Search Results (6,114)

Matrilysins and stromelysins play a vital role in cancer, facilitating tumor invasion and metastasis. The aim of this study was to investigate the diagnostic significance of selected matrilysins and stromelysins in comparison to routine tumor markers in gynecological malignancies, relative to a control group (benign tumors and healthy women). Preoperative plasma levels of selected metalloproteinases were determined using ELISA, while levels of CA125, SCC-Ag, and HE4 by CMIA. In endometrial and cervical cancers, matrilysins (MMP-7 and MMP-26) exhibited higher diagnostic utility than routine markers. Similarly, all stromelysins in cervical cancer outperformed CA125; furthermore, MMP-10 also outperformed SCC-Ag, achieving the highest diagnostic utility among all parameters tested in cervical cancer. For ovarian cancer, diagnostic utility remained highest for routine markers. In endometrial and cervical cancers, the AUCs for all studied parameters exceeded those of standard markers, while in ovarian cancer, MMP-7 had an AUC higher than HE4 and comparable to CA 125. Combined analysis of the studied parameters in diagnostic panels demonstrated that their introduction into routine diagnostics could provide tangible benefits in the detection of malignant gynecological lesions, especially the combination of MMP-7 or MMP-10 with routine markers. These results indicate the usefulness and high diagnostic power of selected MMPs in the detection of these malignancies. Full article

The mammalian brain fundamentally relies on precise lipid homeostasis to maintain structural integrity and complex neural signaling. Emerging evidence positions lipid metabolism reprogramming not merely as a secondary pathological byproduct but as a core initiating driver of age-related neurodegenerative diseases. This review systematically evaluates the mechanisms of cerebral lipid dyshomeostasis during brain aging, highlighting glial cells as the central mediators of this pathological cascade. We comprehensively dissect the age-associated “lipid drift”, emphasizing apolipoprotein E (APOE)-induced cholesterol transport defects and lipid raft pathology, the accumulation of lipid droplets that triggers microglial metabolic stress (LDAMs), and ceramide-driven neuronal apoptosis coupled with the exosome-mediated propagation of pathogenic proteins. Furthermore, we map these aberrant lipid networks to specific pathological signatures in Alzheimer's, Parkinson's, and demyelinating diseases. Finally, we critically evaluate promising therapeutic interventions, including nutritional strategies, LXR/RXR agonists, and nanotechnology-enabled delivery systems designed to bypass the blood–brain barrier. By integrating high-throughput lipidomics for early diagnostic biomarker discovery, we underscore the translational imperative of restoring cerebral lipid homeostasis as a disease-modifying strategy for neurodegeneration. Full article

Cognitive frailty, characterized by the coexistence of physical frailty and cognitive impairment, has emerged as a major challenge in aging populations and is closely linked to sarcopenia, neurodegeneration, and chronic inflammation. Increasing evidence suggests that the gut microbiota acts as a central regulator of neuromuscular and neurocognitive aging through the integrated gut–brain–muscle axis. This review highlights how microbial dysbiosis, reduced short-chain fatty acid (SCFA) production, systemic endotoxemia, and altered microbial metabolites contribute to mitochondrial dysfunction, neuroinflammation, anabolic resistance, and impaired neuroplasticity. Key signaling mediators, including SCFAs, bile acids, tryptophan-derived metabolites, cytokines, and myokines such as irisin, brain-derived neurotrophic factor (BDNF), and cathepsin B, orchestrate bidirectional communication among the gut, skeletal muscle, and brain. We further discuss the role of exercise-induced microbiota remodeling and muscle endocrine signaling in promoting mitochondrial biogenesis and cognitive resilience. In addition, emerging translational strategies including probiotics, prebiotics, postbiotics, polyphenol-rich functional foods, marine bioactives, and precision nutrition are explored as potential interventions targeting this axis. Collectively, the gut–brain–muscle axis provides a novel systems biology framework for understanding cognitive frailty and developing integrated therapeutic strategies for healthy longevity. Full article

Diabetic retinal disease (DRD) has classically been defined as a microvascular complication of diabetes; however, the recent evidence highlighted the key role of neuronal degeneration during the earliest stages of its pathogenesis. Therefore, neuroprotection has emerged as a promising therapeutic strategy to prevent disease progression. Topical administration via eyedrops represents a non-invasive approach to deliver neuroprotective agents directly to the retina. This review summarizes the current advances in the field of neuroprotective therapies against early DRD with a special focus on topical delivery, including preclinical and clinical evidence, while discussing the relevance of the transscleral route of absorption in all of them. In this review, the most promising neuroprotective compounds under development will be discussed, highlighting the opportunity that they represent for treating early stages of DRD. Full article

