Search Results (813)

This study determined the elastic properties of “green” concrete with cement partially replaced by oil shale ash (OSA) and reinforced with short basalt integral fibers (BIFs). Commercially available Deutsche Basalt Faser (DBF) GmbH Turbobuild Integral basalt fibers were used. There is currently a high demand both for strengthening concrete and applying ecological approaches with respect to circular economy. Oil shale ash is the byproduct of oil shale combustion. Basalt fiber is produced by melting basalt rock. Both BIF and OSA are used as additives in concrete. Cement replacement by OSA non-linearly changes the concrete’s strength properties, and the addition of BIF improves them. An experimental investigation was conducted using four-point bending tests and cube sample compression tests. Theoretical methods such as Voigt and Reuss boundaries, the Halpin–Tsai method, and the Mori–Tanaka method were used to predict the elastic properties of the fabricated samples. The theoretical models can provide useful information, although they may not fully capture the real properties observed experimentally. The results show that BIFs protect against instant brittle destruction. The experiments demonstrated an optimal OSA concentration for a fixed amount of BIF, resulting in the highest load-bearing capacity of the concrete. The addition of either 15% OSA only or 20% OSA and CBF can increase the stiffness of the concrete. This article provides guidance to the construction sector on using OSA and CBF together. Full article

This study addresses the issues with traditional rolling protection bearings in vertical magnetic levitation flywheel energy storage systems (FESSs), which are prone to impact, wear, and temperature rise under abnormal conditions, such as drops. It designed a permanent magnet axial protection bearing based on a Halbach array, utilizing N42SH permanent magnet material. The five-layer Halbach array achieved a maximum axial magnetic force of 86 KN and a maximum air gap magnetic flux density of 2.2 T, meeting the application requirements. Simulation results, combined with rotor drop dynamics and thermal analysis, show that under an 8000 rpm drop condition, the permanent magnet bearing reduces radial and axial contact forces by approximately 60% and 54%, respectively, and wear by around 70%. Additionally, the maximum system temperature decreases from 109 °C to 74 °C, with a 32% reduction in temperature rise. Friction experimental analysis indicates that low frequency, low load, and moderate temperatures improve friction stability and reduce wear. Overall, the permanent magnet axial protective bearing effectively mitigates drop impact, reduces friction heat and wear, and enhances the safety and reliability of the flywheel energy storage system under abnormal working conditions, providing valuable theoretical support and a design reference for engineering applications. Full article

Background/Objectives: Meniscal root tears, particularly those of the posterolateral root, are frequently associated with anterior cruciate ligament (ACL) injuries and significantly alter load distribution and knee stability. Surgical repair of the posterolateral meniscal root (PLMR) aims to restore normal biomechanics; however, postoperative rehabilitation strategies remain heterogeneous. The objective of this systematic review was to describe and analyze postoperative weight-bearing (WB) and range-of-motion (ROM) protocols following concomitant PLMR repair and anterior cruciate ligament reconstruction (ACLR), integrating both clinical and biomechanical perspectives. Methods: This systematic review followed PRISMA guidelines and analyzed biomechanical and clinical studies assessing postoperative WB and ROM management following PLMR repair combined with ACLR. Results: Eleven studies were included, describing heterogeneous postoperative rehabilitation protocols for WB and ROM following posterolateral meniscal root repair with ACLR. Biomechanical data consistently showed that root section increased tibial internal rotation and contact pressure on the lateral tibial plateau, whereas repair restored near-native load sharing. Clinically, most authors recommended non-weight-bearing or toe-touch loading for 4–6 weeks and flexion limited to 0–90° during early rehabilitation. Gradual progression to full loading and motion between 8 and 12 weeks was the most consistent strategy. Conclusions: Although the current evidence is limited and mainly based on low-level studies, available data suggest that a cautious and progressive rehabilitation protocol after PLMR repair with ACLR early controlled motion and delayed full loading may optimize repair healing while protecting graft integrity. Full article

