Search Results (818)

Shoot density is a key viticultural factor modulating canopy microclimate, berry composition, and wine quality, although yield–quality relationships are strongly influenced by environmental conditions. Saignée, a winemaking technique involving partial juice removal prior to fermentation, increases the skin-to-juice ratio and may enhance phenolic extraction. This study assessed the combined effects of shoot density (33 [T1], 20 [T2], and 15 [T3] shoots/m) and saignée (20% vs. control) on yield, grape composition, and wine chemical and sensory properties in Malbec across two vintages (2021–2022). At harvest, the pruning weight, yield components, general maturity parameters, and phenolic composition were measured. The wines were analysed for their phenolic and elemental composition, polysaccharides and volatile compounds, colour, and sensory attributes. T1 exhibited the highest yields and vegetative imbalance, whereas T2 and T3 achieved optimal Ravaz indices. The general grape maturity parameters were unaffected; however, T3 had increased berry phenolic content in 2022. T2 and T3 had enhanced wine tannins, total phenols, and polymeric pigments, particularly in 2022. Saignée increased the pH, potassium, total phenols, tannins, and acylated anthocyanins. Targeting yields near 4 kg/vine (≈10,500 kg/ha) improved vine balance and phenolic composition, although the responses were strongly modulated by interannual variability. Full article

There is growing interest in the development of sustainable thermal insulating materials from renewable resources, a strategy which can stand as an alternative to conventional petroleum-based insulating materials. In this study, bio-based porous insulating materials derived from partially hydrolyzed collagen (rabbit-skin) and containing ammonium polyphosphate (APP) as flame retardant and miscanthus fibers as reinforcement are prepared. Four freeze-dried formulations were prepared: pure partially hydrolyzed collagen (COL), partially hydrolyzed collagen with APP (COL-APP), partially hydrolyzed collagen with miscanthus particles (COL-M) and a ternary formulation that included both additives (Col-APP-M). The density, porosity, thermal conductivity, specific heat capacity, compressive mechanical properties and fire behavior were evaluated. The neat collagen foam had the lowest density (122 kg·m⁻³), highest porosity (91%), and lowest thermal conductivity (0.045 W·m⁻¹·K⁻¹). The addition of APP and/or miscanthus increased density and showed limited change in thermal conductivity, which remains comparable with insulating materials (0.0445–0.0510 W·m⁻¹·K⁻¹). Specific heat capacities of partially hydrolyzed collagen foams were also relatively high (1319–1390 J·kg⁻¹·K⁻¹) as compared to some other typical insulating materials. Mechanical experiments demonstrated that APP had considerably improved the compression stiffness and strength through the physical crosslinking and densification effects in the partially hydrolyzed collagen network. Analysis of fire behavior with both Pyrolysis Combustion Flow Calorimetry (PCFC) and cone calorimetry further indicated that the addition of APP yielded improved flame retardancy with a very low heat release. These results showed that partially hydrolyzed collagen-based foams reinforced by APP and lignocellulosic particles are sustainable thermal insulation materials with desired thermal performances, improved mechanical stability, and enhanced flame retardancy. Full article

Skin aging is a central focus of skin health. Supramolecular chemistry has emerged as a powerful strategy for enhancing the performance of cosmetic active ingredients. Adenosine is a promising anti-aging ingredient in skincare products, but its cosmetic application is limited by poor water solubility and low skin penetration. This study developed a supramolecular complex combining adenosine with ectoine through cocrystallization. The supramolecular assembly was characterized by differential scanning calorimetry (DSC) and thermogravimetric analysis (TGA). Powder X-ray diffraction (PXRD), Fourier-transform infrared spectroscopy (FTIR) and density functional theory (DFT) calculations revealed extensive hydrogen-bonding networks between the components. The optimal supramolecular composition (1:1.5 molar ratio) achieved a 5.5-fold increase in water solubility. The supramolecular organization enhanced skin permeability by 3.1-fold in ex vivo porcine skin models. In fibroblast cell models, the supramolecular system exhibited superior antioxidant activity with 30.3% greater reactive oxygen species (ROS) reduction and restored cellular adenosine triphosphate (ATP) levels by 2.1-fold under H₂O₂-induced oxidative stress compared to individual components. These findings demonstrate that the adenosine–ectoine supramolecular complex represents an innovative multifunctional ingredient for basic anti-aging cosmetics, offering enhanced delivery, improved safety, and superior biological efficacy through supramolecular engineering. Full article

