Search Results (646)

The growing demand for sustainable cosmetic products and the rapid expansion of the pet care market have driven the search for environmentally friendly, safe, and effective alternatives to conventional formulations. In this study, an ecofriendly solid shampoo for pets was developed using exclusively natural ingredients and a microbial biosurfactant produced by Starmerella bombicola ATCC 22214 as a surface-active component. The biosurfactant was combined with renewable anionic and nonionic surfactants, conditioning agents, natural oils and butters, and minimal water content to obtain a compact, solid formulation. The shampoo was produced through a controlled multi-phase process and subsequently characterized by physicochemical, microbiological, toxicological, and performance analyses. The formulation exhibited stable pH values suitable for pet skin, low moisture content, absence of free alkalinity, high solid content, and satisfactory foaming capacity. Cleaning efficiency tests demonstrated effective removal of artificial sebum from pet fur while preserving softness and shine. Microbiological assays confirmed the absence of bacterial and fungal contamination, and toxicological evaluations revealed no cytotoxicity and low eye irritation potential. In addition, the shampoo showed 100% biodegradability and maintained physicochemical and organoleptic stability over six months of storage. Overall, the results demonstrate that the developed solid shampoo represents an innovative, safe, and biodegradable alternative that reduces water consumption and plastic packaging, contributing to sustainable development in the pet cosmetics sector. Full article

Achieving optimal skin penetration with bioactive cosmetic ingredients, such as epidermal growth factor (EGF), presents ongoing challenges. This study introduces a novel elastosome-based EGF delivery system co-loading dexpanthenol, which achieves superior skin penetration and multifunctional cosmetic efficacy compared with a conventional liposome formulation. The EGF FLEXIR-SOME formulation was characterized to determine its physicochemical properties measured for comparison against a conventional liposome control. Efficacy and safety were confirmed through in vitro and in vivo evaluations, including clinical trials of the formulation and primary skin irritation tests. The formulated EGF FLEXIR-SOME particles exhibited an average diameter of 124.8 nm and a zeta potential of −57.53 mV, demonstrating enhanced stability and skin penetration relative to the control. The results of clinical trials confirmed significant efficacy in anti-aging, moisture, skin barrier improvement, and hyperpigmentation reduction. Additionally, primary skin irritation tests classified the product as a non-irritant. In conclusion, an elastosome-based EGF formulation significantly enhances skin penetration and bioavailability. The formulation effectively improves skin elasticity, hydration, and barrier function while simultaneously reducing visible signs of aging and pigmentation. This study successfully developed an innovative formulation utilizing elastosome technology, maximizing the transdermal efficiency and stability of EGF, thereby offering a novel strategy for functional cosmeceutical development. Full article

This study aimed to develop an environmentally friendly composite film with effective antibacterial and preservation properties. Silver nanoparticles (AgNPs) were green-synthesized using grape skin extract as a natural reducing agent and incorporated into a PVA/chitosan matrix. The composition of the extract and the structural characteristics of the AgNPs were characterized by UPLC-MS and TEM. The barrier, mechanical performance, antibacterial, and fruit preservation properties of the resulting films were systematically evaluated. The results showed that the incorporation of AgNPs significantly improved the water vapor and oxygen barrier properties of the film and imparted excellent broad-spectrum antibacterial activity. In grape storage experiments, films with higher AgNPs content effectively delayed skin aging and moisture loss, maintaining better visual quality of the fruit. This work provides a green and feasible approach for the preparation of nanoparticle-enhanced antibacterial packaging materials based on natural products, with promising application potential. Full article

This study investigated the effects and mechanisms of broccoli extract containing more than 99.0% β-NMN (BRC) on UVB-induced skin damage, including moisture loss, oxidative stress, inflammation, wrinkle formation, and melanin production, using in vitro and in vivo models. BRC treatment significantly alleviated UVB-induced skin dehydration, oxidative stress, and inflammatory responses, as well as inhibited wrinkle formation and melanin synthesis. Mechanistically, BRC enhanced skin hydration and barrier function by upregulating hyaluronic acid synthases and genes related to sphingolipid metabolism, while simultaneously suppressing NF-κB signaling and COX-2 expression, thereby re-ducing inflammation. Moreover, BRC promoted collagen synthesis by activating the TGF-βR1/Smad3/Collagen pathway and prevented extracellular matrix degradation by inhibiting JNK/c-Fos/c-Jun/MMPs signaling. In addition, BRC modulated the cAMP/PKA/CREB/MITF/TRPs pathway, leading to reduced melanin production. These findings suggest that BRC supplementation may effectively protect against UVB-induced skin damage, supporting its potential application as a functional ingredient for skin health. Full article