Pacific Island communities have long navigated the challenges of climate change. Supporting adaptation options is critical for protecting livelihoods, especially given that these countries will continue to unfairly bear the brunt of global climate change impacts. Understanding and strengthening the capacity of individuals and communities to adapt is vital to ensure effective options are available. However, adaptive capacity is highly context-specific and explicit examples, particularly from the Pacific, remain limited. This study focuses on the experiences of women market vendors, for whom marketplaces are integral to food security, income generation, and cultural and social life. Building on existing global and regional frameworks, we assess the adaptive capacity of market vendors across Vanuatu through interviews with women market vendors (n = 69) and key informants (n = 18). The findings informed the development of a new, tailored adaptive capacity framework that identifies six key drivers: access to tangible resources, human assets, social assets, livelihood diversity and flexibility, systems of influence and mindsets, and decision-making capacity. This study presents a context-specific framework grounded in empirical evidence, offering insights for development and adaptation initiatives that aim to strengthen adaptive capacity. We encourage further research to apply and refine this framework across diverse Pacific contexts and sectors to deepen understanding of adaptive capacity and inform effective adaptation strategies. Full article

Saline water intrusion poses a major threat to groundwater security in arid and semi-arid regions, reducing freshwater availability and challenging sustainable water resource management. Accurate delineation of the fresh-saline water interface is therefore essential; however, conventional hydrochemical and laboratory-based assessments remain costly, invasive, and spatially limited. Resistivity methods have long been used to infer subsurface salinity, as low resistivity typically reflects clay-rich saline water and higher resistivity reflects freshwater-bearing sand or gravel. Yet, resistivity values for similar lithologies frequently overlap, causing ambiguity in distinguishing fresh and saline aquifers. To overcome this limitation, Dar–Zarrouk (D–Z) parameters are often applied to enhance hydrogeophysical discrimination, but previous studies have relied exclusively on one-dimensional (1D) D–Z derivations using vertical electrical sounding (VES), which cannot resolve the lateral complexity of alluvial aquifers. This study presents the first application of electrical resistivity tomography (ERT) to derive two- and three-dimensional D–Z parameters for detailed mapping of the fresh-saline water interface in the alluvial aquifers of Punjab, Pakistan. ERT provides non-invasive, continuous, and high-resolution subsurface imaging, enabling volumetric assessment of aquifer electrical properties and salinity structure. The resulting 2D/3D models reveal the geometry, depth, and spatial continuity of salinity transitions with far greater clarity than VES-based or purely hydrochemical methods. Physicochemical analyses from boreholes along the ERT profiles independently verify the geophysical interpretations. The findings demonstrate that ERT-derived 2D/3D D–Z modeling offers a cost-effective, scalable, and significantly more accurate framework for assessing fresh-saline water boundaries. This approach provides a transformative pathway for sustainable groundwater monitoring, improved well siting, and long-term aquifer protection in salinity-stressed alluvial regions. Full article

Chemotherapy causes primordial follicle apoptosis, resulting in premature ovarian insufficiency (POI) and infertility. In this study, we found that intraperitoneal injection of retinoic acid (RA) and calcitriol partially reversed the cyclophosphamide and doxorubicin treatment-induced decrease in primordial follicles in neonatal mouse ovaries. Furthermore, RA and calcitriol co-treatment reversed cyclophosphamide treatment-induced PI3K/Akt activity and FOXO3a nuclear export in the oocytes within primordial follicles, suggesting that the oocyte transcriptional activity was decreased, which in turn reduced the binding of chemotherapeutic drugs to DNA. Consistent with these findings, RA and calcitriol co-treatment reversed cyclophosphamide treatment-induced changes in reactive oxygen species (ROS), DNA damage response proteins (γH2AX, p-CHK2, p-p53, PUMA, BAX, Cleaved Caspase-3, and cPARP), and antioxidant proteins (NRF2, HO-1, and GPX4). Moreover, RA and calcitriol co-treatment preserved fertility in cyclophosphamide-treated mice without impairing cyclophosphamide’s antitumor efficacy in MCF-7 tumor-bearing mice. Thus, RA and calcitriol protect mouse primordial follicles from cyclophosphamide treatment-induced apoptosis by inhibiting cyclophosphamide treatment-induced oocyte transcriptional activity and enhancing antioxidant capacity. Our results suggest a potential strategy for preserving ovarian reserve during chemotherapy in female cancer patients. Full article

