Increase In Sodium Concentration Research Articles

The effect of water filter pitchers on the mineral concentration of tap water.

To investigate the effect of water filter pitchers on the concentration of different minerals in tap water. Nine water filter pitchers (A-I) were chosen based on consumer preferences and Amazon reviews. Each filter was tested for its ability to modify the concentrations of fluoride, calcium, magnesium, potassium, and sodium in tap water. Tap water samples were collected before and after filtration, at various intervals (1, 5, 10, 30, 50, 75, and 100 L) during filtration, and analyzed using an ion-specific electrode (fluoride) and atomic absorption spectrometry (other minerals). Statistical analyses were conducted to compare filtered and unfiltered water mineral concentrations. Water filter pitcher effect: Filters F (p < 0.001) and G (p = 0.030) decreased fluoride concentrations. All filters except I (p = 0.235) and H (p = 0.717) decreased calcium concentrations (p < 0.01). Filters E (p = 0.018), D (p = 0.014), and G (p = 0.010) decreased magnesium concentrations. Filters I (p = 0.028) and D (p = 0.009) increased potassium concentrations. Filter A (p = 0.002) increased sodium concentrations, while C (p = 0.034) decreased sodium concentrations. Effect of filter aging: All filters affected mineral concentrations over time but to varying extents. Filter G had the most pronounced effect on reducing mineral concentrations compared to all others. No filter was able to completely remove fluoride from tap water, contrary to the claims made by three manufacturers. The present study highlighted that water filter pitchers vary greatly in their ability to affect mineral concentrations in tap water during their use. Further research is needed to develop more effective water treatment solutions.

From grass to yeast; functional insights from heterologous expression of LfHKT2;1 in ion regulation

Saccharomyces cervisceae mutants lacking the major potassium trasnporters trk1 and trk2 show hypersensitivity to aminoglycoside antibiotic hygromycin (hyg). This study demonstrates that expression of the inward K+ transporter LfHKT2;1 can suppress this hygromycin sensitivity in the trk1, trk2 double mutant strain. Growth complementation was performed on solid yeast peptone dextrose (YPD) media supplemented with hygromycin B. Both, wild type and trk1 trk2 yeast strains exhibited growth inhibition in the presence of hygromycin. However the potassium uptake-deficient trk1 trk2 strain (control) showed complete growth arrest when exposed to hygromycin, while expression of LfHKT2;1 resulted in growth recovery. Increased sodium concentrations caused cellular toxicity in the trk1 trk2 strain, which was exacerbated by the addition of hygromycin to the media. The hypersensitivity of trk1 trk2 mutant yeast cells expressing LfHKT2;1 to sodium suggested the presence of an additional sodium uptake system on the membrane, which was further confirmed by transient GFP expression assays. These results provide conclusive evidence that heterologous expression of LfHKT2;1 confers both sodium and K+ uptake capabilities in hygromycin supplemented YPD media, thereby rescuing the growth of K+ transport-deficient S. cerevisiae mutants. This highlights the potential of plant gene expression in yeast as a valuable tool for studying ion transport mechanisms and gene function under stress conditions.

Thirst and the influence of ionic concentration; an investigation into the effect on salivary lubrication and the role of MUC5B

Saliva plays a crucial role in lubricating the oral cavity and maintaining a normal hydrated mouthfeel, with the main macromolecule in saliva, MUC5B, playing a significant role in its lubricating properties. Mucins form a hydrated biogel that covers the oral epithelium and forms part of the mucosal pellicle, maintaining proper hydration. This study investigates the relationship between ionic concentration, saliva lubrication, and the perception of oral dryness. At baseline, sodium was found to be ten times more concentrated in the mucosal pellicle compared to bulk saliva, in contrast to potassium which was only 1.5 times more concentrated in the pellicle. Increasing concentrations of mouthwashes containing sodium or potassium indicated a preferential sequestering of sodium in the mucosal pellicle with sodium chloride rinses being associated with an increased thirst perception. We therefore propose that sodium binds to MUC5B, reducing the electrostatic repulsions between its negatively charged moieties. This interaction subsequently leads to a compaction of the mucin structure, which decreases the hydration of MUC5B and reduces its lubricating properties. We determined that increased sodium concentrations compact the mucin structure as indicated by transmission electron microscopy. However, we found that increased sodium concentrations were associated with improved the lubrication of salivary and MUC5B films in an oral tribology mimic, decreasing the coefficient of friction from 0.044 to 0.018, and 0.416 to 0.100 with the addition of 200 mM sodium chloride for saliva and MUC5B, respectively. MUC5B was also demonstrated to become more hydrated with increasing ionic concentrations, as indicated by Quartz Crystal Microbalance with Dissipation. We therefore propose that increased hydration shells surrounding the sodium counterions are responsible for this improved lubrication via the hydration lubrication mechanism. Lastly, it was observed that the spinnbarkeit of saliva decreased with increasing ionic concentrations, indicating a reduced stretchiness in its rheological properties. However, the concentration of MUC5B alone did not appear to affect spinnbarkeit, highlighting that many factors influence the biophysical properties of saliva.

