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41 pages, 9972 KB  
Article
Statistically Derived Marginal Contribution Thresholds and Key Drivers of Sustainable Agricultural Development in Yunnan, China, Under Multidimensional Constraints
by Zhenli Wang and Longfei Ren
Sustainability 2026, 18(13), 6807; https://doi.org/10.3390/su18136807 (registering DOI) - 4 Jul 2026
Abstract
Sustainable agricultural development requires regional agricultural systems to balance output growth, resource efficiency, ecological protection, and long-term resilience. In mountainous and ecologically sensitive regions, identifying the development constraints and statistically derived marginal contribution thresholds of agriculture is essential for promoting green transformation and [...] Read more.
Sustainable agricultural development requires regional agricultural systems to balance output growth, resource efficiency, ecological protection, and long-term resilience. In mountainous and ecologically sensitive regions, identifying the development constraints and statistically derived marginal contribution thresholds of agriculture is essential for promoting green transformation and sustainable land use. Taking Yunnan Province, China, as a representative plateau mountainous agricultural region, this study uses provincial annual data from 1990 to 2023 to quantitatively identify the key drivers and threshold characteristics of agricultural development under multidimensional constraints. A multidimensional indicator system was constructed covering fiscal and investment support, agricultural production inputs, rural infrastructure, and labor and population conditions. Ridge regression was employed to address multicollinearity among explanatory variables, Bootstrap approximate inference was used to improve the robustness of coefficient estimation, and the SHAP interpretation framework was introduced to rank key driving factors and identify marginal contribution thresholds. By integrating ridge regression, Bootstrap approximate inference, SHAP-based contribution ranking, and threshold identification, the proposed framework advances prior agricultural sustainability studies by linking coefficient-based factor analysis with interpretable marginal contribution thresholds under conditions of high multicollinearity and multidimensional resource constraints. The results show that agricultural development in Yunnan is characterized by multidimensional resource and infrastructure constraints. Rural electricity consumption, total reservoir storage capacity, fixed asset investment in agriculture, forestry, animal husbandry and fisheries, local public fiscal budget expenditure, and agricultural population generally act as positive supporting factors. Rural electricity consumption is the most stable and core driver across the aggregate and three sectoral models. In contrast, pesticide and fertilizer inputs show significant negative associations in most models, suggesting that future agricultural development in Yunnan is unlikely to be sustainably supported by continued expansion of high-intensity chemical inputs. Sectoral heterogeneity is also evident: agriculture and animal husbandry are more dependent on energy, water resources, and mechanization, whereas forestry shows a more distinct operational structure. The SHAP dependence analysis identifies several statistically derived marginal contribution thresholds, including rural electricity consumption of approximately 6.055 billion kWh, total reservoir storage capacity of approximately 10.395 billion m3, total agricultural machinery power of approximately 19.8324 million kW, pesticide use of approximately 37,500 tons, and fertilizer application of approximately 1.5238 million tons. These values should be interpreted as empirical transition points in the modeled marginal contributions rather than definitive biophysical ecological limits. They indicate that the sustainability-related constraint structure of agricultural development in Yunnan is not a single output ceiling but a composite interval shaped by infrastructure support capacity, factor allocation conditions, and the declining marginal contribution of high-intensity chemical inputs. The findings provide directional quantitative evidence for sustainable agricultural governance, agricultural green transformation, and differentiated policy discussion in mountainous agricultural regions and offer reference implications for advancing SDG 2 and SDG 15 through the coordination of food-related production, resource use efficiency, and ecosystem conservation. The identified thresholds should be interpreted as model-derived marginal contribution transition points rather than operational policy cutoffs or directly enforceable ecological standards. Full article
(This article belongs to the Section Economic and Business Aspects of Sustainability)
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17 pages, 1479 KB  
Article
Counter-Current Chromatography Enables Use of Green Solvents for Productive Peptide Purification Processes
by Rosella Prestia, Damian Hauri, Mattia Sponchioni, Sebastian Vogg and Thomas Müller-Späth
Separations 2026, 13(7), 195; https://doi.org/10.3390/separations13070195 (registering DOI) - 4 Jul 2026
Abstract
Peptide purification by preparative reversed-phase liquid chromatography remains one of the most resource-intensive stages in synthetic peptide manufacturing. Production processes commonly rely on acetonitrile/trifluoroacetic acid (ACN/TFA) mobile phases mainly because of their high chromatographic resolution. However, both components raise significant environmental and safety [...] Read more.