Cancer therapies frequently induce hepatotoxicity, complicating treatment courses and outcomes. Natural products, including polyphenol-rich extracts, have shown hepatoprotective activity via anti-oxidative and anti-inflammatory mechanisms, often linked to NF-κB and PI3K–Akt pathways. Apple-derived polyphenols (e.g., phlorizin/phloretin) also demonstrate liver-protective effects in experimental settings. In this study, we examined whether ASE mitigates cancer-related liver damage by rebalancing the apoptosis–survival axis and maintaining PI3K-Akt signaling in an endometrial cancer mouse model. Female Institute of Cancer Research mice with induced endometrial cancer received ASE (0–200 mg) over 13 days; liver tissues were analyzed for Caspase-3, p53, LC3, and SQSTM1 using histology stains, Western blot (e.g., Caspase-3/9, Bcl-xL, PI3K, Akt, PCNA, IGF-IR), ELISA, and qRT-PCR (GAPDH). ImageJ (version 1.54f; RRID: SCR_003070) quantification statistical analysis followed (mean ± SD; post-hoc tests). ASE exhibited dose-dependent modulation of apoptosis and survival readouts in liver tissue of cancer-bearing mice: (i) Caspase-9/3 and Bcl-xL showed differential regulation across doses; (ii) PI3K–Akt and IL-2 signals were preserved or restored toward baseline at specific doses; and (iii) histology indicated partial structural recovery. Thus, ASE may mitigate liver injury by re-balancing apoptosis–survival signaling and promoting structural recovery. Our interpretation emphasizes that dose, route, and formulation are critical for translational potential. Full article

Background: Oncological treatment remains a major clinical challenge. Despite therapeutic advances and the diversity of available approaches, many tumors continue to exhibit limited responsiveness to chemotherapy. In this context, nutrition has emerged as a promising complementary strategy to support cancer therapy. In particular, interventions based on nutritional deprivation have gained prominence due to their ability to modulate tumor metabolism, inducing alterations that may increase the sensitivity of cancer cells to conventional treatments. Accordingly, the present study aimed to evaluate the safety and efficacy of caloric restriction combined with chemotherapy in a Sarcoma-180 model, investigating its effects on immunological and hematological parameters, antioxidant activity, oxidative stress, and tumor and liver morphology, as well as DNA damage. Methods: Mice bearing Sarcoma-180 were randomly assigned to four groups: Ad Libitum (AL), Ad Libitum + Doxorubicin (ALDOX), Caloric Restriction (CR), and Caloric Restriction + Doxorubicin (CRDOX). Assessment included tumor weight and volume, food and caloric intake, hematotoxicity, lipid metabolism, oxidative stress and antioxidant markers, genotoxicity, morphological alterations in the tumor and liver, and overall survival. Results: The data obtained demonstrate that caloric restriction combined with doxorubicin is both safe and feasible, as it preserves body weight and does not induce metabolic disturbances. Importantly, this combined strategy produced a marked reduction in tumor volume and mass while also mitigating the hematotoxicity typically associated with doxorubicin. In peripheral blood, the regimen decreased chemotherapy-induced DNA damage, supporting a systemic protective effect. Consistently, the combination reduced oxidative stress markers (NOx and MDA) and enhanced antioxidant activity within the tumor. Histological analyses further confirmed these outcomes, showing tumor cell death with features compatible with apoptosis and reduced local invasion. Together, these data indicate that caloric restriction enhances the antitumor efficacy of doxorubicin while simultaneously improving treatment tolerance. Conclusions: This study demonstrates that caloric restriction, combined with doxorubicin, is safe, well-tolerated, and enhances the antitumor response in the Sarcoma-180 model. Full article

Aberrant signaling pathways of the acquired immune system are implicated in the development of cardiovascular disease (CVD) and chronic kidney disease (CKD) phenotypes. Understanding the complex abnormalities of lymphocyte subpopulations in CKD is a prerequisite for elucidating their implication in uremic cardiomyopathy. T cell subsets display various patterns of association with indices of myocardial function in both experimental and clinical CKD models. The role of Tregs in CVD and CKD has attracted significant research interest. Although experimental data suggest a protective role of Tregs from the development of arterial hypertension- and pressure overload-induced myocardial hypertrophy, there might be a change in the regulatory T cell (Treg) phenotype towards a profibrotic one in the settings of CKD and heart failure. Depletion of B lymphocytes is a hallmark of CKD and heart failure, bearing adverse prognostic significance, yet evidence of B lymphocytes’ involvement in the pathogenesis of myocardial damage is currently lacking. Considering that myocardial remodeling is the final outcome of diverse pathogenic processes targeting the heart, the aim of this review is to present the evidence available up to now regarding the role of acquired immune cells in the pathogenesis of the structural and functional alterations of the myocardium in CKD. Full article

