Changes In Redox Potential Research Articles

Nitrite manipulation in water by structure change of plasma electrolysis reactor

In this study, experimental reactors for cathodic nitrogen plasma electrolysis were designed by the composition of galvanic (voltaic) and electrolytic cells with wide and narrow connectors filled with tap water and agar solutions. The designed reactor can be used to simultaneously perform and manage nitrification in acidic and alkaline environments. According to the reactor’s performance, it can be installed on the irrigation system and used depending on the soil pH of the fields for delivering water and nitrogen species that are effective in growth. The nitrification process was investigated by choosing the optimal reactor with a wide connector based on different changes in oxidation-reduction potential and pH on the anode and cathode sides. The nitrite concentration changed directly with ammonium and nitrate concentrations on the cathode side. It changed inversely and directly with ammonium and nitrate concentrations on the anode side respectively. Nitrite concentration decreased from 5.387 ppm with water connector, to 0.326 ppm with 20% agar solution, and 0.314 ppm with 30% agar solution connectors on the anode side. It increased from 0 ppm to 0.191 ppm with a water connector, 0.405 ppm with 20% agar solution, and 7.454 ppm with 30% agar solution connectors on the cathode side.

PSVII-28 Unraveling the mechanisms governing boar semen quality during chilled storage

Abstract Artificial insemination (AI) appears as a core of reproductive management in the hog industry. AI involves the use of chilled semen doses meeting routine thresholds for motility (≥ 70%) and morphology (≥ 80%) at collection. However, semen doses meeting these standards exhibit a gradual decline in sperm quality, with likely divergent profiles during preservation that impact fertility outcomes. Hence, this study aims to unravel the sperm quality dynamics of boar semen doses during 7-d chilled storage at 17ºC. Semen doses (n = 25) from proven-fertile Duroc boars were provided by a commercial hog farm (Prestage Farm, MS) and transported to the laboratory within 30 min of collection. Each semen sample was aliquoted and analyzed on the day of collection (d 0) and after 7 d of storage (d 7) at 17°C. Sperm total motility (TM), progressive motility (PM), and normal morphology (NM) were assessed using a computer-assisted sperm analyzer (CASA; CEROS II, IMV Biotechnologies). Apoptosis (Annexin V/7-AAD), viability (Propidium iodide – PI), and intracellular reactive oxygen species (ROS; DCFH-DA) were evaluated using flow cytometry. Total antioxidant activity (TAOC) and lipid peroxidation (malondialdehyde; MDA) were assessed using commercial kits (Cayman Chemical). Data analysis was conducted using parametric statistics (SPSS), with P < 0.05 considered significant. Results were presented as mean ± SEM. Data analysis confirmed the significant decrease of CASA parameters, particularly TM from d 0 to d 7 (78.87 ± 1.37 vs. 73.19 ± 1.98%), with extreme variance on d 7 allowing to discriminate high motility (HM, n = 6) vs low motility (LM, n = 6) semen doses. HM doses evidenced significantly greater (P < 0.05) TM (83.73 ± 1.17%), PM (36.07 ± 1.11%), and NM (89.45 ± 2.30%) compared with LM doses (TM: 59.40 ± 3.35%, PM: 16.57 ± 3.25%, NM: 79.93 ± 2.61%) on d 7. Unlike HM samples, which were comparable between d 0 and d 7, LM doses displayed significantly greater proportions of apoptotic and viable cells, and increased intracellular ROS levels on d 0. Likewise, LM samples revealed significantly greater (P < 0.05) proportions of apoptotic cells (3.69 ± 1.66%), dead cells (38.41 ± 3.71%), and cells with intracellular ROS (36.21 ± 3.62%) than HM samples (apoptotic cells: 0.03 ± 0.02%, dead cells: 4.73 ± 4.65%, ROS: 5.34 ± 4.91%) on d 0; however, only the proportions of dead cells displayed significant increase in LM on d 7. MDA concentrations were comparable between HM and LM samples on d 0. However, on d 7, LM samples exhibited significantly greater MDA concentrations than HM samples. In contrast, TAOC was significantly greater in HM samples (2.53 ± 0.14 mM) compared with LM samples (2.17 ± 0.07 mM) on d 0. In conclusion, semen samples with similar gross characteristics at collection exhibited differential responses during storage. Their initial redox potential and apoptosis-like changes may contribute to their varying ability to withstand prolonged storage. Work supported by USDA-ARS grant# 6066-31000-015-00D.

