Search Results (17,661)

Obesity is a major global health challenge that substantially affects vitamin D metabolism and status. Numerous studies have consistently demonstrated an inverse relationship between body fat and serum 25-hydroxyvitamin D [25(OH)D] concentrations. Emerging evidence suggests that lower serum 25(OH)D in obesity largely reflects altered distribution and metabolism rather than a uniform state of true functional deficiency. Adipose tissue functions both as a storage compartment and as a metabolically active organ capable of modulating vitamin D handling. Mechanisms include the sequestration of vitamin D in fat, volumetric dilution across a larger body mass, and the local expression of enzymes involved in vitamin D metabolism. As a result, obese individuals typically exhibit a blunted increase in serum 25(OH)D in response to supplementation, consistent with altered pharmacokinetics and increased distribution volume. Weight loss, particularly the reduction in visceral fat, is associated with modest increases in circulating 25(OH)D, further supporting a distribution-based mechanism. Although low 25(OH)D levels in obesity have been linked to insulin resistance, inflammation, and metabolic syndrome, randomized controlled trials have not consistently demonstrated that supplementation improves clinically relevant outcomes in this population. Meta-analyses confirm that the increase in serum 25(OH)D after supplementation is smaller in obese individuals, indicating that higher doses are often required to achieve comparable levels to those in normal-weight subjects. Obesity thus represents a major determinant of vitamin D deficiency, highlighting the need for individualized supplementation strategies alongside weight management. Understanding the mechanistic basis for low 25(OH)D in obesity is essential for distinguishing true deficiency from altered distribution, informing clinical decisions, and optimizing interventions to maintain adequate vitamin D status and support metabolic health. Full article

Liquid biopsy (LB) offers a minimally invasive approach to characterizing and monitoring glioblastoma (GB), a tumor marked by extensive heterogeneity, limited surgical accessibility and rapid molecular evolution. By analyzing circulating tumor-derived components such as circulating tumor DNA (ctDNA), extracellular vesicles (EVs), circulating RNA species and circulating tumor cells (CTC), LB provides dynamic molecular information that cannot be captured by neuroimaging or single-site tissue sampling. Cerebrospinal fluid (CSF) currently yields the highest sensitivity for detecting tumor-specific alterations, while plasma enables repeat monitoring despite lower biomarker abundance. EVs have gained particular prominence due to their ability to preserve DNA, RNA, and protein cargo that reflects key genomic changes, treatment resistance mechanisms, and immune evasion. Although advances are substantial, clinical implementation remains constrained by low analyte concentrations, methodological variability, limited standardization and the high cost of testing, which is rarely reimbursed by insurers. This review summarizes current evidence on circulating biomarkers in GB and highlights research priorities essential for integrating LB into future diagnostic and therapeutic workflows. Full article

Background: Infections in hand surgery represent a clinically relevant complication, particularly in trauma-related procedures and in the presence of internal fixation devices. Data specifically addressing microbiological profiles and antimicrobial resistance patterns in hand surgery remain limited. Methods: A monocentric retrospective observational study was conducted, including 72 patients treated for hand surgery infections between January 2024 and June 2025. Microbiological isolates and antimicrobial susceptibility profiles were analyzed and stratified according to the clinical scenario, including trauma-related infections and infections associated with internal fixation devices. Monomicrobial and polymicrobial infections were evaluated separately. Results: Trauma-related infections accounted for 77.8% of cases, of which 64.3% were monomicrobial and 35.7% polymicrobial. Monomicrobial trauma-related infections were predominantly caused by Staphylococcus aureus, with methicillin resistance detected in 25.0% of cases. Polymicrobial trauma-related infections showed greater microbiological complexity but limited antimicrobial resistance. Infections associated with internal fixation devices represented 22.2% of cases and demonstrated a higher proportion of polymicrobial infections. Across all subgroups, no extended-spectrum beta-lactamase–producing Enterobacterales or carbapenem-resistant organisms were identified. Conclusions: This study fills an important evidence gap by characterizing pathogens and antimicrobial resistance in a dedicated hand surgery cohort, an area where published microbiological data remain limited compared with other orthopedic subspecialties. Hand surgery infections exhibit distinct microbiological and resistance profiles depending on the clinical scenario and microbial complexity. Despite frequent polymicrobial involvement, high-level antimicrobial resistance remains uncommon, supporting the value of local microbiological surveillance to guide empirical therapy. Full article

