Search Results (3,989)

The increasing interest in the presence of contaminants of emerging concern (CEC) in aquatic environments has driven research into biological mechanisms capable of eliminating pharmaceutical compounds like paracetamol, considering different plant species as model systems. Thus, the use of hairy roots (HRs) has become an interesting tool. This study explores the ability of tobacco HRs to remove paracetamol, with an emphasis on elucidating the main metabolism steps and key enzymes involved in the green liver detoxification process, as well as the antioxidant response. The deepening of these aspects has been carried out through gene expression and biochemical analysis under circadian regulation. Our results reveal that HRs efficiently removed paracetamol (100 mg L⁻¹) from the culture medium, achieving around 99% removal at ZT16 h (Zeitgeber Time 16). The early activation of antioxidant defense mechanisms, demonstrated by enhanced peroxidase (POD) activity and total antioxidant capacity (TAA) during the light phase, has been observed. Furthermore, glutathione S-transferase (GSTs) activity and glutathione (GSH) levels, potentially linked to paracetamol conjugation, were also assessed. Gene expression analyses confirmed GST gene upregulation in response to paracetamol treatment, with GSTF6-like and GSTF8-like maintaining circadian rhythms as in the control, and GSTZ1-like only displayed rhythmic expression upon treatment. Additionally, the modulation of core circadian clock genes (NtLHY1 and NtTOC1) suggests that the plant response to paracetamol is tightly regulated by the circadian system. Together, these findings shed light on the complex molecular and biochemical mechanisms underlying paracetamol detoxification in tobacco HRs and underscore the significant role of circadian regulation in orchestrating these responses. Full article

Epigallocatechin-3-gallate (EGCG), a major polyphenol in green tea, exhibits strong antioxidant activity but suffers from poor stability due to rapid autoxidation under physiological conditions. In this study, we developed alginate–EGCG conjugates via a site-selective thiol-quinone addition reaction under mild aqueous conditions. The conjugation preserved EGCG’s flavanic structure while enabling tunable degrees of substitution (DS). We systematically evaluated the oxidative stability, antioxidant activity, and cytocompatibility of alginate–EGCG conjugates in comparison with free EGCG and a mixture of EGCG and alginate. Alginate–EGCG conjugates significantly suppressed EGCG autoxidation, reduced hydrogen peroxide generation, and improved cytocompatibility in human renal epithelial cells, especially at a low DS. Furthermore, alginate–EGCG conjugates retained or even enhanced superoxide anion radical scavenging activity, with higher DS conjugates exhibiting greater antioxidant effects. In addition, dynamic light scattering analysis revealed DS-dependent particle formation via self-assembly. These findings demonstrate that covalent conjugation with natural polymers is an effective strategy to improve oxidative stability and biological functionality of plant-derived polyphenols, offering a promising approach for developing advanced antioxidant materials for food, cosmetic, and biomedical applications. Full article

The rational design of artificial lighting systems in pig housing can enhance animal welfare, thereby boosting gilt health and reproductive performance while improving economic metrics for swine farms. To identify the optimal light environments for gilts under artificial illumination, we conducted self-selection-based photic preference testing, ultimately providing actionable insights for welfare-centric precision lighting protocols in modern pig production. In this study, a dynamic multi-chromatic self-selection system was developed, integrating programmable RGBW-LED arrays for spectral control, inter-compartment access channels for autonomous gilt movement, and real-time image recognition technology to investigate light color preferences. Twenty-four gilts (nulliparous female pigs) were housed for five weeks in pens with white, yellow, green, blue, or red light (100 lux), and they were given free access to all of the chromatic zones through inter-compartment channels. A YOLOv8n-based deep learning framework was used to quantify their spatiotemporal distribution, activity levels, and eating behavior. The key findings were the following: (1) a significant preference for green light environments (21.29 ± 3.77% distribution proportion) (p < 0.05), peaking at 6:00–13:00 and 18:00–20:00; (2) the average activity was the highest in a white light environment (25.49 ± 0.77%), significantly exceeding yellow (22.69 ± 0.63%) and green light (21.55 ± 0.61%) (p < 0.05); and (3) the daily feed consumption under green light was the lowest, significantly lower than that under white, blue, and red light (p < 0.05). The findings from this study offer insights into the light environment preferences of gilts, which could improve animal welfare. Full article

