glycerol (GLY), sorbitol (SOR), glucose (GLU), and sucrose (SUC), at concentrations of 0.1–0.5% (v/w, relative to PVA). Thermal analysis showed that GLY and SOR effectively reduced the glass transition temperature from 52.35 °C (control) to as low as 49.14 °C (0.2% GLY) and 50.70 °C (0.4% SOR), while SUC and SOR plasticized films exhibited improved thermal stability, with the highest melting temperature observed for 0.3% SUC (80.6 °C). SEM micrographs revealed that GLY at moderate concentrations (0.2–0.3%) produced the most homogeneous film morphology, whereas SUC at higher concentrations led to surface roughness and phase separation. Water contact angle measurements showed increased surface hydrophobicity at low plasticizer contents, with 0.1% GLY and 0.2% GLU exhibiting contact angles above 100° compared to the control film (<90°). Mechanical testing demonstrated that SUC at 0.2% had the highest tensile strength (3.03 MPa) compared to 0.73 MPa (control), while GLY at 0.3% yielded the highest elongation at break (9.26%), compared to 0.62% for the unplasticized film. These results demonstrate that precise control of plasticizer type and concentration enables effective tuning of PVA/CW film properties, offering a viable strategy for designing biodegradable films tailored for packaging and agricultural applications. Full article

Background: Diabetes mellitus is a global health challenge associated with chronic complications like diabetic nephropathy and diabetic foot infections. Diabetic nephropathy, mediated by hyperglycemia-induced activation of the polyol pathway, represents a primary cause of end-stage renal disease. Additionally, infections caused by multidrug-resistant bacteria like Enterococcus faecalis lead to amputations and contribute to morbidity in diabetic patients. Methods: In this study, we synthetized nitrogen-doped carbon dots (N-CDs) using succinic acid with either hexamethylenediamine (N-HCD) or ethylenediamine (N-ECD) and evaluated their potential therapeutic applications. Results: Both N-HCD and N-ECD demonstrated a significant reduction in aldose reductase (AR) and sorbitol dehydrogenase (SDH) in vitro, with a substantial reduction in polyol pathway enzymatic activity. Furthermore, these N-CDs exhibited antibacterial activity against E. faecalis in vitro. Conclusions: Taken together, our findings suggest that N-HCD and N-ECD represent promising candidates for addressing diabetes-related complications and warrant further investigation for potential drug delivery applications. Full article

Background: Neuroblastoma (NB) progression is influenced by metabolic and redox adaptations. The polyol pathway, driven by aldose reductase (AKR1B1) and sorbitol dehydrogenase (SORD), is activated in hyperglycemic conditions, while detoxification of lipid peroxidation products such as 4-hydroxynonenal (4-HNE) involves carbonyl reductase 1 (CBR1) and AKR1B1. A systematic characterization of these enzymes under distinct metabolic and oxidative challenges in NB is currently lacking. Methods: Human neuroblastoma LAN-5 and SH-SY5Y cells were exposed to hyperglycemic medium to assess polyol pathway regulation, and to exogenous 4-HNE to model aldehyde-induced oxidative stress. Protein expression and enzyme activities were quantified. Cells were treated with Sorbinil or rutin during stress exposure, and viability was analyzed in 2D and 3D models. Results: Hyperglycemia increased AKR1B1 activity and sorbitol accumulation, indicating polyol pathway activation in NB cells. Both NB cell lines displayed an incomplete HNE-detoxifying enzyme profile, with absence of ALDH1A1 and AKR1C3 expression. Exposure to 4-HNE reduced NB cell viability both in 2D and 3D models. Pharmacological inhibition of AKR1B1, but not of CBR1, exacerbated 4-HNE-mediated cytotoxicity. Conclusions: While hyperglycemia stimulates the polyol pathway, aldehyde detoxification by AKR1B1 supports resistance to 4-HNE toxicity, demonstrating that AKR1B1 activity is essential to counteract HNE toxicity, and its impairment may increase the susceptibility of NB cells to oxidative damage. Full article