The cosmetics industry is experiencing dynamic growth, which poses significant environmental challenges, primarily due to the accumulation of cosmetic ingredients in aquatic and soil ecosystems. In response, sustainable solutions aligned with the principles of the circular economy and the concept of “clean beauty” are increasingly sought. One promising approach is the use of bioferments obtained through the fermentation of plant raw materials from the Asteraceae family as alternatives to conventional extracts in cosmetic formulations. This literature review provides up-to-date insights into the biotechnological transformation of Asteraceae plants into cosmetic bioferments, with particular emphasis on fermentation processes enabling enzymatic hydrolysis of glycosylated flavonoids into aglycones, followed by their conversion into low-molecular-weight phenolic acids. These compounds exhibit improved local skin penetration (i.e., higher local bioavailability within the epidermal barrier) compared to their parent glycosides, thereby enhancing antioxidant activity. The analysis includes evidence-based data on the enzymatic hydrolysis of glycosidic flavonoids into free aglycones and their subsequent conversion into low-molecular-weight phenolic acids, which exhibit improved antioxidant potential compared to unfermented extracts. Furthermore, this narrative review highlights the role of lactic acid bacteria and yeast in producing bioferments enriched with bioactive metabolites, including lactic acid (acting as a natural moisturizing factor and preservative), while emphasizing their biodegradability and contribution to minimizing the environmental impact of cosmetics. This review aims to provide a comprehensive perspective on the technological, dermatological, and environmental aspects of Asteraceae-based bioferments, outlining their potential as sustainable and functional ingredients in modern cosmetics. Full article

Flexible strain sensors capable of conformal integration with living organisms are essential for advanced wearable electronics, human–machine interaction, and plant health. However, many existing sensors require complex fabrication or rely on non-breathable elastomer substrates that interfere with the physiological microenvironment of skin or plant tissues. Here, we present a low-cost, breathable, and highly stretchable strain sensor constructed from biomedical materials, in which a double-layer medical elastic bandage serves as the porous substrate and an intermediate conductive medical elastic tape impregnated with carbon nanotubes (CNTs) ink acts as the sensing layer. Owing to the hierarchical textile porosity and the deformable CNTs percolation network, the sensor achieves a wide strain range of 100%, a gauge factor of up to 2.72, and excellent nonlinear second-order fitting (R² = 0.997). The bandage substrate provides superior air permeability, allowing long-term attachment without obstructing moisture and gas exchange, which is particularly important for maintaining skin comfort and preventing disturbances to plant epidermal physiology. Demonstrations in human joint-motion monitoring and real-time plant growth detection highlight the device’s versatility and biological compatibility. This work offers a simple, low-cost yet effective alternative to sophisticated strain sensors designed for human monitoring and plant growth monitoring, providing a scalable route toward multifunctional wearable sensing platforms. Full article

This study describes the developed special prototype of a wearable measuring device based on a photoplethysmography (PPG) sensor. It contains also a humidity sensor and a thermometer to measure skin moisture and temperature, and a force-sensitive (FSR) element to sense a contact pressure between the measuring probe and the skin surface. All parts of the multi-sensor are shielded, to be applicable in a weak magnetic field environment. After the basic sensor’s functionality verification inside the magnetic resonance imaging tomograph, a set of experiments was performed. Comparative measurements by an oximeter confirm good correspondence with heart rate values determined from PPG (HR_PPG) and FSR (HR_FSR) signals—the mean absolute error lies below 0.5 min⁻¹ for both types. The sensing of PPG signals on wrists was realized for Normal, Dry, and Wet skin. In comparison with normal skin conditions, drying decreases the PPG signal range by 7% and the systolic pulse width by 8%, while moistening increases the signal ripple by 3% and decreases the correlation between HR_PPG and HR_FSR values by 5%. The detailed analysis per hand and gender types yields differences between male and female subjects, while the results for left and right hands differ less. Full article

Pequi (Caryocar brasiliense) oil is a lipid-rich natural ingredient with potential cosmetic applications, but its time-dependent clinical effects on skin remain underexplored. This study aimed to characterize pequi oil using GC-MS, develop a minimalist serum formulation containing the oil, and evaluate its immediate, short-term, and long-term clinical efficacy, as well as perceived efficacy. A serum with 3% pequi oil (SPO) and a vehicle control (SV) were developed and tested in twenty healthy female participants (22–30 years). Stratum corneum water content, transepidermal water loss (TEWL), and sebum content were measured on the malar region at baseline (t0) and after 2 h (t2h), 7 days (t7d), and 28 days (t28d) of application. Porphyrin count and sebaceous gland activity were assessed at t7d and t28d and skin microrelief at t28d. GC-MS revealed oleic acid (55.89%) and palmitic acid (34.90%) as the oil’s main constituents. SPO reduced TEWL and increased skin hydration at t2h and t28d compared to baseline values (p < 0.05). At t28d, SPO significantly reduced oily spots and porphyrin scores and improved skin microrelief. Long-term perceived efficacy indicated better hydration, oil control, and skin feel compared with SV. These findings suggest that pequi oil reduced sebum content and sebaceous gland activity, thereby enhancing skin barrier function, hydration, microrelief, and hydrolipidic balance, supporting its potential as an effective cosmetic ingredient. Full article

