Search Results (1,055)

This study evaluated the effects of two euthanasia methods (blanching, blast freezing) and two drying methods (oven drying, freeze drying) on protein extractability, oil recovery, lipid oxidation, and nutritional composition of mealworm-derived full-fat flours, defatted flours, and protein concentrates. Protein extraction yields differed significantly among treatments (ANOVA, p < 0.001), except between blanched + freeze-dried and blast-frozen + oven-dried samples. Blast freezing resulted in higher protein extraction yields than blanching. Blast freezing markedly increased acid values (>40 mg KOH/g oil) relative to blanching (<5 mg KOH/g), while freeze drying increased peroxide values more than tenfold compared with oven drying. Ash contents ranged from 4 to 8% without a treatment effect. Defatting significantly reduced oil content and increased protein and chitin contents. Chitin was nearly absent in protein concentrates. In blast-frozen + oven-dried protein concentrates, the oil content was significantly up-concentrated compared with defatted samples. P, Mg, and K significantly increased in defatted samples, while protein extraction reduced Mg, K, and Ca but increased Na due to alkaline solubilization. Micromineral profiles were most affected in protein concentrates, with increases in Cu and Fe and minor decreases in Mn. Overall, euthanasia and drying methods influence yield and quality, highlighting the need for tailored, scalable processing strategies for mealworm-based food and feed applications. Full article

Honey authenticity is increasingly threatened by the addition of low-cost sugar syrups and substitutes, which reduce its nutritional value and market credibility. In this study, five types of Polish honeys (honeydew, forest, multifloral, nectar–honeydew, and rapeseed) were intentionally adulterated with beet syrup, beet molasses, invert syrup and artificial honey at levels of 10% and 50% (v/v). The impact of adulteration was evaluated using elemental profiling by ICP-OES combined with physicochemical analyses (water content, sugar content and electrical conductivity) and chemometric methods (PCA and HCA). Natural honeys were characterized by high K, Mg and Ca contents and low Na levels, whereas adulterants significantly altered mineral composition, leading to a marked decrease in key authenticity ratios, particularly K/Na (decreases exceeding 90% at the 50% adulteration level, with systematic shifts already observable at 10% addition). Beet molasses caused the strongest disturbances in macroelement balance, while invert syrup induced weaker effects. Adulteration also resulted in increased water content, reduced °Brix values and pronounced changes in electrical conductivity. Chemometric analysis enabled clear discrimination between natural, adulterated and sugar-based samples. The combined use of elemental ratios, physicochemical parameters and chemometrics provides a robust and sensitive approach for detecting honey adulteration and supporting authenticity control. Full article

Sabkhas, hypersaline ecosystems along Kuwait’s coastal zone, are extreme environments that harbor diverse halophilic microorganisms with significant biotechnological potential. Despite this, they remain underexplored, particularly in the context of enzymes that can function under high salinity. The aim of this study is to identify bacterial isolates from Kuwait’s sabkhas that produce α-amylase under extreme environmental conditions and to purify and characterize the resulting halotolerant α-amylase. Among the seven α-amylase-producing isolates, Priestia sp. W243, isolated from Mina Abdullah, exhibited the highest enzyme production under optimal growth conditions of pH 9.0, 37 °C, and 7.5% NaCl. A novel halotolerant α-amylase with a remarkably high specific activity (8112.1 U/mg) was purified from this isolate using ultrafiltration, ion-exchange chromatography, and gel-filtration. The purified enzyme, with a molecular weight of 25 kDa, showed optimal activity at 40 °C, pH 8, and 3% NaCl. Notably, the enzyme remained active in the absence of salt and up to 15% NaCl, demonstrating exceptional halotolerance. Metal ion profiling revealed that enzyme activity was significantly enhanced by Co²⁺, whereas Ca²⁺ had a comparatively moderate effect on enzyme activity. When the effects of metal chelators were examined, EDTA, a strong metal chelator, inhibited the enzyme. However, the enzyme remained active when Ca²⁺ was specifically removed using EGTA, suggesting that this α-amylase may be a cobalt-dependent metalloenzyme, which is an unusual characteristic among known α-amylases. Additionally, the enzyme retained its catalytic activity under reducing conditions (e.g., in the presence of DTT and β-mercaptoethanol), indicating structural stability is independent of disulfide bonds. These unique properties distinguish this α-amylase from typical salt- or calcium-dependent counterparts and highlight its potential for industrial applications in high-salt food processing, baking, brewing, and environmental remediation. Full article

