Search Results (406)

Rare earth elements (REEs) play an important role in emerging renewable energy technology, the production of advanced materials, energy conservation, and high-end manufacturing industries, making them an irreplaceable strategic resource. The diagnostic spectral absorption features of REEs in the visible and near-infrared spectrum can be effectively used for identifying the occurrences of REEs on the Earth’s surface. This study systematically compared three airborne hyperspectral sensors—HyMap, CASI-1500h, and AisaFENIX 1K—for detecting REEs in the Bayan Obo area of Inner Mongolia, China. The CASI-1500h imagery performed most effectively in identifying the locations of REEs among the three sensors evaluated here. Additionally, this study proposed a hyperspectral workflow for REE identification, which enabled the detection of REE-bearing minerals regardless of the host rock types—including carbonatites and associated dikes, fenite-syenites, and metamorphic feldspar-quartz sandstone. Laboratory-based spectroscopy and mineral chemistry analyses indicated that the absorption features of the REE-bearing mineral monazite within the 400–1000 nm range can be ascribed to Nd³⁺. This study demonstrates the potential of airborne hyperspectral technology for efficient and large-scale exploration of REE deposits. Full article

Hair follicles are highly specialized mini-organs within the skin that drive the production of wool and cashmere, traits of major biological and economic importance in sheep and goats. Despite their microscopic size, hair follicles exhibit extraordinary regulatory complexity, integrating genetic programs with seasonal, endocrine, environmental, and epigenetic cues. Although transcriptional networks and signaling pathways underlying follicle morphogenesis and cycling have been extensively investigated, the post-transcriptional mechanisms that fine-tune these processes remain insufficiently understood. MicroRNAs (miRNAs) have emerged as pivotal post-transcriptional regulators that coordinate cell fate determination, lineage commitment, and tissue homeostasis. Growing evidence indicates that miRNAs play essential roles in hair follicle stem cell maintenance, proliferation, differentiation, apoptosis, and organ-level development, functioning through interconnected regulatory networks rather than isolated linear pathways. By modulating the expression of key follicle-determining genes and signaling components, miRNA-mediated regulation shapes follicle formation, cyclic regeneration, and fiber traits. In this review, we synthesize recent advances in miRNA research related to hair follicle biology, with a particular focus on wool- and cashmere-bearing mammals. We integrate findings across species to propose a systems-level framework in which miRNA networks interface with canonical signaling pathways and epigenetic mechanisms to orchestrate follicle development and regeneration. Conserved and species-specific regulatory principles are discussed to bridge fundamental follicle biology with practical applications in fiber production. Overall, this review highlights miRNAs as a critical yet previously underappreciated regulatory layer in hair follicle biology. A deeper understanding of miRNA-mediated control provides new conceptual insights into wool and cashmere development and offers a foundation for future molecular breeding and precision regulation strategies in livestock. Full article

Whole-cell biocatalysis presents a sustainable and efficient approach for the selective reduction in α,β-unsaturated bonds in flavonoid derivatives. This study investigates the capability of yeast strains from the Yarrowia clade to catalyze the chemoselective reduction of 4′-methoxychalcone (1a) to its dihydro derivative. All tested strains exhibited similarly high hydrogenation activity, indicating a broadly conserved enoate reductase function within the clade. Among them, Yarrowia lipolytica KCh 71, previously reported and well characterized in the literature, was selected for preparative-scale transformation of a diverse series of synthetic methoxychalcones bearing additional methoxy groups in positions C-2, C-3, C-4, C-5, and C-6 of ring B. All derivatives were effectively converted into the corresponding dihydrochalcones, with yields ranging from 62% to 92%. Among the tested derivatives, the 2′,4′,6′-trimethoxy chalcone (7a) did not undergo biotransformation under our conditions, whereas mono- and di-methoxy derivatives (2a–6a) were efficiently reduced. These results confirm the broad substrate tolerance, high efficiency, and potential scalability of Y. lipolytica KCh 71, supporting its potential as a whole-cell biocatalyst for the sustainable synthesis of bioactive dihydrochalcones. The consistently high hydrogenation activity observed across 21 tested strains suggests the involvement of evolutionarily conserved enoate reductases. Bioinformatic analysis supports that the Yarrowia clade possesses a robust complement of Old Yellow Enzymes (OYE), providing a reliable enzymatic basis for the observed chemoselective reductions. All Yarrowia tested strains showed the same general transformation type, although the extent and rate of conversion differed among strains, and Y. lipolytica KCh 71 was one of the most tolerant. The broad reduction in α,β-unsaturated chalcones is consistent with the action of flavoenzymatic ene-reductases, particularly Old Yellow Enzyme (OYE)–like reductases. Bioinformatic analysis of Yarrowia genomes reveals putative OYE homologs, supporting this mechanistic interpretation, although the specific enzymes were not identified in this study. Full article