The rapid global spread of antimicrobial resistance (AMR) has significantly reduced the effectiveness of many modern antibiotics, creating an urgent need for alternative therapeutic strategies. One promising approach is the revival and repurposing of older antimicrobial agents whose clinical potential was previously limited by toxicity concerns, pharmacokinetic challenges, or the availability of newer drugs. Recent advances in drug delivery, dosing optimization, and antimicrobial stewardship have renewed interest in these compounds as viable options for the treatment of multidrug-resistant infections. The aim of this review is to provide a comparative, clinically oriented analysis of selected “old” antibiotics, fosfomycin, colistin, streptomycin, and vancomycin, with emphasis on their current therapeutic roles, pharmacokinetic/pharmacodynamic (PK/PD) targets, toxicity mitigation strategies, resistance mechanisms, and evidence supporting combination therapies and alternative routes of administration. This narrative review was conducted using a structured PubMed search and manual reference screening, focusing on clinical, PK/PD, and translational studies relevant to the contemporary use of legacy antibiotics. The review summarises current evidence on the re-emerging clinical applications of these agents, each discussed in the context of historical use, mechanism of action, resistance patterns, and newly identified indications. Attention is given to novel formulations, combination strategies, and alternative routes of administration that enhance efficacy while limiting toxicity, including applications in biofilm-associated infections. Overall, strategic repurposing of older antibiotics represents a valuable complementary approach in the fight against AMR and may extend the therapeutic lifespan of existing agents in an era of limited antibiotic innovation. Full article

Alzheimer’s disease (AD) is the most common cause of dementia and is characterized by progressive cognitive decline, β-amyloid accumulation, tau pathology, oxidative stress, and neuroinflammation. Increasing evidence suggests that metabolic dysregulation may contribute to AD pathogenesis. Glucagon-like peptide-2 (GLP-2), an intestinal peptide hormone, has demonstrated neuroprotective effects in preclinical models, potentially through anti-inflammatory and anti-apoptotic mechanisms. However, its role in human neurodegenerative disorders remains insufficiently understood. This study aimed to compare plasma GLP-2 concentrations between individuals with AD and cognitively healthy controls and to examine associations between GLP-2 levels, cognitive impairment severity, and metabolic parameters. Sixty-one patients with clinically diagnosed AD and twenty-three cognitively unimpaired controls were recruited. Plasma total GLP-2 concentrations were assessed at baseline in all participants and additionally at 6 and 12 months in a subgroup of 34 AD patients. Cognitive function was evaluated using the Mini-Mental State Examination (MMSE) and the Clinical Dementia Rating (CDR) scale. Group comparisons, subgroup analyses based on AD severity, repeated-measures analyses, Spearman correlations, and multivariable linear regression models (including age and clinical group) were performed. Plasma GLP-2 concentrations were significantly higher in AD patients than in controls, with a moderate effect size (Cohen’s d ≈ 0.60). In severity-based subgroup analyses, both the mild and moderate-to-severe AD groups showed significantly higher GLP-2 levels than controls. Longitudinal analyses in AD patients (n = 34) showed no significant changes in GLP-2 concentrations over 12 months. Cognitive performance declined over time, with a significant reduction in MMSE from baseline to 6 months, whereas GLP-2 levels were not correlated with MMSE or CDR at any time point. GLP-2 levels correlated positively with body mass index (BMI), body weight, insulin, and HOMA-IR. In multivariable regression analysis, neither age nor clinical group independently predicted GLP-2 concentrations (both p > 0.05). Plasma GLP-2 concentrations were higher in patients with AD than in cognitively healthy controls; however, GLP-2 levels were not associated with cognitive performance or its progression over 12 months. GLP-2 was positively related to markers of adiposity and insulin resistance, suggesting stronger links to metabolic status than to cognitive severity. Further studies are needed to clarify whether GLP-2 alterations in AD reflect compensatory mechanisms, metabolic factors, or disease-related pathophysiology. Full article