Simplified Electrochemical Approach for End-Point Yet Quantitative Detection of Nucleic Acids in Resource-Limited Settings.

Nucleic acid detection plays a crucial role in various aspects of health care, necessitating accessible and reliable quantification methods, especially in resource-limited settings. This work presents a simplified electrochemical approach for end-point yet quantitative nucleic acid detection. By elevating the concentration of redox species and choosing potential as the signals, we achieved enhanced signal robustness, even in the presence of interfering substances. Leveraging this robustness, we accurately measured pH-induced redox potential changes in methylene blue solution for end-point nucleic acid detection after loop-mediated isothermal amplification (LAMP). Our method demonstrated quantitative detection of the SARS-CoV-2 N gene and human ATCB gene and successful discrimination of the human BRAF V600E mutation, comparable in sensitivity to commercial kits. The developed user-friendly electrochemical method offers a simplified and reliable approach for end-point yet quantitative detection of nucleic acids, potentially expanding the benefits of nucleic acid testing in resource-limited settings.

Use of DFT to Evaluate Properties of Viologen Derivatives for Redox Flow Batteries

Renewable energy technologies, such as wind or solar energy, depend upon intermittent sources, which make long-term storage an important issue for a large-scale application. A way to efficiently store this energy is to use redox flow batteries, where electricity is stored in a liquid electrolyte circulating through an electrochemical cell. The main advantage of this system is the decoupling of power and energy, allowing to increase the storage more efficiently than other technologies, which is advantageous for large-scale stationary systems.1 Most commercial redox flow batteries currently use vanadium as the active material. Although it is a stable metal, its price is high and volatile, and vanadium extraction is responsible for more than 80% of the environmental cost of a vanadium-based redox flow battery. 2 A cheaper, more environment friendly and safer alternative to vanadium is to use organic molecules as active material in an aqueous solvent.3 Organic molecules also offer opportunities to easily tune properties by modifying their structure. This tunability of organic molecules is a great advantage to maximize desired properties: high solubility in water, low viscosity and optimal redox potential (high for positive electrolyte and low for the negative one). The possibilities of modification are however almost infinite and it would be unrealistic to evaluate experimentally all the possible derivatives of even only one family of redox centers. Therefore, computational chemistry, which permits to study molecules properties and draw tendencies within a shorter time frame, is an especially useful tool to assist the design of better performing molecules.4 In this work, we use DFT to study the effect of some structural modifications on the properties of viologen core molecules, with the aim of using them in aqueous organic redox flow batteries (AORFB). In the first part of this presentation, we show the study of PEG chain conformation of PEGylated viologen derivatives in order to explain experimental trends in solubility for different PEG chain lengths. We show that the experimental measure of solubility correlates with the folding of the PEG chain, which is more favored for longer chains. We also see a correlation between asymmetry, dipolar moment and solubility for these molecules, meaning that calculation of the dipole can give an approximate idea of solubility. However, no significant change in redox potential is measured with this type of structural modification.Therefore, in the second part of this study, we present a study of the effect of adding small functional groups directly on the viologen bipyridine core to tune their redox potential. We developed a computational method to calculate the theoretical redox potentials of these derivatives, and we correlate the values to experimental results, and obtained a R factor correlation of 0,9, supporting the validity of the method, which could be used to accurately predict redox potential of other viologen derivatives.These results show the insight computational chemistry can provide for interpretation of experimental data, and the potential of this method to predict and design new optimized molecules for aqueous organic redox flow batteries.References(1) Bai, H. Y.; Song, Z. Y. Lithium-ion battery, sodium-ion battery, or redox-flow battery: A comprehensive comparison in renewable energy systems. J Power Sources 2023, 580.(2) Weber, S.; Peters, J. F.; Baumann, M.; Weil, M. Life Cycle Assessment of a Vanadium Redox Flow Battery. Environ Sci Technol 2018, 52 (18), 10864-10873.(3) DeBruler, C.; Hu, B.; Moss, J.; Liu, X. A.; Luo, J. A.; Sun, Y. J.; Liu, T. L. Designer Two-Electron Storage Viologen Anolyte Materials for Neutral Aqueous Organic Redox Flow Batteries. Chem-Us 2017, 3 (6), 961-978.(4) Asenjo-Pascual, J.; Salmeron-Sanchez, I.; Mauleón, P.; Agirre, M.; Lopes, A. C.; Zugazua, O.; Sánchez-Díez, E.; Avilés-Moreno, J. R.; Ocón, P. DFT calculation, a practical tool to predict the electrochemical behaviour of organic electrolytes in aqueous redox flow batteries. J Power Sources 2023, 564. Figure 1