Wheeled multifunctional motorized crossing frames represent a new type of crossing equipment for high-voltage transmission line construction. The initial design is too conservative, having a large safety margin and high material redundancy. Therefore, it is necessary to study a lightweight design version. However, as the structure constitutes an assembly consisting of multiple components, it also exhibits relatively high complexity. In a lightweight design, optimizing multi-component and multi-size parameters can lead to structural interference and separation, seriously affecting the smooth progress of design optimization. Therefore, an optimization design method of a multi-parameter complex assembly structure is proposed to solve this problem. Firstly, the typical stress conditions of the wheeled multifunctional motorized crossing frame were analyzed using its structural model. Then, a finite element model of the beam was established in ANSYS 2021 R1 Workbench, and the mechanical characteristics were analyzed. The results show that the arm support is the key load-bearing component and has significant optimization potential. Subsequently, functional mapping relationships were established among the 14 dimension parameters of the arm support, reducing the number of design variables to six and successfully avoiding component separation or interference during optimization. Through global sensitivity analysis, the height, thickness, and length of the arm body were screened out as the core optimization parameters from six initial design variables. Then, 29 groups of sample points were generated via central composite design (CCD), and a response surface model reflecting the relationships among the arm body’s dimensional parameters, total mass, maximum stress, and maximum deformation was established using the Kriging method. Leave-one-out cross-validation (LOOCV) was performed, and the coefficients of determination (R²) for model fitting were all higher than 0.995, indicating extremely high prediction accuracy. Taking mass and deformation minimization as the optimization objectives, the MOGA algorithm was adopted to perform multi-objective optimization and determine the optimal engineering parameters. Simulation verification was conducted on the optimized arm support, and an eigenvalue buckling analysis was performed simultaneously to verify structural stability. Finally, the proposed optimization method was experimentally verified through mechanical performance tests of the full-scale prototype under symmetric and eccentric loads. The results show that the mass of the optimized arm support is reduced from 217.73 kg to 189.8 kg, with a weight reduction rate of 12.8%. Under an eccentric load of 70,000 N, the maximum deformation of the arm support is 8.9763 mm, the maximum equivalent stress is 314.86 MPa, and the buckling load factor is 6.08, all of which meet the requirements for structural stiffness, strength, and buckling stability. The maximum error between the experimental and finite element results is only 4.64%, verifying the accuracy and reliability of the proposed method. The proposed optimization methodology, validated on a wheeled multifunctional motorized crossing frame, serves as a transferable paradigm for the lightweight design of complex assemblies with coupled dimensional constraints, thereby offering a general reference for the structural optimization of multi-component transmission line equipment, construction machinery, and other multi-component engineering systems. Full article