MASH is a progressive liver disease closely associated with cellular senescence, which is present in more than 80% of hepatocytes in patients who develop hepatocellular carcinoma (HCC). Although MASH affects both sexes, the incidence of MASH-related HCC is two to four times higher in males. Our group has previously described two apoptotic switches during MASH progression and HCC development, implicating the ATP1A1 signalosome in the late switch. Here, we investigated the role of ATP1A1 and sex-specific differences in the early apoptotic switch during preclinical MASH progression. Male and female C57BL/6J mice (7 weeks old) were fed normal mouse chow (NMC) or a high-fat diet (HFD) for 12, 24, or 48 weeks (n = 5/sex/group). Total body weight (TBW) and body composition were assessed by serial measurement and echo-MRI. Plasma was analyzed by non-targeted metabolomics and glutathione profiling using LC-MS/MS. NAFLD activity scores (NAS), hepatic senescence, and apoptosis were quantified in liver tissue. Statistical analyses were performed using GraphPad Prism and R. Males gained greater TBW and lean and fat mass than females (p < 0.05). At 24 W, males demonstrated higher GSH:GSSG ratios and lower ophthalmate levels than females (p < 0.05), consistent with altered redox balance. HFD-fed females showed increased succinic and deoxycholic acid levels, whereas males exhibited higher butyric acid levels across all time points (p < 0.05). Males had a higher mTOR 1 expression at 24 W and P53 at 12 W compared to females on HFD, but a lower Grb2 expression at 24 W (p < 0.05). By 24 W, males had lower fibrosis scores and reduced apoptotic activity compared with females (p < 0.05), despite similar levels of cellular senescence. The expression of ATP1A1, survivin, and SMAC did not differ by sex or diet, although an upregulation trend in both ATP1A1 and survivin was noted in the male-HFD group. There is sexual dimorphism in the response to HFD during the transition from senescence to the apoptosis-first apoptotic switch in MASH progression. Full article

Background: Bovine mastitis (BM) remains an economically significant disease in the global dairy industry. Multidrug resistance (MDR) in Klebsiella pneumoniae and Klebsiella grimontii has increased in recent years, representing an area of concern related to BM. Methods: Bovine mastitis 1-DH1 and 2-DH2 isolates (n = 2) were investigated. Antimicrobial susceptibility testing was performed using the Neg-Urine-Combo98 panel. Antimicrobial resistance genes (ARGs), virulence factor (VF) genes and plasmid replicons were identified by whole-genome sequencing (WGS). Phylogenomic analyses were performed for a visual comparison of the genomes. Results: Phenotypically, isolates 1-DH1 and 2-DH2 were identified as K. pneumoniae-1DH1 and Klebsiella oxytoca, respectively; the latter was subsequently confirmed as K. grimontii-2DH2 by WGS. K. pneumoniae-1DH1 (20.0%, 5/25) exhibited phenotypic resistance to amoxicillin–clavulanic acid, ampicillin (AM), cefuroxime, colistin (Cl), and nitrofurantoin (Fd), whereas K. grimontii-2DH2 (8.0%, 2/25) was resistant to AM and nalidixic acid (NA). In total, 31 and 32 ARGs and 10 and 15 VF genes were identified in K. pneumoniae-1DH1 and K. grimontii-2DH2, respectively. Two plasmid replicons were detected in K. pneumoniae-1DH1 (one harboring the blaCTX-M ARG) compared to one in K. grimontii-2DH2 (encoding both the blaCTX-M ARG and the astA VF gene) isolates, respectively. Phylogenomic analysis showed that K. pneumoniae-1DH1 clustered most closely with human-derived K. pneumoniae isolates, whereas K. grimontii-2DH2 grouped with environmental K. grimontii isolates. Conclusions: Novel phenotypic resistance profiles were observed in the BM-associated K. pneumoniae-1DH1 (MDR, Cl and Fd) and K. grimontii-2DH2 (AM and NA) isolates. Notably, K. grimontii-2DH2 harbored a plasmid replicon carrying both the blaCTX-M ARG and the astA VF gene. Full article

