Search Results (3,022)

The Arabian honeybee, Apis mellifera jemenitica, is well adapted to the arid and semi-arid conditions of the Arabian Peninsula. However, little is known about the interactions among climatic conditions, Varroa mite, and honeybee viruses affecting A. m. jemenitica colonies. This study investigated the prevalence of Varroa destructor and major honey bee viruses (DWV, BQCV, SBV, CBPV, ABPV, KBV, IAPV and AIV) in A. m. jemenitica colonies located across arid and semi-arid regions of Saudi Arabia. The results revealed a high prevalence of Varroa infestation and DWV in both climatic zones. The other viruses (BQCV, SBV, CBPV, ABPV, KBV, IAPV and AIV) showed significant spatial variation in prevalence across the surveyed regions. Varroa infestation levels were generally low and significantly higher in semi-arid environments compared to arid regions (p < 0.001). Mean regional DWV loads (copies/bee) were consistently low across all A. m. jemenitica colonies (6.8 × 10² to 4.4 × 10³ copies/bee), were positively linked with Varroa infestation levels (R² = 0.63), and demonstrated significant variation among climatic zones (p < 0.001). Virus co-occurrence analysis using Phi (ϕ) coefficients revealed structured viral communities, with several virus pairs exhibiting moderate to strong positive associations. Overall, this study highlights the low DWV loads in A. m. jemenitica colonies, and the impact of climate conditions on Varroa mite–virus interactions in shaping honeybee health under arid and semi-arid conditions. Full article

Scientific studies of mine closure and ecosystem management have become very important since the rate of coal mine closures in China has increased rapidly over the last decade. This study first analyzed spatiotemporal changes in land use and ecosystem services value (ESV) during the period 2000–2020 around the Kailuan Mining Area in Tangshan City. The area has a history of over 100 years of continuous mining activities in the region. The analyses used the PLUS model, multi-scenario simulation, and ESV equivalent factor method and multi-source data on land use, mining activities, socioeconomic factors, and climatic conditions. The study then projected land-use changes and spatiotemporal ESV characteristics for the year 2030 for two alternatives: (1) the Current Development Scenario (CDS), representing the current pace of development without mine closure; and (2) the Ecological Restoration Scenario (ERS), representing mine closure and ecological restoration. Key results include: (1) during 2000–2020, cultivated land and construction land were the primary land uses, with the overall trends showing decrease in cultivated, forest, pasture, and unused lands, varying water use areas, and continuously increasing construction land; (2) the revised ESV results show that total ESV declined from 31.27 million USD in 2000 to 25.30 million USD in 2020, a net decrease of 6.19 million USD, mainly because of cropland loss and degradation of forest and grassland; and (3) for 2030, the CDS projected a continued decline in total ESV to 24.30 million USD, whereas the ERS increased total ESV to 26.50 million USD, which is 2.19 million USD higher than the CDS and 1.20 million USD higher than the 2020 baseline. Compared with the CDS, the ERS increased cropland by 13.20 km² and reduced construction land by 10.06 km², indicating that reclaiming subsided water bodies and idle construction land into cropland and restored ecological land can enhance ecosystem services while mitigating subsidence-related risks. The framework can support data-driven post-mining land-use planning and ecological management in resource-based regions. Full article

