Search Results (1,106)

Adipocyte browning refers to the inducible transdifferentiation or de novo recruitment of thermogenically active beige adipocytes within white adipose tissue depots. Beige adipocytes, characterized by multilocular lipid droplets and high mitochondrial density, express uncoupling protein 1 and possess a metabolic phenotype similar to that of classical brown adipocytes. This plasticity of adipose tissue is regulated by a complex network of transcriptional coactivators (e.g., PRDM16, PGC-1α), epigenetic modulators, non-coding RNAs, and hormonal signals. Environmental cues, such as chronic cold exposure, exercise, and caloric restriction, further potentiate browning via sympathetic nervous system activation and endocrine crosstalk. At the systemic level, adipocyte browning enhances energy expenditure, improves insulin sensitivity, and mitigates lipid accumulation, making it a promising target for the treatment of obesity, type 2 diabetes mellitus, and other metabolic syndromes. Several browning agents (natural products and repositioned drugs) and novel chemicals that induce browning have been reported. However, the translational application of these agents in humans faces challenges related to interspecies differences, depot-specific responses, and long-term safety. This review critically examines molecular regulators, existing browning agents, and the discovery of novel browning agents, with the aim of harnessing them for metabolic disease intervention. Full article

Ulcerative colitis (UC) is a chronic immune-mediated inflammatory disease characterized by substantial heterogeneity in histologic activity, which is frequently uncoupled from clinical symptoms and endoscopic findings. Persistent microscopic inflammation is increasingly recognized as a critical determinant of relapse, therapeutic failure, and long-term disease outcomes, underscoring the need for molecular frameworks that align directly with tissue-level immune dysregulation. Interleukins (ILs) represent central regulators of mucosal immunity in UC, integrating innate and adaptive immune responses that govern epithelial injury and resolution. In this narrative review, we synthesize mechanistic, translational, genetic, and clinical evidence examining IL networks associated with histologic disease activity and persistence. Particular emphasis is placed on IL-23-driven inflammatory pathways, which consistently align with histologic severity, sustained microscopic inflammation, and resistance to immune resolution. In contrast, preserved IL-10-mediated regulatory signaling characterizes histologic remission and effective mucosal healing, whereas its insufficiency permits ongoing tissue-level inflammation. Downstream effector ILs, including IL-6, IL-1β, IL-8, and IL-17A, are discussed as mediators translating upstream immune imbalance into neutrophil recruitment and epithelial injury. Throughout this review, the term “prognostic” is used to denote alignment with histologic disease behavior rather than validated prediction of clinical outcomes. Collectively, the evidence supports the concept that coordinated IL patterns reflect distinct immunopathologic states underlying microscopic inflammation in UC, providing a biologically coherent framework for interpreting histologic activity and disease persistence beyond symptom-based assessment. Full article

This paper presents an analytical model for the hereditary vibrations of a coupled circular plate system interconnected by viscoelastic creep layers. The system is represented as a discrete-continuous chain of thin, isotropic plates with time-dependent material properties. Based on the theory of hereditary viscoelasticity and D’Alembert’s principle, a system of partial integro-differential equations is derived and reduced to ordinary integro-differential equations using Bernoulli’s method and Laplace transforms. Analytical expressions for natural frequencies, mode shapes, and time-dependent response functions are obtained. The results reveal the emergence of multi-frequency vibration regimes, with modal families remaining temporally uncoupled. This enables the identification of resonance conditions and dynamic absorption phenomena. The fractional parameter serves as a tunable damping factor: lower values result in prolonged oscillations, while higher values cause rapid decay. Increasing the kinetic stiffness of the coupling layers raises vibration frequencies and enhances sensitivity to hereditary effects. This interplay provides deeper insight into dynamic behavior control. The model is applicable to multilayered structures in aerospace, civil engineering, and microsystems, where long-term loading and time-dependent material behavior are critical. The proposed framework offers a powerful tool for designing systems with tailored dynamic responses and improved stability. Full article