From mixed brookite/anatase TiO2 nanopowder to sodium titanates: Insight into morphology, structure, and photocatalytic performance

A method to obtain sodium titanate nanoribbons starting from a mixture of brookite and anatase TiO₂ nanopowder is described. As-prepared TiO2 nanopowder with a major brookite phase was used as a precursor in an alkaline hydrothermal approach, where the temperature was kept at 200 °C. The influence of hydrothermal treatment and consequent annealing temperature (T = 500 °C) on the crystal structure, phase composition, and morphology of samples were investigated by X-ray powder diffraction (XRPD), Raman and FTIR spectroscopy, and electron microscopy techniques (FESEM, HRTEM). All these methods point out that the hydrothermally treated sample, containing the NaTi3O6(OH)(H2O)2, Na2Ti3O7, and Na2Ti9O19, is dominated by layer-structured sodium hydroxititanate dihydrate. The annealing leads to the formation of rare sodium titanates, Na3Ti6O13 and Na2Ti9O19, with tunnel structures where the hexatitanate with increased sodium content prevails. The photocatalytic activity of synthesized nanostructures was tested in the degradation process of Reactive Orange (RO16) azo-dye upon UV excitation. It appears that photocatalytic activity is lower after hydrothermal treatment, but subsequent annealing makes sodium titanate nanoribbons faster in the degradation of RO16. The research implies that these sodium titanate nanostructures are promising photocatalytic materials and should be considered in the future for removing different pollutants from water.

Let the dust settle: Impact of enhanced rock weathering on soil biological, physical, and geochemical fertility

Terrestrial enhanced rock weathering (ERW) is a promising carbon dioxide removal technology that consists in applying ground silicate rock such as basalt on agricultural soils. On top of carbon sequestration, ERW has the potential to raise the soil pH and release nutrients, thereby improving soil fertility. Despite these possible co-benefits, concerns such as heavy metal pollution or soil structure damage have also been raised. To our knowledge, these contrasted potential effects of ERW on soil fertility have not yet been simultaneously investigated. This field trial aimed at assessing the impact of ERW on biological, physical, and chemical soil properties in a temperate agricultural context. To do so, three vineyard fields in Switzerland were selected for their distinct geochemical properties and were amended with basaltic rock powder at a dose of 20 tons per hectare (2 kg.m−2). On each field, basaltic rock powder was either applied one year before the sampling campaign, one month before the sampling campaign, or not applied (control) for a total of 27 plots with 9 repetitions of each level. Overall, basaltic rock powder addition had a predominantly positive to neutral effect on soil fertility. Most soil properties showed no significant change either 1 month or 1 year post application. Nevertheless, our study highlighted a significant increase in earthworm abundance (+71 % on average), soil respiration (+50 %) and extractable sodium concentration (+23 %) as early as 1 month post application. The higher soil respiration raises the question of CO2 losses from organic matter mineralization that could limit ERW's efficiency. The increase in sodium raises concerns about a sodification risk potentially damaging soil fertility. These elements now require further investigation before enhanced rock weathering can be considered a viable and secure carbon dioxide removal technology.

Abstract 30: Acute Effects Of Sodium Chloride Or Its Substitute Potassium Chloride On Microvascular Function In Healthy Volunteers