Cutaneous tissue engineering has advanced from simple coverage substitutes to increasingly complex living constructs, yet the field remains constrained by a decisive problem: timely and durable perfusion. Many engineered skin substitutes can appear vascular in static culture or in small-animal models. However, they still fail when blood flow must be established quickly enough to rescue cells across clinically relevant tissue thickness. Rather than re-catalog platforms already summarized in recent reviews, this critical narrative review reframes the field around perfusion as the master functional endpoint rather than vessel density alone. We analyze the vascularization bottleneck as a sequence, internal network formation, host inosculation, flow initiation, and perfusion stability—and use that sequence to reassess biomaterial design, cell-based strategies, immunomodulation, decellularized matrices, bioprinting, microfluidics, and prevascularization. We intentionally distinguish implantable skin substitutes from perfused in vitro platforms such as skin-on-chip systems, arguing that these are linked but non-interchangeable application spaces with different success criteria. Building on this distinction, we propose a research agenda centered on functional benchmarking of perfusion, spatiotemporal coordination of scaffold dynamics, immune–mural–lymphatic–vascular crosstalk, scalable hierarchical vascular fabrication, and predictive human test platforms. The central argument is that translation will depend not on ever more isolated pro-angiogenic interventions but on integrated systems that survive the ischemic interval, connect rapidly, tolerate blood entry, maintain a workable inflow–outflow balance, and remodel into a stable, skin-specific microvasculature. Full article

Surface roughness of woven fabrics plays a key role in tactile comfort and skin–textile interaction, particularly in medical applications involving prolonged contact with human skin. This study focuses on the surface roughness of woven fabrics in plain and twill (1/3 S) weaves intended for hospital bed sheets and bedding applications. Plain weave represents a structurally symmetric system, while twill weave exhibits a pronounced diagonal structure. Roughness was evaluated using the Fabric Touch Tester (FTT) and further analyzed through amplitude (Rq), height distribution (Rku), and frequency-related parameters (linear peak density) obtained by signal processing and peak analysis in OriginPro 2026. The results showed that weave structure is the dominant factor influencing surface topography. Plain weave fabrics exhibited higher amplitude roughness and more uniform height distribution, while twill fabrics showed lower global roughness but stronger directional dependence, particularly in diagonal directions. Linear peak density was not significantly affected by laundering cycles, fiber composition, or finishing, but was strongly dependent on weave type. The findings demonstrate that due to the orthotropic nature of woven fabrics, surface roughness, derived from surface topography, cannot be adequately described by a single parameter, and that a combined analysis of amplitude and spatial descriptors is required, with the surface being evaluated not only along the principal symmetry directions (warp and weft) but also in off-axis directions. These results provide valuable insight for the design of hospital textiles with improved tactile comfort and reduced risk of skin irritation. Full article

Astragalus membranaceus, a medicinal plant used in traditional Chinese medicine for centuries, has attracted growing scientific attention for its potential anti-aging and anticancer properties, particularly for skin and bone health. Its key bioactive compounds like astragalosides, cycloastragenol, and its commercial derivative TA-65, have been associated with telomerase activation and telomere maintenance, suggesting a possible role in modulating cellular senescence and tissue repair processes. In addition to the claimed telomere maintenance, A. membranaceus exhibits antioxidant, anti-inflammatory, and DNA-protective activities, properties that contribute to its anti-aging effects. Emerging evidence also suggests that telomerase modulation by A. membranaceus influences cancer cell dynamics, either suppressing tumor progression through immune regulation and apoptosis induction or, in some contexts, potentially promoting tumor growth. This duality highlights the importance of dose, formulation, and targeted application. Clinically, TA-65 has been reported to improve vascular health, bone mineral density, and skin elasticity in aging individuals. Preclinical studies further support its protective effects against osteoporotic bone loss and photoaging-induced dermal degeneration. This review summarizes the phytochemical composition of A. membranaceus and critically evaluates the mechanistic and therapeutic evidence underlying its anti-aging and anticancer actions on skin and bone tissues. It also discusses the pharmacokinetic properties of A. membranaceus, including its absorption, bioavailability, and safety profile. The integration of A. membranaceus into evidence-based senile therapeutic strategies holds promise, but further mechanistic and clinical studies are required to optimize its safety and efficacy. Full article