Astaxanthin, derived from Haematococcus pluvialis, is a potent antioxidant with significant therapeutic potential. However, its large-scale commercialization is hindered by the “thick-wall challenge”, a phenomenon where the stress conditions required for astaxanthin accumulation also trigger the formation of resistant secondary cell walls. This challenge complicates extraction and reduces bioaccessibility, thereby increasing production costs. Recent advancements have focused on uncoupling astaxanthin biosynthesis from cell wall reinforcement, utilizing metabolic engineering and strain selection to reduce wall formation while maintaining high yields. Furthermore, green extraction techniques, such as electrotechnologies and ionic liquids, are being explored to improve efficiency and environmental sustainability. This review synthesizes these innovations, including biorefinery systems that maximize biomass valorization, and discusses emerging clinical applications. We highlight the challenges in bridging the gap between laboratory successes and clinical translation, and suggest future directions for resolving the thick-wall challenge, advancing astaxanthin production, and expanding its therapeutic uses in nutraceuticals and pharmaceuticals. Full article

Accurate prediction of the rocking and sliding response of free-standing rigid blocks under seismic excitation remains challenging, particularly in regimes where rocking and sliding are strongly coupled and motion mode transitions occur. This study presents a modified semi-analytical framework and an optimized Finite Element Method (FEM) approach to investigate the nonlinear dynamics of rigid rectangular blocks subjected to initial angular displacements, assuming Coulomb friction and near-inelastic impacts. The proposed semi-analytical formulation explicitly captures the coupling between rocking and sliding motions, enabling systematic identification of rest, rocking, sliding, rocking–sliding, and free-flight response modes. Benchmark comparisons with Veeraraghavan’s classical model show overall agreement in limiting cases but reveal notable differences in intermediate regimes, where motion mode transitions are highly sensitive to friction coefficient and slenderness ratio. These discrepancies arise from the ability of the present formulation to resolve transitional rocking–sliding behavior that is not fully represented in uncoupled or limiting-case assumptions. Complementary FEM simulations employing both rigid and deformable body representations further elucidate the role of contact modeling and energy dissipation. While rigid-body FEM models offer computational efficiency, they exhibit localized penetration and residual bouncing due to contact enforcement limitations. In contrast, deformable FEM models more closely approximate near-inelastic collision behavior and dissipate impact energy more effectively, albeit at higher computational cost. The combined semi-analytical and FEM results provide a robust framework for interpreting motion mode transitions, quantifying contact and penetration effects, and defining the applicability limits of simplified rigid-body models. These findings offer practical guidance for selecting appropriate modeling strategies for seismic response assessment of free-standing rigid blocks. Full article

Background: Survivin is an anti-apoptotic protein highly expressed during embryonic development and, in adults, mainly in the gastrointestinal epithelium. Its levels decrease in human gastric tissue and cultured cells upon exposure to Helicobacter pylori gamma-glutamyl transpeptidase (GGT), though the underlying mechanism remains unclear. Objective: We aimed to investigate the role of cap-independent translation driven by the Survivin 5′ untranslated region (5′UTR) in response to H. pylori infection in vitro. Methodology: Human cell lines (AGS, GES-1, HeLa, HEK293T) were used alongside bicistronic and monocistronic (Firefly/Renilla luciferases) reporter assays to assess short and long variants of the Survivin 5′UTR and HIV-1 internal ribosome entry site (IRES) sequences. Additional methods included in vitro transcription/translation, RT-qPCR, agarose gel electrophoresis, Western blotting, coupled/uncoupled translation assays, and siRNA silencing. Results: The short variant of the Survivin 5′ UTR supported cap-independent translation, like the HIV-1 IRES. Notably, H. pylori infection suppressed this translation in a GGT-dependent manner in gastric cells, and a similar reduction was observed following treatment with ATO, a known prooxidant. Conclusion: The Survivin 5′UTR exhibits cap-independent translation activity that is inhibited by H. pylori in a GGT-dependent manner, likely via oxidative stress. This mechanism helps to explain the downregulation of Survivin during gastric infection and indicates that oxidative stress can negatively affect both cellular and viral IRES-mediated translation. Full article

This work presents a straightforward procedure for constructing the solution to the steady-state energy-transfer process in a system of two convex, opaque, gray bodies, with the aim of determining the temperature distribution within these bodies when separated by a vacuum. The methodology proposed in this work combines a sequence of elements that are functions obtained from the solution of uncomplicated, well-known linear, uncoupled heat transfer problems, thereby enabling solutions to be obtained using tools found in basic engineering textbooks. Specifically, these well-known problems resemble classical conduction-convection heat transfer problems, in which the boundary condition is described by the noteworthy Newton’s law of cooling. The limit of sequences of elements that are solutions to straightforward linear problems corresponds to the original, complex, coupled nonlinear problem. The convergence of these sequences is mathematically proven. The phenomenon (considered in this work) encompasses those involving black bodies. Since each element of the sequence arises from a well-known linear problem, numerical approximations can be used to obtain it, yielding a simple and powerful tool for simulations. Some presented results highlight the importance of considering thermal interaction between the two bodies, even in the absence of physical contact. In particular, the alterations in the temperature distributions of two separate gray bodies are explicitly shown to result from their thermal interaction. Full article