Auranofin, a gold(I)-based compound initially developed for the treatment of rheumatoid arthritis, has emerged as a promising anticancer agent with a multimodal mechanism of action. This review comprehensively examines the therapeutic potential of auranofin in oncology focusing on its ability to synergize with conventional and emerging cancer treatments. Here, we discuss the unique pharmacological properties of auranofin, including thioredoxin reductase inhibition, reactive oxygen species induction, and modulation of key apoptotic pathways. Moreover, this article highlights new recent evidence on its ability to synergize with other cancer treatments such as chemotherapy, immunotherapy, and targeted therapies. Particular emphasis is placed on the role of auranofin in overcoming drug resistance and its potential as an adjuvant in precision medicine. By analyzing both preclinical and clinical data, this review provides critical insights into the repositioning of auranofin as a versatile component in contemporary cancer treatment paradigms, while addressing current challenges and future directions for gold-based therapeutics in oncology. Full article

Antimicrobial resistance represents one of the most critical global health challenges of the 21st century, urgently demanding innovative strategies for antimicrobial discovery. Traditional antibiotic development pipelines are slow, costly, and increasingly ineffective against multidrug-resistant pathogens. In this context, recent advances in artificial intelligence have emerged as transformative tools capable of accelerating antimicrobial discovery and expanding accessible chemical and biological space. This comprehensive review critically synthesizes recent progress in AI-driven approaches applied to the discovery and design of both small-molecule antibiotics and antimicrobial peptides. We examine how machine learning, deep learning, and generative models are being leveraged for virtual screening, activity prediction, mechanism-informed prioritization, and de novo antimicrobial design. Particular emphasis is placed on graph-based neural networks, attention-based and transformer architectures, and generative frameworks such as variational autoencoders and large language model-based generators. Across these approaches, AI has enabled the identification of structurally novel compounds, facilitated narrow-spectrum antimicrobial strategies, and improved interpretability in peptide prediction. However, significant challenges remain, including data scarcity and imbalance, limited experimental validation, and barriers to clinical translation. By integrating methodological advances with a critical analysis of the current limitations, this review highlights emerging trends and outlines future directions aimed at bridging the gap between in silico discovery and real-world therapeutic development. Full article

Background: Infective endocarditis (IE) is a severe and multifactorial condition historically linked to dental procedures. Current evidence shows that most cases arise from complex host–microbe interactions and biofilm colonization on damaged endothelium or intracardiac/prosthetic material, while the inappropriate use of antibiotics in dentistry promotes antimicrobial resistance. Objectives: To provide a narrative synthesis of contemporary evidence on (i) the relative contribution of dental procedures versus daily oral inflammatory burden to bacteremia and IE risk, (ii) the role of periodontal disease and the oral resistome in AMR, and (iii) the clinical and medico-legal implications of antibiotic prescribing and guideline adherence in dental practice. Materials and Methods: A narrative review was conducted using PubMed, Scopus, ResearchGate, and Google Scholar, complemented by manual screening of reference lists and relevant guideline documents. The search covered approximately the last decade (2015–2025) and included ESC 2023 and AHA 2021 guidance on IE prevention. Search terms combined concepts related to “infective endocarditis”, “antibiotic prophylaxis”, “dentistry/dental procedures”, “periodontitis/periodontal disease”, “bacteremia”, “biofilm”, “oral microbiome/oral resistome”, and “antimicrobial stewardship/antibiotic resistance”, using Boolean operators. Eligible sources included clinical studies, systematic reviews/meta-analyses, consensus statements and guidelines, and selected medico-legal literature relevant to dental decision-making and documentation. Editorials and non-peer-reviewed items without retrievable full text were not considered for evidence synthesis. Results: The reviewed evidence supports that spontaneous bacteremia associated with active periodontitis and daily oral activities may be more frequent than procedure-related bacteremia, suggesting that inflammation control and biofilm management represent a major preventive lever. Antibiotic prophylaxis should be reserved for a limited subset of high-risk cardiac patients as per contemporary ESC/AHA recommendations, whereas routine “defensive” prescribing in low-risk contexts provides minimal expected benefit and carries individual and societal harms (adverse events, microbiome disruption, AMR selection). Integrating periodontal care pathways with risk stratification and targeted antibiotic stewardship can improve patient safety and support public health. Conclusions: Dentistry plays a strategic preventive role in IE and AMR primarily through periodontal inflammation control, asepsis, and prudent antibiotic use. From a medico-legal standpoint, professional liability should be assessed on a process-based standard (risk assessment, adherence to updated guidelines, causal local treatment, informed consent, and traceable follow-up) rather than on outcome-driven hindsight. Full article

