Effect Of Action Research Articles

Polyfluorene Bearing Quinoline and Ferrocene as the Pendant Groups for Bioelectronics

Abstract Analog-type polymer memristors are preeminent candidates for neuromorphic computation and synaptic biomimicking. A novel polyfluorene bearing quinoline and ferrocene as the pendant groups (PQF) is synthesized. The PQF film sandwiched between the Al and ITO electrodes exhibits outstanding analog-type memristive performance at a small sweep voltage range of ±1V, with 42 distinguishable conductance states. As compared, poly{[9,9-di(2,4-diphenylquinoline)-fluorene]-alt-[9,9-bis(6-bromohexyl)-9H-fluorene]}, and poly {[9H-fluorene]-alt-[fluorene with triazole and ferrocene moieties in the sidechains] only show 12 and 15 distinguishable conductance states, respectively. The former only involves intramolecular charge transfer from the polymer backbone to the quinolone moieties, while the latter mainly concern redox effect from the ferrocene moieties. These results demonstrate that the combined action of intramolecular electron transfer and redox effect could dramatically increase the number of distinguishable conductive states of the resultant materials. Associated with the exceptional memristive performance, the PQF-based memristor can accurately recognize human emotions. After 150 training sessions, the accuracy of emotion recognition reaches up to 98.74%.

Cannabinoid regulation of sex-dependent murine odorant-stimulated salivation

Salivation is easily taken for granted, but without normal salivation, simple essential tasks such as chewing and swallowing become difficult, with consequences for quality of life, nutrition and oral health. Many important drug classes cause dry mouth as a side effect, contributing substantially to patient non-compliance. Available treatments are mostly palliative. Cannabis user complaints of dry mouth prompted a study that showed that basal salivation is likely regulated by cannabinoid CB1 receptors on neurons that innervate the submandibular gland. But what about stimulated salivation? The adjoining parotid gland releases saliva in response to olfactory or other cues and contributes a large portion of the net salivation in humans. We investigated cannabinoid regulation of stimulated salivation using functional and protein-expression studies in mice. In developing a model of stimulated salivary responses to food-related odorants in mice, we noted sex-dependent responses to food-related cues. Only male mice learned to salivate in response to the odor of peanut butter while only female mice responded to a chocolate hazelnut spread. Both males and females responded to sugar or marmite. Testing peanut butter, we found that the cannabinoid receptor agonist CP55940 (0.5 mg/kg, IP) lowered baseline salivation, as shown previously, but also prevented the odorant-induced increase in salivation. CB1 receptors are expressed in axons innervating the parotid gland, paralleling our findings in the submandibular gland. Notably, we also found that CB1 deletion impaired some responses (those to peanut butter and chocolate hazelnut spread) but not others (sugar or marmite). In mice, the CB1 antagonist SR141716 (4 mg/kg, IP) prevented a previously learned salivary response to peanut butter. We find that CB1 receptors are expressed in a subset of glomeruli in coronal sections of olfactory bulb that may serve as a site of action for scent-specific effects of CB1 receptors. We additionally observe CB1 expression in accessory olfactory bulb. In summary, we find a novel sex-dependence in responses to a subset of food-related odorant cues and that cannabinoid receptors regulate some of these responses. We propose that CB1 receptors act at the parotid gland to inhibit stimulated salivation but also in the olfactory system, where functional CB1 receptors are required for salivary responses to specific appetitive odors.

Predicting susceptibility to COVID-19 infection in patients on maintenance hemodialysis by cross-coupling soluble ACE2 concentration with lymphocyte count: an algorithmic approach