Brown adipose tissue (BAT) and beige adipocytes play a crucial role in adaptive thermogenesis, primarily via uncoupling protein 1 (UCP1)-driven heat production. Once considered physiologically irrelevant in adults, BAT is now recognized as an active tissue that contributes to energy expenditure and metabolic homeostasis and represents a potential therapeutic target for obesity and metabolic disorders. This review provides an integrated overview of the molecular regulation of thermogenic adipocytes, emphasizing both canonical UCP1-dependent as well as non-canonical UCP1-independent mechanisms of heat generation. Key transcriptional and epigenetic regulators are discussed in the context of mitochondrial biogenesis, substrate utilization, and thermogenic gene programs. Major upstream signaling routes are further summarized, encompassing classical β-adrenergic pathways, as well as alternative regulatory nodes including AMP-activated protein kinase (AMPK) and mechanistic target of rapamycin (mTOR) together with diverse nutrient- and hormone-responsive cues that converge to activate brown and beige adipocytes. Finally, the cross-talk among neuronal, endocrine, immune, and gut microbiota-derived signals is highlighted as a key determinant of thermogenic adipocyte function. Together, these multilayered regulatory inputs provide a comprehensive framework for understanding how thermogenic adipose tissue integrates environmental, metabolic, and microbial cues to regulate systemic energy balance—knowledge that is essential for developing targeted therapies to combat obesity and metabolic diseases. Full article

Obesity has reached epidemic proportions, driven by energy imbalance and limited capacity for adaptive thermogenesis. Brown (BAT) and beige adipose tissues dissipate energy through non-shivering thermogenesis (NST), primarily via uncoupling protein-1 (UCP1), making them attractive targets for increasing energy expenditure (EE). The canonical β-adrenergic pathway robustly activates NST in rodents through β3 adrenoceptors; however, translational success in humans has been limited by low β3 expression, off-target cardiovascular effects, and the emerging dominance of β2-mediated signaling in human BAT. Consequently, attention has shifted to non-adrenergic and UCP1-independent mechanisms that offer greater tissue distribution and improved safety profiles. This review examines a broad spectrum of alternative receptors and pathways—including GPRs, TRP channels, TGR5, GLP-1R, thyroid hormone receptors, estrogen receptors, growth hormone, BMPs, sirtuins, PPARs, and interleukin signaling—as well as futile substrate cycles (Ca²⁺, creatine, and glycerol-3-phosphate) that sustain thermogenesis in beige adipocytes and skeletal muscle. Pharmacological agents (natural compounds, peptides, and small molecules) and non-pharmacological interventions (cold exposure, exercise, diet, and time shift) targeting these pathways are critically evaluated. We highlight the translational gaps between rodent and human studies, the promise of multimodal therapies combining low-dose adrenergic agents with non-adrenergic activators, and emerging strategies such as sarco/endoplasmic reticulum calcium ATPase protein (SERCA) modulators and tissue-specific delivery. Ultimately, integrating adrenergic and non-adrenergic approaches holds the greatest potential for safe, effective, and sustainable obesity management. Full article

