Search Results (1,295)

An inorganic–organic hybrid nano-adsorbent was prepared by chemical immobilisation of an organic Schiff base Cu (II) ion receptor, DHB ((E)-N-(1-(2-hydroxy-6-methyl-4-oxo-4H-pyran-3-yl) ethylidene) benzohydrazide), a selective dehydroacetic acid-based chemosensor, onto a mesoporous silica support. In order to prepare the sorbent, the silylating agent was anchored onto the silica. During this procedure, 3-Chloropropyl trimethoxy silane (CPTS) was attached to the surface, increasing hydrophobicity. By immobilising DHB onto the CPTS platform, the silica surface was activated, and as a result the coordination chemistry of the Schiff base generated a hybrid adsorbent with the capability to rapidly sequestrate Cu (II) ions from wastewater, as an answer to combat growing Waste Electrical and Electronic Equipment (WEEE) contamination in water supplies, in the wake of a prolonged consumerism mentality and boom in cryptocurrency mining. The produced hybrid materials were characterised by FTIR, proximate and ultimate analysis, nitrogen physisorption, PXRD, SEM, and TEM. The parameters influencing the removal efficiency of the sorbent, including pH, initial metal ion concentration, contact time, and adsorbent dosage, were optimised to achieve enhanced removal efficiency. Under optimal conditions (pH 7.0, adsorbent dosage 3 mg, contact time of 70 min, and 25 °C), Cu (II) ions were quantitatively sequestered from the sample solution; 93.1% of Cu (II) was removed under these conditions. The adsorption was found to follow pseudo-second-order kinetics, and Langmuir model fitting affirmed the monolayer adsorption. Full article

In the current digital age, children are exposed to electronic media at an increasingly early age. The issue of excessive electronic media use has become a significant risk factor affecting the healthy development of young children. To examine the association between parental phubbing and preschoolers’ excessive electronic media use, as well as the underlying mechanism—mediating roles of parent–child attachment and self-control, 758 parents of preschoolers were recruited to complete a set of scales. The results show that: (1) Parental phubbing was positively associated with preschoolers’ excessive electronic media use; (2) Parent–child attachment and self-control significantly mediated this relation, which contains three mediating pathways—the mediating effects of parent–child attachment and self-control, as well as their chain mediating effect. The study revealed the psychological mechanisms between parental phubbing and preschoolers’ excessive electronic media use, providing suggestions for the prevention and intervention of excessive electronic media use among preschoolers. Full article

This study characterizes the chemical defense system of the invasive longhorn beetle Aromia bungii, a destructive pest of Prunus trees, addressing the limited understanding of chemical defensive mechanisms in Cerambycidae. High-speed cameras, environmental scanning electron microscopy (ESEM), dissection, and micro-CT imaging were used to investigate defensive behavior, and the structure of the defense system, in this beetle. Both sexes of A. bungii possess a pair of triangular, sac-like defensive glands symmetrically located in the metathorax, attached to the metasternum. Upon mechanical stimulation, white liquid defensive substances are rapidly ejected through a pair of slit-shaped openings (~200 µm) at the metasternum corners, without gland eversion, reaching over 50 cm. The average weight of substances ejected in first sprays was 7.95 ± 0.79 mg for females and 8.62 ± 2.13 mg for males (mean ± se), with no significant difference between sexes. However, the weight in second sprays after 10 days was significantly lower, at 2.93 ± 0.54 mg for females and 2.22 ± 0.40 mg for males (mean ± se), suggesting that the beetles cannot re-synthesize the substances soon after spray. The weight of ejected substances had no correlation with beetle body weight. Our findings represent the first detailed morphological and functional description of a chemical defense system in Cerambycidae, revealing a specialized metasternal gland and spray mechanism. The substantial but likely non-renewable defensive substances reflect an adaptive trade-off in energy allocation between reproduction and defense in this species that exhibits high fecundity but a short lifespan at the adult stage. Full article