IntroductionPatients on maintenance hemodialysis (MHD) were more vulnerable to and had a higher mortality during the COVID-19 pandemic. As angiotensin converting enzyme 2 (ACE2) and transmembrane protease serine S1 member 2 (TMPRSS2) played crucial roles in viral entry into the human host cells, we therefore investigated in the MHD patients whether their plasma levels were associated with susceptibility to the COVID-19.MethodsBlood samples were collected from the patients in our then COVID-19 free center immediately upon lifting of the stringent quarantine measures in early December of 2022 and infection situation was observed within the following 2 weeks. Plasma levels of the soluble ACE2 (sACE2), ACE (sACE) and TMPRSS2 (sTMPRSS2) were measured with ELISA method. Data were stepwisely tested for independent effect, relevant role and synergistic action on the susceptibility by multiple logistic regression, receiver operating characteristic curve and multiple dimensionality reduction (MDR) method, respectively.ResultsAmong the 174 eligible patients, 95 (54.6%) turned COVID-19 positive with a male to female ratio of 1.57 during the observation period. Comparing with the uninfected, the infected had significantly higher sACE2 and lower sTMPRSS2 levels upon comparable sACE concentration. Besides the sACE2, factors associated with susceptibility were vintage and individual session time of the hemodialysis, smoking and comorbidity of hepatitis, whereas lymphocyte counts showed a tendency (p = 0.052). Patients simultaneously manifesting higher sACE2 level and lower lymphocyte counts had an increased infection risk as confirmed by the MDR method.ConclusionBy sorting out the susceptible ones expeditiously, this algorithmic approach may help the otherwise vulnerable MHD patients weather over future wave of COVID-19 variants or outbreak of other viral diseases.

Future photovoltaic potential in India: navigating the interplay between air pollution control and climate change mitigation

Abstract India has set ambitious solar energy targets to meet its climate commitments. However, climate change, already evident in the country, poses significant challenges to solar power generation. Therefore, assessing the impact of climate change on future photovoltaic potential in India is essential. This study evaluates the mid-century (2041-2050) solar photovoltaic potential across Indian power grids using CMIP6 models under two scenarios: SSP2-4.5 (moderate climate action with intermediate air pollution) and SSP5-8.5 (weak climate action with strong air pollution control). The results indicate that the nationally averaged photovoltaic potential is projected to decrease by -2.3±0.6% (SSP5-8.5) to -3.3±0.9% (SSP2-4.5) compared to the 1985-2014 baseline, primarily due to reduced radiation and increased temperatures. Additionally, cell temperatures are expected to rise by 1.5±0.13°C (SSP2-4.5) to 2±0.11°C (SSP5-8.5), leading to efficiency losses and additional 18±5 days under SSP2-4.5 (26±3 days under SSP5-8.5) of efficiency de-rating, particularly in solar-rich regions. This translates to a loss of 600±160 GWh under SSP2-4.5 and 840±100 GWh under SSP5-8.5, based on the solar generation status of 2023-24. Overall, SSP5-8.5 projects a smaller reduction in photovoltaic potential, it also predicts greater temperature-induced efficiency losses compared to SSP2-4.5, due to aerosol direct effect and weak climate action. Finally, this assessment highlights the need for combined climate and pollution mitigation efforts to boost India’s photovoltaic potential and secure a sustainable, resilient energy future.

Beauveria bassiana associated with a novel biomimetic hydrogel to control Aedes albopictus through lure and kill ovitraps.

Within the framework of sustainable and effective control methods for Aedes albopictus, two different conidial suspensions, BbCS-1 and BbCS-2 (respectively without and with nutrients), were used as solvents for the biopolymers water-soluble 2-hydroxyethylcellulose (HEC) and sodium alginate (SA). In this way, two different classes of hydrogels were prepared for each polymer (previously shown to attract tiger mosquito oviposition) to produce HEC-based and SA-based Bb/Gel systems with and without nutrients. The aim was to achieve a long-lasting and cost-effective lure-and-kill oviposition substrate useful for lethal ovitraps. Beauveria bassiana (Bb) survival and growth in the different Bb/Gel systems were monitored for 24 days. Following the growth assay, 24-day-old Bb/Gel systems were tested against Ae. albopictus eggs through a hatching test to evaluate their lethal effect. Gel systems enhance Bb's longevity (up to 24 days) more effectively than standard liquid conidial suspensions, proving that tested HEC- and SA-based hydrogels are not toxic for Bb (biocompatibility) and create a microenvironment suitable to sustain prolonged fungal growth. In particular, the results indicate that gel system based on hydroxyethylcellulose is a suitable delivery substrate for supporting the activity of Bb and is simultaneously effective against Ae. albopictus eggs through a combined mechanism of mechanical effect and fungal action (CM > 90%). The efficacy of Bb gel systems was assessed according to its properties in favouring the growth and vitality of Bb as well as in reducing the Ae. albopictus hatching eggs rate. Further studies, in semi-field and field conditions, will be useful to evaluate the efficacy of Bb/Gel systems on adults in terms of attraction, oviposition, mortality, and potential autodissemination to propose a new tool in precision pest management. © 2024 The Author(s). Pest Management Science published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry.