Talocalcaneal coalition is a frequent cause of painful rigid flatfoot in adolescents and young adults, resulting from congenital failure of segmentation with fibrous, cartilaginous, or osseous bridging of the subtalar joint. Clinical presentation typically coincides with skeletal maturation and includes hindfoot pain, recurrent ankle sprains, progressive stiffness, and characteristic planovalgus deformity. Although prevalence is likely underestimated, advances in imaging have improved recognition and characterization. Diagnosis relies on the integration of clinical findings with imaging, where computed tomography (CT) remains the reference standard, while magnetic resonance imaging (MRI) enables accurate detection of both osseous and non-osseous coalitions and associated soft-tissue changes. This narrative review aims to provide a comprehensive and updated synthesis of current concepts in talocalcaneal coalition, with specific focus on its clinical implications and contemporary management strategies. We critically analyze diagnostic pathways, including emerging modalities such as weight-bearing CT, and discuss evidence-based indications for conservative treatment, coalition resection, and arthrodesis. Particular attention is devoted to patient selection, prognostic factors, and evolving minimally invasive techniques. Current limitations and areas of controversy are highlighted, emphasizing the need for standardized imaging criteria and optimized treatment algorithms to improve long-term functional outcomes. Full article

Cognitive stress, also known as mental workload, constitutes a central topic within the field of psychophysiology due to its role in modulating attention, autonomic regulation, and stress reactivity. Furthermore, it bears direct relevance to practical monitoring systems that employ non-invasive sensing techniques. This study investigates whether a multimodal, non-invasive measurement setup can detect systematic physiological differences between Resting periods and short episodes of cognitive load within the same individuals. Additionally, it explores the capacity of such a system to differentiate tasks characterized by varying cognitive demands. A sequential, within-subject protocol was employed, comprising five consecutive phases (rest 1, Stroop, rest 12, subtraction, rest 3), during which five modalities were recorded concurrently: EEG, heart rate (HR), galvanic skin response (GSR), facial surface temperature, and oxygen saturation (SpO₂). Beyond phase-wise inspection of time-series data, an exploratory assessment of similarity across participants was conducted using correlation coefficients. The maximum cross-participant correlations observed were 0.88 (HR), 0.90 (GSR), 0.83 (facial temperature), and 0.77 (SpO₂); however, these correlations were used only as exploratory descriptors of inter-individual similarity and did not imply a significant phase effect. For inferential analysis, phase-wise epoch means were evaluated through one-factor repeated-measures ANOVA. The heart rate exhibited a robust main effect of phase (F(4, 32) = 10.5862, p_GG = 0.01044, ηp² = 0.5696), with higher HR observed during cognitive load epochs (e.g., 77.841 ± 11.777 bpm at rest 1 versus 83.926 ± 14.532 bpm during subtraction). The relatively large standard deviation reflects variability between subjects rather than variability within epochs. Regarding processed baseline-referenced GSR, the omnibus phase effect was not statistically significant under the conservative Greenhouse–Geisser correction; therefore, GSR was interpreted as exploratory in this dataset. Facial temperature and SpO₂ likewise did not show statistically significant omnibus phase effects under Greenhouse–Geisser correction (e.g., SpO₂: p_GG = 0.1209). EEG-derived measures provide supplementary central evidence of task engagement; entropy variations within an approximate dynamic range of 0.2 to 0.8 were observed, and the α/θ ratios demonstrated nearly a twofold distinction between rest and cognitive load epochs across different leads. Full article

Cliff carvings, as significant art forms bearing historical, cultural, and religious connotations, face dual threats from natural weathering and human-induced damage. Their protection and restoration of the artistic style present pressing challenges. In recent years, the rapid advancement of digital technologies has offered new opportunities for preserving and reproducing cultural heritage. Particularly, 3D style transfer techniques are emerging as crucial tools for digital safeguarding. The advantages of three-dimensional style transfer in cultural heritage applications include dynamic stylized rendering, simulation of styles from multiple historical periods, alternative modes of exhibition, and facilitating a paradigm shift in conservation practices from static digital archiving to dynamic revitalization. This study proposes a novel 3D stylization method for cliff carvings by integrating 3D Gaussian Splatting (3DGS) and Nearest Neighbor Feature Matching (NNFM) loss metric. The method represents ancient cliff carvings as a set of optimizable 3D Gaussians representation, enabling efficient capture and processing of complex geometric structures and rich textural details. By integrating the textural and geometric characteristics of the target artistic style, 3DGS facilitates high-quality transfer of diverse artistic styles while effectively preserving the original intricate details of the carvings. Additionally, we employ the NNFM loss function to transfer 2D visual details into 3D representations while maintaining multi-perspective style consistency. Experimental results demonstrate that the proposed method exhibits significant advantages in texture fidelity, style consistency, and rendering efficiency. This research showcases the potential of our model for the digital preservation and presentation of cliff-carved cultural heritage, offering an innovative technological approach with theoretical value and practical significance. Full article