The search for alternatives to animal testing in cosmetics has encouraged the development of in vitro systems capable of evaluating formulation-driven biophysical parameters assessed on human skin. This study presents a cell-free tri-layered chitosan membrane as a material-based model for characterizing the physicochemical anti-aging performance of topical formulations. Three cosmetic products were incorporated either in the top layer (1L_(t)) or across all layers (3L), and key parameters—including pore area, water permeation, firmness, elasticity, swelling and moisture retention—were quantified. VitCOil produced consistent effects across configurations, reducing pore area by 52–56% and decreasing water permeation by 54–61%, while increasing moisture retention by 36–38%. OilSerum showed a marked layer-dependent response, enhancing swelling by +70% in 3L and +35% in 1L_(t), and increasing water permeation by 16% (3L) and 4% (1L_(t)). EyeCr improved firmness and elasticity at low concentration, with stronger elastic response in the top layer (+27% in 3L; +34% in 1L_(t)). Overall, this novel platform strengthens early-stage physicochemical screening by linking formulation-dependent mechanisms with directional biophysical trends observed clinically. Full article

Radiation shielding in medical settings has traditionally relied on fixed structural models, with thicknesses and material composition determined by their shielding effect against direct X-rays. However, clinical practice increasingly demands lightweight and biocompatible shielding tools that can be locally applied to specific anatomical regions. Such tools should allow rapid installation and removal, skin protection, and disposable as well as continuous shielding. As a potential solution, this study aimed to improve the effectiveness of a cream-type material that directly coats the skin with shielding agents. A modeling pack was fabricated using bismuth oxide, an eco-friendly shielding material; zinc oxide, commonly utilized in cosmetics for ultraviolet protection; and alginate, which enhances skin adhesion by evaporating moisture. The effects of varying bismuth oxide and zinc oxide ratios on porosity and shielding performance were evaluated to establish assessment criteria for future commercialization. The experimental results demonstrated that higher proportions of bismuth oxide enhanced the shielding effect, while a linear change in shielding rate was observed at a thickness of 1.0 mm. Although pore structure variations were minimal, optimizing inter-particle arrangement may further improve skin adhesion. These findings suggest that cream-type radiation-shielding materials are highly promising for medical applications. Full article

The Olea europaea L., commonly known as the European olive, has been recognized for centuries as one of the most valuable species among useful plants. In contemporary applications, the olive tree provides a wide array of raw materials utilized in the food, pharmaceutical, and nutraceutical industries. Extracts derived from the leaves, bark, and fruits of O. europaea have also gained significant relevance in dermatological and cosmetic formulations. The aim of this paper was to review scientific studies published between 2019 and 2025 concerning the application of olive oil and other derivatives of the European olive in the care of skin, hair, and nails. The analysis underscores the role of olive-derived bioactives in wound healing, stretch mark management, and skin regeneration, highlighting compounds such as oleocanthal and oleuropein in hydration, elasticity, wrinkle reduction, and photoprotection relevant to skin aging. The evidence for olive oil in hair and nail care mainly highlights their moisturizing and strengthening effects, though studies remain limited. O. europaea derivatives show a favorable safety profile with low allergenic potential, and their availability and minimal sensitization risk support use in home cosmetics. The importance of the European olive and its products is expected to grow in the coming years. However, the availability of technologies for processing waste materials obtained from this plant, as well as the associated technological costs, remain significant limitations. Full article