Peptide purification by preparative reversed-phase liquid chromatography remains one of the most resource-intensive stages in synthetic peptide manufacturing. Production processes commonly rely on acetonitrile/trifluoroacetic acid (ACN/TFA) mobile phases mainly because of their high chromatographic resolution. However, both components raise significant environmental and safety concerns related to toxicity, flammability, waste generation, and, in the case of TFA, environmental persistence as a per- and polyfluoroalkyl substance (PFAS, known as a “forever chemical”). Green alternatives based on ethanol, dimethyl carbonate, and sustainable acidic additives such as acetic acid have been proposed, but their industrial adoption remains limited due to reduced chromatographic performance, often resulting in lower yield and productivity under conventional batch operation. In this work, multi-column counter-current solvent gradient purification (MCSGP) was investigated as a strategy to integrate the use of green eluent systems without compromising process performance. Two therapeutic peptides, Tirzepatide and Tetracosactide, were selected as representative case studies with different structural complexity. Using ethanol/acetic acid for Tirzepatide and dimethyl carbonate/acetic acid for Tetracosactide, the MCSGP process achieved purity levels equivalent to those obtained with conventional ACN/TFA batch chromatography, with 88.1% yield at 89.0% purity for Tirzepatide and 93.8% yield at 94.0% purity for Tetracosactide. Productivity for Tirzepatide was improved, reaching 6.3 g/Lresin/h. These results demonstrate that MCSGP can compensate for the reduced separation efficiency typically associated with green eluent systems, enabling sustainable peptide purification without compromising process performance. By combining green solvents with the MCSGP process, this work paves the way for more sustainable peptide purification processes while maintaining high yield and productivity. Full article
(This article belongs to the Special Issue Advanced Separation Media and Technologies for Biomolecules)
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17 pages, 13875 KB  
Review
Global Development Trends of Biomass-Derived Nanocellulose Based on Bibliometric and Patentometric Analysis
by Qimei Chen, Pengbo Liu, Haoze Li, Tangrong Wang, Bing Xiao, Chang Yao and Jianguo Zhu
Energies 2026, 19(13), 3181; https://doi.org/10.3390/en19133181 (registering DOI) - 4 Jul 2026
Abstract
Against the background of carbon neutrality and the global energy transition, biomass-derived nanocellulose has attracted increasing attention because of its renewability, biodegradability, low density, high mechanical strength, and tunable surface chemistry. This study reviews the global development of biomass-derived nanocellulose from the perspectives [...] Read more.
Against the background of carbon neutrality and the global energy transition, biomass-derived nanocellulose has attracted increasing attention because of its renewability, biodegradability, low density, high mechanical strength, and tunable surface chemistry. This study reviews the global development of biomass-derived nanocellulose from the perspectives of research trends, hotspot themes, technological frontiers, patent deployment, and industrial applications. The results show that research output has grown rapidly in recent years, with China leading in publication volume, while the United States and several European countries perform more strongly in highly cited studies and international collaboration. Current research focuses mainly on green preparation technologies, chemical functionalization, multifunctional composites, adsorption and environmental remediation, and energy-related applications. Patent analysis reveals clear international differentiation: China leads in patent quantity and large-scale production technologies, whereas the United States and Japan show stronger advantages in patent quality, overseas patent layout, and high-end applications. Overall, biomass-derived nanocellulose is accelerating from laboratory research to industrial application, but further progress still depends on achieving breakthroughs in cost reduction, continuous manufacturing, functional modification, and standardization. Full article
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21 pages, 16920 KB  
Article
Acid-Based Deep Eutectic Solvents for Structural Modification of Sulphite Pulp Cellulose: A Potential Route Toward Advanced Materials
by María Guadalupe Morán-Aguilar, Iván Costa-Trigo, José Manuel Domínguez and Fabiola Vilaseca
Polymers 2026, 18(13), 1659; https://doi.org/10.3390/polym18131659 - 3 Jul 2026
Abstract
The transition toward renewable and environmentally responsible materials has intensified interest in cellulose-based systems for use in sustainable packaging applications. Although cellulose offers biocompatibility, structural versatility, and tuneable physicochemical properties, conventional modification routes rely on harsh chemicals and generate environmentally burdensome effluents. In [...] Read more.