Background/Objectives: Cognitive impairment and sleep disturbances are highly prevalent in individuals with multiple sclerosis (MS), particularly during middle age, and negatively affect functional independence and quality of life. Although physical exercise has demonstrated cognitive and sleep-related benefits in MS, tolerance to high-intensity training is often limited. Blood flow restriction (BFR) training, which combines low-load resistance exercise with partial vascular occlusion, has emerged as a feasible alternative. This study aimed to evaluate the effects of a 12-week BFR training program on performance in specific cognitive domains and sleep quality in middle-aged adults with MS. Methods: A randomized controlled trial was conducted in 65 adults with relapsing–remitting multiple sclerosis (RRMS) aged 40–65 years and an Expanded Disability Status Scale score below 7. Participants were randomly assigned to a BFR training group or a usual-care control group. The intervention consisted of supervised low-load resistance training with BFR performed twice weekly for 12 weeks. Outcomes assessed before and after the intervention included processing speed (Symbol Digit Modalities Test), executive function (Trail Making Test A and B), verbal fluency (Isaacs Set Test), and self-reported sleep quality (Pittsburgh Sleep Quality Index). Results: Compared with controls, participants in the BFR group showed significant improvements in specific cognitive domains, including processing speed, executive function, and verbal fluency. Significant reductions were also observed in self-reported global sleep disturbance and daytime dysfunction. No adverse events were reported. Conclusions: A 12-week BFR training program improved performance in key cognitive domains and self-reported sleep quality in middle-aged adults with MS, supporting its feasibility and potential clinical relevance as an exercise-based intervention. Full article

Extracellular vesicles (EVs) have emerged as important messengers in cell-to-cell communication, carrying biologically active molecules such as lipids, nucleic acids, and proteins that influence both normal physiology and disease. In cancer, EVs play complex and context-dependent roles, contributing to tumor growth, angiogenesis, immune evasion, metastasis, and resistance to therapy, while in certain settings, they may also support antitumor immune responses. Increasing evidence shows that EVs released from tumor and stromal cells actively reshape the tumor microenvironment (TME) and participate in the formation of pre-metastatic niches, thereby facilitating cancer dissemination. Because EVs are stable, readily detectable in body fluids, and reflect the molecular characteristics of their cells of origin, they have attracted considerable interest as minimally invasive biomarkers for cancer diagnosis, prognosis, and treatment monitoring. In addition, their natural biocompatibility makes them attractive candidates for targeted drug delivery. This review summarizes current knowledge on EV biogenesis, cargo composition, and functional roles in cancer progression, with a particular focus on recent advances in their clinical applications. Key challenges related to EV isolation, characterization, and clinical translations are also discussed, highlighting future opportunities for integrating EV-based strategies into precision oncology. Full article