This study investigates the spatiotemporal dynamics of peri-urban expansion and land use transformation in Izmir, Türkiye, over 36 years (1986–2022) using an integrated GIS-based Multi-Criteria Decision Analysis (MCDA) framework. Multi-source datasets, including Landsat imagery, CORINE land cover (CLC) data, demographic statistics, and spatial variables (slope, transportation proximity, and distance to the city center), were combined to delineate urban, peri-urban, and rural zones. Results reveal a substantial percentage increase in urban areas from 2.8% in 1986 to 10.48% in 2022, corresponding to an expansion of approximately 7.6% (≈908.56 km²). In contrast, agricultural land declined by 5.8%, while forest areas experienced a more severe reduction of 19.1%, indicating significant environmental degradation. Population dynamics further support this transformation, with peri-urban districts exhibiting growth rates exceeding the metropolitan core average of 1.8% (1986–2010), followed by a relative slowdown to 0.5% after 2010, accompanied by outward migration-driven expansion. Spatial analysis demonstrates that peri-urban growth is strongly influenced by accessibility and topography, with development concentrated within 30–50 km of the city center and along major transportation corridors (500–1000 m buffers). Land Surface Temperature (LST) analysis indicates increasing urban heat island intensity, with surface temperatures ranging from 12 °C to 46 °C, particularly in densely built inner peri-urban zones. The MCDA-based classification identifies distinct inner and outer peri-urban belts, characterized by contrasting density, land use patterns, and environmental pressures. Overall, the findings highlight that Izmir’s peri-urbanization is a heterogeneous and rapidly evolving process driven by demographic, spatial, and policy-related factors. The study provides a replicable methodological framework and emphasizes the urgent need for integrated, sustainability-oriented planning strategies to mitigate ecological loss and uncontrolled urban sprawl. Full article

(1) Introduction: Transit-oriented development is often framed as a strategy to expand opportunity and advance equitable transportation. However, evidence suggests it can also contribute to rising housing costs and displacement in historically marginalized communities. This study examines how a light rail expansion reshaped displacement risk in a Latina/o community in the U.S. Southwest, identifying early mechanisms through residents’ interpretations of the expansion during construction. (2) Materials and Methods: Using a qualitative, community-engaged design, the study draws on ten in-depth pláticas with Latina/o residents conducted during construction of a major rail expansion. Data were analyzed abductively and guided by Critical Race Ecological Systems Theory (CrEST) to identify multilevel mechanisms linking infrastructure policy to lived social conditions. (3) Results: Findings identify three mechanisms through which transit investment generated displacement risk prior to relocation. First, historical and intergenerational memory shaping anticipatory displacement. Second, place-based belonging intensifying psychosocial stress and loss. Third, policy-mediated mobility constraining residents’ ability to remain or benefit from reinvestment. (4) Discussion: Transit infrastructure operates as a structural policy intervention that reorganizes risk, belonging, and stability when histories of racialized disinvestment are not incorporated into policy design. These findings position infrastructure planning as a critical site for social work policy analysis and prevention-oriented intervention. Full article

Walking is not merely locomotion but a window into the nervous system, integrating cortical, subcortical, cerebellar, spinal, and peripheral networks into a unified motor behavior. Across neurological diseases—including Parkinson’s disease, atypical parkinsonism, cerebellar ataxias, stroke, multiple sclerosis, neuropathies, neuromuscular disorders, and functional gait syndromes—gait disturbances are among the most disabling clinical features, contributing to falls, loss of independence, institutionalization, and premature mortality. Traditional bedside observation remains indispensable, but it lacks the sensitivity and reproducibility needed to capture subtle, episodic, or prodromal abnormalities. Over the past decade, advances in wearable sensors, marker-based and markerless motion capture, pressure-sensitive walkways, force plates, artificial intelligence, and machine learning have positioned digital mobility outcomes as promising, ecologically valid biomarkers of neurological function. These measures can support differential diagnosis, provide prognostic information on falls and survival, and serve as sensitive endpoints in therapeutic trials. They may also detect early abnormalities, such as increased stride-to-stride variability or prolonged double-support time, before overt clinical deterioration becomes evident. Clinical applications are increasingly evident across disorders, including distinguishing Parkinson’s disease from atypical parkinsonism, quantifying treatment response in normal-pressure hydrocephalus, tracking progression in ataxia and multiple sclerosis, predicting functional decline in motor neuron disease, and guiding rehabilitation after stroke. Integration with neuroimaging, electrophysiology, and molecular biomarkers is beginning to reveal the circuits underlying variability, instability, and freezing, positioning gait as a systems-level marker of neural integrity. Nevertheless, methodological heterogeneity, limited disease-specific validation, insufficient longitudinal data, and lack of consensus on clinically meaningful parameters continue to constrain translation. Cognitive, affective, and environmental influences also remain insufficiently represented in digital frameworks, while equity, accessibility, algorithmic bias, and privacy require careful ethical governance. Reconceptualizing gait as a “sixth vital sign” reframes mobility as a multidimensional biomarker of neural and systemic health. With harmonized protocols, robust validation, multimodal integration, and appropriate ethical frameworks, gait analysis could become a cornerstone of precision neurology. Full article