Background and Objectives: Blood group antigens are well known for their importance in transfusion medicine and transplant compatibility; however, their biological role extends beyond these functions and includes associations with the risk of several diseases. In this study, we investigated the relationship between ABO blood groups and the circulating levels of 73 different molecules. Patients and Methods: Fifty-six healthy donors were enrolled, including 24 individuals with blood group O, 19 with blood group A, and 13 with blood group B. Blood samples were collected and analyzed in a single laboratory using Luminex fluorescent bead-based assay panels to determine the concentrations of 73 circulating molecules. Depending on data distribution, ANOVA or Kruskal–Wallis tests and Student’s t-test or Kolmogorov–Smirnov tests were applied to identify significant differences among groups. Associations were further assessed by binary logistic regression analysis. Results: Subjects with blood group A showed significantly higher circulating levels of IL-1R1, IL-13, IL-23, PDGF-BB, VEGF-A, VEGF-D, soluble VEGF-R2 (KDR), soluble VEGF-R3 (FLT-4), VLA-4, CD141, MMP-1, syndecan-1 (SDC-1), and mannose-binding lectin (MBL) compared with the other blood groups. In contrast, individuals with blood group B exhibited significantly higher levels of IL-22, IL-23, PDGF-BB, CD62P (P-selectin), and amyloid β1–42. Several significant associations were identified by logistic regression analysis. Conclusions: Our findings indicate that ABO blood groups are associated with distinct circulating molecular profiles, supporting the existence of biological differences that may contribute to variations in disease susceptibility among individuals with different blood types. Nevertheless, given the exploratory’s nature and limited sample size of this study, further investigations are required to validate these findings, confirm the observed associations, and clarify their potential clinical implications. Full article

Lipids are commonly viewed as membrane components, energy sources, or precursors of signaling molecules, yet accumulating evidence indicates a broader role in determining the functional state of cells. In this review, we present an integrative cross-domain synthesis in which lipids are discussed as important modulators of cellular functional state across inflammation, tissue regeneration, and chronic disease. We discuss how membrane lipid composition shapes receptor and ion-channel signaling, how bioactive lipid mediators govern the balance between inflammatory initiation and resolution, and how lipid metabolism regulates stem-cell quiescence, activation, and regenerative capacity. We integrate these mechanisms to show how disruption of lipid-regulated processes may bias tissues toward persistent inflammation, impaired repair, and disease progression in conditions such as rheumatic disorders, fibrosis, and neurodegeneration. Depending on context, such lipid alterations may function as causal contributors, permissive conditions, or downstream signatures of pathological state transitions. Finally, we consider how pharmacological and nutritional modulation of lipid pathways may influence cellular states, while emphasizing that the main contribution of this review is a conceptual state-transition framework that links membrane architecture, mediator balance, and lipid metabolic flux across inflammation, regeneration, and chronic disease. Full article

Introduction: Neuroinflammation is a key feature of both Alzheimer’s disease (AD) and glioblastoma, although it leads to different outcomes in each disorder. In AD, chronic activation of microglia and astrocytes by amyloid-β and tau contributes to neuronal injury and cognitive decline. In glioblastoma, tumor cells exploit inflammatory pathways to create an immunosuppressive microenvironment that supports tumor growth. This review compares the shared and distinct neuroinflammatory mechanisms in AD and glioblastoma and highlights their therapeutic relevance. Materials and Methods: This study was conducted as a narrative review based on a PubMed search performed by three reviewers. English-language articles on AD, glioblastoma, and neuroinflammatory pathways were included, covering original studies, reviews, meta-analyses, and experimental and clinical reports. Keywords included neuroinflammation, microglia, astrocytes, tumor-associated macrophages, inflammasomes, NLRP3, NF-κB, HIF-1α, cytokines, blood–brain barrier, and miRNAs. Due to study heterogeneity, findings were synthesized descriptively. Results: AD and glioblastoma share major neuroinflammatory mechanisms, including microglial and astrocytic activation, cytokine signaling, inflammasome activity, blood–brain barrier dysfunction, hypoxia-related changes, and miRNA regulation. In AD, these pathways promote chronic inflammation, synaptic loss, and neurodegeneration, with NLRP3, NF-κB, and M1-like microglial polarization playing central roles. In glioblastoma, similar pathways are redirected toward tumor progression through tumor-associated macrophages, reactive astrocytes, angiogenesis, immune evasion, and therapy resistance. Key overlapping mediators include IL-1β, TNF-α, NF-κB, HIF-1α, GSK-3β, and selected miRNAs. Conclusions: AD and glioblastoma are connected by common neuroinflammatory pathways, but these processes result in neurodegeneration in AD and tumor support in glioblastoma. Understanding these shared and divergent mechanisms may guide the development of biomarkers and targeted therapies focused on microglia, inflammasomes, cytokines, and immune reprogramming in both diseases. Full article