Nuclear energy has become a promising substitute for traditional fossil fuels (e.g., coal, oil, and natural gas) by reason of its ultra-high energy density, firm power generation, and near-zero carbon emissions. However, the shortage of uranium resources is threatening the sustainable development of nuclear power, and meanwhile the nuclear fuel front-end cycle inevitably causes radioactive uranium-bearing wastewater discharge, resulting in severe environmental pollution. Nowadays, the extraction and enrichment of uranium in seawater and uranium-containing wastewater offer a prospective avenue to secure the long-term viability of nuclear power with environmental conservation. Among numerous strategies, photocatalytic extraction of soluble hexavalent uranyl (U(VI)) over graphitic carbon nitride (g-C₃N₄), a conjugated polymer semiconductor, is increasingly attracting widespread attention due to its high solar energy utilization, environmental friendliness, high selectivity, good stability, and low cost. A comprehensive overview that pinpoints research directions for novice researchers is urgently required. Herein, the development progress of g-C₃N₄-mediated photocatalytic U(VI) extraction is briefly introduced. Subsequently, the possible mechanisms are discussed with the assistance of advanced characterization techniques, and the influential factors for catalytic efficiency are also discussed. Moreover, multiple applications of g-C₃N₄-based catalysts on photocatalytic U(VI) reduction and extraction are elaborated, especially for modularization approaches on a large scale. At length, the future challenges and prospects in photocatalytic uranium extraction from water bodies are proposed. This review aims to offer fundamental insights into designing and exploring novel g-C₃N₄-based photocatalysts for soluble U(VI) enrichment in water bodies, especially opening up new avenues for the future development of sustainable uranium extraction technologies in practice. Full article

The oil-bearing rose (Rosa damascena Mill.), traditionally cultivated in Bulgaria for centuries, and the rose oil produced from it are of major cultural and economic importance. Its distinctive fragrance and rich aromatic profile are highly valued worldwide. In this study, a set of 15 start codon-targeted (SCoT) molecular markers was used to evaluate the genetic diversity and relationships of 38 rose accessions. The analyzed materials included Bulgarian-bred R. damascena cultivars, a locally improved population (‘Population 5’), three oil-bearing species (Rosa alba L., Rosa gallica L., and Rosa centifolia L.), Romanian heritage roses, and an unidentified rose genotype from an old Bulgarian plantation (Rosa sp.). The SCoT primers yielded a cumulative count of 238 bands, with an average of 12.9 bands per primer. The range of diversity markers, such as PIC (0.20–0.78), number of different alleles (1.5–2.00), Shannon’s information index (0.24–0.69), and gene diversity (0.15–0.50), provided evidence of genetic differences among the examined accessions. Analysis of Molecular Variance (AMOVA) revealed higher genetic variation within groups (61%) than among the groups (39%). Multivariate analyses (UPGMA, PCoA, and STRUCTURE) resolved the accessions into major genetic clusters corresponding to their taxonomic identity or breeding history. The unidentified Rosa sp. formed a distinct genetic group, showing closer affinity to R. gallica. The locally improved R. damascena ‘Population 5’ exhibited higher genetic diversity than the Bulgarian cultivars. Overall, our results demonstrate the effectiveness of SCoT markers and the value of local and traditional rose germplasm as reservoirs of genetic diversity. The study provides a molecular framework to support breeding, conservation, and sustainable management of oil-bearing rose genetic resources. Full article