Oxygen (O₂) leakage in macrophyte rhizospheres is an adaptive strategy for hypoxic environments, which is important in lake ecological restoration. In this investigation, the fluorescent planar optode (PO) technique is used for two-dimensional (2D) distribution of dissolved O₂ at a submillimeter scale in the rhizosphere of Vallisneria spiralis under various environmental conditions. The spatial heterogeneity in the distribution of oxic microniches is frequently verified in the rhizosphere. The radial oxygen loss (ROL) rate for root systems is characterized by the following sequence: basal root (20.6 ± 5.1–49.6 ± 9.5 nmol m⁻² s⁻¹, n = 7) > lateral root (14.1 ± 4.1–36.6 ± 8.3 nmol m⁻² s⁻¹, n = 7) > root tip (13.1 ± 4.6–28.8 ± 6.4 nmol m⁻² s⁻¹, n = 7). The O₂ maximum value on lines transecting each kind of root also obeys the sequence mentioned above. For one typical root, (1) O₂ decreases from 131.2 ± 2.4–147.4 ± 3.7 μmol L⁻¹ at the root center to 47.2 ± 1.4–75.9 ± 2.2 μmol L⁻¹ in the rhizosphere fringe due to O₂ supply from the root surface and O₂ consumption in rhizosphere sediment, and (2) the furthest distance from the aboveground part to the root tip leads to the lowest O₂ concentration at the root apex of that root. The light/dark transition and O₂ level in overlying water modulate the photosynthetic activity of leaves and the transfer of oxygen in the water column through aerenchyma tissue to the roots. The sequence of the oxygenated area (%), ROL rate, and O₂ concentration in rhizosphere sediment under various conditions is demonstrated as: high illumination/high O₂ > darkness/high O₂ > high illumination/low O₂ > darkness/low O₂. The effect of O₂ in water on the ROL of Vallisneria spiralis is more distinct than illumination. Oxygen storage in roots, and especially O₂ diffusion from overlying water, can supplement O₂ deficiency in the rhizosphere during the cessation of photosynthesis under darkness. This research advances the understanding of complex interrelationships among O₂ dynamics in different root parts, photosynthesis, O₂ in overlying water and O₂ transfer through plant aerenchyma to the rhizosphere. Full article

Wesselsbron disease remains an underrecognized mosquito-borne flaviviral disease despite long-standing evidence of ruminant reproductive loss, neonatal disease, hepatic pathology, zoonotic infection, and mosquito-associated circulation. This narrative review critically synthesizes verified evidence on Wesselsbron virus (WSLV) at the animal–human–vector–environment interface, with the specific aim of clarifying why the virus should be considered a surveillance-sensitive One Health pathogen rather than a rare veterinary curiosity. The review integrates classical veterinary pathology, experimental infection studies, human case reports, serological and molecular evidence, mosquito surveillance, ecological suitability modelling, diagnostic-development studies, and recent evidence from molecular epidemiology, camel investigations, and digital histopathology. The review uses an evidence-weighted synthesis to distinguish experimentally and pathologically supported animal disease, confirmed but poorly quantified human infection, mosquito-associated detection, ecological suitability, diagnostic under-recognition, and unresolved reservoir or transmission questions before integrating these domains into a qualitative One Health risk-assessment framework. The evidence supports WSLV as a cause of ruminant abortion, neonatal disease, and hepatic lesions, confirms zoonotic potential, and indicates repeated detection in ecologically relevant mosquito and multi-host contexts. However, current data remain insufficient for robust estimates of animal burden, human incidence, reservoir competence, natural route frequency, or climate-driven expansion. WSLV should therefore be incorporated into targeted differential diagnosis, laboratory readiness, and One Health surveillance where ruminant abortion events, unexplained neonatal disease, compatible mosquito ecology, undiagnosed febrile illness, diagnostic ambiguity, or ecological suitability indicate plausible risk. Full article