Modulating the reduction potential and ligand basicity of Ni(II) HER catalysts with highly conjugated N2S2 ligands

Molecular catalysts with N2S2 chelates and earth abundant metals have been used in different applications. With their versatile nature to modulate activity through changes in the ligand framework, they are excellent candidates to generate low-cost and sustainable energy as electrocatalysts for the hydrogen evolution reaction (HER). Herein we demonstrate the modulation of the reduction potential and basicity across a series of six square planar Ni(II) complexes with bis(thiosemicarbazonato) (BTSC), hybrid thiosemicarbazonato-alkylthiocarbamato (TSTC), and bis(alkylthiocarbamato) (BATC) ligands and evaluate their activity as homogenous HER catalysts. The redox active ligands have been designed to modulate the electronic structure of the N2S2Ni core and to systematically alter their respective pKa values. Cyclic voltammograms of all six complexes show two reversible reduction events in acetonitrile that systematically shift to more anodic potentials when the pendent methylthiosemicarbazonato (–NN=C(S)NHMe) groups are substituted with ethylthiocarbamato (–NN=C(S)OEt) groups and/or when the 2,4-butanedione backbone is replaced by 1-phenyl-1,2-propandione. Ligand basicity was evaluated by spectroscopic titration in acetonitrile and found to vary systematically across the series. Within the series of complexes the reduction potentials vary over an ∼ 500 mV range and the ligand basicity over ∼ 7 pKa units. Density functional theory (DFT) computations are consistent with experimental changes in redox potential and pKa values across the series of complexes. The results demonstrate a unique example in which electronic properties of the complexes are modulated via small ligand structure variations. The complexes are stable under acidic conditions or upon reduction, but they degrade upon reduction in the presence of acid limiting their application as homogeneous HER electrocatalysts.

Reduction of c-type cytochromes by Fe(II)-ligand under oxic conditions: Roles of Fe(II)-heme complexation and reactive oxygen species

Microbial Fe(II) oxidation is mainly mediated by the outer-membrane proteins that contain c-type cytochromes (c-Cyts), and the widespread Fe(II)-oxidizing bacteria are usually subjected to fluctuations between oxic and anoxic conditions. However, it remains unclear how oxygen affects the redox dynamics of c-Cyts by Fe(II), particularly in the presence of organic ligands that are widely distributed in the environment. Here, the reduction of a model heme-containing c-Cyts by Fe(II) was investigated in the absence and presence of organic ligands (i.e., citrate and acetate) at pH 5.5 under anoxic and oxic conditions. The kinetic results showed that c-Cyts reduction was enhanced by citrate and acetate under anoxic conditions, and the enhancement by citrate was more pronounced than that by acetate. The speciation calculation and cyclic voltammetry results suggested that the proportions of Fe(II)-Citrate complexes were much higher than those of Fe(II)-Acetate complex, but the addition of acetate and citrate caused minor changes in redox potential of Fe(II)/Fe(III) species. Further analysis using quantum chemical computation demonstrated that the formation of Fe(II)-Heme complexes via lateral binding to the carboxyl group of c-Cyts was more stable than those via replacing the S-linked axial ligand of heme, with the recombination energy with Heme ranking as Fe(II)-Citrate < Fe(II)-Acetate < Fe(II). Therefore, the stronger complexation of Fe(II)-Citrate and its lower recombination energy with c-Cyts drive the enhanced c-Cyts reduction under anoxic conditions. By contrast, the c-Cyts reduction by Fe(II) and Fe(II)-ligand was inhibited under oxic conditions. The electron spin resonance characterization indicated that both O2−• and OH• radicals were produced in the system of c-Cyts with Fe(II) or Fe(II)-ligand under oxic conditions and the signals were higher with Fe(II)-ligand than those with Fe(II). These reactive oxygen species were proposed to enable a re-oxidation of the c-Cyts that was reduced by Fe(II) or Fe(II)-ligand, causing an inhibitory effect on the observed c-Cyts reduction and forming more reactive oxygen species. Our findings shed light on the important roles of Fe(II)-ligand-heme complexation and reactive oxygen species in the interaction between Fe(II) and c-Cyts, which deepen the understanding of microbial/enzymatic Fe(II) oxidation under oxic conditions at the molecular level.