Grindelia mutabilis (Asteraceae, Astereae), a new species from Brazil endemic to the Espinal Ecoregion of the Río de La Plata Grasslands Bioregion and Pampa Province of the Chaco Biogeographical Domain, is proposed and illustrated. The new species is characterized by a combination of traits: small, rosette cespitose habit, linear to linear–oblanceolate leaves, light-yellow to pastel salmon ray florets, three-winged ray floret cypselae bearing a pappus of two to four elements and two-winged disc floret cypselae bearing a pappus of two elements. It has a highly restricted habitat and is known exclusively within Parque Estadual do Espinilho in Rio Grande do Sul, Brazil. Preliminary conservation assessments classify the new species as Critically Endangered. We provide illustrations and photographs, as well as a distribution map with an identification key for the South American Grindelia species with winged cypselae. The intriguing morphology of this species combines characters traditionally regarded as diagnostic for Notopappus, a genus segregated from Haplopappus and Grindelia. Previously published phylogenetic studies of related taxa indicate that the recognition of Notopappus as monophyletic is not supported and render Grindelia as non-monophyletic too. Based on this combined morphological evidence and existing phylogenetic hypotheses, we reaffirm the non-monophyly of Notopappus and formally propose its synonymization under Grindelia s.l. Full article

High-strength concrete (HPC/UHPC) provides a new way to optimize the performance of nuclear power containment, but the mechanism of its application in the bi-directional dense anchorage zone is not clear. In this paper, a three-dimensional nonlinear model was established by ABAQUS to systematically study the effects of concrete strength, cylinder thickness and other parameters on the local pressure-bearing performance of the anchorage zone. The study shows that the use of C80–C120 concrete can thin the thickness of the containment by 30–40% and significantly enhance the pre-compressive stress safety reserve. Comparison of the existing design codes (e.g., Kim’s formula, Highway Bridge Specifications and UHPC-related regulations) reveals that the prediction results have a non-conservative or over-conservative tendency, which restricts the full utilization of the material performance. This study reveals the working mechanism of bi-directional multiple anchorage zones, demonstrates the advantages of high-strength concrete containment in terms of safety and economy, and provides a theoretical basis for the design of advanced nuclear power structures. Full article

Background: Meniscal injuries are common athletic injuries, and isolated meniscal repair is a critical procedure for restoring knee function. However, rehabilitation protocols after meniscal repair remain controversial. This systematic review aimed to evaluate rehabilitation protocols to determine the best strategies for enhancing recovery following isolated meniscal repair. Objectives: Analyze current rehabilitation protocols following isolated meniscal repair, focusing on the efficacy of approaches in improving functional outcomes and reducing recovery time. This study also aims to identify gaps in the existing literature and provide recommendations for future studies. Data sources: Search was conducted using PubMed, Scopus, and Web of Science databases, covering studies published between May 2015 and May 2024. Inclusion criteria: Studies reporting on isolated meniscal repair with defined postoperative rehabilitation protocols and quantifiable outcome measures. Data extraction: Focused on patient demographics, meniscal tear types, repair techniques, and rehabilitation outcomes. The methodological quality of the included studies was assessed, and narrative synthesis was conducted. Results: The review included 13 studies with significant variability in rehabilitation protocols and outcomes. Early weight-bearing and range of motion exercises have been associated with improved recovery in some studies for stable meniscal tears. However, conservative approaches have better outcomes in patients with complex tears. The use of adjunctive therapies such as blood flow restriction training has demonstrated potential in enhancing muscle preservation and overall recovery. Conclusions: Rehabilitation protocols after meniscal repair surgery should be individualized. Although innovative protocols show promise, further research is needed to standardize rehabilitation approaches and optimize long-term outcomes. Full article