Background/Objectives: Hereditary fructose intolerance (HFI) is an inherited metabolic disorder caused by a deficiency of the enzyme fructose-1,6-bisphosphate aldolase. Treatment consists of a lifelong diet restricted in fructose, sucrose, and sorbitol (FSS). The aim of this study was to determine dietary intake of FSS and to analyze the consumption patterns of vegetables, fruit, legumes, pulses, and dried fruit in a nationwide cohort of HFI patients. Methods: Overall, 36 HFI patients and 28 age-, sex- and BMI-matched healthy control subjects participated in this study. A self-administered three-day dietary record and an adapted quantitative food frequency questionnaire (FFQ) including frequency and portion sizes were collected. FSS intake was calculated using the DIAL Nutritional Calculation Program (ALCE INGENIERÍA). Total fructose intake was calculated as the sum of free fructose, 50% of sucrose, and sorbitol. Results: Protein intake was significantly higher in HFI patients compared to the controls (92.43 g/day [65.1–165.03] vs. 70.39 g/day [35.21–133.83]; p = 0.001). In most patients, total fructose intake was within the recommended limits (9.79 mg/kg bw/day [0.29–59.09]), with no significant differences between children and adults (p = 0.325). Although the established dietary recommendations did not always match the actual intake observed in a real-life setting, in general, foods with higher fructose content were consumed less frequently and in smaller quantities. Conclusions: Further research on the fructose content of various foods, particularly fruits and vegetables, and updated dietary recommendations for HFI patients are warranted to provide the best tools for the nutritional management of the disease. Full article

A bisphenol-A-free lignin hydrogel platform with programmable network density is reported. Lignin was crosslinked with poly(ethylene glycol) diglycidyl ether (PEGDGE) and sorbitol polyglycidyl ether (SPE) via epoxide ring-opening to generate hydrogel networks spanning eleven PEGDGE/SPE ratios. A single compositional lever—the SPE fraction—allowed the predictable densification of the network, translating into a monotonic shift in swelling and viscoelastic/mechanical responses. Importantly, the well-performing hydrogel (LS₁P₉) coupled swelling ratio with adsorption functionality, removing 72% methylene blue from water under the tested conditions. This work positions lignin as more than a passive filler: it serves as an active phenolic macromonomer for designing sustainable, multifunctional hydrogels. Full article

The increasing demand for recombinant proteins has driven innovation in bioprocessing strategies using Komagataella phaffii as a host organism. Conventional fed-batch cultivation with pure methanol induction remains widely used but presents challenges including high methanol consumption, extended downtime, and elevated operational costs. This study evaluates alternative strategies combining mixed induction (methanol/sorbitol) with continuous cultivation to enhance productivity, sustainability, and improved economic outcome. Using KEX2 protease as a model industrial recombinant protein, we compared four cultivation modes: fed-batch with methanol (benchmark), fed-batch with mixed induction, continuous with methanol, and continuous with mixed induction. Cell growth, volumetric yield, and specific productivity were evaluated at 5L scale and then modelled to simulate industrial scales (40 L and 400 L). Results demonstrate that continuous cultivation with mixed induction significantly improves yield up to 9-fold compared to conventional fed-batch and reduces methanol usage and oxygen demand. Techno-economic simulations reveal that a 40 L continuous process can match or exceed the output of two 400 L fed-batch runs, while lowering capital and operating costs and minimizing environmental footprint. This integrated strategy offers a scalable, low-cost, and safer method for recombinant protein production, supporting compact and sustainable manufacturing solutions. Full article

Cyrtorhinus lividipennis, a key natural enemy of the brown planthopper, Nilaparvata lugens, has been observed to tolerate short-term high-temperature exposure; however, the physiological and molecular mechanisms underlying this heat tolerance remain unclear, which may hinder its effective conservation and utilization. Here, we combined physiological and biochemical assays with transcriptome sequencing to elucidate the physiological and molecular mechanisms of heat tolerance in C. lividipennis following 1 h exposure to three temperatures: 26 °C (control), 33 °C (moderate heat stress), and 40 °C (severe heat stress). At 40 °C, sorbitol, trehalose, lipid, and glycogen contents increased significantly, whereas glycerol levels declined. Transcriptomic profiling revealed temperature-dependent DEGs enriched in starch and sucrose metabolism, galactose metabolism, glycerolipid metabolism, oxidative phosphorylation, and protein folding, sorting, and degradation, with pronounced temperature-dependent upregulation of heat shock protein (HSP) gene families. Together, these results demonstrate that C. lividipennis coordinates its heat stress response through soluble polyol accumulation, which is known to act as a compatible osmolytes that help stabilize proteins and membranes and mitigate thermal damage, energy metabolic reprogramming, and HSP-mediated proteostasis, thereby providing a theoretical basis for its conservation and utilization in sustainable paddy agroecosystems. Full article