This study addresses the challenges of low-pressure oil well workover operations, namely, severe loss of water-based workover fluid, significant reservoir damage from conventional temporary plugging agents, and slow production recovery, by focusing on the yet-mechanistically unclear “fuzzy-ball workover fluid.” Laboratory experiments combined with field data were used to evaluate its plugging performance and reservoir-protective mechanisms. In sand-filled tubes (diameter 25 mm, length 20–100 cm) sealed with the fuzzy-ball fluid, the formation’s bearing capacity increased by 3.25–18.59 MPa, showing a positive correlation with the plugging radius. Compatibility tests demonstrated that mixtures of crude oil and workover fluid (1:1) or crude oil, workover fluid, and water (1:1:1) held at 60 °C for 80 h exhibited only minor apparent viscosity reductions of 4 mPa·s and 2 mPa·s, respectively, indicating good stability. After successful plugging, a 1% ammonium persulfate solution was injected for 2 h to break the gel; permeability recovery rates reached 112–127%, confirming low reservoir damage and effective gel-break de-blocking. Field data from five wells (formation pressure coefficients 0.49–0.64) showed per-well fluid consumption of 33–83 m³ and post-workover liquid production index recoveries of 5.90–53.30%. Multivariate regression established mathematical relationships among bearing capacity, production index recovery, and fourteen geological engineering parameters, identifying the plugging radius as a key factor. Larger radii enhance both temporary plugging strength and production recovery without harming the reservoir, and they promote production by expanding the cleaning zone. In summary, the fuzzy-ball workover fluid achieves an integrated “high-efficiency plugging–low-damage gel-break–synergistic cleaning” mechanism, resolving the trade-off between temporary-plugging strength and production recovery in low-pressure wells and offering an innovative, environmentally friendly solution for the sustainable and efficient exploitation of oil–gas resources. Full article

Using the geologically complex Wanning (Hainan) site as context, this study applies finite-element analyses to quantify how three construction-induced conditions—foundation out-of-level, directional misalignment, and seabed scour—affect the bearing performance of deep-water pile-anchor foundations for floating offshore wind. For the Wanning case, typical installation and loading deviations reduce the characteristic resistance by a clearly measurable amount: changing the loading inclination from 30° to 45° and superimposing a 5° out-of-level installation leads to reductions in R_c of approximately 7–10%. A 3 m scour pit around the pile has a more severe impact, decreasing R_c by about 18% for 30° loading and up to 28% for 45° loading. Under accidental-limit-state loading, the maximum pile-head displacement increases from about 0.247 m (ULS) to 0.396 m (ALS), i.e., by roughly 60%. These quantitative results demonstrate that construction-induced deviations and scour can significantly erode safety margins, highlighting the need to control installation accuracy and to explicitly incorporate scour allowances and protection in design. Full article

This study investigates how women at a Muslim island community-based tourism (CBT) site convert performed respectability and routine paperwork into everyday organizational authority. Drawing on four months of ethnographic fieldwork in Bang Rong, Phuket—supported by seventeen semi-structured interviews, three years of social-media observation (2023–2025), and analysis of rosters, ledgers, receipts, and LINE threads—the study examines how gendered norms and material devices structure authority in daily tourism practice. The analysis identifies an authorization stack (veil, uniform, tone) and a set of paperwork devices (ledgers, rosters, receipts, digital groups) that make women’s visibility both morally credible and institutionally legible. Using a poststructural feminist lens and Barriteau’s gender-system framework, the article develops an interpretive, case-derived Respectability-in-Action Conversion Model, showing that moral credit converts into procedural authority only when respectability cues align with control of at least one device. Conversion, however, remains partial and contingent: strategic levers stay largely male or mosque-adjacent unless women obtain rights-bearing tools, such as co-signature authority, petty-cash control, or platform access, along with institutional protection against sanction. Age, class, and endorsement shape these trajectories, enabling some women to consolidate authority while rendering others easily replaceable. The study contributes: (1) a case-specific, empirically grounded account of authority formation in island CBT; (2) an analytic lens for understanding how performance, devices, and rights interact in this setting; and (3) practice-oriented implications for small-island CBT contexts that emphasize shared device access, rotating administrative duties, co-signature and budget rights, and safeguards against organizational capture. Full article