Atrial fibrillation (AF) is the most prevalent sustained arrhythmia worldwide and is now increasingly regarded as a disease of chronic inflammation and progressive atrial fibrosis. Understanding of molecular mechanisms that mediate the linkage between systemic metabolic dysregulation, inflammation, and structural atrial changes is crucial for informing risk stratification and targeting of prevention strategies. This review provides evidence from 105 studies focusing on the contributions of transforming growth factor-β1 (TGF-β1), tumor necrosis factor-a (TNF-α), interleukin-6 (IL-6), galectin-3, and galectin-1 to cardiac fibrogenesis, atrial fibrosis, and AF pathogenesis. We also link metabolic syndrome to these biomarkers and to atrial remodeling, as well as echocardiographic correlates of fibrosis. TGF-β1 is established as the central profibrotic cytokine and promotes Smad-based fibroblast activation, collagen accumulation, and structural atrial remodeling. Its role is highly potentiated by thrombospondin-1 by turning latent TGF-β1 into its potent form. TNF-α and IL-6 also play an integral role in the inflammatory fibrotic continuum by activating NF-κB and STAT3 signaling, promoting fibroblast proliferation, electrical uncoupling, and extracellular matrix accumulation. Galectin-3 is a potent profibrotic mediator that promotes TGF-β signaling and is a risk factor for negative outcomes, whereas Gal-1 seems to regulate inflammation resolution and may exert context-dependent protective or maladaptive roles. Metabolic syndrome is strongly associated with excessive levels of these biomarkers, chronic low-grade inflammation, oxidative stress, and ventricular and atrial fibrosis. Chronic clinical findings show that metabolic syndrome (MetS) increases AF risk, exacerbates atrial dilatation, and is associated with worse postoperative outcomes. Echocardiographic data are connected to circulating biomarkers and are non-invasive for evaluating atrial remodeling. The evidence to date supports that atrial fibrosis should be considered an end point of systemic inflammation, metabolic dysfunction, and activation of profibrotic molecular pathways. Metabolic syndrome, due to its chronic low-grade inflammatory environment and prolonged levels of metabolic stress, manifests as an important upstream factor of fibrotic remodeling, which continuously promotes the release of cytokines, oxidative stress, and fibroblast activation. Circulating fibrotic biomarkers, in comparison with metabolic syndrome, serve separate yet interdependent pathways that help orchestrate atrial structural remodeling through the simultaneous process but can also provide a long-term indirect measure of ongoing profibrotic activity. The integration of these biomarkers with superior atrial imaging enables a broader understanding of the fibrotic substrate of atrial fibrillation. This combined molecular imaging approach can facilitate risk stratification, refine therapeutic decisions, and facilitate early identification of higher-risk metabolic phenotypes, thus potentially facilitating directed antifibrotic and anti-inflammatory therapy in atrial fibrillation. Full article

The increasing use of Technology-Critical Elements (TCEs) in modern technology has led to widespread environmental release, raising questions about their biological effects, as emerging evidence suggests significant toxicity. We investigated the effects of three technology-critical elements, Indium oxide (In₂O₃), Lanthanum nitrate hexahydrate (La(NO₃)₃·6H₂O) and Cerium(III) nitrate hexahydrate (Ce(NO₃)₃·6H₂O), on human dermal fibroblasts (BJ) and hepatocarcinoma cells (HepG2), assessing their uptake, impact on viability, and induced cellular stress responses, quantified by markers of inflammation, oxidative stress, and membrane damage. Our results show a strong differential susceptibility: normal BJ fibroblasts proved vulnerable, whereas HepG2 cells were highly resistant. This divergence occurred despite substantial and comparable accumulation of all three TCEs in both cell lines, indicating that toxicity is uncoupled from the magnitude of the uptake. Mechanistically, the differential toxicity correlated strongly with opposing antioxidant responses. Additionally, low concentrations of cerium (III) nitrate (12.5–50 µg/mL) uniquely stimulated the proliferation of HepG2 cells (up to 129% of control). While these findings identify multiple mechanistic hazards regarding the potential of low-level technology-critical element exposure, they must be interpreted cautiously and warrant further investigation in more complex biological models. Full article

Obesity treatments increasingly target multiple pathways beyond appetite suppression. We evaluated KBN2202, a salicylate-derived small molecule, in a high-fat diet (60% kcal from fat) mouse model using female and male C57BL/6J mice treated for 8 weeks with oral KBN2202 (20 mg/kg/day) or a matched-volume vehicle (1% DMSO/PBS). Body weight was recorded weekly, and food intake was measured daily; serum hormones and cytokines, adipose tissue histology, and open-field behavior were assessed at the end of the study. Under our experimental conditions, HFD increased body weight and gonadal white adipose tissue (gWAT)/brown adipose tissue (BAT) mass in females, whereas males showed only modest HFD-associated weight gain and did not develop a clear obesity phenotype. KBN2202 significantly reduced peri-ovarian gWAT mass and adipocyte size without altering overall body weight. In females, circulating glucagon-like peptide-1 (GLP-1) increased, uncoupling protein 1 (UCP1) in gWAT showed a non-significant upward trend, and serum TNF-α was selectively decreased, while MCP-1 and IL-1β were unchanged. Locomotor activity was unaltered, and anxiety-like behavior was reduced. Male mice did not show comparable adipose effects. These findings indicate depot-specific, peripheral modulation of adipose remodeling, hormonal balance, and inflammatory tone by KBN2202, supporting its further investigation as an adipose-targeted metabolic modulator complementary to incretin-based therapies. Full article