Fiber-reinforced rubber composites (FRRC) are widely employed in critical industries, such as the automotive, aerospace, and construction protection industries, due to their excellent deformation resistance and superior mechanical properties. Polyester (PET) fiber, with its outstanding dimensional stability and cost-effectiveness, has increasingly replaced nylon as the primary reinforcement in radial tires. However, the lack of polar groups on PET surfaces results in poor interfacial adhesion with rubber matrices, limiting composite performance. Traditional resorcinol–formaldehyde–latex (RFL) dipping systems enhance adhesion but raise environmental and health concerns due to the release of hazardous substances. This study develops a novel eco-friendly γ-Aminopropyltriethoxysilane (KH550)–glycerol triglycidyl ether–sorbitol glycidyl ether–2-Ethyl-4-methylimidazole–latex (KG-SML) dipping system to enhance PET–rubber interfacial adhesion. At an optimal KH550 dosage of 2 phr, the 180° peel force and H pull-out force reached maximum values of 23.5 N/piece and 109.0 N, respectively, significantly surpassing the performance of the conventional RFL system. The KG-SML system offers an effective and sustainable alternative to RFL, with enhanced interfacial performance and less environmental impact. Full article

Nitrite is a common toxic substance in aquaculture, and microplastics are environmental pollutants capable of adsorbing small molecules/particles. Shrimp rely mainly on the hepatopancreas to accomplish detoxification metabolism. In this study, we investigated the individual and combined effects of nitrite and microplastics on the physiological function of the P. vannamei hepatopancreas. The results demonstrated that both nitrite and microplastics induced morphological damage, with the combined stress exacerbating tissue damage. Oxidative stress biochemical indicators were disrupted, and most enzyme activities and gene expression levels were upregulated to varying degrees in each experimental group. The expression levels of immune genes (cytC, CASP-3, Crus, ALF, and proPO), detoxification metabolism genes (CYP450, EH1, SULT, and UGT), and oxidative-stress-related genes (ROMO1, SOD, GPx, and Trx) exhibited different fluctuations. Nitrite and microplastic stress resulted in altered hepatopancreatic function, mainly involving amino acid biosynthesis and metabolism, ABC transporters, oxidative phosphorylation, and the mTOR pathway. We identified 17 metabolic biomarkers, including 6 lipids (Oleic acid, Prostaglandin G2, Linoleic acid, Palmitic acid, Docosahexaenoic acid, Docosapentaenoic acid), 6 amino acids (L-Leucine, Agmatine, L-Arginine, L-Tyrosine, Ornithine, N-Acetylornithine), and 5 carbohydrates (Glyceric acid, Citric acid, D-Mannose, Sorbitol, Fumaric acid). These findings suggest that nitrite and microplastic stresses cause hepatopancreatic tissue damage and induce oxidative stress, physiological and metabolic dysfunction in the shrimp P. vannamei, thereby impacting its normal physiological functions. Full article

Osmotic stress affects ion transport and cell hydration, potentially disrupting redox homeostasis through altered proteostasis and mitochondrial metabolism. However, how immune hemocytes coordinate volume regulation with these stress-linked processes, particularly oxidative stress and antioxidant responses, remains unclear in crustaceans. This study integrated quantitative cytology, RNA sequencing, and network analysis to profile hemocyte volume plasticity in the euryhaline shrimp Penaeus monodon across a salinity gradient. Hemocytes were incubated for 24 h in hypoosmotic, isosmotic, and hyperosmotic media, with significant volume shifts observed while maintaining membrane integrity and morphology. The permeability of solutes (urea and sorbitol) suggested that volume adjustment is coupled with solute transport. Transcriptomic analyses identified key salinity-responsive pathways, including oxidative phosphorylation, MAPK signaling, ribosome biogenesis, and antioxidant defense mechanisms, underscoring the activation of redox-regulatory systems under osmotic stress. Weighted gene co-expression network analysis highlighted ribosomal proteins as central hubs in a salinity-responsive module, with qRT-PCR confirming the co-regulation of these hubs alongside representative osmoregulatory and antioxidant genes (AQP4, Na⁺/K⁺-ATPase, HSP70, CHOP, and antioxidant enzymes). These findings reveal how hemocyte volume dynamics are coupled to redox regulation, providing a mechanistic framework for understanding osmotic stress–redox coupling in crustacean immune cells. Full article