Sintered nano-silver is widely investigated as a die-attach material for next-generation power electronic modules due to its high thermal conductivity, favorable electrical performance, and stability at elevated temperatures. However, how bonding pressure and joint thickness jointly affect densification, interfacial diffusion, and mechanical reliability has not been systematically clarified, especially under the low-pressure conditions required for large-area SiC and GaN devices. In this work, nano-silver lap-shear joints with three bond-line thicknesses (50, 70, and 100 μm) were fabricated under two applied pressures (1.0 and 1.5 MPa) using a controlled sintering fixture. Shear testing and cross-sectional SEM were employed to evaluate the relationships between microstructural evolution and joint integrity. When the bonding pressure was increased from 1.0 to 1.5 MPa, more effective particle rearrangement and reduced pore connectivity were observed, together with improved metallurgical bonding at the Ag–Au interface, leading to a strength increase from 15.3 to 28.2 MPa. Although thicker joints exhibited slightly higher bulk relative density due to greater heat retention and accelerated local sintering, this densification advantage did not lead to improved mechanical performance. Instead, the lower strength of thicker joints is attributed to a narrower Ag–Au interdiffusion region, which limited the formation of continuous load-bearing paths at the interface. Fractographic analyses confirmed that failure occurred predominantly by interfacial delamination rather than cohesive fracture, indicating that the reliability of the joints under low-pressure sintering is governed by the quality of interfacial bonding rather than by overall densification. The experimental results show that, under low-pressure sintering conditions (1.0–1.5 MPa), variations in bonding pressure and bond-line thickness lead to distinct effects on joint performance, with the extent of Ag–Au interfacial interaction playing a key role in determining the mechanical robustness of the joints. Full article

The formation of interfacial charge transfer (ICT) complexes between phenolic ligands and metal oxide surfaces enables surface functionalization strategies with potential applications in catalysis and bioconjugation. In this study, magnetite (Fe₃O₄) nanoparticles were modified with two phenolic ligands, 5-aminosalicylic acid (5ASA) and caffeic acid (CA), to generate ICT complexes capable of covalent or non-covalent enzyme immobilization, respectively. The modified nanomaterials were structurally characterized using X-ray diffraction (XRD), transmission electron microscopy (TEM), and Fourier-transform infrared spectroscopy (FTIR). Horseradish peroxidase (HRP) was immobilized on these functionalized supports using varying nanoparticle amounts (10–30 mg) and initial enzyme concentrations (25–250 µg mL⁻¹). Catalytic activity was evaluated using pyrogallol oxidation assays. The Fe₃O₄/5ASA–HRP system exhibited a maximum activity of 2.5 U per 20 mg of support (approximately 125 U g⁻¹), whereas Fe₃O₄/CA showed minimal activity under the same conditions. Enzyme loading studies confirmed that 5ASA-enabled covalent attachment resulted in significantly higher immobilization efficiency (up to 1068 mg g⁻¹) compared to the CA system. Reusability tests demonstrated that the Fe₃O₄/5ASA system retained high absolute catalytic activity during the initial reaction cycles and consistently outperformed the non-covalently immobilized Fe₃O₄/CA system upon repeated reuse. The magnetic properties of Fe₃O₄ allowed rapid recovery of the biocatalysts using an external magnetic field. These results highlight the effectiveness of ICT-based functionalization for enzyme immobilization, positioning Fe₃O₄/5ASA as a promising platform for robust and reusable biocatalysts in environmental and industrial applications. Full article