Wearable pressure-sensing orthoses are increasingly used in neurorehabilitation to support gait recovery, monitor plantar pressure distribution, and improve patient mobility during repetitive therapy sessions. The performance of these devices depends strongly on the materials used in the skin-contact layer, since material properties influence comfort, flexibility, durability, and force transmission during daily use. This study proposes a hybrid multi-criteria decision-making framework based on the Analytic Hierarchy Process (AHP) and the VIKOR method for material selection in sensor-integrated plantar orthoses. Five candidate materials, ethylene vinyl acetate (EVA), polyethylene (PE), polyurethane (PU), cobalt–chromium–molybdenum alloy (CoCrMo), and polypropylene (PP), were evaluated using five criteria: comfort and skin compatibility, elasticity, fatigue resistance, density, and energy dissipation. AHP was applied to determine the relative importance of the evaluation criteria using expert judgment, while VIKOR was used to rank the material alternatives and identify the compromise solution. The results showed that polyurethane achieved the best overall performance due to its balanced behavior in comfort, elasticity, and fatigue resistance, which are essential properties for long-term wearable neurorehabilitation devices. A sensitivity analysis confirmed that moderate variations in expert weighting did not modify the final ranking. Compared with conventional selection approaches based mainly on isolated material properties, the proposed framework offers a clear and reproducible method for integrating mechanical and user-related requirements into the material selection process for wearable orthoses. Full article

The demand for naturally derived ingredients in cosmetics is constantly growing, with marine algae emerging as promising candidates due to their rich antioxidant and protective metabolites. Skin aging, driven by oxidative stress, impaired hydration, and weakening of the dermal–epidermal junction (DEJ), manifests as dryness, loss of elasticity, and reduced density. Conventional synthetic antioxidants raise safety concerns, highlighting the need for effective natural alternatives. Ecklonia cava, an edible brown seaweed abundant in phlorotannins, has been reported to possess strong antioxidant and anti-inflammatory properties, yet its effects on key molecular markers of hydration and DEJ integrity remain underexplored. In this study, we standardized an E. cava extract (ECE) and evaluated its antioxidant activity, gene regulatory effects, and clinical efficacy. ECE was standardized by measuring total polyphenols and flavonoids, evaluated by DPPH scavenging assay, and shown to upregulate DEJ-related genes, reinforcing dermal–epidermal cohesion. A randomized clinical trial further confirmed that topical application of ECE improved hydration, elasticity, and density compared with placebo, with benefits evident within weeks. Collectively, these findings establish ECE as a multifunctional cosmetic ingredient capable of protecting the skin while enhancing structural and functional aspects of skin health, supporting its potential application in anti-aging skincare. Full article

Background and Objectives: Sjögren’s disease (SjD) is a chronic autoimmune disorder in which the immune system attacks the glands that produce tears and saliva, leading to symptoms such as dry eyes and dry mouth. If left untreated, SjD can also cause inflammation and damage to other parts of the body, including the skin, lungs, kidneys, and nervous system, and increase the risk of developing lymphoma. The human leukocyte antigen (HLA) class II molecule HLA-DR3 is strongly associated with SjD. Materials and Methods: To investigate how post-translational modifications (PTMs) influence the presentation of SjD-associated autoantigens by HLA-DR3, we employed a computational framework to determine the binding of PTM-mimic peptides to HLA-DR3. We further supported the in-silico results with in-vitro experiments. Results: Our analysis revealed that PTM-mimic substitutions at canonical anchor positions rarely improved predicted binding affinity using the Stabilized Matrix Method, with most modifications resulting in reduced affinity. However, a comprehensive analysis of full-length SjD-associated autoantigen sequences (Ro60, Ro52, La) identified discrete regions with high densities of PTM-eligible anchor sites, specifically, the Ro60 HEAT solenoid, Ro52 RING/B-box/PRY-SPRY modules, and the La motif-RRM1 region, suggesting that PTMs may alter epitope presentation in a sequence-dependent manner. Experimental validation of selected PTM-mimic peptides showed enhanced T cell responses, which were associated with increased binding affinity to HLA-DR3. Structural modeling of a representative complex revealed that PTM-mimic peptides adopt a slightly shifted backbone orientation and altered side-chain positioning, leading to a larger peptide–DR3 interaction interface. Conclusions: These findings provide new insights into the role of PTMs in shaping the immunogenicity of SjD-associated autoantigens and highlight the potential for PTM-mimic peptides to modulate T cell responses in SjD. Full article