This study aims to investigate the functional and biochemical characteristics of sprouted and unsprouted red and black amaranth flours by fermentation with four probiotic strains (Lactiplantibacillus plantarum MIUG BL21, Lactiplantibacillus pentosus MIUG BL24, Lacticaseibacillus rhamnosus MIUG BL38, and Lactiplantibacillus paraplantarum MIUG BL74). Aqueous extracts from freeze-dried fermented products derived from sprouted and raw seed of two Amaranthus species (Amaranthus cruentus—red amaranth and Amaranthus hypochondriacus—black amaranth) were characterised for their acidification and phytochemical profiles by titrimetric, spectrophotometric and chromatographic methods, and their antioxidant activities by ABTS and DPPH assays. Water-soluble proteins were evaluated by SDS-PAGE analysis. Nine phenolic acids (gallic acid, protocathechic acid, syringic acid, ellagic acid, ferulic acid, cinnamic acid, caffeic acid, p-coumaric acid, and chlorogenic acid) and twelve flavonoids (epicatechin gallate, hesperitin, quercetin, apigenin, luteolin, naringenin, quercetin 3-glucoside, isorhamnetin, peonidin 3-O rutinoside, epicatechin, keracyanin, and rutin trihydrate) were identified in the extracts of amaranth samples. The titratable acidity ranged from 0.59 to 5.50 mL of 0.1 N NaOH. Total flavonoid content (TFC) varied from 1.09 to 4.67 mg CE/g DW; whereas, total phenolic content (TPC) fluctuated from 1.99 to 5.76 mg GAE/g DW. The spectrum of ABTS and DPPH values was from 17.49 to 56.82% and 0.60 to 35.50%, respectively. More biologically active compounds were found in red amaranth-based samples, both sprouted and unsprouted, compared to black amaranth-based samples. There was a moderate correlation between the TPC and the antioxidant activity. The fermentation of red amaranth with L. rhamnosus MIUG BL38 led to a global increase in the protein background intensity, consistent with protein hydrolysis. Overall, sprouting and probiotics fermentation improved the fermentative performance of the amaranth seeds, enabling their effective use as a nutritive food with potential health-promoting properties. Full article

In the male body, zinc accumulates most abundantly in prostatic cells, where it plays a key role in producing high amounts of citrate in seminal fluid. Intraprostatic accumulation of Zn increases during the development of benign prostatic hyperplasia (BPH), one of the most common diseases in men over 50 years of age. Continuing our investigations on intraprostatic androgens, in this study, we analyzed the mineral content (Zn, Ca, Cu, K, Mg, Mn, and Na) in the transitional zone (TZ) of the prostate using inductively coupled plasma optical emission spectrometry (ICP-OES). The concentrations of testosterone (T) and dihydrotestosterone (DHT) were determined by liquid chromatography–mass spectrometry (LC-MS). Group-wise and correlation analyses demonstrated a descriptive trend toward a volume-dependent increase in Zn concentrations within TZ tissue, whereas other elements exhibited heterogeneous covariance patterns; intraprostatic hormone levels, although elevated in larger prostates, showed no consistent linear correlations with elemental concentrations. Given the observational design of the present study, the reported tissue Zn profiles cannot be interpreted as evidence supporting supplementation in BPH, and any potential clinical implications warrant evaluation in rigorously designed interventional studies. Full article