The rapid growth of the palm oil industry produces large amounts of palm oil mill effluent (POME), which contains high organic content and is challenging to treat using conventional ponding systems. These traditional systems often fail to meet discharge standards for biochemical oxygen demand (BOD) and chemical oxygen demand (COD). This study tested anaerobic biofilm reactors enhanced with biochips and chemically treated palm oil fuel ash (TPOFA) to improve POME degradation and biogas production. Two 3 L reactors were operated at the same feed-to-microorganism (F/M) ratio: a control (C) and a combination of both (P + B). Biochips helped microbes attach and form biofilms, while TPOFA acted as an adsorbent, creating better conditions for anaerobic breakdown. The P + B reactor outperformed others, achieving over 95% COD removal, high microbial biomass (MLVSS: 24,500 mg/L), and the highest biogas yield at 917 mL per day. Microbial analysis showed dominant groups, including phyla groups of Halobacterota, Bacteroidota, and Firmicutes. Class Methanosarcina in archaeal phylum of Halobaterota was key in converting acetate to methane. Bacteroidota primarily aided organic matter breakdown and nutrient removal, while Firmicutes supported hydrolysis and electron transfer. Less abundant Desulfobacterota also helped by interacting with methanogenic archaea. Overall, combining biochips with TPOFA in anaerobic biofilm reactors offers an effective, sustainable method for treating POME and recovering renewable energy through biogas. Full article

Background/Objectives: Three-dimensional (3D) cell cultures are increasingly used because 3D cell aggregates better mimic tissue-level biological mechanisms and support studies of tissue physiology and drug screening. However, existing laboratory methods and commercial microwell platforms often yield inconsistent results and can be error-prone, time-consuming, or costly. The objective of this work was to develop a reproducible, high-yield, and cost-effective approach for generating homogeneous cell aggregates using custom 3D-printed microwell stamps. Methods: Custom conical and semi-spherical microwell stamps were fabricated using 3D printing. Stamp resolution was characterized by scanning electron microscopy (SEM). Negative imprints were cast in polydimethylsiloxane (PDMS), a biocompatible and hydrophobic polymer conducive to cell aggregation. These PDMS microwells were then used to generate pluripotent stem cell aggregates (embryoid bodies, EBs) and tumor spheroids from adherent cancer cell lines. Results: The 3D-printed stamps produced high-resolution conical and semi-spherical microwells in PDMS. Semi-spherical microwells enabled rapid, simple, and cost-effective formation of pluripotent stem cell aggregates that were homogeneous in size and shape. These aggregates outperformed those produced using commercial microwell plates and ultra-low attachment plates. The fabricated microwells also generated uniform tumor spheroids from adherent cancer cells, demonstrating their versatility. Conclusions: The in-house 3D-printed microwell stamps offer a reproducible, efficient, and economical platform for producing homogeneous cell aggregates. This system improves upon commercial alternatives and supports a broad range of applications, including pluripotent stem cell embryoid body formation and tumor spheroid generation. Full article

L. ferrooxidans and their metabolic products have been explored as viable flotation reagents of pyrite and chalcopyrite for froth flotation. Scanning electron microscopy (SEM), near edge X-ray absorption fine structure (NEXAFS) spectroscopy, time-of-flight secondary ion mass spectrometry (ToF-SIMS) and captive bubble contact angle measurements have been used to examine the surface physicochemical properties of pyrite upon exposure to L. ferrooxidans grown in HH medium at pH 1.8. C K-edge NEXAFS spectra, collected using scanning transmission X-ray microscopy (STXM), indicate hydrophilic lipids, fatty acids, and biopolymers are formed at the mineral–bacterium interface within hours of exposure. The Fe L-edge NEXAFS show oxidation of the mineral surface from Fe (II) sulfide to Fe (III) oxyhydroxides. The leaching of the iron species at the pyrite surface is accelerated in the presence of L. ferrooxidans and extracellular polymeric substances (EPS) as compared to HH medium controls, as shown by ToF-SIMS. The surface chemical changes induced by the interaction with L. ferrooxidans show a significant decrease in surface hydrophobicity within the first 2 h of exposure. The implications of these findings are the potential use of EPS, produced during early attachment of L. ferrooxidans, as a depressant for bioflotation or to enhance bioleaching. Full article