Impact of maternal age on oxidation-reduction potential in follicular fluid and assisted reproductive technology treatment outcomes

Background: Maternal age influenced the quantity and quality of oocytes. The composition of follicular fluid was changed in advanced maternal age. This study was conducted to evaluate changes in redox potential and blastocyst formation potential in older women. Methods and materials: Retrospective study collected data from December 2020 to October 2023 on patients treated with in vitro fertilization with follicular fluid surveyed at the Center for Reproductive Endocrinology and Infertility (HUECREI), Hue University of Medicine and Pharmacy, Hue. Results: Two cohorts comprised the 456 patients: Group 1, consisting of individuals younger than 35 years of age, and Group 2, comprising those 35 years or older. Anti-Müllerian hormone (AMH), initial follicle-stimulating hormone (FSH), and total FSH dose utilized differed significantly between Groups 1 and 2, with median values of 3.79 versus 2.10 ng/mL (P value &lt; 0.001), 225.00 versus 277.50 IU/L (P value &lt; 0.001), and 2025.00 versus 2325.00 IU/L (P value &lt; 0.001), respectively. However, there were no significant differences in ORP, maturation rate, fertilization rate, or blastocyst formation rate between the two age groups. Variations in ORP were only observed among subgroups of patients with the ability to achieve an expected fertilization rate of ≥ 70% in Group 1. Specifically, the subgroup meeting expectations had a lower ORP of 83.00 ± 83.00 mV, in contrast to the non-expectation group which had an ORP of 96.14 ± 83.00 mV, accompanied by a P value of 0.005. The difference of ORP was not observed in the group that reached and did not reach the benchmark embryo formation ≥ 60% in the two age groups. Conclusion: Advanced maternal age have declined in ovarian function but no statistically significant difference in redox potential in follicular fluid has been observed. The fertilization rate and blastocyst formation rate were equivalent across the two age groups of women. The redox potential of follicular fluid was not statistically significant difference between cycles that reached and did not reach the benchmark of blastocyst formation ≥ 60% in the two age groups of women. Key words: Blastocyst, advanced maternal age, oxidative-reduction potential (ORP), in vitro fertilization.

Effects of catchment land use on temperate mangrove forests

Human land use changes are threatening the integrity and health of coastal ecosystems worldwide. Intensified land use for anthropogenic purposes increases sedimentation rates, pollutants, and nutrient concentrations into adjacent coastal areas, often with detrimental effects on marine life and ecosystem functioning. However, how these factors interact to influence ecosystem health in mangrove forests is poorly understood. This study investigates the effects of catchment human land use on mangrove forest architecture and sedimentary attributes at a landscape-scale. Thirty sites were selected along a gradient of human land use within a narrow latitudinal range, to minimise the effects of varying climatic conditions. Land use was quantified using spatial analysis tools with existing land use databases (LCDB5). Twenty-six forest architectural and sedimentary variables were collected from each site. The results revealed a significant effect of human land use on ten out of 26 environmental variables.Eutrophication, characterised by changes in redox potential, pH, and sediment nutrient concentrations, was strongly associated with increasing human land use. The δ15N values of sediments and leaves also indicated increased anthropogenic nitrogen input. Furthermore, the study identified a positive correlation between human land use and tree density, indicating that increased nutrient delivery from catchments contributes to enhanced mangrove growth. Propagule and seedling densities were also positively correlated with human land use, suggesting potential recruitment success mechanisms. This research underpins the complex interactions between human land use and mangrove ecosystems, revealing changes in carbon dynamics, potential alterations in ecosystem services, and a need for holistic management approaches that consider the interconnectedness of species and their environment. These findings provide essential insights for regional ecosystem models, coastal management, and restoration strategies to address the impacts of human pressures on temperate mangrove forests, even in estuaries that may be relatively healthy.