In recent years, increasing attention has been given to adjunctive therapies aimed at improving clinical outcomes in periodontal treatment. Among these, antimicrobial photodynamic therapy (aPDT) using the photosensitizer indocyanine green (ICG) has shown great promise. Objective: This narrative review seeks to summarize the existing evidence from randomized controlled trials, systematic reviews, and in vitro and in vivo studies on the use of antimicrobial photodynamic therapy with indocyanine green (ICG) as a photosensitizer, as well as the emerging approach of double-light aPDT with ICG, in the treatment of periodontitis. Materials and Methods: PubMed, Web of Science, and Cochrane Library databases were searched to find relevant articles regarding the topic. The articles were published in English between the years 2015 and 2025. The search used keywords such as (“indocyanine green” AND “antimicrobial photodynamic therapy” AND (“efficiency” OR “efficacy” OR “effect”) AND (“periodont*” OR “gingivitis” OR “gingival” OR “gum”). The articles chosen were required to evaluate the treatment outcomes of periodontitis with ICG-aPDT. Conclusions: ICG-aPDT represents an effective adjunct treatment in periodontal therapy. It can non-invasively target biofilms and minimize systemic action. It makes this technique an attractive adjunct in modern periodontology practice. This narrative review shows that ICG-aPDT can be integrated into comprehensive periodontal care as an adjunct measure promoting tissue healing. However, more high-quality clinical trials are needed to develop standardized protocols and demonstrate long-lasting benefits. Full article

Interest in improving roadside services for long-haul truckers’ health, safety, and well-being has led to an effort to describe the services offered at truck stop/rest areas. This study aimed to describe services offered in truck stop and rest areas and to determine, based on what was available, their implications for the health of long-haul truck drivers. A systematic and structured direct observation of thirteen truck stop and rest areas was undertaken within one state in the US on a major north–south interstate highway from October 2023 to June 2024. The categories of services observed included food, physical activity, rest, personal hygiene and health, and safety. A descriptive analysis of the data was performed. Seventeen visits were carried out in 13 truck stop and rest areas. All sites offered paved parking areas, with lighting and signage; 92% offered internet access; more than 85% offered food, safety, and personal hygiene services; 69% offered laundry services; 54% had a convenience store and hotel nearby; and 15% had green/natural areas with benches. The services offered at the truck stop and rest areas in this study meet the basic needs of food, personal hygiene, and safety of truckers and can serve as lessons for other states and countries to consider. Full article

Tetracycline hydrochloride (TC-HCl) is widely used in the prevention and treatment of human/animal bacterial infection due to its good antibacterial activity. However, because of its high hydrophilicity and low volatility, TC-HCl can enter the natural water body through various ways and exist in it statically for a long time, which then causes environmental toxicity and even threatens human health. Photocatalysis, which can use free, clean and sustainable solar energy to provide power, achieves the conversion of solar energy to chemical energy and is a promising green technology for solving global environmental and energy challenges. BiOCl has suitable valence/conduction potential and good stability and hierarchical structure, which contributes to smooth transfer of surface charge. BiOCl photocatalyst materials with deionized water, anhydrous ethanol (EtOH), and ethylene glycol (EG) as solvents were prepared by using different viscosity solutions as reaction media. The characterization results showed that the type of solvent is what mainly affected the morphology and absorption intensity of the photocatalyst. BiOCl prepared with EG as solvent has the best photocatalytic degradation performance of TC-HCl, and the removal rate can reach 76% after 60 min of visible light irradiation. Its strong light response intensity and unique spherical structure contribute to the enhancement of photocatalytic activity. Full article

Photocatalytic overall water splitting (PWS) offers a green, economical, and sustainable pathway for hydrogen production. However, the efficiency is still hindered by severe charge recombination in catalysts, high energy barriers for water oxidation, and sluggish reaction kinetics. Therefore, it is crucial to address these challenges by enhancing charge separation efficiency, accelerating reaction kinetics, and lowering PWS energy barriers. In this work, we constructed donor–acceptor covalent triazine-based organic frameworks (CTFs), such as CTF-BP, CTF-DBT, and CTF-DBTS, using biphenyl (BP), benzothiophene (DBT), and benzothiophene sulfone (DBTS) as basic units, respectively. DFT calculations revealed that all three CTFs exhibit comparable bandgaps with strong visible-light absorption. Notably, strong dipole moments between donor and acceptor units were observed within these frameworks, effectively promoting in-plane charge separation. DBT and DBTS derivatives generated stronger dipole moments compared to biphenyl. Furthermore, hydrogen evolution reaction (HER) and oxygen evolution reaction (OER) pathway analyses demonstrated that CTF-DBTS substantially reduces energy barriers for both half-reactions relative to CTF-DBT and CTF-BP, exhibiting the most promising potential for PWS. This work provides a reference for the application of DBTS-incorporated COFs in PWS systems. Full article