This paper investigates the thermal shock response of a spacecraft solar panel. The panel is represented as a thin homogeneous plate. The governing equations are derived from the coupled thermoelasticity theory for a homogeneous medium, combining the heat equation with compressibility effects and the Lamé equations for the displacement vector. The aim of the paper is to analyze new properties of a specific formulation of the coupled thermoelasticity problem and to establish a justified simplification. New properties follow from a specific formulation of the thermoelasticity problem for a real physical object (a solar panel). They are subjective properties of this formulation and allow, in particular, to reduce the coupled thermoelasticity problem to a simpler, uncoupled problem, with certain limitations. This simplification is driven by the physics of the thermal shock process and the resulting plate deformation, which allows the thermal problem to be reduced to a one-dimensional formulation. The main result is a simplified thermoelasticity model that reveals several new properties. Notably, in the region where longitudinal displacements are negligible, the coupled problem generates into an uncoupled one. This result can be applied to model disturbances caused by thermal shock on spacecraft. Full article

Metabolic reprogramming allows cancer cells to proliferate rapidly, survive nutrient limitation, and resist stress, making tumor metabolism an important therapeutic target. However, pharmacological inhibition of metabolic enzymes often causes systemic toxicity and compensatory pathway activation. To overcome these limitations, recent studies have highlighted an alternative host-centered strategy based on increasing systemic energy expenditure. Recent studies highlight an alternative strategy in which the host increases energy expenditure through uncoupling protein 1 (UCP1) dependent thermogenesis, thereby lowering systemic glucose, fatty acid, and nucleotide availability for tumors. Engineered beige adipocytes overexpressing UCP1, PR domain-containing protein 16 (PRDM16), or peroxisome proliferator–activated receptor gamma coactivator 1 alpha (PPARGC1A/PGC1A) suppress tumor growth through nutrient competition, suggesting that activating endogenous UCP1 may provide a non-genetic and physiologically aligned anticancer approach. Building on this concept, natural products such as polyphenols, terpenoids, alkaloids, and carotenoids have emerged as promising UCP1 activators that stimulate beige and brown adipocyte thermogenesis through pathways involving AMP-activated protein kinase (AMPK), sirtuin 1 (SIRT1), PGC1A, PRDM16, and mitochondrial biogenesis. In parallel, computational studies further indicate that several plant-derived compounds bind directly to the central cavity of UCP1 with high affinity, offering structural support for their thermogenic action. Importantly, many of these compounds also inhibit cancer cell intrinsic metabolism by reducing glycolysis, oxidative phosphorylation, lipid synthesis, and amino acid dependent anaplerosis. This review integrates UCP1 biology, natural product mediated thermogenesis, molecular docking evidence, and tumor metabolic suppression, proposing a unified framework in which natural compounds impose coordinated metabolic pressure on cancer through both adipocyte-driven nutrient competition and direct inhibition of tumor metabolism. Full article

Brown adipose tissue (BAT) has emerged as a promising therapeutic target for metabolic disorders such as type 2 diabetes and obesity. To advance research on BAT activation and elucidate the mechanisms underlying adipogenesis, it is crucial to develop a reliable in vitro model. This study aimed to optimize the differentiation of adipose-derived stem cells (ADSCs) into beige adipocytes and to validate the protocol using primary human ADSCs obtained from eight donors. Protocol optimization was first performed with commercial ADSCs, testing more than 30 combinations of adipogenic conditions. Differentiation was assessed by microscopy, Oil Red O staining, and uncoupling protein 1 (UCP1) expression via reverse transcription-quantitative polymerase chain reaction (RT-qPCR) and Western blot. Among the key adipogenic factors, rosiglitazone proved more effective than indomethacin. Extending the induction phase from 4 to 8 days and maintaining dexamethasone throughout the culture markedly enhanced differentiation efficiency. Serum concentration above 5% was inhibitory, while optimal conditions were identified as 5 μM rosiglitazone and 20 μg/mL insulin. The optimized protocol successfully induced beige adipogenesis in ADSCs from eight independent donors, though efficiency varied considerably which could be attributed to individual donor variability. These findings provide a robust in vitro model for studying beige fat biology and highlight the relevance of personalized approaches in metabolic research. Full article