Transitional waters—such as estuaries, lagoons, deltas, and coastal wetlands—are dynamic environments where freshwater and seawater interact, forming highly productive and biologically diverse ecosystems. Shaped by temperature and salinity gradients, tidal influence, sediment transport, and nutrient-rich conditions, these habitats support diverse ecological functions. Their structural complexity—including seagrass beds, salt marshes, mudflats, and mangroves—provides essential habitats for many fish species. These areas are crucial for fish life cycles, serving as nurseries, spawning grounds, feeding zones, and refuges from predators. Many commercially important species depend on them during early life stages before moving offshore, making them vital for both commercial and recreational fisheries. Beyond food provision, they deliver key ecosystem services, including water purification, coastal protection, and carbon storage. Research on the fish community of the Ria Formosa lagoon in Portugal since the 1980s highlights long-term changes in the fish community and the dominant role of habitat structure and temporal dynamics. Subtidal seagrass beds support higher fish abundance and diversity than unvegetated areas, acting as key nursery habitats and provide important fish provisioning services. Seasonal variation is also central, driven by recruitment pulses of marine migrants in late winter–spring. Recent pressures on this system have been driven by human activity and environmental change. Seagrass loss reduces nursery and feeding areas, while pollution degrades water quality. Overfishing (including illegal fishing), recreational activities, and aquaculture expansion add stress. Climate warming and invasive species such as Caulerpa prolifera, further disrupt ecosystem balance and threaten biodiversity. Sustainable management—such as habitat restoration, protected areas, and integrated policies—is essential to preserve the ecological and economic value of this unique lagoon. Ongoing research, monitoring, habitat restoration, and stakeholder engagement remain critical for ensuring resilience. Full article

Currently, in Catalonia, Spanish toothcarp (Apricaphanius iberus) has a discontinuous distribution, with its main populations located in the Ebro Delta and the Empordà wetlands. Along the Catalan coast, there are some small, isolated populations, most of which have been recently introduced. In the Empordà area, this species still maintains three isolated populations within two natural parks, where it currently occupies the northernmost site of its global distribution. Between 2017 and 2025, several fish sampling campaigns were carried out in the Empordà wetlands (Northeast Catalonia), gradually covering the entire area of potential distribution of this species in the area. In total, 228 points have been sampled, at least in one occasion, in all types of water bodies (rivers, canals, lagoons, marshes). In 106 points, more than two sampling events have been performed. Furthermore, in 2025, a specific diagnosis was carried out to better understand the current situation of the species in these protected spaces after a prolonged and severe drought. Sampling was carried out everywhere with fykenets, adding the use of nets and electrofishing in some stations located in large bodies of water. The known historical evolution of Spanish toothcarp distribution in the Empordà has been presented since the first data was made available at the beginning of the 1980s of the 20th century until now. Today, this fish only occupies approximately 10% of its potential distribution in the area. Over the last five decades, its distribution has expanded and contracted several times, but in 2025, it was once again in the worst possible situation of the analysis period. Therefore, the implementation of protected areas, or the execution of several large ecological restoration projects, have only succeeded in maintaining existing populations, but not in the expansion of its potential distribution to unoccupied areas. The main factors that explain this general situation are mainly (1) the proliferation of exotic species, (2) the loss of ecological status, and (3) hydrological alterations and increasingly severe droughts. Thus, the recovery and long-term conservation of Spanish toothcarp in the Empordà area inevitably requires the implementation of more extensive and decisive measures to reverse the incidence of these factors. Full article

Ecological degradation is accelerating worldwide, yet the losses of species, ecosystems, and landscapes often remain socially and culturally unmourned. This article explores how contemplative ecology may offer a pathway for engaging with ecological grief. Drawing on the case study of Lab Landschapspijn Veluwe in the Netherlands, it examines how contemplative practices—such as contemplative dialogue and contemplative walking—can help participants attune to ecological loss in degraded landscapes. Using heuristic inquiry and interpretative phenomenological analysis, the study investigates how participants perceive and articulate tangible ecological losses and their emotional, moral, and spiritual dimensions. The findings show that contemplative practices can function as forms of contemplative witnessing, making ecological loss more perceptible, grievable, emotionally acknowledged, and relationally processed. Contemplative practices may foster an open-ended engagement with ecological loss; an orientation that allows grief, wonder, uncertainty, and care to coexist without demanding immediate resolution. Therefore, contemplative ecology may cultivate the emotional, existential and relational capacities required to remain engaged with ecological crisis. Full article