Naomaohu coal from the Santanghu Basin, Xinjiang, is characterized by anomalously high Na and Ca contents, which strongly affect its gasification behavior and slagging tendency. However, the genetic linkage between geological alkali enrichment and their transformation during thermal processes remains insufficiently constrained. In this study, an integrated investigation combining coal seam profile analysis, coal petrography, mineralogical characterization, and fixed-bed gasification experiments was conducted to elucidate the enrichment mechanisms and transformation pathways of alkali and alkaline earth metals (AAEMs). A total of forty six samples were collected along a vertical seam profile to determine the depositional control of alkali and alkaline earth metals (AAEMs), and seven representative samples were further subjected to pressurized fixed-bed gasification. Alkali migration and mineral phase evolution were systematically analyzed using XRD, XRF, and SEM-EDS. The results indicate that Na enrichment is mainly controlled by groundwater infiltration and weak paleoweathering, while Ca accumulation reflects deposition in humid, Ca-rich mire environments. During gasification, Na volatilizes and recondenses as Na-feldspars (NaAlSi₂O₆) and NaCl, whereas Ca decomposes into gehlenite (Ca₂Al₂SiO₇) and brownmillerite (Ca₂AlFeO₅). The formation of these low-melting Na–Al–Si phases and Ca–Fe–Al phases dominate the ash fusion and slagging behavior. This study establishes a coupled geological–thermal transformation model for AAEMs in high-Na coal, providing mechanistic insight into mineralogical inheritance and offering guidance for mitigating alkali-induced slagging during gasification. Full article

Thanks to its valuable nutritional value and captivating flavour, tahini, an oily paste made from sesame seeds, has recently become popular outside of Middle Eastern cuisine. However, alongside valuable and balanced levels of lipids, proteins, sterols, and minerals, this product may contain various contaminants, including toxic and potentially toxic elements. The aim of this study was therefore to evaluate the quality and safety of seven brands of commercial tahini. To this end, the proximate composition and the fatty acid and sterol profiles were determined. Moreover, the atherogenicity index (AI) and thrombogenicity index (TI) were also assessed. The elemental composition was screened, and the uptake percentage of each element was evaluated. The percentages of saturated (SFAs), mono- (MUFAs), and poly- (PUFAs) fatty acids fell within the following ranges, respectively: 15.44–17.14%, 37.93–43.36%, and 38.51–45.14%. The order of abundance of macro-elements for most samples was P > K > Ca > Mg > Na. Significant concentrations of essential trace elements were found in the tahini samples, including Zn, Fe, Mn, Cu and Se. As regards toxic elements, only one brand appears to exceed the maximum limits for Cd and Pb specified in the European Regulation. However, a low intake of most inorganic elements was obtained from the consumption of 1 g of tahini per day. Full article

This review examines and hypothesizes cytoprotection as a conceptual therapeutic criterion for antiarrhythmic drugs, referring to the possibility of suppressing arrhythmias while avoiding adverse electrophysiological or systemic effects. Toward a theoretically complete cytoprotective profile—preserving benefits and eliminating toxicity—the criterion was the degree of counteraction of arrhythmias (i.e., bradycardia, tachycardia, atrioventricular (AV) block, ventricular tachycardia (VT), ST-segment changes, prolonged P, PR, QRS, and QT/QTc intervals, and repolarization). Conventional and new antiarrhythmics share class I–IV ≈ partial cytoprotection/narrow range; late INa inhibitors, IKs enhancers, RyR2 stabilizers, gap junction modulators, and atrial-selective antiarrhythmics ≈ partial cytoprotection/more extended range. Still predominantly in preclinical models, stable gastric pentadecapeptide BPC 157, in the clinic, has not demonstrated adverse effects in available human trials (non-cardiac) to date. As a prominent cytoprotection mediator (LD1 not achieved in toxicology studies), it demonstrates well-matched cytoprotective–antiarrhythmic effects, BPC 157 ≈ full cytoprotection/wide-range homeostasis. In vivo, this was across models of hypo-/hyperkalemia, hypermagnesemia, ischemia–reperfusion, myocardial infarction, drug-induced arrhythmias (including local anesthetics), and vascular occlusion. BPC 157 restores sinus rhythm, normalizes P/QRS/QT intervals, prevents AV block, suppresses VT, attenuates ST-segment changes, and stabilizes heart rate, even when insults are advanced. In vitro, HEK293 studies confirm direct membrane-stabilizing actions: BPC 157 prevents hypokalemia-induced hyperpolarization, reduces hyperkalemia- and hypermagnesemia-induced depolarization, and mitigates local anesthetic-induced Na⁺/Ca²⁺ dysregulation, reflecting bidirectional homeostatic modulation of membrane potential. Thus, to confirm the hypothesis, these BPC 157 conditional, not constitutive effects, in rodent models or in vitro systems (HEK293 cells), mandate expansion of now limited clinical data and mechanisms in human investigated as a translational cytoprotective strategy for complex arrhythmias. Full article