High-Resolution and Dynamic Visualization of Intracellular Redox Potential Using a Metal-Organic Framework-Functionalized Nanopotentiometer.

Redox potential plays a key role in regulating intracellular signaling pathways, with its quantitative analysis in individual cells benefiting our understanding of the underlying mechanism in the pathophysiological events. Here, a metal organic framework (MOF)-functionalized SERS nanopotentiometer has been developed for the dynamic monitoring of intracellular redox potential. The approach is based on the encapsulation of zirconium-based MOF (Uio-66-F4) on a surface of gold-silver nanorods (Au-Ag NRs) that is modified with the newly synthesized redox-sensitive probe ortho-mercaptohydroquinone (HQ). Thanks to size exclusion of MOF as the chemical protector, the nanopotentiometer can be adapted to long-term use and possess high anti-interference ability toward nonredox species. Combining the superior fingerprint identification of SERS with the electrochemical activity of the quinone/hydroquinone, the nanopotentiometer shows a reversible redox responsivity and can quantify redox potential with a relatively wide range of -250-100 mV. Furthermore, the nanopotentiometer allows for dynamic visualization of intracellular redox potential changes induced by drugs' stimulation in a high-resolution manner. The developed approach would be promising for offering new insights into the correlation between redox potential and tumor proliferation-involved processes such as oxidative stress and hypoxia.

Impact of Surface Ligand Identity and Density on the Thermodynamics of H Atom Uptake at Polyoxovanadate-Alkoxide Surfaces.

An understanding of how molecular structure influences the thermodynamics of H atom transfer is critical to designing efficient catalysts for reductive chemistries. Herein, we report experimental and theoretical investigations summarizing structure-function relationships of polyoxovanadate-alkoxides that influence bond dissociation free energies of hydroxide ligands located at the surface of the cluster. We evaluate the thermochemical descriptors of O-H bond strength for a series of clusters, namely [V6O13-x(OH)x(TRIOLR)2]-2 (x = 2, 4, 6; R = NO2, Me) and [V6O11-x(OMe)2(OH)x(TRIOLNO2)2]-2, via computational analysis and open circuit potential measurements. Our findings reveal that modifications to the TRIOL ligand (e.g., changing from the previously reported electron withdrawing nitro-backed ligand to the electron-donating methyl variant) have limited influence on the strength of surface O-H bonds as a result of near complete thermodynamic compensation in these systems (i.e., correlated changes in redox potential and cluster basicity). In contrast, changes in surface density of alkoxide ligands via direct alkoxylation of the polyoxovanadate-alkoxide surface result in measurable increases in bond dissociation free energies of surface O-H bonds for the mixed-valent derivatives. Our findings indicate that the extent of (de)localization of electron density across the cluster core has an impact on the bond dissociation free energies of surface O-H bonds across all oxidation states of the assembly.

Enhanced Reactivity through Equatorial Sulfur Coordination in Nonheme Iron(IV)-Oxo Complexes: Insights from Experiment and Theory.