The Iberian barbel (Luciobarbus bocagei Steindachner, 1864) is a potamodromous species that displays migratory movements, with adults moving upstream during spring to spawn, followed by downstream migration in autumn by both adults and juveniles to feed and inhabit more productive river stretches. Increasing river fragmentation due to dam construction and operation causes a loss of connectivity and suitable habitat, which can affect this natural behaviour. In a tributary of River Douro, River Tua, a 108 m high dam, was recently built (i.e., Foz Tua dam in 2017) at only 1.1 km from the river mouth, leaving the upstream spawning area inaccessible. To evaluate the species behavioural response to this impact, a passive acoustic telemetry array was deployed in the study area, and between 2018 and 2023, 120 tagged fish had their movements tracked. The results showed two different behavioural profiles in the same population with migratory (42.5%) and resident (54.0%) individuals. During this period, a specific experimental study was developed to evaluate the response of a subset of 90 fish, captured upstream of the Foz Tua dam and translocated to an alternative downstream Douro tributary (River Pinhão, ~20 km downstream from River Tua). From these, 66.7% remained at the release site, whilst 23.3% returned to the river of origin, i.e., River Tua. From the returned fraction, 28.6% of the tagged fish maintained this migratory behaviour between both rivers in the following years. Generalized Additive Models were used for each of the two behavioural profiles observed in this study, to identify which environmental variables were associated with the presence of the tagged barbels downstream the Foz Tua dam. Ecological flow, temperature and day-period were some of the predictors explaining the use of this river stretch downstream of Foz Tua dam. This study substantially updates the available information regarding this species’ movement patterns at large spatial and temporal scales, contributing to enhancement of management and conservation programs for potamodromous species, in highly impounded and fragmented rivers. Full article

Introduction: Aquatic chemical pollution is among the most worrying threats to ecosystem health. There is an ever-increasing variety of pollutant substances detected across the source-to-sea continuum, causing loss of biodiversity and ecological disequilibrium. Achieving cleaner and healthier systems relies on carrying out sustained, cost-effective, diagnosis and aquatic effects monitoring, within the adaptive management cycle. The available methods are, however, cumbersome, which creates a clear need for innovative expeditious approaches for low-cost surveillance monitoring. In the last decade, Raman Spectroscopy (RS) has gained wide recognition for application to biological questions, for its ability to uncover the complexity of molecules and their interactions. Various fields, from pharmacology to disease diagnosis and prognosis, have suffered an innovation revolution through the application of RS. In this technique inelastic light scattering of a small part of photons of an incident electromagnetic monochromatic light beam (ranging from near-infrared to visible or ultraviolet) is caused by the molecular vibration of chemical bonds. This results in shifts in energy, which indicate discrete vibrational modes of polarisable molecules, providing qualitative and quantitative assessments of the chemical composition and molecular structure of the sample. The technique shows high sensitivity, no need for sample preparation and the possibility of use in non-invasive and label-free analysis. Objective: The aim of this work is to present and discuss evidence about the application of Raman Spectroscopy (RS) to environmental diagnosis and aquatic effect monitoring of pollution. Methodology: The technique was applied to different biological models, i.e., diatoms, zebrafish embryos and larvae and freshwater snails. Quality assessments with diatoms were tested in environmental monitoring, while assessments with other models were done upon exposure to metals and organic contaminants. Results and conclusions: The Raman spectra obtained from the samples analysed comprised bands detected within the 800 to 2000 cm⁻¹ wavenumber range. These were related to bond vibrations of carbohydrates, DNA phosphate groups, proteins or CH, NH and OH stretching in lipids and proteins. Data analysis using chemometric methods clearly distinguished pollutant exposure from control sites or treatments, pointing out the potential for surveyance monitoring. The next steps include the comparison with other sensitive methods (e.g., locomotion and avoidance behaviours, omics methods) to assess efficiency and bring further mechanistic understanding. Full article