Background/Objectives: Neurodegenerative diseases such as Alzheimer’s disease (AD) and Parkinson’s disease (PD) represent a growing public health concern. Both disorders are driven by mitochondrial dysfunction, oxidative stress, impaired autophagy, neuroinflammation, and neuronal loss. Single-target therapeutics have failed to halt disease progression, highlighting the need for multi-target interventions that address the complex and interconnected nature of neurodegeneration. Natural health products (NHPs) such as curcumin (CUR), coenzyme-Q10 (CoQ10), and Ashwagandha (ASH) possess antioxidant, anti-inflammatory, neuroprotective, and neurotrophic properties that may collectively address this complex pathology. However, poor bioavailability and hydrophobicity have limited clinical translations. Novel formulations, including nanomicellar Ubisol-Q10 (UQ) and water-solubilized ASH (PTS-ASH), have demonstrated enhanced metabolic uptake and neuroprotective efficacy in preclinical models. Moreover, co-administered NHPs, such as CUR + CoQ10 and CoQ10 + ASH, may provide further benefits by diversified targeting of disease pathways. Methods: This review presents an integrative interpretation of a combined UQ + ASH “tonic” in transgenic AD and paraquat-induced PD animal models using previously published qualitative immunohistochemical and functional results. This report constructs a proposed mechanistic model illustrating how these compounds may interact across multiple stages of disease AD and PD progression. Results: Based on comprehensive interpretation of the previous published reports, consistent trends suggest UQ stabilizes mitochondrial energetics and suppresses oxidative damage upstream, whereas ASH promotes downstream repair and synaptic modulation. Combined administration remained as providing balanced neuroprotective and functional outcomes. Conclusions: These interpretations of published reports and proposed mechanistic models aim to improve the translation and support the therapeutic potential of multi-component natural interventions for neurodegenerative diseases and highlight the importance of bioavailability-enhancing formulations in future preclinical and clinical research. Full article

The GGGGCC hexanucleotide repeat expansion (HRE) in C9ORF72 was recognized as the most common genetic cause of amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD). Repeat-associated non-AUG (RAN) translation of the expanded repeat generated dipeptide repeat proteins (DPRs), which disrupted multiple cellular processes and contributed to neurodegeneration. Emerging evidence indicated that disease pathogenesis involved both gain-of-function (GOF) and loss-of-function (LOF) mechanisms. DPR-mediated GOF toxicity induced ribosomal dysfunction, nucleolar stress, proteostatic impairment, and neuronal injury, whereas C9ORF72 LOF disrupted lysosomal and autophagic pathways in microglia, impairing the immune homeostasis. Neuronal injury further promoted the release of damage-associated signals that triggered secondary microglial activations and chronic neuroinflammations. This review summarized current knowledge of DPR biology, microglial dysfunction, and their contributions to disease progression in C9ORF72-associated ALS/FTD. Therapeutic strategies targeting repeated RNA, DPR productions, proteostasis, autophagy, and neuroinflammatory pathways were also discussed. In addition, the potentials of fluid biomarkers, including cerebrospinal fluid poly (GP) and blood neurofilament light chain (NfL), for diagnosis, disease monitoring, and therapeutic assessment were shown. Together, these findings provided important insights into disease mechanisms and potential avenues for improved clinical management. Full article