Emerging RNAi Therapies to Treat Hypertension.

Hypertension (HTN), often dubbed the "silent killer," poses a significant global health challenge, affecting over 1.3 billion individuals. Despite advances in treatment, effective long-term blood pressure (BP) control remains elusive, necessitating novel therapeutic approaches. Poor control of BP remains a leading cause of cardiovascular morbidity and mortality worldwide and is becoming an even larger global health problem due to the aging population, rising rates of obesity, poorer dietary patterns and overall cardiometabolic health, and suboptimal rates of patient adherence and optimal BP control. Ribonucleic acid interference (RNAi) technology, which leverages the body's natural gene-silencing mechanism, has emerged as a promising strategy for several diseases and has recently been tested for its antihypertensive effects. We systematically reviewed peer-reviewed articles from databases including PubMed, EMBASE, and Scopus for studies examining RNAi's role in managing HTN, focusing on mechanisms, clinical utility, and safety profile. Key early-phase trials of some RNAi-leading candidate drugs are detailed. Also highlighted are challenges such as target specificity, delivery mechanisms, durability of effect, and immunogenicity. We conclude by summarizing how RNAi has a significant potential role in HTN therapy due to their unique benefits, such as long-term duration of action, infrequent dosing, and lack of major side effects.

Purple Butter Clam (Saxidomus Purpurata) as a Potential Functional Food Source for Obesity Treatment.

Saxidomus purpurata extract (SPE) is a highly consumable seafood worldwide with known health-related benefits. However, there are no reports of its' anti-obesity effect. This study explores the potential of SPE for anti-obesity effects by modulating adipogenesis and lipolysis. SPE reduced intracellular lipid and triglyceride accumulation while increasing free glycerol release in adipocytes. SPE inhibited lipogenesis protein expressions and increased the phosphorylation of hormone-sensitive lipase and Adenosine monophosphate-activated protein kinase (AMPK) to promote lipolysis. In addition, SPE suppressed adipogenesis by downregulating protein expression of key adipogenic markers, peroxisome proliferator-activated receptor gamma (PPARγ), CCAAT/enhancer-binding protein α (C/EBPα), and sterol regulatory element-binding protein 1 (SREBP1) via Wnt/β-catenin signaling. SPE augmented the heme oxygenase-1 (HO-1) expression. Thus, pharmacological intervention with Zinc protoporphyrin (ZnPP-HO-1 antagonist) was employed to validate the HO-1 role. The presence of ZnPP increased the lipid accumulation and reduced the free glycerol release. At the molecular level, adipogenic transcription factors (PPARγ, C/EBPα, and SREBP1) expressions were restored in the presence of ZnPP. GC-MS analysis revealed that SPE was comprised of several fatty acids, contributing to its anti-obesity activity. SPE is an effective nutraceutical that can be used to reduce the progression of obesity. HO-1 expression during adipogenesis might be the mechanism of action for the anti-obesity effect of SPE.

