Search Results (1,092)

Understanding the motivational factors influencing student teachers’ self-efficacy in adopting Artificial Intelligence (AI) is essential in technology-driven learning environments, but this area has received less research attention in resource-scarce settings like Ethiopia. To this end, this study was initiated to explore the motivational factors influencing the self-efficacy in adopting AI among Ethiopian student teachers. The study employed structural equation modeling to analyze data collected from 278 student teachers enrolled in teacher education programs to determine the relationship between motivational factors (commitment to the teaching profession, along with intrinsic, extrinsic, and altruistic motivations) and dimensions of self-efficacy (teaching AI skills, planning and classroom management, and student affective domains). The result demonstrated that strong and positive associations were found between affective commitment to teaching and self-efficacy (p < 0.01) in AI teaching skills, planning and managing the classroom, and addressing the student affective domain. In addition, positive and moderate associations were noted between extrinsic motivation and self-efficacy (p < 0.05) in the student affective and teaching AI skills domains. No significant relationships were observed for intrinsic or altruistic motivations. Thus, by highlighting the role of commitment and extrinsic motivation, the findings can inform teacher education programs aiming to enhance the holistic development and effectiveness of future educators and contribute to developing targeted recruitment and training strategies that nurture motivated and technologically proficient teachers. Full article

In this paper, we present the result of the study conducted on aging tests carried out by the artist Emile Claus (1849–1924), composed of oil paint samples from three manufacturers: Blockx, Lefranc Bourgeois and Fritz Behrendt. These colors were applied neat and mixed with white on wooden panels prepared with white ground layer. A non-invasive analytical protocol, combining imaging techniques and physico-chemical analyses, was used to characterize potential differences between manufacturers for nominally identical colors. The differences highlight in this study include variations in nickel content in cobalt blue colors and aluminum content in madder lakes. It also discusses the intrinsic and extrinsic factors that led to the degradation of certain colors. Hyperspectral imaging further demonstrated that the addition of lead white induces a systematic shift of spectral inflection points toward shorter wavelengths, consistent with the optical dilution effect in pigment-white mixtures, while the altered colors do not follow the same trend. Full article

This study is a narrative review of natural killer (NK) cells in Behcet disease (BD). BD is an inflammatory disorder with manifestations in mucosal tissues. Unlike autoimmune diseases that generate autoantibodies, BD is believed to be an autoinflammatory disease triggered by innate immune cells rather than adaptive cells. Hyperactivation of neutrophils causes vasculitis and thrombosis, and they migrate into cutaneous and ocular lesions. Dominance of M1 macrophages promotes the differentiation of Th1 cells. Moreover, the cross-reaction of bacterial heat shock proteins induces production of cytokines such as IL-4 and IFN-γ in γδT cells, which alters the balance between Th1 and Th2 phenotypes. Nevertheless, NK cells play more critical roles in BD pathogenesis than other innate immune cells because not only is their activity precisely controlled by the interaction between ligands and receptors, but NK1 shift also elicits Th1 dominance. The genetic factors associated with BD are HLA-B51 and major histocompatibility complex class I-related chain A (MICA), which stimulate NK receptors as ligands. Improperly processed peptides dysregulate their interaction with NK receptors, triggering the inflammatory response. NK1 and NK2 subsets represent cytokine production in relapse and remission periods; however, the cytotoxicity of NK cells in relapse is lower than that in remission periods. It still remains unclear how NK cells are activated recurrently and expand cytokine production. This review highlights the regulation of gene expression encoding NK receptors, tissue-resident NK cells, and adaptive NK cells to discuss their potential for relapse. Splicing variants and readthrough genes encoding NK receptors easily alter cytokine production. Moreover, tissue-resident NK cells in mucosal tissues and adaptive NK cells that memorize the virus infection have the potential to trigger hyperactivation in relapse. Full article