Diabetic retinopathy (DR) is a major microvascular complication of type 2 diabetes (T2D) and is strongly associated with chronic inflammation. Neutrophils contribute to this inflammatory milieu, and the hyperosmolar stress-responsive transcription factor NFAT5 and its downstream effector aldose reductase (AR) may play crucial roles in this process. NFAT5 regulates AR, which converts glucose to sorbitol; excessive sorbitol accumulation promotes endothelial and retinal cell damage. Given the links between NFAT5, metabolic stress and immune activation, dysregulation of the NFAT5–AR axis in neutrophils may contribute to DR pathophysiology. This study evaluated NFAT5 and AR expression in peripheral blood neutrophils from 150 individuals classified as nondiabetic (n = 50), T2D without DR (n = 50), or T2D with DR (n = 50). Clinical, metabolic, and ophthalmic assessments were performed, and neutrophils were isolated to quantify NFAT5 and AR via ELISA. Associations with renal function, plasma osmolarity (pOSM), and hematological inflammatory ratios (NLR, NMR, NPAR, and SII) were analyzed. T2D-DR subjects presented impaired renal parameters, increased pOSM, reduced eGFR, and elevated NLR and NPAR. NFAT5 and AR levels were significantly increased in T2D-DR neutrophils and correlated positively with pOSM and the inflammatory ratios, whereas NFAT5 correlated inversely with the eGFR. These findings suggest that activation of the NFAT5–AR pathway contributes to neutrophil-driven inflammatory and hyperosmolar dysregulation in T2D and may influence DR progression. Full article

This study evaluated the extraction efficiency of two Natural Deep Eutectic Solvents (NADESs), glycerol–urea (1:1) and citric acid–sorbitol (1:2), for recovering phenolic compounds from the different parts of the fruit (pulp, seed-containing pulp, seeds, and peel) of Opuntia robusta and Opuntia ficus-indica in comparison with 50% methanol. Phytochemical profiling was performed using ultra-high-performance liquid chromatography–high-resolution mass spectrometry, alongside antioxidant and enzyme inhibition assessments (acetylcholinesterase, butyrylcholinesterase, tyrosinase, α-glucosidase, and α-amylase). Glycerol–urea performed similarly to methanol in extracting phenolic compounds with notable antioxidant properties. Peel extracts contained the highest levels of bioactive compounds, particularly phenolic acids (525.49 in O. robusta and 362.96 µg/g_DW in O. ficus indica). Enzyme inhibition varied across species and fruit parts, with extracts from both species inhibiting all targeted enzymes. Notably, this study provides the first evidence of tyrosinase inhibitory activity in O. robusta, which exhibited the strongest inhibition. Overall, these results emphasize the potential of cactus fruit extracts, particularly from O. robusta, for valorization, and support the use of NADESs as a sustainable and medium for extracting antioxidant compounds. Furthermore, the potential of fruit peel as waste with nutraceutical applications was demonstrated. Full article

Background: Uncontrolled diabetes is characterised by a loss of blood glucose control and increased oxidation of fatty acids to produce ATP. Use of metabolic inhibitors to blunt fatty acid oxidation and restore glucose metabolism is a poorly studied intervention for diabetes. Methods: Steptozotocin-induced diabetes was developed in Wistar male rats. A subset was supplemented with mildronate (100 mg/kg—14 days). Exploiting liquid chromatography-mass spectrometry for workflows including ion exchange-, C18-reverse phase- and HILIC-based chromatography methods, metabolite levels were quantified in plasma liver and brain tissue. Using both untargeted and targeted metabolomic analysis changes to the global tissue metabolome and individual metabolic pathways were estimated. Results: We document that an inhibitor of carnitine synthesis, mildronate, decreased plasma (50% p < 0.01) carnitine abundance and decreased plasma glucose concentration by one-third compared to streptozotocin (STZ)-treated rats (p < 0.001). Targeted metabolomic analysis of the liver showed decreased alpha-ketoglutarate abundance (35% p < 0.05) by STZ diabetes that was further decreased following mildronate treatment (50% p < 0.05). For both beta-hydroxybutyrate and succinate levels, STZ diabetes increased hepatic abundance by 50% (p < 0.05 for both), which was restored to control levels by mildronate (p < 0.05 for both). In contrast, brain TCA intermediate abundances were unaffected by either STZ diabetes or mildronate (NS for all). STZ diabetes also decreased abundance of pentose phosphate pathway (PPP) metabolites in the liver (glucose-6-phosphate, 6-phosphogluconolactone, 6-phosphogluconate 50% for all; p < 0.05), which was not restored by mildronate treatment. However, brain PPP metabolite abundance was unchanged by STZ diabetes or mildronate (NS for all). However, mildronate treatment did not affect the increased abundance of brain sorbitol, sorbitol-6-phosphate and glucose-6-phosphate as a result of STZ diabetes. Conclusions: Together, these observations highlight the potential role that metabolic inhibitors, like mildronate, may play in restoring blood glucose for diabetic patients, without a direct effect of tissues that represent obligate consumers of glucose (e.g., brain) whilst manipulating fat oxidation in tissues such as the liver. Full article