In the face of rising antimicrobial resistance, food insecurity, and climate change, bacteriophages are gaining renewed attention as promising biological alternatives to antibiotics across human, animal, and plant health sectors. Their high specificity, self-replicating capacity, and biodegradability make them valuable tools for combating antimicrobial or pesticide resistance and promoting sustainable biocontrol. This review discusses commonly accepted selection criteria for therapeutic phages, such as avoiding temperate types and screening for undesirable genes, while acknowledging ongoing debates and exceptions in specific clinical or ecological contexts. An overview of phage-based applications within a One Health framework is provided, spanning human medicine, veterinary practice, aquaculture, food safety and crop protection. Particular attention is given to agricultural biocontrol, where several successful plant protection strategies are highlighted, illustrating the feasibility and diversity of phage-based approaches. Despite their potential, key challenges remain regarding phage stability, formulation, and persistence under environmental conditions. Emerging innovations such as encapsulation, carrier bacteria, and protective formulations aim to enhance field performance. Furthermore, this review emphasizes the need to assess the environmental safety of phage applications, particularly their impacts on natural ecosystems, microbial communities, and ecological functions. Finally, the regulatory and policy challenges that currently limit the large-scale deployment of phages, particularly in the European Union, where they remain evaluated under conventional chemical pesticide frameworks are discussed. The development of dedicated regulatory pathways, better adapted to the specificities of phages, is argued to be essential for supporting their integration into agroecological transition strategies and next-generation antimicrobial policies. Full article

Background: AMR is a public health concern which leads to high global morbidity and mortality. Immunocompromised patients, who are more susceptible to contracting potentially life-threatening infections, are faced with reduced treatment options due to emerging AMR. Ceftolozane/tazobactam is a novel β-lactam/β-lactamase inhibitor which displays effectiveness against resistant Gram-negative infections. Methods: SPECTRA was a multinational, observational study conducted in seven countries including 617 patients who received ≥48 h of ceftolozane/tazobactam. Medical-record data were collected up to 6 months before treatment and 30 days after the final dose or until death. This analysis describes clinical outcomes and healthcare resource use in patients with sepsis or who were immunocompromised, specifically in patients with hematologic malignancy with and without solid tumor, febrile neutropenia, and solid organ transplant patients. Results: Clinical success ranged from 50.0% in patients with hematologic malignancy and solid tumor to 69.4% in 38 patients with febrile neutropenia. All-cause in-hospital mortality was 23.1–42.9%, with the lowest rates in patients with solid organ transplant. ICU admission was 46.4–68.2% across subpopulations (excluding febrile neutropenia) with the lowest rates in patients with hematologic malignancy. ICU length of stay was lowest within transplant patients (9 days) and highest within the hematologic malignancy and solid tumor population (32 days). Conclusions: The results from this sub analysis of SPECTRA showed that ceftolozane/tazobactam was associated with clinical success in the selected immunocompromised and sepsis patient populations and may lead to reduced morbidity, mortality, and healthcare-resource use. Further research is required to standardize treatment protocols and improve patient outcomes. Full article

Cyclin-dependent kinase 4/6 inhibitors (CDK4/6i; palbociclib, ribociclib, abemaciclib, dalpiciclib) combined with endocrine therapy (ET) were a major advance in the treatment of hormone receptor-positive (HR+), human epidermal growth factor receptor 2-negative (HER2-) metastatic breast cancer (MBC) worldwide. Notably, clinical activity has also been observed in HR+HER2-positive (HER2+) MBC, with significant progression-free survival (PFS) benefits. Cyclin-dependent kinases 4/6 (CDK4/6) are downstream of HER2 and pathways driving resistance to HER2-targeted therapies. However, clinical development of CDK4/6i in HER2+ MBC slowed, given the advent of highly effective tyrosine-kinase inhibitors (TKIs) (i.e., tucatinib) and antibody–drug conjugates (ADCs) (i.e., trastuzumab deruxtecan), which currently dominate the treatment armamentarium. The observation that luminal disease defined by a predictive analysis of microarray 50 (PAM50) was independently associated with a significantly longer PFS versus nonluminal disease was important, with researchers inferring that intrinsic molecular subtypes could be used to identify patients most suitable for ET + CDK4/6i + HER2-targeted treatment. Subsequently, the phase III PATINA trial (which included patients with 1L HR+HER2+ MBC, treated with palbociclib vs. placebo with maintenance ET+ H[P]) noted a striking PFS improvement of >15 months in the palbociclib arm, renewing interest in CDK4/6i-based treatments for HR+HER2+ MBC. Herein, we review the development of CDK4/6i in HER2+ BC, discussing current challenges and potential future directions. Full article