Flexible strain sensors capable of conformal integration with living organisms are essential for advanced wearable electronics, human–machine interaction, and plant health. However, many existing sensors require complex fabrication or rely on non-breathable elastomer substrates that interfere with the physiological microenvironment of skin or plant tissues. Here, we present a low-cost, breathable, and highly stretchable strain sensor constructed from biomedical materials, in which a double-layer medical elastic bandage serves as the porous substrate and an intermediate conductive medical elastic tape impregnated with carbon nanotubes (CNTs) ink acts as the sensing layer. Owing to the hierarchical textile porosity and the deformable CNTs percolation network, the sensor achieves a wide strain range of 100%, a gauge factor of up to 2.72, and excellent nonlinear second-order fitting (R² = 0.997). The bandage substrate provides superior air permeability, allowing long-term attachment without obstructing moisture and gas exchange, which is particularly important for maintaining skin comfort and preventing disturbances to plant epidermal physiology. Demonstrations in human joint-motion monitoring and real-time plant growth detection highlight the device’s versatility and biological compatibility. This work offers a simple, low-cost yet effective alternative to sophisticated strain sensors designed for human monitoring and plant growth monitoring, providing a scalable route toward multifunctional wearable sensing platforms. Full article

Background/Aim: This systematic review and meta-analysis aimed to evaluate the clinical efficacy of oxygen-based adjunct therapies in patients with periodontitis, including ozone therapy, hyperbaric oxygen therapy, and local oxygen delivery, as adjuncts to subgingival instrumentation. These interventions have been proposed to counteract tissue hypoxia and inflammation, which sustain an environment favorable to anaerobic pathogens in periodontitis. Methods: An electronic search was conducted in MEDLINE PubMed, the Cochrane Library, the Cochrane Central Register of Controlled Trials, and SciELO. Risk of bias was assessed using the Cochrane Risk of Bias Tool 2. Standardized mean difference was calculated for gains in clinical attachment level, and a random effects model was applied due to high variability. Results: The meta-analysis of adjunct ozone therapies presented a pooled standardized mean difference of 0.53 (95% CI [−0.14, 1.19]), indicating a clinically relevant medium effect in favor of ozone therapies, though this effect was not statistically significant and substantial heterogeneity was observed (I² = 70%, p < 0.01). Meta-analysis was restricted to adjunct ozone therapies due to the limited availability of qualifying studies for hyperbaric oxygen therapy and local oxygen therapies. Conclusions: While the medium effect size in favor of ozone therapies could be clinically relevant, the statistical non-significance underscores the need for more evidence before widespread adoption. Individual studies reported significant benefits for adjunct HBOT and ozonated olive oil, but comparison between oxygen delivery modes was not possible due to heterogeneous protocols. Full article

High-risk human papillomavirus (HPV), including types 16–18, is the established cause of cervical intraepithelial neoplasia (CIN) and invasive carcinoma of the cervix. While preventive vaccination is highly effective in preventing infection from becoming reconstituted following treatment of existing disease, its use among cervical intraepithelial neoplasia (CIN)-positive females has remained sporadic. The following review provides an update on the current state of evidence about the acceptance, awareness, or perception of HPV vaccination by women following a diagnosis or treatment of CIN. Methods: A narrative synthesis of literature from the publication period of 2010 to 2025 was performed on PubMed, Scopus, and Google Scholar. Surveys that quantified literature on post-CIN vaccination attitudes, risk perceptions, or behavioral factors were considered. Results: Acceptance levels varied from 20–95% across all continents. The highest acceptance levels (≥80%) among the populations belong to the European and Oceanian groups, followed by moderate acceptance among the North Americans (60–80%), which was influenced by financial costs, misconceptions, and sociocultural stigmas. Several systemic-level features in Europe and Oceania have been shown to be consistently associated across these regions with high acceptance rates. These features include public funding of HPV vaccine delivery universally in these regions and reminder and recall systems established in their electronic health records. In these two regions, provider recommendation demonstrates particular significance because there is follow-up care after treatment of CIN. In these regions, mass awareness about HPV conducted in conjunction with their cervical screening programs increases baseline knowledge and favorability towards HPV vaccination. The lowest levels (20–70%) of awareness of HPV diseases and vaccination programs among Asians and Africans can be attributed to obstacles that include misconceptions about fertility concerns. In the case of Asia, there are various socially ingrained stigma factors that contribute to the poor awareness and acceptance levels. These factors include the possibility of being perceived as promiscuous, embarrassment linked to STI conditions, as well as the possibility of rejection from partners and in-laws. In particular regions, there might be stigmas attached to HPV vaccination that cause tension within married women who perceive the vaccine as an indicator of being unfaithful. Also, distrust from the general community has been driven by past incidents, including the halting of proactive HPV vaccine recommendations in Japan in 2013. Moreover, there are numerous myths concerning infertility and menstruation linked to poor vaccine acceptance. The key determinant of acceptance levels was physician endorsement, lack of knowledge of the association of HPV-CIN, or the belief that there is no need for vaccination after treatment. Conclusion: The acceptance of HPV vaccination among women following CIN is influenced by educational level, the structure of the healthcare system, and sociocultural factors. Incorporating evidence-based cervical vaccination counseling into follow-up care after biopsy could help increase its acceptance and prevent recurrent high-grade lesions. Full article