Splicing defects represent a significant class of human genetic disorders, yet strategies to directly correct aberrant splice-site recognition remain limited. The small nuclear RNA (snRNA) U1 plays a critical role in pre-messenger RNA splicing by base-pairing with the conserved 5′ splice-site ‘GU’ dinucleotide. Disruption of this interaction can lead to abnormal splicing or frameshift mutations, contributing to disease pathology. Extracellular vesicles (EVs) can transport small molecules to cells for therapeutic applications. Here, U1 snRNA-overexpressing HEK293T cells were used to generate approximately 120 nm-diameter U1 snRNA-enriched EVs, whose purity and content were confirmed by exosomal marker Western blots and reverse transcription–quantitative PCR. When HeLa cells expressing a β-globin minigene bearing a β-thalassaemia-like 5′ splice-site mutation were treated with U1-snRNA-enriched EVs, they corrected up to sixty percent of normal exon–intron junction recognition in a dose-dependent manner. Recovery was abolished by heat or RNase treatment, suggesting that intact vesicular RNA cargo was essential for activity. These findings provide the first demonstration that EVs can transport spliceosomal snRNAs capable of reconstituting splice-site recognition in recipient cells and introduce a novel class of RNA-based therapeutics that exploit the natural cargo-shuttling capacity of EVs to correct splicing defects associated with genetic disease. Full article

Background/Objectives: Juvenile osteochondritis dissecans (JOCD) of the knee is commonly treated using conservative or joint-preserving surgical techniques. While clinical outcomes are generally favorable, the risk of early cartilage degeneration remains unclear. Joint space width (JSW) on weight-bearing radiographs serves as an indirect marker of cartilage health. Artificial intelligence (AI)-based JSW assessment may enable sensitive and reproducible detection of early degenerative changes. Methods: This cross-sectional feasibility study included 21 skeletally immature patients treated for JOCD of the distal femur between 2002 and 2017. Treatment modalities comprised conservative management, retrograde drilling, and fragment refixation. Fully automated JSW measurements were performed on standardized anteroposterior knee radiographs using a validated AI-based software IB Lab KOALA™, Version 2.4. JSW of the affected compartment was compared with the contralateral knee and between treatment groups. Clinical outcomes were assessed using the Lysholm Knee Scoring Scale and the International Knee Documentation Committee (IKDC) score. Additionally, a systematic review of the literature on post-treatment degenerative changes following OCD therapy was conducted according to PRISMA guidelines. Results: Compared with manually reviewing images, the software IB Lab KOALA™, Version 2.4 as easy to implement. AI-based analysis revealed no significant differences in JSW between the affected and contralateral knees, nor between treatment modalities. Average JSW exceeded 6 mm in all groups after a median follow-up of 64 (min. 27, max. 177) months. Clinical scores were high and comparable across treatments. A moderate positive correlation was observed between the JSW and Lysholm score, while increasing age and longer follow-up were associated with a reduced JSW. The systematic review identified ten relevant studies, reporting generally favorable long-term clinical outcomes with a low but present risk of osteoarthritis progression. Conclusions: Our AI-based analysis showed no differences in JSW between conservative and joint-preserving surgical treatments of JOCD in the follow-up. This technology can provide a valuable tool for standardized and sensitive radiographic monitoring in young patients. Full article

Background: Fragility fractures of the pelvis (FFPs) are increasingly prevalent given ageing populations. Conservative management is often primarily utilised due to its initial minimal displacement and the high risks of surgery in this vulnerable population. However, this can lead to rapid deconditioning, especially with non-weight-bearing protocols. Parathyroid hormone (PTH), as a bone anabolic agent, has the potential to improve clinical and radiological outcomes in FFPs, but the evidence remains limited. Methods: A systematic review and meta-analysis following PRISMA guidelines was undertaken. Database search results were independently screened by two authors, and data were extracted. The primary outcome measure was time to fracture healing as assessed by imaging, with the secondary outcome measure of pain levels (VAS/NRS). Results: There were 1230 articles screened, and 893 unique results identified. Six studies were included in the final analysis. These compared the use of PTH and its analogues with standard care, placebo, or sacroplasty. The findings suggest that PTH may accelerate fracture healing and reduce pain in this patient population, although evidence is limited and at high risk of bias. Conclusions: Treatment with PTH may improve bone healing and visual analogue pain scores, although the evidence is limited. There may be a benefit from adjunctive PTH treatment for patients with FFPs; however, larger methodologically robust studies are required to confirm this. Full article