Among the microorganisms present in the microbiome of Camellia japonica flowers, extracellular vesicles (EVs) derived from Leuconostoc mesenteroides were isolated to investigate their modulatory effects on moisturizing and barrier-related molecular markers. To identify the function of major proteins in L. mesenteroides DB-21-derived extracellular vesicles (LEVs), Gene Ontology (GO) analysis was performed, revealing ATP binding, ribosomal structural proteins, and metal ion binding as predominant molecular-function categories. These proteomic characteristics provide a molecular context that supports the interpretation of the moisturizing and barrier-related responses observed in this study. To further verify new findings, we performed functional evaluations using in vitro and 3D skin models. LEVs increased the mRNA expression level of HAS3, which encodes hyaluronic acid synthase. In addition, the expression levels of filaggrin and involucrin, key proteins involved in skin barrier formation, increased, and these markers were determined a concentration-dependent increase in a 3D artificial skin model. Also, we confirmed that the expression levels of filaggrin and involucrin, which were reduced by UVB damage, were restored when LEVs were applied. In conclusion, LEVs are effective in enhancing various molecular markers related to the skin barrier function, and these results reveal that they hold promise as next-generation microbiome-based functional ingredients. Full article

This paper presents a knowledge-based and interpretative model for the conservation of the House of Arianna, located in the Archaeological Park of Pompeii, developed within the CHANGES project, Spoke 6—History, Conservation and Restoration of Cultural Heritage. The research focused on two critical components of the site: the free-standing peristyle columns and the mosaic and frescoed surfaces preserved in situ. This workflow yielded a high-resolution digital model, analytical condition maps, and diagnostic datasets that directly inform conservation decisions. The results show that the columns exhibit internal discontinuities and weaknesses at their joints, a condition linked to heterogeneous construction techniques which increases the risk of drum slippage under wind and seismic loading. The mosaics display a marked loss of tesserae in exposed sectors over recent years, driven by moisture ingress, biological growth and mechanical stress. These findings support the adoption of low-impact, reversible measures, embedded within a prevention-first strategy based on planned conservation. The study formalizes a replicable methodology that aligns diagnostics, monitoring and conservation planning. By linking ‘skin’ and ‘structure’ within a unified interpretative matrix, the approach enhances both structural safety and material legibility. The workflow proposed here offers transferable guidance for the sustainable preservation and inclusive interpretation of exposed archaeological ensembles in the Vesuvian context and beyond. Full article

Since the causes of aging are diverse, anti-aging requires a wide range of strategies. Kampo, a traditional medicine of Japan, which has its roots in traditional Chinese medicine, is generally prepared by combining several natural compounds to produce a multiple pharmacological effect, which is considered useful against aging with various changes. In this study, we evaluated the effects of a medical cosmetic Kampo cream on 14 healthy female subjects aged 31 to 59 years with dry skin and shallow wrinkles at the corners of the eyes using the split-face method. The subjects applied the test cream to only one side of their faces twice a day for 4 weeks. Their wrinkles around the eyes on both sides of their faces were evaluated from photographs taken by expert examiners who were blinded to the subjects. The effects on skin condition were also assessed using a questionnaire given to the subjects. Judgments made by the experts from the photos suggest that the wrinkles on the side of the face where the cream was used were improved, while those on the other side were not. The reduction in wrinkles was more pronounced in elder subjects. This reduction in wrinkles on the test side of the face was also supported by the results of the questionnaire administered to the subjects. In addition to wrinkles, many other aging-related parameters such as skin softness, makeup adhesion, smoothness, tightness after washing the face, and moisture were suggested to be improved with the use of the test cream. These results indicate that the application of the Kampo cream for 4 weeks showed an anti-wrinkle effect and the preservation of the facial skin in a healthy condition, which may be due to the combined effects of the natural ingredients used in Kampo medicine. Full article

Despite extensive use of polyvinylpyrrolidone (PVP)–polyethylene glycol (PEG) hydrogels in biomedical adhesives, a systematic understanding of how water content governs their rheological and adhesive performance remains lacking—particularly under variable humidity. This work addresses this gap by introducing 3–12 wt% hydroxypropyl cellulose (HPC) as a non-covalent crosslinker into a PVP/PEG gel (2/1 wt/wt) to tune its moisture uptake and stabilize viscoelasticity, thereby enabling robust, humidity-adaptive adhesion. Analysis of water content in hydrogels across a relative humidity range of 3% to 100% revealed that HPC restricts their water absorption capacity, thereby enhancing their tolerance to high-humidity conditions. The adhesive and rheological properties of the hydrogels were investigated as functions of HPC and water concentrations. With an increase in the HPC content, the adhesive properties of the initial low-water hydrogels decreased. However, high humidity strongly affected the hydrogels’ adhesive and rheological properties. The water content for hydrogels to maintain their adhesive properties was about 7–16%, depending on the hydrogel composition. This range corresponds to relative air humidity of 45–80%, tending to shift towards more moisture conditions under the effect of HPC. Thus, HPC enables PVP/PEG adhesives to operate over a broader range of relative humidities and in contact with wet skin when used in medicine as matrices for transdermal therapeutic systems, wound dressings, and flexible electrodes. Full article