Silicon (Si) plays a critical role in regulating plant physiological processes, particularly through its influence on non-enzymatic antioxidant systems and amino acid metabolism. This study aims to assess soybean performance in response to both soil and foliar Si applications under well-watered and drought conditions, with the goal of enhancing Si accumulation in plant tissues and potentially strengthening the crop’s physiological responses to water deficit stress. This is especially pertinent given that the mechanisms underlying Si fertilization and its contribution to drought tolerance in soybean remain poorly understood. Greenhouse experiments were conducted using a 3 × 2 factorial design. The factors were: (i) three foliar Si treatments: control (no Si), potassium silicate (SiK; 128 g L⁻¹ Si, 126.5 g L⁻¹ K₂O, pH 12.0), and sorbitol-stabilized potassium silicate (SiKe; 107 g L⁻¹ Si, 28.4 g L⁻¹ K₂O, 100 mL L⁻¹ sorbitol, pH 11.8); and (ii) two soil water levels: well-watered (80% field capacity) and water-restricted (40% field capacity), the latter simulating tropical dry spells. Silicon was applied to the soil via irrigation and to the leaves via foliar spraying prior to the onset water restriction. All Si solutions were adjusted to pH 7.0 with 1 M HCl immediately before application. Potassium (K) levels were standardized across treatments through supplementary applications of KCl to both soil and foliage. Biometric and physiological parameters were subsequently measured. Sorbitol-stabilized Si enhanced Si accumulation in soybean tissues and improved plant resilience under both well-watered and drought conditions by promoting key physiological traits, including increased levels of daidzein and ascorbic acid levels, along with reduced amino acid concentrations. It also improved biometric parameters such as leaf area, root development, and number of pods per plant. These findings further support the role of Si as a beneficial element in enhancing stress tolerance and contributing to sustainable agricultural practices. Full article

This study aimed to identify fungal species causing fruit rot of chestnut (Castanea mollissima Blume) in Hebei Province, China and analyze the resistance differences among major cultivars. A total of 220 fungal isolates were obtained from healthy and diseased kernels, which were classified into six distinct genera: Diaporthe (48.6%), Talaromyces (22.3%), Alternaria (10.5%), Mucor (9.5%), Fusarium (5.5%), and Rhizopus (3.6%). Based on both morphological and molecular analyses, six representative isolates of the six genera were identified as Diaporthe eres Nitschke, Talaromyces rugulosus Samson, N. Yilmaz, Frisvad & Seifert, Alternaria alternata (Fr.) Keissl., Mucor circinelloides Tiegh., Fusarium proliferatum (Matsush.) Nirenberg, and Rhizopus stolonifer (Ehrenb.) Vuill. Among these, D. eres was first reported to cause fruit rot on C. mollissima in China. Moreover, disease resistance evaluation of major cultivars showed significant differences: YG, YSSF, and DBH exhibited strong resistance under both natural conditions (with 1.67% to 5.27% DI after 180 days storage) and artificial inoculation (with 32.96 ± 0.64 to 52.61 ± 0.55 DI); while YJ was highly susceptible (with 47.71% decay incidence and 70.50 ± 7.22 DI). Correlation analysis revealed that the disease index was negatively correlated with sucrose and sorbitol contents, but positively correlated with stachyose and fructose contents. This study advances the understanding of postharvest chestnut fruit rot and provides a theoretical basis for breeding resistant cultivars and developing control strategies to mitigate losses and ensure food safety. Full article