Fibroblast growth factor receptor 2 (FGFR2) rearrangements represent one of the most actionable molecular alterations in biliary tract cancer, particularly in intrahepatic cholangiocarcinoma (iCCA). Approximately 10–16% of iCCA cases harbor FGFR2 fusions or rearrangements, defining a distinct molecular subtype characterized by sensitivity to FGFR-targeted therapies. Selective FGFR tyrosine kinase inhibitors, including the reversible inhibitor pemigatinib and the irreversible inhibitor futibatinib, have demonstrated clinically meaningful response rates and durable disease control in patients with previously treated FGFR2-altered iCCA, leading to regulatory approvals and the incorporation of FGFR inhibition into contemporary treatment paradigms. However, the development of acquired resistance—most commonly driven by secondary kinase-domain mutations and activation of bypass signaling pathways—remains a major limitation to sustained therapeutic benefit. This review summarizes the biological basis of FGFR2 alterations, highlights current clinical evidence supporting FGFR inhibition, and discusses the evolving landscape of resistance mechanisms. We further examine emerging therapeutic strategies aimed at overcoming resistance, including next-generation FGFR inhibitors and rational combination approaches. In addition, we highlight the growing role of circulating tumor DNA as a noninvasive tool for longitudinal molecular monitoring and treatment guidance. Together, these insights underscore the central role of FGFR2-directed therapy in precision oncology for biliary tract cancer and provide a framework for optimizing and extending targeted treatment in this molecularly defined disease subset. Full article

Objective: We aimed to characterize the somatic mutational landscape of oropharyngeal squamous cell carcinoma (OPSCC) and identify potential genomic drivers of tumor progression and therapeutic resistance using the AACR GENIE database. Study Design: Retrospective genomic analysis was employed. Setting: We used publicly available data from the American Association for Cancer Research (AACR) Project GENIE database accessed via cBioPortal. Methods: We analyzed 412 tumor samples from 401 patients diagnosed with OPSCC. Somatic mutations, clinical variables and tumor characteristics were extracted and analyzed. Statistical comparisons of mutation frequencies across gender and tumor stage (primary vs. metastatic) were conducted. Co-occurrence and mutual exclusivity analyses were performed to identify significant genomic patterns. Results: The most frequently mutated genes included TP53 (30.1%), PIK3CA (26.0%), and KMT2D (21.6%). Gender-specific analyses suggested potential enrichment of TP53 and MET mutations in females and of ZNF750 in males. Distinct mutation patterns were observed between primary and metastatic tumors; primary tumors were enriched for mutations in TP53 and CDKN2A, while metastatic lesions harbored unique alterations in genes like CBLB and BUB1B, suggesting pathways involved in immune evasion and chromosomal instability may drive disease progression. Co-occurrence was noted between PIK3CA and FBXW7, and mutual exclusivity between TP53 and CYLD. Conclusions: This study identifies distinct genomic signatures in OPSCC subgroups, highlighting candidate biomarkers in pathways like PI3K/AKT signaling that warrant further investigation. Validating these markers in prospective trials is a critical next step to translate these findings into personalized therapeutic strategies for OPSCC patients. Full article