Tick-borne encephalitis virus (TBEV) is a major arthropod-borne flavivirus responsible for severe neurological disease in humans across Europe and Asia. It is maintained in nature through complex interactions within ticks and between tick vectors, vertebrate hosts and environmental factors. This review summarizes current knowledge on TBEV–tick interactions, focusing on virus acquisition, dissemination, vector competence, and long-term persistence within tick vectors. TBEV is acquired by ticks during blood feeding on viremic hosts or through co-feeding transmission under experimental conditions. Transovarial transmission has also been reported, as indicated by the detection of infected larvae in nature, although its efficiency appears to be low and variable. Following ingestion, TBEV infects and replicates in the tick midgut before dissemination via the hemolymph to secondary tissues, including the salivary glands and reproductive organs, which are essential for viral persistence and transmission. Vector competence and capacity vary between tick species and are shaped by intrinsic and extrinsic factors. Although transstadial transmission and transovarial transmission contribute to long-term virus maintenance, their efficiency is generally low and variable. In vitro models, including tick cell lines, have provided valuable insights into virus–tick interactions. Nevertheless, important knowledge gaps remain, particularly in understanding early events at the tick–host interface and mechanisms underlying viral dissemination and persistence within ticks. Full article

A semi-distributed interferometer is a low-reflectivity device with refractive index sensing capability, exploiting the random reflectivity of a nanoparticle-doped fiber to form a weak distributed cavity. In this work, we extend this concept to an extrinsic semi-distributed interferometer (ESDI), using an overlay made of polydimethylsiloxane (PDMS) around the fiber tip; this structure can then be surface-modified using a thin metallic film or a nanoparticle coating. We report gold-sputtered and gold-nanoparticle-coated ESDI structures for refractive index sensing capability, with the latter achieving superior performances with an average sensitivity of 62.8 dB/RIU (refractive index units) with resolution of 3.9 × 10⁻⁵ RIU over the range of 1.34790–1.35981. We also report a possible biological application using a biofunctionalized version of this probe for the detection of VEGF (vascular endothelial growth factor); the gold-sputtered probe achieves the highest sensitivity, 0.0565 dB for each 10× concentration increase, with 355 fM detection limit. Full article

Geosites in the Safi Province in Morocco are increasingly exposed to a combination of natural and anthropogenic factors (landslides, karstification, pollution, improper visitor behavior, etc.) that threaten their integrity and accelerate their degradation. Assessing geoheritage degradation risks is therefore a fundamental step in any geoconservation strategy, particularly given the growing impacts of climate change on Morocco’s Atlantic coastline. This study proposes a quantitative methodology for evaluating degradation risk by integrating extrinsic factors that can damage geosites. The methodology was applied to the Safi Province, an area characterized by exceptional geological diversity—ranging from coastal cliffs and marine terraces to karst systems, Quaternary deposits, and paleontological and archaeological sites of international significance such as Jbel Irhoud. Three main criteria were used to assess degradation risk: anthropogenic vulnerability, public use, and natural vulnerability, each supported by a set of detailed parameters enabling precise numerical evaluation. The results show that degradation risk in Safi’s geosites is primarily driven by a lack of awareness of and recognition of their geological importance, leading to public misuse, inadequate management, uncontrolled access, and unregulated extraction. Moreover, the region’s strong coastal dynamics amplify natural vulnerability, especially at geosites along exposed cliffs, beaches, and estuarine environments. Overall, the findings provide a comprehensive assessment of the condition of Safi’s geosites and constitute a valuable tool for the planning, prioritization, and implementation of effective protection and management measures, particularly in the face of increasing pressures associated with climate and environmental change. Full article

Background: TV-44749 is a subcutaneous (sc) long-acting injectable (LAI) formulation of olanzapine that recently demonstrated efficacy and safety as a treatment for schizophrenia in adults without the occurrence of post-injection delirium/sedation syndrome (PDSS) in the phase 3 SOLARIS trial (NCT05693935). TV-44749’s sc route of administration and formulation were designed to provide prolonged olanzapine release over a monthly dosing interval and to avoid the risk of post-injection delirium/sedation syndrome (PDSS). It was designed as a copolymer in situ-forming depot technology to provide a LAI formulation that could withstand physiological and environmental factors that could affect controlled-release kinetics. Methods: To evaluate the robustness of the TV-44749 formulation, an in vitro release (IVR) study in human plasma was conducted, comparing TV-44749 to the commercially available intramuscular (im) long-acting injection formulation of olanzapine pamoate monohydrate. In addition, in vivo studies in rats were conducted to assess the effect of injection site manipulation following TV-44749 sc injection on olanzapine release from the depot. Results: The IVR study showed that upon contact with human plasma, copolymers comprising TV-44749 formulation instantly precipitate and form a solid matrix that entraps olanzapine particles. This prevents an uncontrolled release of olanzapine. Additionally, in vivo rat studies found that manipulation of the injection site after TV-44749 administration, by either heating or rubbing at different time-points, resulted in no meaningful effect on overall olanzapine exposure. Conclusions: The presented findings support the robustness of the TV-44749 formulation in maintaining controlled-release properties, even under conditions that could otherwise compromise release performance. Full article