Objectives: Burn being a major traumatic issue worldwide impacts millions of lives annually. Herein, a novel xanthan dialdehyde/sodium alginate/copper-doped mesoporous bioactive glass nanoparticle (XDA/Na-ALG/Cu-MBGN) hydrogel is presented in this study. Methods: The hydrogel was fabricated by a casting method, followed by its characterization in terms of its morphology, surface topography, and in vitro biochemical and physical interactions. Results: Scanning electron microscopy images revealed the rough surface of the hydrogel, ideal for cell attachment and proliferation. The nanoporous structure revealed by BET enabled it to hold moisture for an extended span. The nanopores were developed because of the ether linkage developed between XDA and Na-ALG, as evident from Fourier Transform Infrared Spectroscopy. The loading of Cu-MBGNs was also confirmed by FTIR. The release of copper ions was sustained throughout the 7 days, and it is accounting for about 22 µg/mL in 330 h, which follows the degradation kinetics of XDA/Na-ALG/Cu-MBGN hydrogels. The released copper ions promoted angiogenesis, as confirmed by the enhanced release of vascular endothelial growth factor (VEGF) for the XDA/Na-ALG/Cu-MBGN hydrogel (275 ng/mL) in comparison to 200 ng/mL of the bare TCP. The hydrogel, despite being bactericidal against Escherichia coli (E. coli) and Staphylococcus aureus (S. aureus) did not show toxicity towards human dermal fibroblasts confirmed via a Water-Soluble Tetrazolium 8 assay. Conclusions: Hence, the developed XDA/Na-ALG/Cu-MBGN hydrogel possesses potential to be investigated further in terms of in vivo interactions. Full article

Background and Objectives: Periodontitis leads to progressive destruction of periodontal tissues and, despite advances in regenerative approaches, clinical outcomes remain inconsistent. Lasers have been proposed as adjuncts in regenerative periodontology because of their antimicrobial, hemostatic, and photobiomodulatory properties. However, available evidence remains heterogeneous. This scoping review aims to systematically map clinical and experimental evidence on the role of lasers in periodontal tissue regeneration. Materials and Methods: The review was conducted in accordance with the PRISMA-ScR guidelines. PubMed, Scopus, and Web of Science were searched up to September 2025 without time restrictions. Eligible studies included in vitro, ex vivo, in vivo and clinical research assessing the application of lasers for periodontal healing. Reviews, conference abstracts and studies unrelated to regeneration were excluded. Results: The electronic search retrieved 314 records, of which 193 unique articles were screened after duplicates removal and 17 full texts were assessed. A total of 15 studies met the eligibility criteria and were included in the review. Included studies comprised 5 in vitro investigations, 2 ex vivo studies, 1 in vivo animal study, 4 case reports and 3 RCTs, published between 2015 and 2025. In vitro and ex vivo evidence demonstrated that laser irradiation enhanced cell proliferation, differentiation, growth factor release, and root surface conditioning. The in vivo study confirmed increased angiogenesis and bone formation after Er:YAG PBM. Clinical studies, including RCTs and case reports, reported improvements in PD reduction, clinical attachment gain, and radiographic bone fill, particularly when lasers were applied as adjuncts to regenerative techniques or biomaterials. Conclusions: Available evidence suggests that lasers can positively modulate biological processes and enhance the outcomes of regenerative periodontal procedures. However, the limited number of high-quality clinical trials, variability in laser types and parameters, and heterogeneity in protocols limit the strength of current conclusions. Further standardized RCTs with long-term follow-up are needed to clarify the clinical relevance of lasers in periodontal regenerative outcomes. Full article