Determining factors for the selection of soybean cultivars and the cause and effect relationships with grain yield

The objective of the present study was to apply the trail analysis model to extract the cause and effect action on soybean grain yield as a function of agronomic attributes. The present study was developed in the agricultural years of 2023 and 2024. The experimental design used was strips with randomized blocks, consisting of 10 cultivars and five replications. Through the means comparison test, the highest grain yields were observed in the cultivars C 2531 E, BMX Vênus CE, B 5595 CE and NEO581 CE. It was observed that in addition to the higher grain yield, the cultivar C 2531 CE also presented a higher grain weight per plant, despite having the lowest final plant height and productive zone height among the cultivars. As for BMX Vênus CE, it was observed that despite its medium height, it presented a shorter internode length on the main stem, which optimized the number of total nodes on the main stem, in addition to presenting a high grain weight per plant. Cultivar B 5595 CE can be highlighted for its greater final plant height, as well as greater height of the productive zone, promoting a greater number of total nodes on the main stem. Another highlight of this cultivar is the high number of plants per final linear meter, indicating its adaptability in the field. The cultivar NEO581 E, despite having one of the smallest heights among the cultivars, presented one of the highest grain yields, which can be attributed to the stability of the cultivar in the field, as it showed intermediate performance for all agronomic traits.

A dual-channel fluorescent probe based on salamo-Cu(II) complex for sensitive detection of S2- in river and tap water

A new double-salamo-type tetranuclear copper complex [Cu4(L)2](ClO4)2.2CH2Cl2 was designed and prepared, in which the metal atoms in the complex crystals have two different coordination systems, forming a symmetric structure as a whole. As a complex probe molecule, the addition of S2- in solution can achieve a red shift in the fluorescence spectrum, revealing bright green fluorescence, colorimetric and fluorescent dual-channel specific recognition ability and excellent anti-interference ability. The probe can be used to detect S2- by adding acidic and alkaline solutions to adjust the pH of the system for several cycles, which is suitable for ion recognition in most organisms and environments under pH conditions. The working mechanism of S2-recognition by Cu–ZTS was determined to be a synergistic action of ESIPT effect and ICT effect by correlation spectroscopy experiments, HR-MS and XPS tests, and this conclusion was subsequently further verified using theoretical calculations. Finally, the probe molecule showed good practical application value, and the portable test strips were prepared to qualitatively detect the ions, and by testing four different water samples, it was shown that the quantitative recognition of S2- could be realized almost without interference in real water samples. It proves that the coordination probe molecule has good prospects for practical application.

The antibacterial activity of the copper for Staphylococcus aureus 124 and Pseudomonas aeruginosa 18 depends on its state: metalized, chelated and ionic.

The hypothesis that the antibacterial effect of copper depends on its state was tested. It was studied the antibacterial effect of copper applied to the fabric, copper in chelated and free (ionic) forms on the growth intensity of Staphylococcus aureus 124 and Pseudomonas aeruginosa 18 in the in vitro system after a single or “primary” contact. Classical microbiology methods were used. Copper was applied to the fabric by magnetron and arc planar discharge systems, and the culture of microalgae Dunaliella viridis, resistant to the action of high concentrations of copper, was used to obtain copper in chelated form. It was shown that a thin layer of copper (3 μm) applied to the fabric showed pronounced antibacterial activity against Staphylococcus (85% compared to the antibiotic meropenem) and less pronounced activity against Pseudomonas, which is resistant to meropenem. Copper in ionic form inhibited the growth of Staphylococcus aureus 124 as well as the antibiotic, and also effectively inhibited the growth of Pseudomonas aeruginosa 18 i.e., copper ions did not have species specificity like the antibiotic. Components of Dunaliella viridis microalgae cells had weakly expressed antibacterial effect to these types of bacteria, and supplementary addition of copper sulfate to the biomass of microalgae led to an increase of their antibacterial activity and this is more pronounced for microalgae culture in which the ratio «chelated/ionic» forms of copper is shifted to the ionic form. It was shown that the antibacterial activity of microalgae biomass after the first introduction into the tested bacterial cultures depends on the amount of free or “weakly bound” with cell components copper ions. It is suggested that the antibacterial effect of fabric with a thin layer of copper may be determined by two mechanisms: the action of copper ions and mechano-bactericidal effects, while chelated forms of copper may have a prolonged effect on bacterial cultures.