Dietary high sodium intake is a modifiable risk factors for cardiovascular (CV) diseases including vascular dysfunction and subsequently arteriosclerosis. A partial sodium substitution by potassium is associated with a lower risk of CV events and death. Our aim was to investigate the acute impact of sodium and potassium on retinal microvascular function, an established biomarker for systemic CV risk stratification. Eighteen male and 27 female healthy individuals (mean age 31years) were randomized to eat a salty soup containing either 9g sodium chloride (high salt group), 6g sodium chloride (intermediate salt group) or 6g sodium chloride plus 3g potassium chloride (substitution group). Microvascular measurements were performed before (t0) as well as four (t4) and 24 hours (t24) after soup intake. Microvascular health was measured by investigating retinal vessel diameters. A higher arteriolar-to-venular diameter ratio (AVR) is associated with improved vascular health. Microvascular endothelial function was quantified by flickerlight-induced retinal arteriolar dilation. The 9g (139±2mmol/l vs. 141±2mmol/l, p&lt;0.001) and 6g salt group (140±1mmol/l vs. 141±2 mmol/l, p=0.028) had higher serum sodium concentrations at t4 compared to baseline. Serum sodium concentrations of the substitution group showed no significant difference between time points, but a significant increase in serum potassium (3.7±0.3mmol/l vs. 3.9±0.2mmol/l, p=0.019). Microvascular endothelial function was significantly decreased in the high salt group from baseline to t4 (4.5±2.2% vs. 3.7±2.2%, p=0.041), without significant changes in the other groups. In the sodium groups, there was a strong correlation between the increase in serum sodium concentration from t0 to t4 and an impaired endothelial function after t4 (R 2 =0,255, p=0,005). The substitution group showed improved microvascular health, quantified by higher AVR at t4 compared to t0 (0,83±0,07 vs. 0,86±0,07, p&lt;0,001). An increase in serum sodium was negatively associated with AVR (R 2 =0,14, p=0,013) whereas an increase in serum potassium was positively correlated with AVR (R 2 =0,19, p=0,003). An acute increase in serum sodium is associated with impaired microvascular endothelial function. Replacement of sodium by potassium seems to improve microvascular function already after a single potassium intake. These results might explain the beneficial effects of potassium on CV outcomes as well as the harmful effects of sodium on vascular function.

Unveiling the Patterns of Water Diuresis in Profound Hyponatremia Management in Intensive Care Unit Settings.

Hyponatremia treatment guidelines recommend avoiding excessive increases in serum sodium concentration (s[Na]) to prevent osmotic demyelination syndrome. Although an unexpected rise in s[Na] has been attributed to water diuresis during the treatment of hyponatremia, clinical courses of water diuresis are unclear. We conducted this study to investigate the clinical characteristics of water diuresis during profound hyponatremia management. In this retrospective observational study, we examined patients with profound hyponatremia (s[Na] ≤120 mEq/L) admitted to the intensive care unit of a Japanese hospital. The manifestation of water diuresis was defined as a urine volume ≥2 ml/kg/h and a urinary sodium plus potassium concentration (u[Na+K]) ≤50 mEq/L. We analyzed changes in urine volume and u[Na+K] over time for patients experiencing water diuresis. This analysis employed a mixed-effects model with spline terms for time, and the results are graphically presented. Among 47 eligible patients, 30 (64%) met the criteria for water diuresis. The etiologies of hyponatremia were drug-related hyponatremia (n=10; 33%), primary polydipsia (n=8; 27%), hypovolemic hyponatremia (n=7; 23%), syndrome of inappropriate secretion of antidiuresis (n=7; 23%), and acute heart failure (n=1; 3%). Among patients with water diuresis, 27 (90%) experienced the manifestation of water diuresis within 24 hours after the start of correction. The increased urine volume and decreased u[Na+K] levels began several hours before the peak manifestation of water diuresis. Within 6 hours after the manifestation of water diuresis, 29 patients (97%) received electrolyte-free infusions and 14 (47%) received desmopressin. One patient (3%) with water diuresis experienced overcorrection. Water diuresis is common during the treatment for profound hyponatremia and typically occurs within the first 24 hours, preceded by changes in urinary characteristics. Early detection and prompt response to water diuresis through urine monitoring during the early periods of hyponatremia treatment may be effective for managing water diuresis.

Solid humic substance enhanced spinach abiotic stress tolerance under combined drought, salinity, and daily heat stress