Colorectal cancer (CRC) is a significant global health concern, ranking as the third most frequently diagnosed cancer and the second leading cause of cancer-related deaths. Advances in screening, such as the implementation of liquid biopsies (LB), have improved early detection, thus enhancing survival rates. This review summarizes the multifaceted nature of CRC, focusing on its genetic background, the complex tumor microenvironment, and the influence of gut microbiota, nutrition, and metabolic alterations. The development of CRC is influenced by various risk factors, including age, genetics, chronic diseases, and lifestyle choices. The genetic heterogeneity of CRC defines distinct molecular subtypes, characterized by different treatment responses and patient prognoses. Chronic inflammation and dysbiosis in the gut microbiota further contribute to CRC pathogenesis. In addition, nutritional factors play a crucial role in CRC, affecting carcinogenesis and treatment efficacy through direct interaction with the immune system and microbiome. Current therapeutic strategies include surgical interventions, chemo- and radiotherapy, targeted therapies, immunotherapy as well as dietary interventions, and microbiome modulation, highlighting the challenges posed by tumor heterogeneity and treatment resistance. In sum, a comprehensive understanding of CRC’s intrinsic and extrinsic drivers, including genetic, metabolic, and dietary influences, is essential for developing personalized treatment strategies and improving patient outcomes. Full article

B cells, an important component of adaptive immunity, play a key role in defense against a variety of infections and diseases including cancer. B cells play a dual role in cancer, contributing to both anti-tumor immunity and tumor progression. Metabolic reprogramming in the TME has a profound impact on B cell dynamics, reshaping their energetic landscape, influencing their differentiation and effector cell functions. These alterations arise from the complex interplay between intrinsic metabolic pathways and extrinsic factors, such as nutrient availability, hypoxic conditions, and tumor-derived signals. In the TME, B cells promote glycolysis over oxidative phosphorylation (OXPHOS) to meet the high energy demands of activation and proliferation. However, this metabolic plasticity is also mimicked by tumors, leading to dysfunctional B cell phenotypes, such as regulatory B cells (Bregs), which suppress anti-tumor immunity. Nutrient deprivation and accumulation of metabolic byproducts, including lactate, further impair B cell-mediated immune responses. This review highlights the complex interaction between B cell metabolism and cancer, emphasizing the effects of altered energetics on B cell function and implications on tumor progression and therapy. Decoding the metabolic vulnerabilities of B cells in the tumor niche can uncover novel therapeutic strategies against cancer. Full article

Pancreatic ductal adenocarcinoma (PDAC) is characterized by a dense stromal microenvironment and profound hypoxia, which contribute to therapeutic resistance. Using an in vitro system incorporating pancreatic cancer cells and cancer-associated fibroblasts (CAFs), we show that hypoxia suppresses CD8⁺ T cell accumulation and, in combination with cancer cell- and CAF-derived factors, further impairs T cell fitness by increasing cell death and reducing proliferation. Although the combination of hypoxia and cancer cell/CAF-derived factors enhances IFNγ and granzyme B expression in CD8⁺ T cells on a per-cell basis, the overall number of functional effector T cells is markedly reduced. Analysis of human PDAC single-cell RNA sequencing data corroborates these findings, revealing that CD8⁺ T cells enriched for hypoxia signatures exhibit elevated apoptosis and stress-response pathways. Furthermore, hypoxia is associated with downregulation of stemness-related genes and upregulation of terminal differentiation markers. Together, these data suggest that the integration of intrinsic hypoxic responses and extrinsic cues from tumor cells and CAFs impairs CD8⁺ T cell fitness and correlates with a terminally differentiated, dysfunctional T cell state. Full article