Meningeal KATP channels contribute to behavioral responses in preclinical migraine models

Abstract Human experimental studies have shown that levcromakalim, an ATP-sensitive potassium (KATP) channel opener, induces migraine attacks in people with migraine but not in healthy volunteers. However, the exact site of action for KATP channels in migraine pathophysiology remains unclear. This study investigates the role of these channels in the meninges in eliciting behavioral hypersensitivity responses in mice. The effects of KATP channel signaling were assessed using preclinical migraine models induced by repetitive stress or dural stimulation. Prolactin, CGRP, sodium nitroprusside (SNP), and KATP channel openers or blockers were administered systemically or onto the dura of mice followed by behavioral testing using periorbital von Frey or facial grimace measurements. Repetitive stress sensitized mice to a normally subthreshold systemic dose of levcromakalim. The KATP blocker glibenclamide significantly reduced responses to systemic SNP following repetitive stress. In naive mice, direct dural application of levcromakalim or SNP elicited periorbital hypersensitivity. Responses to dural levcromakalim were inhibited by coinjection with glibenclamide or sumatriptan. By contrast, injection of levcromakalim in the periorbital skin did not induce hypersensitivity. Moreover, repetitive stress sensitized mice to dural injection of normally subthreshold doses of levcromakalim or SNP. Finally, dural coinjection of glibenclamide inhibited periorbital hypersensitivity induced by CGRP or prolactin in female mice. These studies demonstrate that the meninges can be one site of action for the migraine-triggering effects of KATP channel openers. They also show that NO donors, CGRP, and prolactin can produce behavioral hypersensitivity through opening of KATP channels in the meninges.

Ensuring the normalization of the aero-ionic regime in production areas by means of ultrasonic air ionization

The results of studies on the normalization of the aeroionic regime in rooms under ultrasonic ionization of humidified air are presented. The increase in the concentration of negative aeroions under these conditions by the combined effect of the balloelectric effect and ultrasonic cavitation is substantiated. It has been established that when distilled water is used as a source of air ions under the action of a 10 W ultrasonic generator at a distance of 0.5 m, the concentration of negative air ions increases almost sixfold. At the same time, due to the joint effect of ultrasonic cavitation in the surface layer of water and the balloelectric effect, no generation of ozone and nitrogen oxides is caused. It is proved that with a decrease in the degree of water mineralization, the concentrations of negative and positive aeroions increase due to changes in the physicochemical properties of water and the resulting mechanochemical phenomena. The mechanism of formation of air ions in the air of industrial premises under the combined action of the balloelectric effect and ultrasound is proposed. It is substantiated that the quality of the air ionic composition of industrial premises air improves at a temperature of demineralized water of 20-25 °C and a directed air flow of 6 m/s towards the working area with the combined effect of ultrasound and balloelectric effect, which contributes to the improvement of sanitary and hygienic working conditions. The structure of an automated system for controlling the aeroionic regime of the working area of industrial premises with artificial ionization of humidified air using an aeroion generator and a ventilation system is proposed. This will allow monitoring and processing of information on technological, electrical and microclimatic parameters, adjusting, coordinating and jointly controlling the ventilation system devices and the ultrasonic generator of air ions.

Surface Coloring and Plasmonic Information Encryption at 50000 dpi Enabled by Direct Femtosecond Laser Printing.

Femtosecond (fs) laser pulses drive matter into a highly nonequilibrium state, allowing precise sculpturing of irradiated surface sites with sophisticated nanomorphologies. Here, we used fs-laser patterning to create diverse plasmonic morphologies on the top Au layer of the metal-insulator-metal sandwich. Mutual action of laser-driven thermomechanical effects and ultrafast solid-to-liquid transition allows control of the morphology resulting in pronounced surface reflectivity modulation, i.e., in a structural color effect. This enables template-free high-resolution color printing at a superior lateral resolution up to 50000 dots per inch and facile tunability of the color tone and saturation. Moreover, precise control over the orientation of the printed nanostructures within subwavelength lattices allows modulation of their local plasmonic response encrypting the optical information within the colorful images. The hidden information can be unveiled using a facile cross-polarized optical visualization scheme, rendering the proposed method with extra modalities combining high resolution information encryption, coloring, and security labeling.