Spinach is a crop of economic importance in the Wintergarden region of Texas, where increasing soil salinity, irrigation water restrictions, and heat stress challenge its production. Improving abiotic stress tolerance and resource use efficiency are important goals for sustainable agricultural production. Although the effect of humic substances (HS) on abiotic stress tolerance in spinach has been evaluated under single stress, such as heat, drought, or salinity, their impact under combined abiotic stresses is unknown. We hypothesized that solid humic substances would be effective in alleviating multifactorial abiotic stress in spinach, which we examined in our first experiment, and further hypothesized that salinity stress in spinach would occur after a threshold intensity but that humic substance applications would ameliorate stress intensity past this threshold, which we examined in our second experiment. Three-week-old spinach seedlings (Spinacia oleracea L. cv. ‘Seaside’) were grown using an automatic gravimetric watering system in a climate-controlled high tunnel where daily maximum temperatures exceeded 32 °C. In a factorial experiment, we applied HS (control and 1 % v/v HS media amendment), drought (100 % and 50 % field capacity), and salinity (25 mL of RO water or 100 mM NaCl every other day) treatments. HS and HS×Salinity treatments more than doubled shoot and root FW and DW, leaf area, root length, and root surface area compared to other stresses, indicating HS improved growth and stress tolerance. Improved growth was matched with improved resource use efficiency, as HS and HS×Salinity treated plants exhibited the greatest WUE. Drought stress also increased WUE relative to the control but lowered transpiration rate responses to VPD in contrasts to HS and HS×Salinity treated plants, which increased their transpiration rates in response to increasing VPD. Salinity treatments increased sodium content (Na+) in both shoots and roots. No HS effect was observed in shoot Na+ accumulation, but HS reduced Na+ in roots under the Drought×Salinity treatment. Strong interactions between drought and salinity were observed for shoot and root Na+, Na+/K+, and shoot K+, showing that spinach accumulates Na+ and reduces K+ when drought and salinity stress are combined. HS had no apparent effect on leaf metabolites. Drought and salinity differentially impacted MDA, proline, and antioxidant content and activities, while HS showed no effect. Drought stress significantly increased MDA and proline while reducing TPC, TFC, ABTS, and FRAP. Salinity stress significantly decreased MDA, TPC, ABTS, FICA, and FRAP. In conclusion, HS improved overall spinach growth and WUE while decreasing root Na accumulation, and subsequently enhancing spinach stress tolerance.

A comprehensive evaluation of the contamination scenario and water quality in the gas fields of north-east region, Bangladesh

Gas fields generate a significant volume of produced water, disposed in the vicinity of gas fields in Bangladesh after processing. It may have a variety of effects on ecology and the environment. This study was conducted to assess the contamination scenario and quality of produced and discharged water from gas fields in northeastern Bangladesh. The physicochemical analyses for this study were performed using standard procedures. Based on the outcomes of the analyzed samples, the current research employs a variety of indexing and statistical approaches to investigate the overall status of the studied water. The physiochemical analysis revealed high electrical conductivity (EC), total dissolved solid (TDS), salinity, and Na contents in both produced and discharged water. No severe cases have been identified, certain metals, such as Fe, Ni, and Cd, have been detected at levels high enough to impact specific index values in some cases. The results of the weighted contamination index (WCI) indicated mild to considerable pollution in the gas field region. The average score of potential ecological risk (PER) reflects minimal ecological risk. The heavy metal toxicity load (HTML) reveals negligible metal pollution in the studied water. The agricultural risk indices displayed increased sodium concentrations and EC, resulting in salinity and sodium risks. The magnesium absorption ratio is within the allowable range. In addition, the average heavy metal pollution index (HMPI) value demonstrates that the produced and discharged water is unsuitable for drinking. The entropy-based water quality index (EWQI) is below the threshold limit (<100) for all samples, indicating satisfactory water quality. This study is an early effort to evaluate the quality of wastewater produced and discharged from gas fields in Bangladesh. The findings of this research will provide valuable insights for future researchers and regulators in effectively managing and mitigating pollution from wastewater.

COMPARATIVE ANALYSIS OF MECHANISMS OF ACTION OF PEPTIDE TOXINS, INHIBITORS OF CALCIUM AND SODIUM CHANNELS, UNDER ISCHEMIA/REPERFUSION

Ischemia contributes to many pathological conditions encountered in clinical practice. Besides, subsequent reperfusion may worsen tissue damage, exacerbating injuries caused by ischemia. Shifts in the balance of calcium and sodium ions play a major role in the development of ischemia-reperfusion injury. Inhibitors of calcium and sodium ion channels located on the membrane surface can help to avoid a sharp disturbance in the ion balance. Although such inhibitors reduce cell death, their mechanisms of action differ. The aim of the study is to conduct a comparative analysis of the mechanisms of action of peptide inhibitors of calcium and sodium channels on ischemia-reperfusion damage to epithelial cells. Materials and Methods. Peptide synthesizer was used for toxin synthesis. Chromatography and mass spectrometry were used for quality control. Analysis of cell death, changes in calcium and sodium ion concentrations, and pH levels were performed using fluorescent dyes and a multimodal reader. Results. It was found that peptide inhibitors of calcium and sodium channels reduce apoptosis and necrosis levels in CHO-K1 culture under simulated ischemia/reperfusion. The calcium channel inhibitor reduces cell death by lowering calcium and sodium ion concentrations and maintaining physiological pH levels throughout the reperfusion phase. The sodium channel inhibitor reduces death by lowering calcium and increasing sodium concentrations, and by maintaining an elevated pH throughout the reperfusion phase. Conclusion. Although both calcium and sodium concentrations as well as their mutual influence play an important role in the development of ischemia-reperfusion injury, inhibition of certain channels has different effects on intracellular processes with the same result, namely reduced cell death.