Background/Objectives: In digenic populations, all females produce males and females in their offspring. Monogenic populations are composed of gynogenic (female-producing) and androgenic (male-producing) females. A theoretical population genetic model for evolution of digenic to monogenic populations is presented here. Methods: A controlling gene was associated with each of the four processes that characterise monogenic populations: (1) oogenesis is conventional, whereas spermatogenesis is unusual and it is characterised by the exclusive formation of X-bearing sperm (gene (s)), i.e., the paternal chromosomes are eliminated so that only the maternal ones are transmitted to the next generation; (2) the X chromosome that is eliminated in the zygote is the one inherited from the father (gene r); (3) an imprinting process occurs in the mother (gene g), which protects the maternally inherited X chromosome from elimination in the zygote and the whole maternal chromosome complement in spermatogenesis; (4) a maternal factor is produced during oogenesis (gene e), which inactivates the elimination factor [r] in the zygote, thus controlling the elimination of the paternal X chromosome. The sequences of emergence of the genes (e s r g) that transform a digenic population into a monogenic one were analysed. Results: The following evolutionary sequences were found: (1) the sequence (r s e) under dominant conditions of gene (s) and recessive conditions of gene (r); and (2) the sequences (s r e), (r s e), and (e s r) under recessive conditions of gene (s) and gene (r). It was also found that the process of genomic imprinting is a necessary condition for the generation of a monogenic population. Furthermore, a quantitative change in the interaction between the elimination factor and its maternal inhibitor modifies the genotypic formula of the monogenic state. Conclusions: The number and types of evolutionary transitions of a digenic to a monogenic population depends on the dominant or recessive characteristic of the newly emerging genes. The imprinting process must already be present in the digenic population from which the monogenic one evolves; otherwise, the population cannot reach the monogenic state. Full article

The monitoring of wildlife habitats is crucial for effective conservation efforts, particularly where biodiversity faces significant threats. This study aimed to monitor the biodiversity of wild mammals in a protected area (PA) of Northeastern Bangladesh, with a particular focus on detecting previously unrecorded species using camera traps. We deployed nine camera traps across 19 locations inside the PAs of Satchari National Park (SNP) from May 2024 to April 2025. Further, the camera-trap data were analyzed to evaluate the existing wild mammals, along with their activity patterns and seasonal variations, in SNP. Our study identified the Asiatic black bear in SNP for the first time, representing a significant contribution to biodiversity records of Bangladesh. Among the other frequently documented wild mammals were the wild boar, northern pig-tailed macaque, and barking deer, whereas less commonly detected species included the crab-eating mongoose and jungle cat. Activity pattern analysis of Asiatic black bear revealed a predominantly nocturnal-to-crepuscular behavior, with distinct bimodal peaks during early morning and evening. The present study showed that the Asiatic black bear was active in pre-monsoon and winter; however, it was absent during the rainy season, suggesting seasonal habitat use or detectability challenges. This is the first study to confirm the presence of Asiatic black bears in PAs of SNP using camera traps. These findings also highlight the importance of long-term biodiversity monitoring for continued conservation efforts to protect the diverse wildlife of SNP. The detection of previously undocumented wild mammals highlights the ecological importance of SNP, urging authorities to tighten the ongoing conservation initiatives. Understanding the diel and seasonal activity patterns would instruct the timing of conservation and habitat management strategies. This study also makes the integration of camera-trap monitoring into long-term biodiversity management to guide evidence-based conservation policies in Bangladesh’s PAs. Full article

Human–wildlife conflicts can be broadly categorized from the perspective of human activities into conflicts (a) caused by the expansion of human activities into wildlife habitats, and (b) resulting from the re-expansion of wildlife habitats due to the decline of human activities. The first type of conflict has been managed through the systematic training of wildlife managers, field specialists, and well-organized institutional frameworks. In Japan, Asiatic black bears (Ursus thibetanus) and brown bears (Ursus arctos) have increasingly come into human contact because of habitat re-expansion. Short-term measures to protect human life and property include the implementation of the 2024 and 2025 revisions of the Wildlife Protection and Hunting Management Act, which designated bears as “managed wildlife” and “dangerous wildlife” and permitted emergency culling in residential areas. However, Japan’s approach remains limited in scope and depth, relies on ad hoc responses by local hunters, and lacks adequate public education and effective long-term sustainability planning. This study highlights the necessity of a multi-layered policy framework that integrates human–wildlife conflict management, particularly human–bear conflict, by comparing U.S. laws and policies and incorporating them into medium- and long-term strategies for community resilience and national land conservation. This approach may serve as a model for countries and regions facing similar demographic and ecological challenges. Full article