Gut microbiota drives colon cancer risk associated with diet: a comparative analysis of meat-based and pesco-vegetarian diets

BackgroundColorectal cancer (CRC) risk is strongly affected by dietary habits with red and processed meat increasing risk, and foods rich in dietary fibres considered protective. Dietary habits also shape gut microbiota, but the role of the combination between diet, the gut microbiota, and the metabolite profile on CRC risk is still missing an unequivocal characterisation.MethodsTo investigate how gut microbiota affects diet-associated CRC risk, we fed Apc-mutated PIRC rats and azoxymethane (AOM)-induced rats the following diets: a high-risk red/processed meat-based diet (MBD), a normalised risk diet (MBD with α-tocopherol, MBDT), a low-risk pesco-vegetarian diet (PVD), and control diet. We then conducted faecal microbiota transplantation (FMT) from PIRC rats to germ-free rats treated with AOM and fed a standard diet for 3 months. We analysed multiple tumour markers and assessed the variations in the faecal microbiota using 16S rRNA gene sequencing together with targeted- and untargeted-metabolomics analyses.ResultsIn both animal models, the PVD group exhibited significantly lower colon tumorigenesis than the MBD ones, consistent with various CRC biomarkers. Faecal microbiota and its metabolites also revealed significant diet-dependent profiles. Intriguingly, when faeces from PIRC rats fed these diets were transplanted into germ-free rats, those transplanted with MBD faeces developed a higher number of preneoplastic lesions together with distinctive diet-related bacterial and metabolic profiles. PVD determines a selection of nine taxonomic markers mainly belonging to Lachnospiraceae and Prevotellaceae families exclusively associated with at least two different animal models, and within these, four taxonomic markers were shared across all the three animal models. An inverse correlation between nonconjugated bile acids and bacterial genera mainly belonging to the Lachnospiraceae and Prevotellaceae families (representative of the PVD group) was present, suggesting a potential mechanism of action for the protective effect of these genera against CRC.ConclusionsThese results highlight the protective effects of PVD while reaffirming the carcinogenic properties of MBD diets. In germ-free rats, FMT induced changes reminiscent of dietary effects, including heightened preneoplastic lesions in MBD rats and the transmission of specific diet-related bacterial and metabolic profiles. Importantly, to the best of our knowledge, this is the first study showing that diet-associated cancer risk can be transferred with faeces, establishing gut microbiota as a determinant of diet-associated CRC risk. Therefore, this study marks the pioneering demonstration of faecal transfer as a means of conveying diet-related cancer risk, firmly establishing the gut microbiota as a pivotal factor in diet-associated CRC susceptibility.6mA3tL1nA724D7oE9_suJhVideo

Experimental investigation on the residual strength of concrete under the multi-factor coupling action of chloride penetration, freeze-thaw, and fatigue effect

With the ongoing process of globalization and the rapid expansion of the global economy, the proliferation of coastal constructions and infrastructures has witnessed a notable surge. These structures often encounter a confluence of environmental stressors in practical engineering, including cyclic fatigue loading, chloride salt erosion, and freeze-thaw cycles. These synergistic factors accelerate concrete’s failure, resulting in accelerated deterioration and significantly reduced durability. A comprehensive understanding of the damage characteristics of concrete materials in offshore environments, under the multi-factor coupled action of freeze-thaw phenomena, along with an assessment of their residual strength, is crucial for the development of relevant structural analysis and lifetime prediction models. To address this, twenty-seven dedicated specimens were designed and fabricated for this investigation. They were employed to scrutinize the residual strength of concrete under the combined influences of fatigue, freeze-thaw, and chloride penetration. Nine distinct multi-factor coupling actions were meticulously devised and characterized by different parameters. Following the multi-factor coupling action, tests were conducted to assess the residual flexural and compressive strengths, as well as the chloride ion content near the specimen edges. The findings revealed a substantial negative correlation between the residual flexural and compressive strengths with both the number of freeze-thaw cycles and fatigue loading iterations. In contrast, chloride ion concentration and the stress level of fatigue loading (stress ratio: 0.1–0.3) exhibited a comparatively marginal influence. Despite the relatively short test duration, it was evident that both freeze-thaw cycles and fatigue loading exerted a discernible promotional effect on chloride ion ingress in the concrete of the specimens.