Sivelestat sodium inhibits neutrophil elastase to regulate intrahepatic biliary mucin 5AC expression

To explore whether sivelestat sodium could reduce the expression of mucin 5AC (MUC5AC) in intrahepatic bile duct epithelial cells by inhibiting neutrophil elastase (NE) and thus provide new potential therapeutic ideas for the treatment of intrahepatic bile duct stone (IBDS). (1) Bioinformatics analysis: differential gene analysis was performed on gallbladder stone cholecystitis sequencing data based on the gene expression omnibus (GEO) to screen for significantly different genes related to neutrophils and mucins. The search tool for the retrieval of interacting genes database (STRING) was used for protein interaction analysis to predict whether there was an interaction between NE and MUC5AC genes. (2) Animal experiment: a total of 18 male SD rats were divided into the sham-operated group, cholangitis model group and sivelestat sodium treatment group according to the random number table method, with 6 rats in each group. The cholangitis rat model was established by a one-time injection of 1.25 mg/kg lipopolysaccharide (LPS) into the right anterior lobe of the liver of rats in combination with the pre-experiment; the liver of the sham-operated group was injected with an equal volume of saline. After the modelling, 100 mg/kg of sivelestat sodium was injected into the tail vein of the cevalexin treatment group once a day for 5 days, and an equal volume of saline was injected into the tail vein of the sham-operated group and the cholangitis model group. Two weeks later, the rats were euthanized and their liver and bile duct tissues were taken. The pathological changes in the liver and bile duct tissues were observed under the light microscope. Immunohistochemical staining was used to detect the expressions of NE and MUC5AC in liver and bile duct tissues. The protein expressions of NE, MUC5AC and Toll-like receptor 4 (TLR4) were detected by Western blotting. (3) Cell experiment: primary human intrahepatic biliary epithelial cell line (HiBEpiC) was divided into blank control group, NE group (10 nmol/L NE), NE+sivelestat sodium low dose group (10 nmol/L NE+1×10-8 g/L sivelestat sodium 1 mL), NE+sivelestat sodium medium dose group (10 nmol/L NE+1×10-7 g/L sivelestat sodium 1 mL), NE+sivelestat sodium high dose group (10 nmol/L NE+1×10-6 g/L sivelestat sodium 1 mL). Cells were collected after 48 hours of culture, and EdU was performed to detect the proliferative activity of cells; enzyme linked immunosorbent assay (ELISA) and Western blotting were performed to detect the expression of MUC5AC in cells. (1) Bioinformatics analysis: the NE gene (ELANE) had a reciprocal relationship with MUC5AC. (2) Animal experiment: light microscopy showed that hepatocyte edema, hepatocyte diffuse point and focal necrosis, confluent area fibrous tissue and intrahepatic bile ducts hyperplasia and inflammatory cell infiltration in the cholangitis model group; hepatic lobule structure of sivelestat sodium treatment group was clear, and the degree of peripheral inflammatory cell infiltration was reduced compared with the cholangitis model group. Immunohistochemical staining showed that the expressions of NE and MUC5AC were increased in the cholangitis model group compared with the sham-operated group, and the expressions of NE and MUC5AC were decreased in the sivelestat sodium group compared with the cholangitis model group [NE (A value): 5.23±2.02 vs. 116.67±23.06, MUC5AC (A value): 5.40±3.09 vs. 23.81±7.09, both P < 0.05]. Western blotting showed that the protein expressions of NE, MUC5AC, and TLR4 in the hepatic biliary tissues of the cholangitis model group were significantly higher than those of the sham-operated group; and the protein expressions of NE, MUC5AC, and TLR4 in the liver biliary tissues of the sivelestat sodium treatment group were significantly higher than those of the sham-operated group (NE/β-actin: 0.38±0.04 vs. 0.70±0.10, MUC5AC/β-actin: 0.37±0.03 vs. 0.61±0.05, TLR4/β-actin: 0.39±0.10 vs. 0.93±0.15, all P < 0.05). (3) Cell experiment: fluorescence microscopy showed that the proliferation of HiBEpiC cells in each group was good, and there was no significant difference in the proportion of positive cells. ELISA and Western blotting showed that the expressions of MUC5AC in cells of the NE group were significantly higher than those of the blank control group. The expressions of MUC5AC in the NE+different dose of sivelestat sodium group were significantly lower than those in the NE group, and showed a decreasing trend with the increase of sevastatin sodium concentration, especially in the highest dose group [MUC5AC (μg/L): 3.46±0.20 vs. 6.33±0.52, MUC5AC/β-actin: 0.45±0.07 vs. 1.75±0.10, both P < 0.05]. LPS can upregulate the expression of NE and MUC5AC in rats with cholangitis, while sodium sivelestat can reduce the expression of MUC5AC in in intrahepatic biliary epithelial cells by inhibiting NE, providing a new direction for the treatment of IBDS.