The construction industry is one of the most hazardous occupational sectors globally, with persistently high rates of worker injuries and fatalities. This study examined the association between safety motivation and safety climate among construction workers, addressing a critical gap in understanding their bidirectional relationship. A cross-sectional survey was administered to 922 construction workers across multiple commercial projects within a single U.S. state, yielding 383 valid responses (41.5% response rate). The survey instrument measured safety motivation types (intrinsic, extrinsic, and negative) and multiple safety climate dimensions, including leadership and communication, safety procedures and training, peer support, recognition, and equipment availability. The results revealed that safety motivation demonstrated a significant positive correlation with overall safety climate (r = 0.467, p < 0.01), with leadership and communication showing the strongest association (r = 0.514, p < 0.01). Analysis of motivation types indicated that negative motivation (fear of accidents) predominated (41%), followed by extrinsic (34%) and intrinsic motivations (25%). The findings support a reciprocal relationship wherein safety motivation and safety climate mutually reinforce one another, influencing safety performance and outcomes. The study highlights the need for safety interventions that simultaneously address organizational climate factors and diverse individual motivational pathways to improve safety performance in the construction industry. Full article

Skin aging is driven by both intrinsic and extrinsic factors, including ultraviolet (UV) radiation and environmental stressors. Tumor necrosis factor-alpha (TNF-α) is a key pro-aging cytokine that promotes reactive oxygen species (ROS) production, leading to collagen degradation and inflammatory responses in skin cells. In this study, we investigated the protective effects of Prunus persica flower extract and its major constituents (1–4) against TNF-α–induced oxidative and inflammatory responses in human dermal fibroblasts (HDFs) and human epidermal keratinocytes (HEKs). In HDFs, the extract and isolated compounds significantly suppressed TNF-α–induced ROS generation and matrix metalloproteinase-1 (MMP-1) secretion while enhancing collagen synthesis. Notably, mandelamide (4) markedly reduced MMP-1 secretion (from 7.53 ± 0.28 to 2.97 ± 0.12, p < 0.001) and restored collagen levels (from 3.3 ± 0.03 to 19.1 ± 0.58, p < 0.001). In HEKs, mandelamide attenuated the production of inflammatory mediators under TNF-α stimulation and further suppressed MMP expression while restoring the mRNA expression of hyaluronan synthase genes under TNF-α/ interferon-γ (IFN-γ) co-stimulation. Importantly, mandelamide exhibited selective activity under inflammatory conditions without affecting basal cellular states. Collectively, these findings demonstrate that mandelamide is a key bioactive constituent of Prunus persica (P. persica) flowers and exerts protective effects against inflammation-associated skin aging through the modulation of oxidative stress and extracellular matrix homeostasis. Full article

Background: Blood flow restriction training (BFRT) is a low-load resistance training modality capable of inducing muscle hypertrophy and strength adaptations that are comparable to traditional high-load resistance training. Beyond athletic performance settings, BFRT has growing relevance for musculoskeletal health, rehabilitation and populations unable to tolerate high mechanical loads. However, substantial inter-individual variability in adaptive responses has been reported. Genetic and molecular factors may partly contribute to this variability and inform more individualised exercise strategies. Other intrinsic and extrinsic factors, including age, sex, training status, nutrition, and protocol-related differences, may also influence adaptive responses. Objective: This scoping review aimed to map available evidence on molecular modulators of adaptation to BFRT and to identify gaps in the literature regarding genetic influences on BFRT responses. Methods: A structured search of PubMed, Web of Science and Google Scholar was conducted till 1 February 2026. Experimental and quasi-experimental studies examining BFRT in relation to genetic polymorphisms, gene expression, and molecular signalling pathways associated with strength and hypertrophy outcomes were included. Primary outcomes were genetic and molecular factors relevant to BFRT adaptation, including genetic polymorphisms, gene expression, and molecular signalling markers. Secondary outcomes included muscle strength, hypertrophy, vascular responses, and related functional outcomes where reported. Study selection and data extraction were conducted according to PRISMA-ScR guidelines. The methodological quality of randomised controlled trials was assessed using the PEDro scale. This scoping review was registered retrospectively in the Open Science Framework on 17 March 2026, after completion of the literature search. Results: From an initial 47 records, only three studies (n = 3) met the inclusion criteria. The included studies reported molecular responses associated with BFRT, including downregulation of proteolytic genes, suppression of myostatin expression, and upregulation of angiogenic markers. Notably, no studies directly examined genetic polymorphism or genotype–BFRT interactions, highlighting a clear need for these studies in this field. Conclusions: This scoping review therefore identifies a critical evidence gap, with genotype-informed BFRT prescription remaining unsupported by the current literature. Limited evidence supports the possible role of BFRT in molecular responses associated with muscle adaptation. Future research should prioritise well-designed studies integrating both genetic and molecular analyses to better understand inter-individual variability in BFRT adaptations. Full article