The transition toward renewable and environmentally responsible materials has intensified interest in cellulose-based systems for use in sustainable packaging applications. Although cellulose offers biocompatibility, structural versatility, and tuneable physicochemical properties, conventional modification routes rely on harsh chemicals and generate environmentally burdensome effluents. In this study, an efficient and a potentially green strategy for cellulose modification was developed using acid-based deep eutectic solvents (DES) composed of choline chloride and lactic, acetic, or citric acid at different molar ratios. Under mild conditions (110 °C, 4 h), DES pretreatment reduced glucan content in sulphite pulp from 99% to 79–93%, depending on the hydrogen bond donor (HBD), while suggesting an apparent increase in relative crystallinity, from approximately 82% to 90%, as estimated by the Segal method. FTIR, XRD, and morphological analyses revealed the disruption of the hydrogen bonding network, enhanced fibrillation, and residual DES-derived functional groups detectable by FTIR. Although DES pretreatment increased structural order, it also reduced enzymatic digestibility due to the higher proportion of crystalline domains. Overall, the results demonstrate that acidic DES constitutes a sustainable and recyclable medium capable of modulating cellulose structure and generating materials with enhanced physicochemical properties. These findings suggest that DES-modified cellulose could serve as a potential reinforcement platform for future biodegradable packaging and bioplastic formulations, enabling the development of high-performance, renewable, and environmentally compliant packaging materials. Full article
(This article belongs to the Special Issue Green Innovation in the Processing of Cellulose Derived Polymers)
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22 pages, 20190 KB  
Article
Construction of PEGMC Copolymerized Modified Hydrogel and Its Mechanism for Salt Retardation and Nutrient Immobilization in Dryland Soil
by Jianwei Cheng, Rui Xiang, Jingcai Liu, Baocun Yang and Xiaobing Ma
Gels 2026, 12(7), 595; https://doi.org/10.3390/gels12070595 - 3 Jul 2026
Abstract
Aiming at severe soil secondary salinization, poor water retention and insufficient salt tolerance of conventional acrylic-based modifiers in arid and semi-arid regions of China, a poly(ethylene glycol) maleate citrate (PEGMC) crosslinking monomer was synthesized through esterification, and a dual covalent–hydrogen crosslinked P(PEGMC/AA) hydrogel [...] Read more.
Aiming at severe soil secondary salinization, poor water retention and insufficient salt tolerance of conventional acrylic-based modifiers in arid and semi-arid regions of China, a poly(ethylene glycol) maleate citrate (PEGMC) crosslinking monomer was synthesized through esterification, and a dual covalent–hydrogen crosslinked P(PEGMC/AA) hydrogel was fabricated via free radical copolymerization with acrylic acid (AA). The hydrogel was characterized by NMR, FTIR, SEM, TGA and elemental mapping, while its binding mechanism with saline–alkali ions was elucidated through DFT calculations and molecular dynamics simulations. Its amelioration performance was evaluated through swelling, soil water retention, desalination and pot germination experiments. The hydrogel exhibited outstanding water absorbency, salt resistance and dry–wet cycling stability, with swelling ratios of 712 g/g in deionized water and 285 g/g in 0.9% NaCl solution, and remained 200 g/g after four dry–wet cycles. It enhanced soil water retention remarkably (over 93% after 72 h). At 0.30% dosage, soil salt content declined from 7.1 g/kg to 1.3 g/kg with desalination efficiency exceeding 80%, owing to porous physical adsorption and chemical chelation toward Na+, Ca2+ and Mg2+, with a binding energy of −136.936 kJ/mol. Pot tests revealed that crop germination rate rose from 19% (blank) to 75% under severe saline–alkali stress. Meanwhile, the hydrogel inhibited nutrient leaching and favored soil-water conservation. This work first incorporated PEGMC monomer into agricultural hydrogels to construct a stable dual crosslinked network, clarifying its synergistic mechanisms for salt fixation and water retention macroscopically and microscopically. It provides a promising functional material and theoretical basis for green, efficient in situ amelioration of dryland saline–alkali soil. Full article
(This article belongs to the Section Gel Analysis and Characterization)
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22 pages, 452 KB  
Review
Camellia-Derived Bioactive Compounds: Research Advances and Application Prospects in Dermatology
by Lianxin Zhang, Baoyan Dai, Hong Shen, Siyu Chen and Wenxiang Zhang
Int. J. Mol. Sci. 2026, 27(13), 5963; https://doi.org/10.3390/ijms27135963 - 2 Jul 2026
Viewed by 102
Abstract
Camellia japonica L., an East Asian species with extensive ethnobotanical use, is a rich source of bioactive metabolites including polyphenols, saponins, terpenoids, sterols, and fatty acids. These compounds have attracted significant attention in cosmetic research due to increasing demand for natural, multifunctional ingredients [...] Read more.