Sulfur ligation in metalloenzymes often gives the active site unique properties, whether it is the axial cysteinate ligand in the cytochrome P450s or the equatorial sulfur/thiol ligation in nonheme iron enzymes. To understand sulfur ligation to iron complexes and how it affects the structural, spectroscopic, and intrinsic properties of the active species and the catalysis of substrates, we pursued a systematic study and compared sulfur with amine-ligated iron(IV)-oxo complexes. We synthesized and characterized a biomimetic N4S-ligated iron(IV)-oxo complex and compared the obtained results with an analogous N5-ligated iron(IV)-oxo complex. Our work shows that the amine for sulfur replacement in the equatorial ligand framework leads to a rate enhancement for oxygen atom and hydrogen atom transfer reactions. Moreover, the sulfur-ligated iron(IV)-oxo complex reacts through a different reaction mechanism as compared to the N5-ligated iron(IV)-oxo complex, where the former reacts through hydride transfer with the latter reacting via radical pathways. We show that the reactivity differences are caused by a dramatic change in redox potential between the two complexes. Our studies highlight the importance of implementing a sulfur ligand into the equatorial ligand framework of nonheme iron(IV)-oxo complexes and how it affects the physicochemical properties of the oxidant and its reactivity.

Cytotoxic and apoptotic effects of the Adenium obesum extract on the hepatocellular carcinoma cell line (HepG2)

BackgroundSince ancient times, medicinal plants have been used in the treatment of many diseases. It has been shown that Adenium obesum (A. obesum) has antiviral, antibacterial, and cytotoxic activities. In this study, the cytotoxic effects and the ability of apoptosis induction of A. obesum extract on HepG2 cells were investigated. MethodsCell cytotoxicity of green leaf extract of A. obesum was evaluated using MTT assay. Changes in the cells'redox potential were determined in the treated cells by catalase activity, released nitrite oxide, and GSH concentration, and induction of apoptosis was evaluated using alkaline comet assay. ResultsThe results showed that plant extract containing various proteins concentrations (0.2, 0.75, and 3 μg/mL) has apoptosis and ROS effects on HepG2 cells. The folded proteins in the extract agglutinated the red blood cells. The results also showed that following the addition of the extract, the amount of NO released to the culture media was significantly increased, while the catalase enzyme activity was significantly decreased. However, the GSH content was not changed significantly. The results of the comet assay confirmed the apoptosis induction in the HepG2 cells following the treatment. ConclusionsOur results show the apoptotic effects of green leaf extract of A. obesum on hepatocellular carcinoma cell line. This finding proposes that the A. obesum extract is a valuable therapeutic agent against cancerous cells.

Design of Functional Globular β-Sheet Miniproteins.

The design of discrete β-sheet peptides is far less advanced than e. g. the design of α-helical peptides. The reputation of β-sheet peptides as being poorly soluble and aggregation-prone often hinders active design efforts. Here, we show that this reputation is unfounded. We demonstrate this by looking at the β-hairpin and WW domain. Their structure and folding have been extensively studied and they have long served as model systems to investigate protein folding and folding kinetics. The resulting fundamental understanding has led to the development of hyperstable β-sheet scaffolds that fold at temperatures of 100 °C or high concentrations of denaturants. These have been used to design functional miniproteins with protein or nucleic acid binding properties, in some cases with such success that medical applications are conceivable. The β-sheet scaffolds are not always completely rigid, but can be specifically designed to respond to changes in pH, redox potential or presence of metal ions. Some engineered β-sheet peptides also exhibit catalytic properties, although not comparable to those of natural proteins. Previous reviews have focused on the design of stably folded and non-aggregating β-sheet sequences. In our review, we now also address design strategies to obtain functional miniproteins from β-sheet folding motifs.

Fluctuation Relations to Calculate Protein Redox Potentials from Molecular Dynamics Simulations.

The tunable design of protein redox potentials promises to open a range of applications in biotechnology and catalysis. Here, we introduce a method to calculate redox potential changes by combining fluctuation relations with molecular dynamics simulations. It involves the simulation of reduced and oxidized states, followed by the instantaneous conversion between them. Energy differences introduced by the perturbations are obtained using the Kubo-Onsager approach. Using a detailed fluctuation relation coupled with Bayesian inference, these are postprocessed into estimates for the redox potentials in an efficient manner. This new method, denoted MD + CB, is tested on a de novo four-helix bundle heme protein (the m4D2 "maquette") and five designed mutants, including some mutants characterized experimentally in this work. The MD + CB approach is found to perform reliably, giving redox potential shifts with reasonably good correlation (0.85) to the experimental values for the mutants. The MD + CB approach also compares well with redox potential shift predictions using a continuum electrostatic method. The estimation method employed within the MD + CB approach is straightforwardly transferable to standard equilibrium MD simulations and holds promise for redox protein engineering and design applications.