The A3 adenosine receptor (A3AR) is a stress-inducible G-protein-coupled receptor that is selectively upregulated in inflamed, hypoxic, and fibrotic tissues as well as in many malignancies, while remaining weakly expressed in most normal organs. This distinctive expression pattern provides a strong biological basis for pathology-selective pharmacology. Activation of A3AR by highly selective agonists, including piclidenoson (IB-MECA) and namodenoson (Cl-IB-MECA), initiates signaling through Gi proteins and phospholipase C (PLC), which in turn regulate a coordinated network of downstream intracellular pathways, including PI3K/Akt, NF-κB, MAPKs, and Wnt/β-catenin, resulting in suppression of inflammation, inhibition of pathological cell survival, and protection of metabolically stressed tissues. Over the three decades, extensive preclinical studies have demonstrated that A3AR agonism exerts anti-cancer, anti-fibrotic, immunomodulatory, neuroprotective, and organ-protective effects across diverse disease models, including hepatocellular carcinoma, pancreatic cancer, psoriasis, osteoarthritis, metabolic dysfunction-associated steatohepatitis, ischemic stroke, neurodegeneration, ophthalmic disorders, and inherited metabolic syndromes. Importantly, these mechanistic insights have been translated into clinical programs, with piclidenoson and namodenoson demonstrating favorable safety profiles and disease-modifying activity in inflammatory, fibrotic, and oncologic indications. This review integrates molecular, cellular, and translational evidence to highlight A3AR activation as a unifying therapeutic principle for diseases driven by inflammation, oxidative stress, hypoxia, and dysregulated cell survival, positioning selective A3AR agonists as first-in-class agents targeting the A3AR, with broad clinical applicability across multiple disease domains. Full article

Not all sleep loss is equal, and overlooking this limits progress in sleep and neurological disease research. We compared nine rodent sleep deprivation paradigms, gentle handling, multiple platform variants, disk-over-water, the Unpredictable Chronic Sleep Deprivation (UCSD) paradigm, novel object introduction, curling prevention by water, automated systems, and head-lifting, evaluating stress confounds, sleep stage specificity, chronicity, and neurobiological outcomes. Effects included hippocampal plasticity, prefrontal chemistry, glymphatic clearance, neuroinflammation, oxidative stress, neurogenesis, and circadian regulation, linked to Alzheimer’s, Parkinson’s, and psychiatric comorbidities. UCSD with caffeine produced antioxidant depletion, serotonin reduction, acetylcholinesterase upregulation, and synaptophysin loss, early neurodegeneration markers. We propose a disease-targeted framework with six translational priorities and reporting standards. Full article

Multiple sclerosis (MS) is a neuro-inflammatory disease characterized by demyelination in the central nervous system (CNS). Although a substantial endogenous capacity for remyelination has been demonstrated, this process is frequently incomplete and exhibits marked intra- and inter-individual heterogeneity. Several factors influence the extent of spontaneous myelin regeneration, including age, sex, disease course, and lesion localization. Oligodendrocytes (OL), derived from oligodendrocyte progenitor cells (OPCs), are the principal myelinating cells of the CNS. The regenerative cascade involves several key stages, including OPC activation, recruitment, differentiation into oligodendrocytes (OL), and myelin deposition. This process is orchestrated in a spatiotemporal manner by a complex interplay of intracellular signaling pathways, genetic determinants, and dynamic microenvironmental cues, which together balance inhibitory and pro-remyelinating influences. Several lines of evidence indicate that chronically demyelinated axons are vulnerable to degeneration, whereas successful remyelination may confer neuroprotection. These observations underscore remyelination as a promising neuroprotective therapeutic target for preventing or slowing disability progression in MS, a condition in which gradual neuroaxonal degeneration is believed to underlie irreversible disability progression. In this review, we aim to bridge the gap between fundamental biological mechanisms of remyelination and their clinical relevance. We examine recent advances in in vivo techniques for assessing remyelination and discuss how these measures correlate with clinical and disability outcomes. In addition, we review recent clinical trials of remyelination-promoting therapies and analyze the challenges that have limited their advancement beyond phase II. Overall, we seek to provide a comprehensive overview of the remyelination process from bench to bedside, highlighting both the obstacles and the therapeutic potential of remyelination strategies in MS. Full article

Multiple sclerosis (MS) is a chronic immune-mediated disease of the central nervous system characterized by demyelination, neuroinflammation, and progressive neurodegeneration. While there is a small component of genetic susceptibility to MS risk, environmental factors, including infectious exposures, are gaining increased recognition as playing a critical role in MS initiation and progression. Viral infections, especially by Epstein–Barr virus (EBV), have emerged as strong candidates and triggers of MS symptoms, through antibody-mediated molecular mimicry and B-cell dysregulation. In contrast, parasitic infections, including helminths and select protozoa, appear to exert neuroprotective effects by skewing immune responses toward regulation and tolerance. In this review, we examine antibody-driven mechanisms by which viral pathogens promote autoimmunity in MS and contrast these with parasite-induced immunoregulatory pathways that suppress pathogenic inflammation. We further discuss diagnostic and therapeutic implications, highlighting how insights from infectious immunology may inform novel strategies for MS treatment. Full article