Camellia japonica L., an East Asian species with extensive ethnobotanical use, is a rich source of bioactive metabolites including polyphenols, saponins, terpenoids, sterols, and fatty acids. These compounds have attracted significant attention in cosmetic research due to increasing demand for natural, multifunctional ingredients with antioxidant, anti-inflammatory, antimicrobial, moisturizing, and skin-brightening properties. This review summarizes the major classes of Camellia metabolites, their chemical characteristics, and mechanisms of action. Terpenoids and polyphenols, including phenolic acids, flavonoids, and tannins, exhibit potent antioxidant and anti-aging properties. Camellia saponins serve as mild natural surfactants for gentle skin cleansing, while phytosterols, amino acids, proteins, and seed fatty acids synergistically reconstruct the epidermal barrier and maintain cutaneous hydration. This review further addresses the current applications of these Camellia-derived bioactives in ameliorating photo-aging, hyperpigmentation, skin inflammation, and barrier dysfunction. Despite significant progress, key challenges persist, including incomplete understanding of biosynthetic regulation, suboptimal extraction methods, limited study of synergistic effects, and insufficient human safety data. Future studies should employ omics technologies and green extraction approaches to elucidate biosynthetic pathways, validate efficacy, and promote sustainable utilization of Camellia resources in cosmetics, pharmaceuticals, and related industries. Full article
(This article belongs to the Special Issue Advances in Bioactivity and Molecular Mechanisms of Natural Products)
19 pages, 1400 KB  
Review
Steam Explosion Processing of Bast Fibers: Effects on Fiber Structure and Performance in Textile and Composites Applications
by Peter El Hage, Roland El Hage, César Segovia, Jingjing Liao, Didilia Ileana Mendoza-Castillo, Nicolas Brosse and Henri Vahabi
Fibers 2026, 14(7), 79; https://doi.org/10.3390/fib14070079 - 2 Jul 2026
Viewed by 179
Abstract
In response to the increasing needs for environmentally friendly products, lignocellulosic natural fibers have been of interest as potential replacements for synthetic reinforcement materials in textiles, composites, and related applications. Among these resources, bast fibers derived from plant stems (flax, hemp, nettle, jute, [...] Read more.
In response to the increasing needs for environmentally friendly products, lignocellulosic natural fibers have been of interest as potential replacements for synthetic reinforcement materials in textiles, composites, and related applications. Among these resources, bast fibers derived from plant stems (flax, hemp, nettle, jute, hop), which contain a high cellulose content, have good mechanical properties, low density, and are renewable, are highly promising. Steam explosion has emerged as a green fiber extraction, defibrillation, and surface modification pretreatment technology. Despite the growing number of studies on steam-exploded natural fibers, a comprehensive understanding of the relationships between processing conditions, fiber modifications, mechanisms, and end-use performance remains limited. This review investigates the structural, chemical, and morphological influences of steam explosion on bast fibers. Specifically, it focuses on the mechanism of steam explosion including the solubilization of hemicellulose, partial lignin redistribution or removal, fiber individualization, and cellulose enrichment. The literature indicates that steam explosion can improve fiber separation, fineness, surface morphology, and interfacial adhesion of the composite materials and reduce the use of hazardous chemicals compared with conventional extraction methods. Nonetheless, conflicting results have also been documented, where the same steam explosion conditions can yield distinct fiber characteristics according to biomass type, composition of biomass, moisture concentration, and the amount of processing involved. Excessive treatment severity may lead to fiber shortening, cellulose degradation, and deterioration of fiber quality, particularly for textile applications requiring long fibers. This review highlights current knowledge gaps regarding the optimization of processing conditions, the understanding of steam explosion mechanisms, and the scale-up of the technology for industrial applications. Full article
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18 pages, 405 KB  
Review
A Comprehensive Review of Liquid Organic Hydrogen Carriers: Typology, Energy Efficiency, Life Cycle Assessment, and Techno-Economic Analyses
by Jacqueline Garrido, Gasim Ibrahim, Nicolas Schröder, Neha Shakelly and Guiyan Zang
Energies 2026, 19(13), 3134; https://doi.org/10.3390/en19133134 (registering DOI) - 2 Jul 2026
Viewed by 230
Abstract
This paper presents a holistic review of Liquid Organic Hydrogen Carriers (LOHCs), focusing on typology, energy efficiency, techno-economic analyses (TEAs), and life cycle assessments (LCAs). Initially, the study categorizes various LOHC systems documented in existing literature, outlining their chemical structures, catalysts, properties, and [...] Read more.