Electrokinetic and Microstructural Peculiarities of the Portland Cement Hydration with Microadditives

AbstractThe results of given studies included a comparison of changes in temperature, redox potential, OH‐ions concentration and pH values in the Portland cement‐water‐additive system depending on the hydration time and features of hydration processes in the microstructure of the cement stone. The studied additives were selected taking into account the prospects for their use in the complex modifiers compositions for cement‐containing building materials. The results of electrokinetic measurements are presented and regularities and features of the influence of each studied additives on the processes of hydration structure and phase formation in Portland cement paste in the early stages of hardening are determined. The microstructure and fracture surfaces of cement stone samples formed during cement paste hardening with the optimal content of additives and features of hydration processes of cement stone were studied. The features of the mutual arrangement of individual phases in crystalline hydrate aggregates of cement stone, as well as the nature of the porosity of its microstructure, were investigated.

Indole-based Fluorometric and Colorimetric Chemosensors for the Selective Detection of Cu2+: A Brief Review From the Year 2011-2021

The development of chemosensors has been driven by concurrently advanced research in fluorescence and colorimetric chemosensing. Over the last few decades, the development of copper ion-selective fluorogenic and chromogenic chemosensors has been extensively studied due to their high sensitivity, low cost, and simplicity. They can interact with the metal ion in a unique manner and create measurable color, fluorescence, or redox potential changes. Copper (Cu2+) ion is deemed the third most prevalent transition metal in human beings owing to its various biological and physiological processes. It has drawn a great deal of attention from many researchers in various disciplines such as biology, medicine, and environmental studies. However, an excessive buildup of copper in the body has been linked to several diseases. Thus, more recent research is being focused on developing fluorometric and colorimetric chemosensors for the selective detection of copper ions. Recently, there have been a lot of studies reported in this field of study that describe highly sensitive and sophisticated indole-based chemosensors for various metal ions of interest. In addition, indole derivatives possess inherent fluorescence properties due to their electron-rich nature caused by the π-excessive system of indole, and therefore they can be employed in chemosensors for metal ion detection. Both cations and anions employ it as a molecular recognition system. This review summarizes selective and sensitive Cu2+ ion detection accomplished byvarious indole-based chemosensors between the years 2011 to 2021. Furthermore, sensor design, sensing methods, ligand-metal binding stoichiometry, association constant, and the detection limit by the chemosensors are all summarized and explored.&#x0D; Keywords: Indole, Fluorescent chemosensors, Colorimetric chemosensors, Cu2+, Turn-on, Turn-off

NADH-based kinetic model for acetone-butanol-ethanol production by Clostridium

We present in this work a kinetic model of the acetone-butanol-ethanol (ABE) fermentation based on enzyme kinetics expressions. The model includes the effect of the co-substrate NADH as a modulating factor of cellular metabolism. The simulations obtained with the model showed an adequate fit to the experimental data reported by several authors, matching or improving the results observed with previous models. In addition, this model does not require artificial mathematical strategies such as on-off functions to achieve a satisfactory fit of the ABE fermentation dynamics. The parametric sensitivity allowed to identify the direct glucose → acetyl-CoA → butyryl-CoA pathway as being more significant for butanol production than the acid re-assimilation pathway. Likewise, model simulations showed that the increase in NADH, due to glucose concentration, favors butanol production and selectivity, finding a maximum selectivity of 3.6, at NADH concentrations above 55 mM and glucose concentration of 126 mM. The introduction of NADH in the model would allow its use for the analysis of electrofermentation processes with Clostridium, since the model establishes a basis for representing changes in the intracellular redox potential from extracellular variables.

Effects of sediment dredging on freshwater system: a comprehensive review.