Accurate light simulations using virtual plant models are essential for analyzing how plant structures influence the micro-light climate within canopies. Such simulations are increasingly important in applications including remote sensing, greenhouse optimization, and synthetic data generation for agricultural systems. However, many current models simplify leaf optical behavior by assuming purely diffuse reflectance, thereby neglecting the spectral and angular variability described by the bidirectional reflectance distribution function (BRDF). To address this limitation, the spectral BRDF of cucumber leaves was experimentally measured and corresponding Phong reflectance model parameters were determined for use in the GroIMP simulation environment. These parameters were optimized to replicate the angular and spectral reflectance distribution patterns and evaluated against a diffuse reflectance model. The Phong model successfully reproduced key features of the BRDF, particularly the increased diffuseness in the green and far-red spectral regions, although deviations in hemispherical reflectance emerged at high incidence angles. The resulting Phong parameters offer a practical method for incorporating wavelength- and direction-dependent reflectance into virtual plant simulations. These parameters can be adapted to other reflectance values of leaves with similar optical properties using hemispherical reflectance measurements, enabling more realistic light modeling in virtual canopies. Within a 30–60° incidence, the Phong BRDF reduced per-wavelength error relative to a diffuse baseline across all spectral regions. Full article

Poly(lactic acid) (PLA) is an aliphatic polyester considered a “green” material due to its natural-based origin and biodegradable properties. This is why PLA fibres may be compared with poly(ethylene terephthalate) (PET) fibres in an effort to partially replace the latter in industrial production. The purpose of this study is to investigate the dyeability of poly(lactic acid) fibres using six (6) commercially available disperse dyes with different energy levels, molecular weights and chemical structures, namely Disperse Red 59 (Serisol Fast Pink RFL), Disperse Red 60 (Serilene Red 2BL), Disperse Red 92 (Serilene Red TBLS), Disperse Orange 31 (Serisol Br Orange RGL), Disperse Yellow 54 (Serilene Yellow 3GL) and Disperse Blue 79 (Serilene Navy Blue GRLS). The dyeing characteristics, such as dye exhaustion, colour strength (K/S value), colorimetric values, wash fastness, light fastness and sublimation fastness of dyed fibres, were examined at dyeing temperatures of 110 and 130 °C, while the presence of carrier agent was also investigated. The dye exhaustion values of PLA fibres were found to be lower than those of PET fabrics; however, K/S values were higher than those of the corresponding PET fabrics in some cases. Dyed PLA fibres illustrated good colour fastness, light fastness and sublimation fastness properties, comparable to similarly dyed PET fibres. Full article

This study aims to guide the management and service of highways towards a more efficient and intelligent direction, and also provides intelligent and green data support for achieving sustainable development goals. The forecasting of traffic flow at highway stations serves as the cornerstone for spatiotemporal analysis and is vital for effective highway management and control. Despite considerable advancements in data-driven traffic flow prediction, the majority of existing models fail to differentiate between directions. Specifically, entrance flow prediction has applications in dynamic route guidance, disseminating real-time traffic conditions, and offering optimal entrance selection suggestions. Meanwhile, exit flow prediction is instrumental for congestion and accident alerts, as well as for road network optimization decisions. In light of these needs, this study introduces an enhanced heterogeneous spatiotemporal graph network model tailored for predicting highway station traffic flow. To accurately capture the dynamic impact of upstream toll stations on the target station’s flow, we devise an influence probability matrix. This matrix, in conjunction with the covariance matrix across toll stations, updated graph structure data, and integrated external weather conditions, allows the attention mechanism to assign varied combination weights to the target toll station from temporal, spatial, and external standpoints, thereby augmenting prediction accuracy. We undertook a case study utilizing traffic flow data from the Chengdu-Chengyu station on the Sichuan Highway to gauge the efficacy of our proposed model. The experimental outcomes indicate that our model surpasses other baseline models in performance metrics. This study provides valuable insights for highway management and control, as well as for reducing traffic congestion. Furthermore, this research highlights the importance of using data-driven approaches to reduce carbon emissions associated with transportation, enhance resource allocation at toll plazas, and promote sustainable highway transportation systems. Full article

This study determined the feasibility of using zinc oxide nanoparticles of various origins as an active compound for biopolymer packaging films. The study focused on the effects of green synthesis using passion fruit or tomato extracts and commercial zinc oxide nanoparticles on the physicochemical properties of pectin films, including thickness, microstructure, water content, optical properties, water vapour permeability, water contact angle, sorption properties, and thermal stability. Zinc oxide nanoparticles resulted in lower lightness, higher absorbance, especially in the UV light range, and increased transparency, from 1.55 to 2.18 a.u./mm. Films containing zinc oxide nanoparticles showed reduced water vapour adsorption but increased water vapour permeability, from 6.35 to 12.07 × 10⁻¹⁰ g/m·s·Pa. The initial water contact angles were in a similar range, from 57.3° to 59.2°, but a decrease in contact angle values was observed over 60 s. All films containing nanoparticles exhibited better thermal stability, particularly during the third stage of degradation above 200 °C. Developed composite active films, prepared from apple pectin and zinc oxide nanoparticles of different origins, showed their potential for practical use as UV-VIS light barrier packaging films or protective coatings for food applications. Full article