This study evaluated the safety and effectiveness of HYDRAGEL A2, an injectable medical device containing hyaluronic acid (HA), polynucleotides (PN), and niacinamide, for improving facial skin quality. These ingredients are increasingly recognized for their synergistic effects in aesthetic medicine, with HA and PN providing hydration and skin support, and niacinamide offering anti-inflammatory and antioxidant properties. A prospective, open-label clinical investigation was conducted on 42 female subjects (mean age 45 ± 1 years, Fitzpatrick skin phototypes II-V) to assess skin elasticity, hydration, and mild skin depression correction following cheek area injections. Efficacy was measured using the Global Aesthetic Improvement Scale (GAIS), Antera 3D^® (texture), Cutometer^® (elasticity/firmness), Corneometer^® (hydration), and Dermascan^® (density/thickness) devices at baseline (D0), week 2 (W2/D14), and week 6 (W6/D42). GAIS values showed significant overall facial improvement (p < 0.001) by both investigators and subjects, where 100% of subjects rated their appearance as improved immediately post-injection (D0), with sustained improvements at D42. Objective measurements revealed significant improvements in skin texture (reduced roughness), elasticity, firmness, hydration (p < 0.001), density, and thickness, demonstrating the combined benefits of the HA, PN, and niacinamide blend. Injection site reactions, primarily mild and transient, were reported immediately post-injection. Investigators and subjects reported high satisfaction with the product’s ease of use and aesthetic outcomes. Globally, HYDRAGEL A2, leveraging the established benefits of HA, PN, and niacinamide, was well-tolerated and effectively enhanced facial skin quality, demonstrating significant and sustained improvements in monitored skin parameters. The study concludes that this combination of ingredients, formulated in HYDRAGEL A2, provides a well-tolerated approach associated with improvements in skin quality. Full article

Background/objectives: Alpha-synuclein (aSyn) is best known for its role in Parkinson’s disease. Increasing evidence suggests a bidirectional relationship between diabetes mellitus and synuclein pathology. Carboxymethyllysine (CML), an advanced glycation end-product, serves as a marker of cumulative glycation stress and tissue damage in diabetes. Our study aimed to evaluate epidermal phosphorylated alpha-synuclein at Ser129 (p-aSyn) immunoreactivity in relation to CML accumulation in epidermis. Methods: Skin punch biopsies were obtained from seven diabetic patients with long-standing type 2 diabetes (T2DM), and from seven healthy volunteers. Tissue samples were processed and analyzed by immunohistochemical DAB-staining for p-aSyn and CML. Quantitative analysis was performed by measuring the percentage area of positive staining using Fiji/ImageJ2. Integrated density was also assessed as a complementary threshold-limited measure of staining signal intensity. Statistical analysis and data visualization were conducted using GraphPad Prism. Comparisons between groups were performed using the exact two-tailed Mann–Whitney U test. Results: Area-fraction analysis showed significantly greater CML-positive staining in diabetic epidermis than in controls (median 10.18 vs. 8.955, p = 0.0262), whereas p-aSyn-positive area fraction did not differ significantly between groups (13.53 vs. 14.64, p = 0.8048). In the complementary integrated density analysis, p-aSyn signal was significantly higher in diabetic epidermis than in controls (21,365 vs. 10,960, p = 0.0023), whereas the increase in CML integrated density did not reach statistical significance (14,165 vs. 6585, p = 0.1282). In diabetic epidermis, both markers showed a more widespread distribution, involving basal keratinocyte cytoplasm and extension into suprabasal layers. Control samples showed staining largely restricted to basal cell contours. In serial sections, p-aSyn and CML showed a similar topographic distribution in diabetic skin. Conclusions: These preliminary observations suggest that chronic diabetic skin changes are associated with increased epidermal CML burden when assessed by area fraction and with higher p-aSyn signal intensity when assessed by integrated density. However, because the study was small and based on semiquantitative DAB immunohistochemistry, the findings should be interpreted cautiously and require validation in larger multimodal studies. Full article

Hybrid stepper (HB) motors are widely used in precision actuation systems such as cryogenic refrigerator robotic arms. Under cryogenic working conditions, the core loss characteristics of magnetic materials change significantly, while conventional core loss models calibrated at room temperature can hardly provide reliable prediction accuracy. In this work, the electromagnetic properties of 35SW1900 non-oriented silicon steel were measured from 25 °C − 100 °C using a BROCKHAUS Epstein frame system. Variations in permeability, core loss and coercivity with magnetic flux density, temperature and frequency were obtained. An improved core loss model was developed by introducing a flux-dependent exponent and dual temperature correction coefficients for hysteresis and eddy current losses. Experiments place the prediction error of the proposed model within 4% under cryogenic conditions. Compared with the classical Bertotti model, the proposed model effectively reduces high-frequency deviation caused by the temperature-dependent material properties and skin effect. The core loss of silicon steel increases by 15–30% at −100 °C compared with room temperature, which is mainly attributed to the decrease in resistivity and the strengthening of domain wall pinning. This paper provides an accurate loss prediction method and design references for HB motors applied in ultralow temperature working conditions. Full article