As a common geo-engineering method to control internal load of nutrients and pollutants, sediment dredging has been used in many freshwater basins and has achieved certain effects. However, dredging can disturb water bodies and substrates and cause secondary pollution. It negatively affects the water environment system mainly from the following aspects. Dredging suddenly changes the hydrological conditions and many physical indicators of the water body, which will cause variations in water physicochemical properties. For example, changes in pH, dissolved oxygen, redox potential, transparency, and temperature can lead to a series of aquatic biological responses. On the other hand, sediment resuspension and deep-layer sediment exposure can affect the cycling of nutrients (e.g., nitrogen, phosphorus), the release and valence conversion of heavy metals, and the desorption and degradation of organic pollutants in the overlying water. This can further affect the community structure of aquatic organisms. The aim of this paper is to analyze the relevant literature on freshwater sediment dredging, and to summarize the current knowledge of the potential environmental risks caused by the dredging and utilization of freshwater sediments. Based on this, the paper attempts to propose suggestions to mitigate these adverse environmental impacts. These are significant contributions to the development of environmentally friendly freshwater sediment dredging technologies.

Induction of bioactive constituents and antioxidant enzyme activities in Achillea fragrantissima (Forskal) callus cultures using ZnO nanoparticles

The medicinally effective plant Achillea fragrantissima exhibits a magnitude of pharmacological activities. In this study, the effects of different ZnONP concentrations on antioxidant enzymes, bioactive secondary metabolites, redox potential, and molecular changes in A. fragrantissima callus cultures were investigated. First, the concentrations of the growth regulators 2,4-D and BA were optimized using Murashige and Skoog (MS) medium. The MS medium was then administered with 2,4-D and BA at its optimal dosage (1.0 mg.L−1); afterward, different ZnONP supplements (0.0, 5.0, 10.0, 15.0, and 20.0 mg.L−1) were added. ZnONPs resulted in many physiological and molecular responses. ZnONPs significantly increased POD, APX, and SOD activities. While 10.0 mg.L−1 ZnONPs significantly increased POD and APX activities, 15.0 mg.L−1 ZnONPs significantly increased SOD. However, CAT activity gradually decreased with ZnONPs. Metabolically, ZnONPs increased phenolics, flavonoids, alkaloids, and saponin levels. Phenolic levels peaked at 20.0 mg.L−1, flavonoids at 15.0 mg.L−1, and alkaloids and saponins at 10.0 mg.L−1. Terpenoids were more prevalent at lower levels of ZnONPs. With 15.0 and 10.0 mg.L−1 giving the maximum activity, ZnONPs enhanced the DPPH activity and TAC of the callus culture extracts, respectively. RAPD and ISSR fingerprinting were applied using 12 random and ISSR primers to evaluate the genetic stability of ZnONP-induced callus cultures. Six RAPD primers showed 83% polymorphism while the seven ISSR primers achieved 30% polymorphism. Consequently, DNA mutations may have been induced by ZnONPs and caused DNA fragments to either appear or disappear in RAPD and ISSR callus profiles. The dendrogram based on RAPD and ISSR combined data showed that by increasing ZnONP concentration the genetic differentiation among callus cultures was elevated. In conclusion, higher accumulation of secondary metabolites and redox activity were increased in A. fragrantissima callus cultures using low ZnONPs (10.0 mg.L−1) concentration.

Impurity-driven simultaneous size and crystallinity control of metal nanoparticles

Both the size and crystallinity should be optimized for practical applications utilizing metallic nanoparticles because they strongly influence the nanoparticles property. Herein a liquid phase chemical reduction method controls the defects (crystallinity) in metallic Cu nanoparticles simply and easily. Although the addition of an impurity substance, which cannot be thermodynamically alloyed with Cu, reduces the crystallinity of synthesized Cu nanoparticles, it also affects the deposition behavior, and consequently, the nanoparticle size changes unexpectedly. Therefore, a precise control of the synthesis condition is required to synthesize the nanoparticles having optimal size and crystallinity. To clarify the nanoparticle formation mechanism in an impurity-containing solution, the catalytic activity of the reductant and the redox potential change due to the metastable product are electrochemically evaluated to reveal the correlation between nanoparticle formation behavior and synthesis condition. Finally, the synthesis of two types of Cu nanoparticles, which have similar sizes but different crystallinities is demonstrated. This simple nanomaterial design approach to control the crystallinity and the interpretation of the deposition process in an impurity-containing condition should be widely applicable to metallic nanoparticle syntheses.