Background/Objectives: Amblyaudia (AMB) and dichotic dysaudia (DD) are distinct subtypes of dichotic listening deficits characterized by different behavioral profiles. AMB is associated with marked interaural asymmetry, whereas DD is defined by bilaterally poor but relatively symmetric performance. The present study investigated whether these behavioral distinctions are reflected in the auditory middle latency response (MLR). Specifically, we examined whether children with AMB exhibit asymmetric MLR patterns and whether children with DD demonstrate more symmetric responses, relative to typically performing (TYP) peers. Methods: Thirty-seven children aged 9–12 years with normal peripheral hearing were recruited through clinical referrals and community outreach. Participants were classified as AMB, DD, or TYP based on performance on standardized dichotic listening measures. MLRs were recorded in response to monaural click stimulation delivered to each ear at both slow and fast presentation rates. Peak-to-peak Na–Pa amplitude and latency were analyzed to assess ear- and electrode-related effects across groups. Results: Children with AMB showed significant ear effects, with larger Na–Pa amplitudes elicited by left-ear stimulation, particularly at electrode C4, consistent with their behavioral asymmetry. In contrast, the DD group exhibited minimal amplitude asymmetry but showed prolonged Na–Pa latencies for right-ear stimulation at faster presentation rates. TYP children demonstrated small, expected asymmetries without significant latency delays. No reliable electrode effects were observed across groups. Conclusions: The MLR differentiated between subtypes of dichotic listening deficits in ways that paralleled behavioral performance, with amplitude asymmetry characterizing AMB and rate-dependent latency differences observed in DD. These findings suggest that the MLR may provide complementary, objective information relevant to the characterization of distinct dichotic listening profiles in children. Full article

Soil salinization and alkalinization critically constrain alfalfa (Medicago sativa L.) productivity, yet the regulatory mechanisms underlying its responses to salt–alkali stress are not fully understood. In this study, the alfalfa variety “Zhongmu No. 1” was used as experimental material. The seeds were subjected to salt stress (75 mM NaCl), alkali stress (15 mM NaHCO₃), and combined salt–alkali stress (50 mM NaCl + 5 mM NaHCO₃) in dishes, with ddH₂O serving as the control (CK). After 7 days of germination, the seedlings were transferred to a hydroponic system containing Hoagland nutrient solution supplemented with the corresponding treatments. Following 32 days of stress exposure, leaf and root tissue samples were collected for morphological and physiological measurements, as well as mRNA and miRNA sequencing analyses. Physiological assays revealed significant growth inhibition and increased electrolyte leakage under stress conditions. Transcriptome profiling identified over 5000 common differentially expressed genes (DEGs) in both leaves and roots under stress conditions, mainly enriched in pathways related to “iron ion binding”, “flavonoid biosynthesis”, “MAPK signaling”, and “alpha-Linolenic acid metabolism”. MiRNA sequencing detected 453 miRNAs, including 188 novel candidates, with several differentially expressed miRNAs (DEMs) exhibiting tissue- and stress-specific patterns. Integrated analysis revealed 147, 81, and 140 negatively correlated miRNA–mRNA pairs across three treatment groups, highlighting key regulatory modules in hormone signaling and metabolic pathways. Notably, in the ethylene and abscisic acid signaling pathways, ERF (XLOC_006645) and PP2C (MsG0180000476.01) were found to be regulated by miR5255 and miR172c, respectively, suggesting a post-transcriptional layer of hormonal control. DEM target genes enrichment pathway analyses also identified stress-specific regulation of “Fatty acid degradation”, “Galactose metabolism”, and “Fructose and mannose metabolism”. qRT-PCR validation confirmed the expression trends of selected DEGs and DEMs. Collectively, these findings reveal the complexity of miRNA–mRNA regulatory networks in alfalfa’s response to salt–alkali stress and provide candidate regulators for breeding stress-resilient cultivars. Full article