Deoxynivalenol (DON) is a prevalent trichothecene mycotoxin in cereals that poses food and feed safety risks while causing important economic losses. Microbial biotransformation offers a selective, mild strategy for DON detoxification. Here, we screened aerobic soil-derived bacterial communities from diverse agricultural environments, using DON as the sole carbon source for this mycotoxin depletion. More than half of the tested enrichment samples showed a reduced DON signal, as observed by HPLC-UV. To assess the biological relevance, culture extracts were tested for cytotoxicity in HepG2 cells. Z13, a soil sample that depleted DON but produced no other detectable metabolites, showed reduced cytotoxicity, comparable to the negative control. In contrast, samples that depleted DON but produced 3-keto-DON remained toxic. High-resolution LC-MS analysis indicated the formation of metabolites putatively identified as 3-keto-DON in enrichment cultures and 3-epi-DON in a Devosia strain culture. Community composition was profiled with 16S rRNA gene amplicon sequencing, which showed that Z13 presented a remarkable drop in diversity upon microbial cultivation, and included genera such as Devosia, Nocardioides, and Pseudomonas. Together, these results provide integrated chemical, biological, and ecological evidence for aerobic DON biotransformation in soil-derived communities, identify pathway products, and highlight practical constraints related to community dependence and storage sensitivity. Full article

Rapid urbanization, climate change, and biodiversity loss are intensifying environmental pressures on arid coastal cities through extreme heat, water scarcity, salinity intrusion, and increasing flood risks. Despite substantial investment in urban green spaces across the Gulf region, many public parks provide limited ecological functionality and climate adaptation benefits. This study evaluated the ecological performance of three coastal parks in Muscat, Oman Sarooj Beach Park (23,080 m²), Ghubrah Beach Park (34,818 m²), and Al Athaiba Beach Park (17,370 m²), to identify opportunities for more resilient landscape design. The assessment revealed that although green space occupied 76.8–82% of park areas, tree canopy cover remained low (8–12%), limiting thermal comfort, habitat provision, and ecological performance. Based on these findings, a Functional and Climate-Responsive Planting Strategy (FCRPS) was developed by integrating the 10–20–30 biodiversity guideline with performance-based planting criteria tailored to arid and saline environments. The framework was applied to the proposed Majis Beach Ecological Park in Sohar, Oman, to demonstrate the implementation of ecological urbanism and nature-based solutions in a hyper-arid coastal environment. The resulting design incorporates biodiversity-enhancing planting, blue–green infrastructure, wetland restoration, and climate-responsive spatial planning. The study demonstrates how multifunctional landscapes can enhance biodiversity, improve thermal comfort, strengthen stormwater management, and support community well-being while providing a transferable framework for resilient public park design in arid coastal cities. Full article

Anemia represents one of the most frequent systemic complications of inflammatory bowel disease (IBD), with a consistently higher prevalence reported in patients with Crohn’s disease (CD) compared with ulcerative colitis (UC). While chronic inflammation, impaired iron absorption, and intestinal blood loss are recognized contributors, microbiome-mediated mechanisms influencing host iron availability remain insufficiently explored. Emerging evidence indicates that CD-associated dysbiosis is characterized by an increased abundance of siderophore-producing bacteria, particularly members of the Enterobacteriaceae family. Because siderophores are high-affinity iron-chelating molecules capable of competing with host iron acquisition systems and partially escaping lipocalin-2-mediated sequestration, their expansion may contribute to reduced luminal iron bioavailability. In this systematic review, we analyzed comparative microbiome studies published between 2016 and 2026 that directly evaluated microbial differences between CD and UC. CD microbiota consistently demonstrated enrichment in siderophore-associated taxa relative to UC. Based on these findings, we propose that microbiome-driven iron competition may represent an additional mechanistic contributor to the increased prevalence and persistence of anemia observed in CD. Although direct in vivo quantification of siderophore activity in IBD remains limited, the convergence of ecological, functional, and strain-level microbiome evidence supports a biologically plausible interaction between microbial iron-scavenging strategies and host iron metabolism. Full article