Effects of Winery Wastewater to Soils on Mineral Properties and Soil Carbon

Winery wastewater (WW) is a high-volume biowaste and, in the context of Marlborough and New Zealand wineries, there is a growing recognition of the need to improve current WW disposal systems to mitigate negative environmental impacts. The application of WW to land is a low-cost method of disposal, that could significantly reduce the environmental risk associated with WW directly entering surface and groundwater bodies. This study analysed elemental concentrations in WW and soils from three Marlborough vineyards across their annual vintage to determine the loading rates of nutrients into WW and the subsequent accumulation effects of WW irrigation on receiving soils. The findings showed loading rates of approximately 1.8 t ha−1 yr−1 of sodium within WW and a significant increase in soil sodium concentration and pH, attributed to sodium-based cleaning products. A loading rate of approximately 4 t ha−1 yr−1 of total organic carbon was also identified within WW, however, significant losses in soil carbon, nitrogen, magnesium and calcium concentrations were identified. Focusing efforts to retain key nutrients from WW within soils could provide benefits to New Zealand’s wine industry, facilitating increased biomass production in irrigation plots, thereby increasing biodiversity and potentially generating incentives for vineyard owners to contribute to increasing biomass carbon stocks and offset agricultural greenhouse gas emissions.

Correlations of structural, thermal and electrical properties of sodium doped complex borophosphosilicate glass

Borophosphosilicate glasses with varying sodium ion concentrations were investigated for their, structural, thermal, and electrical properties. All the obtained glasses were transparent except the glass with the highest sodium content, which exhibited translucency due to inhomogeneities. Increasing sodium content led to reduced boron and silicon content while maintaining a constant B/Si ratio, indicating progressive depolymerization of the glass network. Confocal microscopy, scanning electron microscopy, and atomic force microscopy showed homogeneous and granular structure for samples with lower sodium content, but higher sodium content resulted in visible agglomeration/nanocrystallization. X-ray diffractograms showed amorphous nature for most samples, with samples doped with the highest concentrations of Na2O showing several broad reflections suggesting nanoscale crystallinity. Fourier-transform infrared spectroscopy revealed shifts in dominant bands with increasing sodium content, indicating depolymerization of the borate network. An observed decrease in glass transition temperature and thermal stability with increasing sodium content was attributed to depolymerization and formation of non-bridging oxygens. Impedance spectroscopy revealed two relaxation processes associated with the transport of Na+ ions through two different regions. DC conductivity and activation energy predominantly increased with the sodium ion content at high temperatures.

Enriched biochars with silicon and calcium nanoparticles mitigated salt toxicity and improved safflower plant performance

Modifying biochar with nano-nutrients is one of the most effective methods in improving the efficiency of biochar in reducing the adverse effects of environmental stresses such as salinity on plant growth and productivity. The possible effects of solid biochar, nano-silicon dioxide enriched biochar, nano-calcium carbonate enriched biochar, and combined application of these enriched biochars on physiological performance of safflower (Carthamus tinctorius L.) were evaluated under different levels of salt stress (non-saline, 6 and 12 dSm−1). Salt stress increased sodium content, reactive oxygen species generation, and antioxidant enzymes activity, but decreased potassium, calcium, magnesium, iron, zinc, silicon, photosynthetic pigments, leaf water content, and seed yield (by about 36%) of safflower plants. The addition of biochar forms to the saline soil improved growth (up to 24.6%) and seed yield (up to 37%) of safflower by reducing sodium accumulation (by about 32%) and ROS generation and enhancing nutrient uptake, photosynthetic pigments, and water contents of leaves. The combined forms of enriched biochars were the best treatment on reducing salt stress effects on safflower plants. Therefore, application of enriched biochars has a high potential to reduce the harmful effects of salt stress on plants.