This paper presents a holistic review of Liquid Organic Hydrogen Carriers (LOHCs), focusing on typology, energy efficiency, techno-economic analyses (TEAs), and life cycle assessments (LCAs). Initially, the study categorizes various LOHC systems documented in existing literature, outlining their chemical structures, catalysts, properties, and main applications. This survey aims to provide a comprehensive understanding of LOHC varieties, making it easier to compare across different types. Next, we explore the efficiency of LOHC systems by reviewing hydrogenation and dehydrogenation energy requirements, catalyst behavior, heat-management constraints, product-separation needs, and net energy storage capabilities. This review also includes reaction stoichiometries, recent catalyst and reactor developments, catalyst-deactivation mechanisms, and heat-integration options for high-temperature dehydrogenation. Finally, our investigation offers a detailed evaluation of TEA and LCA for LOHC systems found in the literature. By exploring economic feasibility and environmental impact, this study presents a complete picture of the sustainability of LOHC deployment. It includes assessments of life-cycle carbon emissions, levelized cost, supply-chain configuration, carrier recyclability, infrastructure compatibility, renewable-electricity capacity factors, and heat-recovery assumptions. Our findings aim to contribute to hydrogen storage and transport research by identifying the most important technical, economic, and environmental trade-offs for LOHC systems. By addressing gaps in recent literature, TEA comparability, and LCA coverage, this paper seeks to advance the development of LOHC technologies and support their broader adoption in a green and sustainable energy landscape. Full article
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40 pages, 19956 KB  
Review
Thermophysical Consolidation and Dimensional Fidelity in Precious Metal Additive Manufacturing: A Review for the Jewelry Sector
by Niloofar Naeimabadi, Luca Cattani, Marco Bernagozzi and Fabio Bozzoli
Thermo 2026, 6(3), 53; https://doi.org/10.3390/thermo6030053 - 1 Jul 2026
Viewed by 218
Abstract
Additive Manufacturing (AM) for jewelry applications is increasingly adopting Binder Jetting (BJ) to overcome the fusion-related limitations associated with precious metals, including unstable melt pools, excessive reflectivity, and high thermal conductivity. In this context, the present review establishes a thermophysical and manufacturability-oriented framework [...] Read more.
Additive Manufacturing (AM) for jewelry applications is increasingly adopting Binder Jetting (BJ) to overcome the fusion-related limitations associated with precious metals, including unstable melt pools, excessive reflectivity, and high thermal conductivity. In this context, the present review establishes a thermophysical and manufacturability-oriented framework that redefines thermal management beyond localized melt-pool stabilization toward the furnace-scale control of densification kinetics, shrinkage evolution, atmosphere-assisted sintering, and viscoplastic deformation. Particular emphasis is placed on gold-, silver-, and platinum-based jewelry alloys, with a specific focus on the thermal, mechanical, and chemical phenomena governing Binder Jetting sintering. During consolidation, low-density green bodies (~40–65% relative density) must transform into highly dense components through extensive volumetric shrinkage and gravity-driven deformation, creating major challenges in dimensional fidelity and surface quality. The review further examines predictive viscoplastic constitutive models (SOVS/ROH), reversed-deformation compensation strategies, and atmosphere-engineering approaches for oxide reduction, pore-pressure regulation, and residual-porosity control. By linking thermophysical consolidation, dimensional fidelity, polishability, and jewelry-grade manufacturability within a hierarchical framework, this review provides a structured basis for the development of high-precision and low-waste precious-metal additive manufacturing. Full article
(This article belongs to the Special Issue Thermal Science and Metallurgy)
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25 pages, 4614 KB  
Article
Study on Material Properties of Iron Tailings Sand Concrete and Its Application in Reinforced Concrete Short Columns
by Jiuyang Li, Songzhe Zhang, Yuepeng Zhu, Chenkai Zhou, Chongsheng Luo, Bingxin Wang and Liqiang Jiang
Buildings 2026, 16(13), 2630; https://doi.org/10.3390/buildings16132630 - 1 Jul 2026
Viewed by 100
Abstract
The huge demand for natural sand in the global construction industry has caused resource shortages and severe environmental issues. Meanwhile, China produces massive annual iron tailings, and their stockpiling poses prominent potential safety hazards. At present, numerous investigations have been carried out on [...] Read more.