Background/Objectives: Alzheimer’s disease (AD) disproportionately affects women, who account for nearly two-thirds of affected individuals worldwide. This sex imbalance cannot be explained by longevity alone and likely reflects complex interactions among biological sex, endocrine aging, genetic susceptibility, and brain-specific mechanisms of vulnerability. Neuroimaging has played a pivotal role in characterizing these sex-related differences in vivo, enabling the assessment of amyloid-β deposition, tau propagation, neurodegeneration, cerebral glucose metabolism, and network reorganization. This invited review examines AD through a rigorously sex-specific neuroimaging perspective, with particular emphasis on implications for women’s brain health. Methods: We integrated evidence from structural MRI, FDG-PET, amyloid-PET, tau-PET, estrogen receptor PET, diffusion MRI, and fluid biomarkers, together with epidemiological, molecular, genetic, and endocrine studies. The review focuses on female-specific trajectories of AD initiation and progression, highlighting the contribution of neuroendocrine aging, menopause, metabolic dysfunction, and sex-modulated genetic risk factors. Results: Available evidence indicates that women exhibit distinct biological and neuroimaging signatures across the AD continuum. Menopause emerges as a critical neuroendocrine transition associated with metabolic decline, altered brain connectivity, increased amyloid and tau vulnerability, and progressive neurodegeneration. Female-specific patterns of tau propagation and sex-dependent interactions with genetic risk factors further contribute to differential disease trajectories. Advanced multimodal neuroimaging approaches have substantially improved the characterization of these mechanisms and their relationship with cognitive decline and clinical progression. Conclusions: A sex-specific neuroimaging framework is essential to improve understanding of AD pathophysiology and to advance precision medicine approaches tailored to women’s brain health. Recognition of endocrine aging and female-specific biological vulnerability may inform earlier identification of at-risk individuals and the development of targeted prevention and treatment strategies. Future research should prioritize sex-aware longitudinal studies and multimodal biomarker integration to optimize personalized interventions in AD. Full article

Accumulation of aggregated amyloid beta (Aβ) species is a defining pathological hallmark of Alzheimer’s disease and is associated with extensive neuronal structural abnormalities. Mild cognitive impairment (MCI), a transitional stage between normal aging and the onset of dementia, is thought to represent an early phase of this pathological continuum. Studies at the cellular level suggest that the conditions impair the maintenance of established neuronal processes/networks and restrict their capacity for elongation or re-elongation. They may also attenuate the activation and process extension of quiescent neural progenitor or stem-like cells. These early cellular changes precede overt neurodegeneration in neural tissue and are likely to contribute to cognitive decline. They highlight the importance of in vitro models for identifying molecular targets involved in recovery from disease. In this study, we investigated the effects of aggregated Aβ (25–35) on neuronal process elongation and associated intracellular events in the N1E-115 cell line, a widely used model of neuronal differentiation. Addition of aggregated Aβ to cultured N1E-115 cells attenuated process elongation in a concentration-dependent manner. This morphological impairment was accompanied by decreased expression of neuronal differentiation markers. In contrast, at the half-maximal inhibitory concentration for process elongation, long-term cultured cells did not exhibit apparent process retraction or degenerative morphology. This mild but progressive impairment, without extensive cell death, is consistent with the cellular features of early-stage conditions rather than advanced Alzheimer’s pathologies. Similar results were observed in primary cortical neurons. Aβ also decreased the level of GTP-bound Ras and phosphorylation of the downstream mitogen-activated protein kinase/extracellular signal-regulated kinase (MAPK/ERK). Furthermore, treatment with hesperetin, a bioactive flavonoid compound, recovered the Aβ-induced inhibition of neuronal process elongation. Hesperetin also restored Ras and MAPK/ERK states, suggesting that its effects are associated, at least in part, with modulation of signaling through Ras and MAPK/ERK. Our findings suggest that hesperetin may serve as a useful molecular probe for modulating early cellular responses associated with Alzheimer’s disease-related pathology. This in vitro model might serve as a useful platform for investigating the molecular target candidates involved in recovery from nervous system disorders. Full article