Boroxazolidones: Synthesis, In Silico and In Vitro Evaluation as ACE/AChE Dual Inhibitors, and In Vivo Testing of Antihypertensive Activity.

Systemic arterial hypertension is a serious chronic health problem caused by multiple factors. It is a major risk factor for Cardiovascular Diseases (CVDs), including heart failure, coronary heart disease, and myocardial infarction. Hypertension can be effectively treated with inhibitors of the Angiotensin Converting Enzyme (ACE), such as captopril, enalapril, and lisinopril. However, these drugs are associated with significant adverse reactions (e.g., persistent coughing, skin rashes, and angioedema). Considering the recent insights obtained by our group into the antihypertensive effect of boroxazolidones, the aim of the current contribution was to design and synthesize a series of these compounds derived from α-amino acids and evaluate them (in silico and in vitro) as inhibitors of ACE and acetylcholinesterase (AChE). The best candidates were examined for their in vivo antihypertensive activity to regulate high blood pressure in male spontaneously hypertensive rats. Although boron-containing compounds were once thought to be toxic in any medical context, they have increasingly been used as antibiotics, antiseptics, and antineoplastic agents. BXZHis, BXZ-Lys, BXZ-Orn, BXZ-Phe, and BXZ-Pro were selected in silico as promising ACE and AChE inhibitors. After synthesis, these molecules were tested in vitro as ACE and AChE inhibitors, finding that most were effective at micromolar concentrations. The two best candidates, BXZ-Lys and BXZ-His, were evaluated in vivo with spontaneously hypertensive rats. BXZ-Lys significantly decreased systolic, diastolic, and mean blood pressure, being more potent than a common ACE inhibitor, captopril. Future research is required to elucidate the mechanism of action of this antihypertensive effect.

The use of silver diamine fluoride to prevent/treat enamel carious lesions: a narrative review.

This comprehensive literature review examines the use of silver diamine fluoride (SDF) for the prevention and treatment of enamel carious lesions. SDF has been approved by different international drug associations as a caries-preventing agent to be used on deep carious lesions (dentin). However, SDF can cause staining of exposed tooth structures. Furthermore, the effect of SDF on the bond of adhesives to the tooth structure is still being determined. This review explores various studies on the use of SDF to treat enamel carious lesions, highlighting its effectiveness and preventive action. The literature suggests that SDF inhibits bacterial growth, promotes remineralization, and does not negatively affect adhesive retentions. Potassium iodide (KI) or glutathione (GSH) can reduce staining and discoloration. However, the reviewed studies have limitations. Further research, including well-designed clinical trials, is necessary to validate the findings and evaluate the long-term implications of SDF treatment. Conclusion: Despite the above-mentioned limitations, SDF shows potential as a therapy for enamel caries prevention, remineralization, and use as an adjuvant to other dental treatments, warranting further investigation and the refinement of application methods.

Research on the migration law of aggregate particles in the compaction process of asphalt mixture based on discrete element method

Asphalt mixture compaction is among the key technologies in asphalt pavement construction, but the effect of asphalt mixture mixing quality on mixture compaction performance is still unclear. This research aimed to develop an asphalt mixture compaction model by discrete element simulation and verify it by compaction degree. Asphalt mixture compaction process was simulated and the effect of asphalt mixture workability on the stress, migration law and void distribution properties of aggregate particles during compaction process was investigated. The obtained results showed that the developed asphalt mixture compaction model was reasonable and correct. The more uniform the asphalt mixture is mixed, the smaller the average force on the aggregates, the aggregate particle migration velocity, and the aggregate particle displacement during the compaction of the asphalt mixture. Under the same conditions, increasing the mixing temperature from 140℃ to 180℃ increased the average velocity of the aggregates in the asphalt mixture by 92 %. It also decreased the voids in the compacted mixture specimens. At the same time, under the action of edge effect, void distribution at the center of compacted specimen was small, void distribution around the specimen was high, and void distribution along specimen compaction force direction was also high.