The escalating concerns about global warming and energy shortages have presented an urgent need for efficient and environmentally sustainable hydrogen production methods. This work presents an efficient Ni₃S₂/ZnIn₂S₄ (ZIS) composite photocatalyst synthesized via a hydrothermal process, demonstrating enhanced performance for hydrogen evolution and benzyl alcohol oxidation under visible-light irradiation. Specifically, the optimized 3.2% Ni₃S₂/ZIS composite achieves hydrogen and benzaldehyde production rates of 4.342 mmol g^–1 h^–1 and 4.213 mmol g^–1 h^–1, respectively, 1.79 and 1.76 times greater than those of pristine ZIS. The system exhibits excellent selectivity, producing benzaldehyde as the sole by-product, and maintains stability over multiple reaction cycles. Mechanistic studies reveal that Ni₃S₂ facilitates charge separation and accelerates reaction dynamics by providing conductive channels and enhancing catalytic activity at the ZIS interface. These findings highlight the potential of Ni₃S₂/ZIS composites as cost-effective, scalable, and noble-metal-free photocatalysts for hydrogen production and green chemical synthesis, offering a promising pathway toward energy sustainability. Full article

Organic phase change materials (OPCMs) offer high energy density for thermal storage but suffer from crystallization kinetics dependent on ambient temperature, leading to uncontrolled heat release and limited storage lifetime. Although doping OPCMs with azobenzene (Azo) derivatives enables optically controlled energy storage and release, existing systems require UV irradiation for E-to-Z isomerization. This UV dependency seriously hinders their development in practical solar applications. Herein, we develop a visible-light-responsive Azo@OPCM composite by doping tetra-ortho-fluorinated azobenzene into eicosane. Systematic characterization of composites with different dopant ratios via UV–visible spectroscopy and differential scanning calorimetry reveals that green-light irradiation drives E-to-Z isomerization, achieving 97–99% Z-isomer conversion. This photoisomerization could introduce supercooling through photo-responsive energy barriers generated by Z-isomer, allowing thermal energy storage at lower temperatures. Subsequent blue-light irradiation triggers Z-to-E reversion to eliminate supercooling and enable optically controlled heat release. Additionally, by regulating the molar ratios of dopant, the optimized composites achieved 280.76 J/g energy density at 20% molar doping ratio, which surpassed that of pure eicosane and the reported Azo-based photothermal energy storage system. This work establishes a complete visible-light-controlled energy harvesting–storage–release cycle with significant potential for near-room-temperature solar thermal storage applications. Full article

Rapid urban growth leads to an extension of artificial surfaces and inefficient energy management, an increase in urban heat islands, and local climate change. This has increased the need for green infrastructure and urban trees are playing an important role. It is important to ensure that tree groups can withstand climate warming and disturbances. This study investigated the physiological parameters of Tilia tomentosa ‘Seleste’ trees situated in a medium-sized Hungarian city, examining their relationship with microclimatic differences observed on opposing sides of a street. Instruments placed on 10 trees recorded air temperature and humidity, revealing a significant difference in total insolation, which resulted in higher maximum daily temperatures on the sunny side. These microclimatic variations were found to significantly affect physiological attributes, particularly pigment content. Trees on the sunny side exhibited a higher relative water content and a higher ratio of chlorophyll a/b, indicative of light acclimatisation. Trees on the sunny side exhibited a higher relative water content and a higher ratio of chlorophyll a/b, indicating an acclimatisation to light. Furthermore, a positive correlation was observed between pigment content, total insolation, and growing degree days. The findings demonstrate how fine-scale microclimate differences influence tree physiology, providing crucial physiological indicators that inform the capacity of urban trees to provide vital ecosystem services, such as local climate regulation. This emphasises the importance of climate-conscious urban planning, as even small-scale climate change can have a broader impact. Full article

The wide application of light emitting diodes (LEDs) in lighting systems has necessitated the inclusion of spectral tunability by using multi-color LED chips. Since the lighting requirement depends on the specific application, it is very important to have flexibility in terms of the driving conditions. While many applications use single or rather white color, some recent applications require multi-spectral lighting systems especially for agricultural or human-medical treatment applications. These systems are underexplored and pose specific challenges. In this paper, a mixture of red, green, blue, white (RGB-W) LED chips was used to develop a compact light engine specifically for agricultural applications. A computational study was performed to understand the optical distribution. Later, attention was turned into development of prototype light engines followed by experimental validation for both the thermal and optical characteristics. Each LED string was driven separately at different current levels enabling an option for obtaining an infinite number of colors for numerous applications. Each LED string on the developed light engine was driven at 300 mA, 500 mA, 700 mA, and 900 mA current levels, and the optical and thermal parameters were recorded simultaneously. A set of computational models and an experimental study were performed to understand the optical and thermal characteristics simultaneously. Full article