Effects of ingesting beverages containing glycerol and sodium with isomaltulose or sucrose on fluid retention in young adults: a single-blind, randomized crossover trial.

We evaluated changes in hyperhydration and beverage hydration index (BHI, a composite measure of fluid balance after consuming a test beverage relative to water) during resting, induced by the consumption of beverages containing glycerol and sodium supplemented with fast-absorbing sucrose or slow-absorbing isomaltulose. In a randomized crossover, single-blinded protocol (clinical trials registry: UMIN000042644), 14 young physically active adults (three women) consumed 1L of beverage containing either 7% glycerol+0.5% sodium (Gly+Na), Gly+Na plus 7% sucrose (Gly+Na+Suc), Gly+Na plus 7% isomaltulose (Gly+Na+Iso), or water (CON) over a 40min period. We assessed the change in plasma volume (ΔPV), BHI (calculated from cumulative urine output following consumption of water relative to that of the beverage), and blood glucose and sodiumfor 180min after initiating ingestion. Total urine volume was reduced in all beverages containing glycerol and sodium compared to CON (all P≤0.002). The addition of isomaltulose increased BHI by ∼45% (3.43±1.0vs. 2.50±0.7 for Gly+Na, P=0.011) whereas sucrose did not (2.6±0.6, P=0.826). The PV expansion was earliest for Gly+Na (30min), slower for Gly+Na+Suc (90min), and slowest for Gly+Na+Iso (120min) with a concomitant lag in the increase of blood glucose and sodium concentrations. Supplementation of beverages containing glycerol and sodium with isomaltulose but not sucrose enhances BHI from those of glycerol and sodium only under a resting state, likely due to the slow absorption of isomaltulose-derived monosaccharides (i.e., glucose and fructose).

Solution-Induced Degradation of the Silicon Nanobelt Field-Effect Transistor Biosensors.

Field-effect transistor (FET)-based biosensors are powerful analytical tools for detecting trace-specific biomolecules in diverse sample matrices, especially in the realms of pandemics and infectious diseases. The primary concern in applying these biosensors is their stability, a factor directly impacting the accuracy and reliability of sensing over extended durations. The risk of biosensor degradation is substantial, potentially jeopardizing the sensitivity and selectivity and leading to inaccurate readings, including the possibility of false positives or negatives. This paper delves into the documented degradation of silicon nanobelt FET (NBFET) biosensors induced by buffer solutions. The results highlight a positive correlation between immersion time and the threshold voltage of NBFET devices. Secondary ion mass spectrometry analysis demonstrates a gradual increase in sodium and potassium ion concentrations within the silicon as immersion days progress. This outcome is ascribed to the nanobelt's exposure to the buffer solution during the biosensing period, enabling ion penetration from the buffer into the silicon. This study emphasizes the critical need to address buffer-solution-induced degradation to ensure the long-term stability and performance of FET-based biosensors in practical applications.

Glutathione Mediates Growth Regulation of Chickpea Plant Cicer arietinum and Mitigates Salinity Stress.

Glutathione is water-soluble with a low molecular weight and is commonly spread in plants. It is a co-factor in several biochemical reactions and acts together with signaling molecules and hormones, and its redox state activates signal transduction. The experiment was conducted in the botanical garden, Department of Biology, College of Education for Pure Sciences, Ibn Al- Haitham, University of Baghdad, during the growing season 2020-2021 to evaluate the potential effects of foliar spraying with (25, 50, 75 mg.L-1) glutathione in addition to the control (0) on the growth of chickpea plants subjected to sodium chloride salt (100, 200 mM.L-1) addition to the control (0). The results point out that salinity clearly decreased, as did plant height, branch number, shoot dry weight, nitrogen, phosphorus, potassium concentration, protein percentage, and increased sodium concentration in chickpea plants. A foliar spray of Glutathione, notably 50 and 75 mg.L-1, enhanced the tolerance of chickpea plants by improving growth traits.

A machine learning approach for predicting treatment response of hyponatremia.