The huge demand for natural sand in the global construction industry has caused resource shortages and severe environmental issues. Meanwhile, China produces massive annual iron tailings, and their stockpiling poses prominent potential safety hazards. At present, numerous investigations have been carried out on the fundamental properties of concrete prepared by replacing natural sand with iron tailings sand (ITS). However, most studies are limited to single replacement ratios and conventional strength mix proportions. Systematic research focusing on high-replacement-ratio systems, long-term durability performance, and supporting practical construction technologies for engineering applications remains insufficient. Obvious gaps still exist regarding the key mechanisms and practical operation standards for high-value and large-scale utilization. Against this background, this paper prepares concrete with three strength grades (C30, C40, C50) and six ITS replacement ratios (0%, 20%, 40%, 60%, 80%, 100%). Cube compressive tests and prism axial compressive tests are conducted, combined with SEM microscopic microstructure analysis. Axial compression tests and bearing capacity research are further carried out on reinforced concrete short columns (RCSC) with the optimal replacement ratio. The results show that concrete compressive strength increases first and then decreases with the rise in iron tailings sand concrete (ITSC), with 60% identified as the optimal replacement ratio. At this ratio, the compressive strength of C30, C40 and C50 concrete increases by 24.3%, 11.5% and 12.9%, respectively, while the bearing capacity of short columns rises correspondingly by 18%, 14.1% and 8.1%. Microscopic test results reveal that ITS exerts both physical filling and chemical active effects. Its fine particles fill internal pores inside the matrix and refine the pore structure. Meanwhile, the reactive mineral components contained in ITS can participate in the hydration reaction of the cementitious system, accelerate the hydration rate and generate more dense hydration products. Therefore, ITS facilitates the hydration process and improves the mechanical properties of concrete. A calculation method for the axial bearing capacity of RCSC incorporating ITS is proposed via theoretical analysis. This study provides a theoretical basis for preparing concrete by replacing natural sand with ITS. Using ITS as aggregate is expected to alleviate tailings stockpiling risks, reduce natural sand consumption, and realize solid waste resource recycling. It also offers valuable references for the green development of the construction industry and safety protection in mining areas. Full article
(This article belongs to the Section Building Materials, and Repair & Renovation)
18 pages, 2012 KB  
Article
Saponin-Enriched Fraction of Sarcomphalus joazeiro: Chemical Characterization, Silver Nanoparticle Synthesis, and Their Mutual Antibiotic-Modifying Potential
by Natália Kelly Gomes de Carvalho, Mariana Pereira da Silva, Débora Odília Duarte Leite, Fazia Fernandes Galvão Rodrigues, Joice Barbosa do Nascimento, Milena Lima Guimarães, Helinando Pequeno de Oliveira, Lucicléia Barros de Vasconcelos, Maryana Melo Frota, Josean Fechine Tavares, Thiago Araújo de Medeiros Brito, Fabiola Fernandes Galvão Rodrigues and José Galberto Martins da Costa
Chemistry 2026, 8(7), 92; https://doi.org/10.3390/chemistry8070092 - 1 Jul 2026
Viewed by 162
Abstract
Antibiotic resistance has emerged as a major global health challenge, underscoring the urgent need for alternative therapeutic strategies capable of enhancing the efficacy of existing antibiotics. In this context, saponin-based nanomaterials have attracted considerable attention due to their potential as antibiotic-modulating systems. This [...] Read more.
Antibiotic resistance has emerged as a major global health challenge, underscoring the urgent need for alternative therapeutic strategies capable of enhancing the efficacy of existing antibiotics. In this context, saponin-based nanomaterials have attracted considerable attention due to their potential as antibiotic-modulating systems. This study investigated a saponin-enriched fraction obtained from the bark of Sarcomphalus joazeiro Mart. (SEF-4), its application in the green synthesis of silver nanoparticles, and the antibiotic-modulating potential of the resulting nanoformulation. SEF-4 was obtained from the ethanolic bark extract through liquid–liquid partitioning (52% yield), followed by column chromatographic purification and chemical characterization using LC-ESI-QTOF-MS. The purified fraction was subsequently employed as both a reducing and stabilizing agent for the synthesis of silver nanoparticles (putative AgNP-SEF-4), which were physicochemically characterized. Antibacterial activity and antibiotic-modulating effects were evaluated using the broth microdilution method against standard and multidrug-resistant bacterial strains. LC-ESI-QTOF-MS analysis enabled the putative identification of five jujubogenin-type triterpenoid saponins bearing tetra-, penta-, and hexasaccharide moieties with distinct glycosylation profiles; however, the precise sugar sequence, monosaccharide composition, and glycosidic linkage positions remain to be confirmed through complementary NMR and hydrolysis studies. Although neither SEF-4 nor putative AgNP-SEF-4 displayed clinically relevant intrinsic antibacterial activity, the nanoformulation significantly enhanced the activity of aminoglycoside antibiotics. The most pronounced modulatory effects were observed against Klebsiella pneumoniae ATCC 1705 in combination with amikacin and against both standard and multidrug-resistant Escherichia coli strains when combined with gentamicin or amikacin. These findings highlight the potential of putative AgNP-SEF-4 as an antibiotic adjuvant capable of potentiating aminoglycoside efficacy and increasing bacterial susceptibility, including in multidrug-resistant strains. Full article
(This article belongs to the Section Chemistry of Natural Products and Biomolecules)
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19 pages, 1290 KB  
Article
Research on Environmentally Friendly Drilling Fluid System and Exploration of Waste Utilization in Desert Saline–Alkali Lands
by Ming Tian, Xiaoming Su, Ruixue Wang, Siying Xu, Shaojun Zhang, Fuyuan Deng, Siyu Wu and Peng Xu
Processes 2026, 14(13), 2141; https://doi.org/10.3390/pr14132141 - 1 Jul 2026
Viewed by 149
Abstract
The Tarim Basin, as the core strategic replacement area for oil and gas resources in western China, holds immense deep oil and gas development potential. However, this region features extensive deserts, fragile saline–alkali ecosystems, and extreme geological conditions—160°C high temperatures, high-salt/high-alkali formation fluids, [...] Read more.