Molecular hydrogen is the basis of hydrogen energy. It is formed and used in many fields of industry, physics, and chemistry. Molecular hydrogen is the main product formed during the gamma radiolysis of liquid cyclohexane. When studying the mechanism of molecular hydrogen formation during the gamma radiolysis of liquid cyclohexane, we found that the values of adiabatic electron affinity, one of the fundamental characteristics of atoms and molecules, had not yet been experimentally determined for hydrogen and cyclohexane molecules. Theoretical estimates of the adiabatic electron affinity of the hydrogen molecule made by other authors varied widely ([−0.3; −5.771] eV) and could not be compared with experimental values due to the absence of such data. Using DFT calculations at the PBE0/TZVPP level of theory, and a constructed correlation with experimental values of the adiabatic first ionization potential and electron affinity for a number of molecules, neutral radicals, and atoms, we estimated, for the first time, the experimental adiabatic electron affinities of hydrogen (−3.08 eV) and cyclohexane (−2.13 eV) molecules in the gas phase. When an electron is attached to a cyclohexane molecule, a cyclohexane radical anion is formed, a new, highly reactive species that has not been studied before. A new perspective on molecular hydrogen formation during the gamma radiolysis of liquid cyclohexane was introduced and discussed. Full article

Purpose: The increasing demand for alternatives to autologous and resorbable bone grafts in the treatment of bone defects is driving research efforts. This study aims to evaluate the effects of different surface treatments on zinc-1%-magnesium (Zn-1Mg) alloy scaffolds on chondrocytes and osteoblasts, focusing on cytotoxicity, biocompatibility, and cell proliferation. Methods: Zn-1Mg alloy disks were manufactured additively by the powder bed fusion of metals using a laser beam (PBF-LB/M) and underwent different distinct surface treatments, including as-built treatment, sandblasting, Zn-1Mg-blasting, and electropolishing, respectively. Chondrocytes and osteoblasts were cultured separately on these additively manufactured Zn-1Mg alloy disks for 3, 7, and 14 days to assess biocompatibility and cellular growth. Cell viability, cytotoxicity, and proliferation were analyzed using DAPI staining, live/dead staining, fluorescence microscopy, and flow cytometry. Additionally, cellular morphology was investigated using Phalloidin/DAPI staining and scanning electron microscopy (SEM). Zn-1Mg scaffolds were also manufactured and subjected to the same surface treatments. All aforementioned experiments were repeated using Zn-1Mg scaffolds with co-cultured osteoblasts and chondrocytes. Results: All samples, irrespective of the surface treatment, showed similar effects compared to the reference surfaces in terms of cell viability, cytotoxicity, and proliferation for both chondrocytes and osteoblasts. SEM analysis revealed comparable cellular morphology across all scaffolds, with cells observed attaching and growing on all scaffold surfaces. This indicates that all scaffolds independent of different surface treatments exhibit good biocompatibility. Conclusions: The findings indicate that Zn-1Mg alloy samples with different surface treatments exhibit no significant differences in cytocompatibility with chondrocytes and osteoblasts. Zn-1Mg alloy scaffolds, composed of 99% zinc and 1% magnesium, demonstrate biocompatibility, with cells attaching and growing on all scaffold surfaces. These results suggest that Zn-1Mg alloy scaffolds manufactured additively by PBF-LB/M hold promise for use in resorbable bone graft applications. Full article