Hyponatremia leads to severe central nervous system disorders and requires immediate treatment in some cases. However, a rapid increase in serum sodium (s-Na) concentration could cause osmotic demyelination syndrome. To achieve a safety hyponatremia treatment, we develop a prediction model of s-Na concentration using a machine learning. Among the 341 and 47 patients admitted to two tertiary hospitals for hyponatremia treatment (s-Na <130 mEq/L), those who were admitted to the general unit with urine sodium <20 mEq/L or treated with desmopressin were excluded. Ultimately, 74 and 15 patients (342 and 146 6-hourly datasets) were included in the learning and validation data, respectively. We trained the prediction model using three regression algorithms for shallow machine learning to predict s-Na every 6 h during treatment with the data of patients with hyponatremia (median s-Na: 112.5 mEq/L; range: 110.0-116.8 mEq/L) from one hospital. The model was validated externally using the data of patients with hyponatremia (median s-Na: 117.0 mEq/L; range: 112.9-120.0 mEq/L) from another hospital. Using 5-7 predictors (water intake, sodium intake, potassium intake, urine volume, s-Na concentration, serum potassium concentration, serum chloride concentration), the support vector regression model showed the best performance overall (root mean square error = 0.05396; R2 = 0.92), followed by the linear regression and regression tree models. The predicted s-Na levels, using explainable machine learning algorithms and clinically accessible parameters, correlated well with the actual levels. Thus, our model could be applied to the treatment of hyponatremia in clinical practice.

Thirst for Knowledge: Exploring Dubai's Water Quality through a Public Health Lens

The current study aimed to evaluate the biochemical quality of both bottled water and tap water in the Emirate of Dubai. A total of sixty samples were collected (6 Brand x 10 samples each), while an additional 10 samples were taken from the tap water source. The analysis results were then compared to international standards established by IBWA, FDA, USEPA, WHO, and Abu Dhabi's specific standards. The objective was to identify any potential risks or hazards to public health arising from chemical or biological contaminants in the water. The study assessed various parameters, including total alkalinity, total hardness, and heavy metals, all of which were found to fall within international limits. Microbial content was also analyzed and compared to various standards. The results of this analysis demonstrated that the water's composition met the international norms for safe drinking water. To investigate the impact of different sodium concentrations on blood tonicity, a qualitative microscopic assessment was employed. The results revealed that sodium concentrations exceeding 3mg/L rendered the cells hypertonic. Any further increase in sodium concentration beyond this level directly correlated with increased cell hypertonicity. However, further research is required to delve into other critical aspects of water consumption in the UAE, such as public attitudes toward water and the influence of water pricing on residents' purchasing choices. Public awareness campaigns are essential to rectify misconceptions about both tap water quantity and bottled water quality.

Na+ and K+ compartmentalization in Spinacea oleracea and their effects on growth, water relations, endogenous melatonin, and non-structural carbohydrates

Spinacea oleracea is an economically important vegetable crop. Its growth and nutrition are impacted by the changes in its hydraulic traits due to soil salinity caused by the fluxes of Na+ and K+ which need further investigations to promote its cultivation in degraded agriculture lands. The objective of this study was to assess the impact of different concentrations of NaCl on water relations and non-structural carbohydrates of S. oleracea. For which the hydraulic traits such as rate of photosynthesis, transpiration, stomatal conductance, relative water content, stomatal and vein anatomy, non-structural carbohydrates, and growth were assessed. The compartmentalization of Na+ and K+ was analyzed in both the above and below ground parts. We found that the application of NaCl significantly reduced K+ concentrations, growth, stomatal conductance, photosynthesis, relative water content and also impacted the veins and stomata. The maximum amount of Na+ was compartmentalized in leaf-blade while the minimum was in roots. Meanwhile, maximum K+ was compartmentalized in the mid-rib and minimum in the stem. The K+ and K+: Na+ decreased significantly with the increasing salinity in the treatments. Non-structural carbohydrates also decreased with an increase in sodium concentration. Further, some significant linear relationships were also found between Na+, K+ and the studied hydraulic traits. Endogenous melatonin exhibits an elevated concentration in response to the application of stress. Furthermore, the concentration of melatonin was found to be further increased with the administration of treatment T1 to T4. We conclude that S. oleracea can tolerate NaCl stress up to 80 mML−1. The findings can be helpful to cultivate S. oleracea in excessive sodic soil and can also be useful to cultivate other crops when successive cultivation of S. oleracea is carried out and Na+ is absorbed by the crop from the soil. This can help to promote the sustainable agriculture in some degraded lands.