The Tarim Basin, as the core strategic replacement area for oil and gas resources in western China, holds immense deep oil and gas development potential. However, this region features extensive deserts, fragile saline–alkali ecosystems, and extreme geological conditions—160°C high temperatures, high-salt/high-alkali formation fluids, and well-developed microfractures—that impose stringent dual requirements on drilling fluids for both engineering performance and environmental compatibility. Traditional drilling fluids suffer severe performance deterioration under high-temperature/high-salt coupling, and their poorly biodegradable, toxic additives exacerbate ecological pollution upon disposal, failing to meet green development demands. To address these issues, this study prepared four eco-friendly, temperature- and salt-resistant drilling fluid additives via chemical modification of natural degradable materials, and constructed a 160°C-resistant eco-friendly water-based drilling fluid system using orthogonal experiments. Furthermore, an innovative “waste-to-resource” strategy was proposed to repurpose spent drilling fluid for saline–alkali land restoration, investigating its improvement effects and environmental safety. The results show that the system withstands 160 °C and 15% NaCl, with excellent engineering performance (HTHP filtration loss ≤ 9.0 mL at 160 °C, friction coefficient ≤ 0.18) and compliance with national environmental standards (EC50 = 36,000 mg/L, BOD5/COD = 6.8%). Applied at an optimal 10–15% dosage, the spent fluid significantly improves saline–alkali soil properties, promotes Haloxylon ammodendron growth, and achieves >90% pollutant degradation within 3 months without secondary pollution. This integrated technology synergizes drilling engineering and ecological protection, providing technical support for green oil and gas development and saline–alkali land restoration in the Tarim Basin. Full article
(This article belongs to the Section Petroleum and Low-Carbon Energy Process Engineering)
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32 pages, 4683 KB  
Review
Microalgae-Mediated Nanotechnology for Sustainable Agriculture: Applications, Advances, and Future Prospects
by Yu Xie, Zirui Yang, Shoukai Guo, Liqin Sun, Hongli Cui and Zhongliang Sun
Int. J. Mol. Sci. 2026, 27(13), 5875; https://doi.org/10.3390/ijms27135875 - 30 Jun 2026
Viewed by 262
Abstract
The overreliance on chemical pesticides has caused severe environmental contamination, health risks, and increasing pest and pathogen resistance, creating an urgent need for greener and more efficient alternatives in sustainable agriculture. Microalgae-mediated green nano-synthesis has emerged as a promising strategy because of its [...] Read more.
The overreliance on chemical pesticides has caused severe environmental contamination, health risks, and increasing pest and pathogen resistance, creating an urgent need for greener and more efficient alternatives in sustainable agriculture. Microalgae-mediated green nano-synthesis has emerged as a promising strategy because of its environmental compatibility, cost-effectiveness, and multifunctional potential. This review critically summarizes recent advances in microalgae-derived nanomaterials for agricultural applications. First, we discuss the biochemical basis of nanoparticle biosynthesis, highlighting the roles of microalgal polysaccharides, proteins, photosynthetic pigments, extracellular polymeric substances, and secondary metabolites as reducing, capping, and stabilizing agents. We then summarize intracellular and extracellular synthesis pathways, advanced synthesis strategies, and key reaction parameters, including temperature, pH, and metal precursor concentration, which regulate nanoparticle size, morphology, stability, and yield. Subsequently, major microalgae-derived nanomaterials, including gold, silver, selenium, zinc oxide, bimetallic, and other functional nanoparticles, are discussed in relation to their agricultural applications. These nanomaterials show potential in bacterial, fungal, and viral disease control, biofilm disruption, plant growth promotion, yield enhancement, and abiotic stress mitigation. Their agronomic effects are associated with multiple mechanisms, including reactive oxygen species generation, pathogen membrane disruption, inhibition of biofilm formation, enhanced nutrient bioavailability, antioxidant regulation, and activation of plant systemic resistance. In addition, this review evaluates the phytotoxicity, biocompatibility, soil microbial impacts, and environmental safety of microalgae-derived nanomaterials, emphasizing that green synthesis does not automatically guarantee biosafety. Finally, we discuss their integration into circular agriculture through CO2 capture and wastewater-derived metal recovery, while highlighting remaining challenges in scale-up, quality control, economic feasibility, regulatory classification, and public acceptance. Overall, microalgae-mediated nanotechnology offers a promising platform for developing safer, more efficient, and circular agricultural inputs. Full article
(This article belongs to the Section Molecular Nanoscience)
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20 pages, 7442 KB  
Article
Green-Engineered Clays Tightly Adsorb and Detoxify Environmentally Persistent Polychlorinated Biphenyls and Complex Mixtures
by Johnson O. Oladele, Xenophon Xenophontos, Phanourios Tamamis, Stephen Safe and Timothy D. Phillips
Toxics 2026, 14(7), 573; https://doi.org/10.3390/toxics14070573 - 29 Jun 2026
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Abstract
Commonly occurring polychlorinated biphenyls (PCBs) in the environment have been linked to a broad range of adverse toxicological effects in both animals and humans. In this study, in vitro, in silico, and in vivo models were used to investigate the surface [...] Read more.