The retina is a complex sensory neural tissue composed of six major types of neurons and one type of glial cell. The cell fate specification of retinal cells is tightly governed by intrinsic factors and extrinsic microenvironmental cues. Among the key regulators directing retinal cell fate differentiation is a group of bHLH family transcription factors (TFs). Our previous work demonstrated that the bHLH TF Ngn3 exhibits robust potential to induce retinogenesis in both distantly related fibroblasts in vitro and late retinal progenitor cells (RPCs) in vivo. However, the underlying molecular mechanisms remain largely elusive. In this study, we combined immunohistological examination and RNA-seq and ATAC-seq analyses to investigate the cellular and molecular mechanisms governing Ngn3-driven retinogenesis in late RPCs. Our results revealed that Ngn3 overexpression promotes premature cell cycle exit in late RPCs and remodels their transcriptomic and epigenomic landscape towards a state favoring rod photoreceptor and RGC differentiation. Furthermore, cross-comparison with Ngn3-overexpressing fibroblasts in vitro revealed cell-type-specific mechanisms underlying Ngn3-mediated neuronal fate reprogramming. These findings advance our understanding of Ngn family-mediated retinal cell fate regulation and provide a mechanistic framework for optimizing Ngn3-based retinal regeneration strategies for the treatment of retinal degeneration diseases. Full article

Milk production in dairy herds is determined by both intrinsic and extrinsic factors, with reproductive efficiency serving as a primary determinant. Infectious, nutritional, and management-related challenges can reduce this efficiency. Following parturition, cows are more susceptible to clinical disorders due to a temporary loss of integrity in the cervix, vagina, and vulva, which allows environmental bacteria to ascend and alter the vaginal microbiota. These microbial changes may disrupt endocrine responses related to conception and contribute to repeat breeder cow syndrome (RBCS), which is defined as failure to conceive after three or more inseminations. This study investigated associations among cultivable vaginal bacteria, circulating progesterone and glucose concentrations, and reproductive performance in 30 fourth-parity Holstein cows with a body condition score of 3.5. Cows were classified by reproductive history as repeat breeders (RBCS; n = 14) or controls (CTL; n = 16). Vaginal mucosal samples were collected at insemination and cultured on blood agar and MacConkey media under aerobic and microaerobic conditions. Bacterial identification was conducted using Gram staining and standard biochemical assays. Blood samples were collected at insemination, on day 5 post-insemination, and every two days thereafter to measure progesterone and glucose concentrations. Fertility outcomes were analyzed using PROC GLIMMIX, and hormonal data were analyzed using mixed models with repeated measures. The bacterial genera identified included Bacillus, Escherichia coli, Staphylococcus, Klebsiella, Proteus, Streptococcus, and Actinomyces. Progesterone and glucose concentrations did not differ significantly between groups (p > 0.05). However, the fertility rate (p < 0.05; CTL:87.50% vs. RBCS:57.14%) and number of attempts to conceive (p < 0.001; CTL:2.5 vs. RBCS:6.7) differed statistically between treatments. A higher prevalence of S. hyicus was detected in RBCS cows, and E. coli, S. hyicus, and Proteus spp. were more frequently detected in non-pregnant cows. These findings suggest that the identified cultivable vaginal bacteria are associated with reproductive status in dairy cows. Full article