Background/Objectives: Soil salinization and alkalization critically limit global agricultural production. This study aimed to investigate the differential response mechanisms of rapeseed (Brassica napus L.) varieties to saline and alkaline stresses at the seedling stage. Methods: Seedlings of a salt-tolerant variety, Huayouza 62 (H62), and a non-salt-tolerant variety, Xiangyou 15 (X15), were exposed to saline (NaCl:Na₂SO₄ = 1:1) and alkaline (Na₂CO₃:NaHCO₃ = 1:1) stresses. An integrated analysis combining physiology, biochemistry, transcriptomics, and metabolomics was conducted to systematically elucidate their differential stress responses. Results: (1) H62 maintained favorable photosynthetic and carbon–nitrogen homeostasis. Notably, under saline and alkaline stresses, the activity of glutamate dehydrogenase (GDH) in H62 showed a significant increasing trend, whereas it was inhibited in X15. (2) Alkaline stress triggered more differential genes than saline stress, with H62 exhibiting broader transcriptional up-regulation in carbon–nitrogen metabolism. (3) Metabolomic profiling showed that H62 accumulated more beneficial metabolites than X15 under both stresses, such as phenolic acids, amino acids, and their derivatives. (4) In multi-omics analysis, key genes in starch–sucrose and amino acid metabolism in H62 were up-regulated to accumulate osmolytes, enabling an efficient defense network. However, X15’s responses were disordered. Conclusions: H62 leverages robust transcriptional reprogramming to coordinate carbon–nitrogen metabolism, constituting a multidimensional defense network. This study provides potential physiological indicators, candidate genes, and metabolite markers associated with short-term saline–alkaline stress responses, laying a foundation for further exploration of stress response mechanisms. Full article

Per- and polyfluoroalkyl substances (PFAS) are global pollutants, yet data from tropical freshwater ecosystems remain scarce. This study provides the first assessment of PFAS occurrence in the Rusizi delta (Burundi), from tributaries to Lake Tanganyika, by analyzing water, sediment, macrophytes, and fish, and by evaluating human health risks from fish consumption. In water, only PFOA (<0.60–7.80 ng/L) was detected and showed a uniform spatial distribution. Sediment concentrations were largely below quantification limits, likely reflecting unfavorable sorption conditions. Macrophytes were dominated by short-chain PFAS, particularly PFBS, without consistent species- or site-specific patterns, supporting their potential as biomonitors of cumulative PFAS exposure. Fish exhibited the highest PFAS diversity, with more diverse profiles in liver than muscle, although tissue-specific patterns were often absent. PFBS was dominant across fish species, and emerging PFAS (e.g., PFBS and NaDONA) were frequently detected. Human health risks from fish consumption were, except for children, mostly below EFSA tolerable weekly intake values for regulated PFAS, but potential concern for adolescents and adults emerged when PFAS were expressed as PFOA equivalents. This study provides essential baseline data for tropical freshwater systems and highlights the need for expanded PFAS monitoring and risk assessment in data-poor regions. Full article

Molting is an important biological and physiological stage in penguins, influenced by environmental and nutritional factors. Feather composition analysis before and after molting can consequently place boundaries on element bioaccumulation and excretion. We quantified and compared elemental concentrations in African penguin (Spheniscus demersus) feathers collected pre- and post-molt across three zoos to evaluate how molt stage and zoo-specific conditions influence feather elemental composition. Feathers were retrieved from individual penguins at Zoom Torino (Italy), Overloon ZooParc (Netherlands), and Zoo Magdeburg (Germany). Quantification of elemental concentrations were performed by analytical methods, with both ICP-OES and HR-ICP-MS techniques. A statistical approach involving MANOVA and factorial analysis helped identify important trends. Pre-molt features had more variability than post-molt, with both showing significant differences in elemental concentrations. Factorial analysis showed geogenic trends in Mg, Sr, and Ni trends as well as anthropogenic trends in Pb. While Na and K differed among all treatment groups, this likely points to physiological adaptations in response to increased demand during feather regrowth. Additionally, inter-zoo comparisons highlighted distinct elemental profiles linked to local environmental and dietary conditions, particularly in Zoo Magdeburg, where Na levels were markedly elevated. This study highlights the influence of environmental and dietary conditions on feather composition during molt, offering insights for improving captive penguin welfare and broader ecological implications related to climate change and pollution. Full article