Background/Objectives: Cutaneous squamous cell carcinoma (cSCC) develops through inflammation-driven preneoplastic alterations characterized by epidermal hyperplasia, dysplasia, and increased proliferative activity. C-phycocyanin (C-PC) possesses antioxidant and anti-inflammatory properties; however, its topical potential to attenuate a tumour-promoting cutaneous microenvironment is limited by poor skin penetration. This study evaluated the effects of C-PC-loaded transfersomes in a 7,12-dimethylbenz[a]anthracene (DMBA)/12-O-tetradecanoylphorbol-13-acetate (TPA)-induced mouse model of skin carcinogenesis. Methods: Male BALB/c mice were assigned to six groups (n = 10 per group). Carcinogenesis was initiated with a single topical application of DMBA, followed by twice-weekly TPA application for 16 weeks. C-PC-loaded transfersomes (1 mg/mL or 10 mg/mL) were applied topically. Histopathological assessment included epidermal thickness, rete ridge depth, mitotic activity, mast cell density, and semi-quantitative scoring of hyperplasia, dysplasia, and inflammation. Ki-67 immunohistochemistry was used to evaluate basal and suprabasal proliferation. Results: Carcinogen exposure induced marked epidermal thickening, severe dysplasia, increased mitotic activity, elevated Ki-67 expression, and pronounced dermal inflammation. Treatment with C-PC-loaded transfersomes significantly reduced epidermal thickness, rete ridge depth, mast cell density, mitotic counts, and suprabasal Ki-67 index. The 1 mg/mL concentration demonstrated the most consistent attenuation of dysplasia severity and inflammatory changes. No adverse histopathological alterations were observed in internal organs. Conclusions: These findings indicate that transfersome-mediated topical delivery of C-PC attenuates early inflammation-driven epidermal remodelling and tumour-promoting alterations in experimental skin carcinogenesis, supporting its potential as a topical preventive strategy. Full article

The development of future electrical aircraft, such as the Hybrid-Electric Regional Aircraft (HERA) platform, presents challenging cooling demands due to the heat generated by electric powerplants, fuel cells and power electronics. Traditional heat exchangers in ram air channels may not be sufficient, necessitating alternative solutions like Skin Heat Exchangers (SHXs) to enhance heat transfer and reduce parasitic drag. Aircraft drag reduction and efficiency increase are expected with the integration of SHXs in two-phase cooling systems. This study employs Computational Fluid Dynamics (CFD) models, specifically the Volume of Fluid (VOF) multiphase model together with the Lee model, to simulate the condensation process of two Hydrofluoroolefin (HFO) refrigerants in SHX channels (R1233zd(E) and R1234yf). An analytical model based on empirical equations is used to preliminarily correlate and validate the CFD results, showing deviations below 15%. The simulations reveal distinct flow behaviours for each refrigerant, influenced by the differences in liquid and gas densities. The study also establishes a basis for understanding and selecting the inverse of the relaxation time coefficient, which is crucial for multiphase CFD modelling. The CFD models used in this article could be of great importance for future SHX design optimization. Full article

A recently identified mesenchymal cell population, telocytes (TCs), has been found in many tissues of different animal species. Jet needle-free injection (JNFI) is a promising non-invasive drug-delivery method that can trigger effective immune responses in the skin. In this preliminary morphological study, an inactivated porcine circovirus vaccine was delivered into pig neck skin by JNFI, and untreated normal neck skin served as the control. Histopathology, immunohistochemistry (IHC), immunofluorescence (IF), and transmission electron microscopy (TEM) were used to evaluate TC distribution, ultrastructure, and selected quantitative TEM parameters 24 h after injection. TCs were widely distributed in porcine skin, located between collagen fibers and around blood vessels, adipocytes, and sweat glands. They were also observed in contact with mast cells. TCs around sweat glands were CD34⁺, Vimentin⁺, and α-SMA⁺, whereas TCs at other sites were CD34⁺, Vimentin⁺, and α-SMA⁻. After JNFI, inflammatory cell infiltration into the skin was observed; TCs were in contact with these cells, and TCs surrounding adipocytes redistributed into the adjacent loose connective tissue. Quantitative TEM analysis showed that TC profile density and visible telopod length did not differ significantly between normal skin and JNFI 24 h skin (p ≥ 0.05). In contrast, vesicle profiles per TC increased significantly in both perivascular and adipose-associated compartments (p < 0.05). These findings provide morphological evidence suggesting that TCs may participate in early cutaneous responses after JNFI vaccine delivery. Full article