Optimization and Spectrum-Effect Analysis of Ultrasonically Extracted Antioxidant Flavonoids from Persicae Ramulus.

The objectives of this study were to optimize the ultrasonic-assisted flavonoid extraction process from PR and to establish fingerprints in order to analyze the spectrum-effect relationship of antioxidant activity. The ultrasonic-assisted flavonoid extraction process from PR was optimized using RSM, and the fingerprints of twenty-eight batches of flavonoids from PR were established using UHPLC. Meanwhile, the in vitro antioxidant activity of PR was evaluated in DPPH and ABTS free radical-scavenging experiments. Then, the peaks of the effective antioxidant components were screened using the spectrum-effect relationships. The results show that the optimal extraction yield of flavonoids from PR was 3.24 ± 0.01 mg/g when using 53% ethanol, a 1:26 (g/mL) solid-liquid ratio, and 60 min of ultrasonic extraction. Additionally, the clearance of two antioxidant indices by the flavonoids extracted from PR had different degrees of correlation and showed concentration dependence. Simultaneously, the similarity of the UHPLC fingerprints of twenty-eight batches of PR samples ranged from 0.801 to 0.949, and four characteristic peaks, namely peaks 4, 12, 21, and 24, were screened as the peaks of the components responsible for the antioxidant effect of PR using a GRA, a Pearson correlation analysis, and a PLS-DA. In this study, characteristic peaks of the antioxidant effects of PR were screened in an investigation of the spectrum-effect relationship to provide a scientific basis for the study of pharmacodynamic substances and the elucidation of the mechanism of action of the antioxidant effect of PR.

Carbon nanoparticle exposure strengthens water-relation parameters by stimulating abscisic acid pathway and aquaporins genes in rice

Mechanism of action and molecular basis of positive growth effects including yield increase due to carbon nanoparticle (CNP) treatment in rice plants is dissected here. CNP at 500 -750 µg/mL were found to be the optimum dosages showing best seedling growth. CNP treatment resulted increase in stomata size, stomatal conductance and water use efficiency along with low relative humidity, decrease in stomata frequency and internal CO2 concentration. CNP-coupled with water uptake was found to be endocytosis mediated, although CNP uptake was not affected by endocytosis inhibitor application in roots. Genomic analysis resulted major involvement of ABA pathway and stomata size and frequency genes in Arabidopsis and rice. Elevated endogenous ABA in rice seedlings and flag leaves along with increased expression of ABA biosynthetic genes in Arabidopsis and rice AtNCED3, AtNCED6, OsNCED1 confirmed increased ABA synthesis. Negative regulators of ABA pathway, OsSNRK2 down-regulation and up-regulation of stomagen (OsEPFL9) reconfirmed ABA's involvement. CNP treatment exerted cold tolerance in seedlings and water stress tolerance in reproductive stage. CNP treatment under water withheld condition resulted water stress tolerance by maintaining lower stomatal conductance, transpiration rate and higher relative water content. Increased ABA (OsSNRK1, OsSNRK2) and aquaporin (OsPIP2–5 and OsPIP1–3) genes’ expressions could explain the better water stress tolerance in rice plants treated with CNP. Altogether, due to thermomorphogenesis, down-regulation of Phytochrome B transcript resulted altered the ABA pathway and stomatal distribution with size (Graphical Abstract). These changes resulted improved water relation parameters and water use efficiency (WUE) showing improvement in yield. Detailed mechanism of action of CNP in abiotic stress tolerance can be exploited using nano-agriculture at field level.