Commonly occurring polychlorinated biphenyls (PCBs) in the environment have been linked to a broad range of adverse toxicological effects in both animals and humans. In this study, in vitro, in silico, and in vivo models were used to investigate the surface interactions of PCBs with green-engineered clays (GECs). Earlier studies showed that these GECs significantly reduced the toxicities of important planar aromatic chemicals such as benzene and aflatoxin B1 along with ochratoxin A, a chlorinated aromatic chemical. The overall objective for this study was to show that GECs could tightly adsorb PCBs, resulting in a decrease in toxicity of a commercial PCB mixture (Aroclor 1260). Gastrointestinal pH and temperature were simulated in vitro, and the clay surface binding interactions of six PCBs were characterized using isothermal analyses. Molecular dynamics (MD) simulations were employed to provide atomistic understanding into PCB congener interactions with parent and chlorophyll-amended clays. To confirm the ability of GECs to protect a living organism, Aroclor 1260 was investigated using a well-established hydra bioassay. According to simulations, coplanar PCBs had an increased probability of binding to parent clay compared to non-coplanar ones, in line with experiments, due to their ability to lay flat on the clay surface. Chlorophyll amendments enhanced binding of all PCBs according to both experiments and computations. Within the simulations, chlorophyll amendments facilitated both coplanar as well as non-coplanar PCBs to directly bind to the clay and additionally interact with chlorophyll amendments, as well as to bind to chlorophyll amendments without necessarily interacting with the clay. Aroclor 1260 caused irreversible damage to hydra. At 0.05% inclusion, parent clay offered limited protection (20%) while GECs offered 55% to 65% protection, showing the advantage of GECs over parent clays. The findings of this study indicate that edible GECs adsorb PCBs, with the highest sorption associated with the coplanar congeners. Further studies are warranted to determine the application of GECs as potential disaster-response supplements in the diet to reduce the bioavailability of PCBs from contaminated food and water, especially following floods and other emergencies. Full article
(This article belongs to the Section Toxicity Reduction and Environmental Remediation)
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Article
Optimization of Environmentally Friendly Flotation Reagents for Quartz–K-Feldspar Separation Using Response Surface Methodology
by Kalyani Mohanty, Josep Oliva, Pura Alfonso, Carlos Hoffmann Sampaio, Hernan Anticoi, Jordi Lladó and Amina Eljoudiani
Appl. Sci. 2026, 16(13), 6484; https://doi.org/10.3390/app16136484 - 29 Jun 2026
Viewed by 177
Abstract
Selective separation of quartz and feldspar is vital for high-purity silicate raw materials but is challenging due to similar surface chemistries. Conventional flotation typically requires high reagent dosages and hazardous chemicals, raising environmental and economic issues. This study proposes a sustainable flotation strategy [...] Read more.
Selective separation of quartz and feldspar is vital for high-purity silicate raw materials but is challenging due to similar surface chemistries. Conventional flotation typically requires high reagent dosages and hazardous chemicals, raising environmental and economic issues. This study proposes a sustainable flotation strategy using green, bio-derived reagents to improve quartz–feldspar separation by eco-friendly bio-derived reagents. Sodium oleate, a fatty acid collector, was used with low-toxicity modifiers to create synergistic systems. Flotation performance was tested by reagent dosage and pH, with mineral characteristics analyzed via X-ray Fluorescence (XRF) and Particle Size Distribution (PSD). Results showed that the investigated reagent systems improved the differential flotation response between quartz and K-feldspar. Under the optimized flotation conditions (pH 9.24), quartz recovery reached 84.01%, demonstrating that environmentally friendly reagent combinations can achieve favorable flotation performance while reducing chemical consumption. Response Surface Methodology (RSM) was used to optimize flotation variables like pH and reagent dosage, developing a model to predict conditions for favorable flotation response, enabling systematic process improvement. These findings highlight reagent-system optimization as an eco-friendly method for mineral beneficiation, aligning with green chemistry and sustainable practices. Full article
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