Search Results (231)

Clove essential oils (CEOs) are widely studied because of their biological potential; however, their applications are limited because of their water immiscibility. Microemulsions (MEs) can protect, deliver, and enhance the biological activities of CEOs, including their antioxidant and cytotoxic activities. In this research, the effects of ethanol as a cosurfactant and the polysorbate 80:cosurfactant mixture (S_mix = 1:0, 9:1, 7:1, 5:1, 3:1, and 1:1) on the formation of CEO-MEs were evaluated via a pseudo-ternary phase diagram. After 35 days, all the systems produced clear, monodisperse, and thermodynamically stable MEs, characterized by average sizes below 25.6 nm and low polydispersity index values (<0.21). The S_mix dose–response experiments without CEO revealed that the S_mix ratios of 1:1 and 3:1 resulted in the lowest cytotoxicity to HT-29 (colorectal adenocarcinoma) cells. The antioxidant capacity of the CEO-ME was greater than that of the CEO. Finally, the CEO-MEs enhanced the in vitro cytotoxic activity of the CEO against Caco-2, HT-29, HeLa, PC-3, and A549 cancer cells. These findings provide valuable information for the development of low-energy clove essential oil MEs for potential incorporation into functional foods and pharmaceutical products. Full article

Polymer flooding is a highly promising enhanced oil recovery (EOR) technique for improving sweep efficiency, particularly in complex reservoirs at advanced stages of water production. While polymer flooding effectively improves sweep efficiency, efficient mobilization of residual oil requires further reduction in interfacial tension. Surfactant systems capable of forming microemulsions have therefore been introduced to enhance oil displacement through improved oil mobilization. The underlying oil displacement mechanisms of microemulsions are strongly dependent on phase behavior, which is governed by Winsor phase conditions. In this study, the pore-scale oil displacement mechanisms of Winsor I, II, and III microemulsion systems were systematically investigated using glass micromodel experiments. Winsor I mainly promoted oil detachment and emulsification, leaving residual oil as corner-bound oil and dispersed droplets. Winsor II showed limited efficiency due to its oil-continuous nature and viscous water-in-oil emulsions, resulting in persistent columnar residual oil. In contrast, Winsor III formed a continuous middle-phase microemulsion, enabling a solubilization-migration mechanism that effectively mobilized and transported oil. Accordingly, Winsor III achieved the highest recovery (81.37%), followed by Winsor I (75.6%) and Winsor II (64.9%). Optimized microemulsion slug injection further improved performance, with Winsor II-III-I reaching 82.2% and Winsor III-I sequence achieved the highest recovery of 85.6%. This study provides a mechanistic framework linking Winsor phase behavior to oil mobilization and demonstrates that both phase optimization and slug design are critical for improving microemulsion flooding performance in complex reservoir conditions. Full article

Lipopeptide biosurfactants and petroleum sulphonates (PSs) have complementary molecular structures that can achieve ultralow interfacial tension (IFT), which is considered the primary mechanism for enhanced oil recovery (EOR). In this study, the phase behavior of lipopeptide compounded with PS/crude oil/water was investigated, which revealed that lipopeptide addition led to the formation of Winsor III middle-phase microemulsion. The synergistic mechanism of ultralow IFT and microemulsion formation enables the lipopeptide-compounded system (LASP) to achieve superior oil displacement efficiency compared with the regular alkaline/surfactant/polymer (ASP) flooding system. Core flooding results proved that under the same conditions, the LASP system increased oil recovery by 10.58% relative to the ASP system. Furthermore, when the ASP system could no longer improve recovery, switching to the LASP system provided an additional 9.55% oil recovery rate. Moreover, the LASP system exhibited superior wettability, interfacial activity, and anti-adsorption properties. These findings highlight the potential of lipopeptide biosurfactants as high-performance, environmentally friendly alternatives to synthetic surfactants in EOR processes. Full article

The development of stable and efficient essential oil delivery systems remains a persistent challenge in active food packaging applications. This research aimed to develop a multi-functional soy protein isolate (SPI)-based composite gel film integrating a tea tree oil micro emulsion (TME) via a microemulsion-in-gel approach, featuring sustained antioxidant release. The TME was first optimized using pseudo-ternary phase diagrams and exhibited excellent physicochemical stability. It maintained a droplet size ranging from 10 to 13 nm, with a polydispersity index (PDI) less than 0.2 under diverse stress situations (such as dilution, heat treatment, pH change, centrifugation, and 30-day storage). Afterward, TME-SPI composite gel films containing 1 to 3% TME were fabricated through solution casting and subsequent gelation of the protein matrix. The incorporation of TME markedly improved the properties of the gel film network. It raised the opacity by around 2.5 times, boosted the elongation at break to 144% (which is three times that of the control), and distinctively enhanced both water solubility and the water vapor barrier. Importantly, the 2% TME-SPI gel film exhibited sustained antioxidant activity from within the gel matrix, retaining more than 50% of its original 1,1-diphenyl-2-picrylhydrazyl (DPPH) scavenging activity after 72 h, significantly outperforming films containing free TTO. The microemulsion-in-gel approach was shown to be effective in creating SPI-based gel films that possess combined light-barrier characteristics, adjustable moisture resistance, improved flexibility, and extended antioxidant release. This offers a promising framework for the next generation of active food packaging. Furthermore, the composite gel films exhibited concentration-dependent antibacterial activity against Staphylococcus aureus, with the 3% TME-SPI film achieving an 82% inhibition rate, thus experimentally validating its active packaging potential. Full article

An eco-friendly microemulsion biofungicide derived from Allamanda cathartica was developed for the control of papaya anthracnose caused by Colletotrichum gloeosporioides. The formulation was prepared by blending surfactants, carrier oil, and water and optimized using ternary phase diagrams to identify stable microemulsion systems. All selected formulations exhibited surface tension values ranging from 29 to 31 mN/m, while particle sizes ranged from 51.79 to 1801.05 nm. The optimized formulation, coded as AM8, consisted of 35% Allamanda concentrated liquid crude extract (ACLCE), 26% water, 13% alkyl polyglucoside surfactant, and 26% dimethylamide oil. Papaya fruits coated with the formulations showed significant reductions (p < 0.05) in anthracnose incidence caused by C. gloeosporioides. Control fruits treated with water showed 75% disease incidence, whereas fruits treated with benomyl showed 42% disease incidence. Disease incidence, severity, and disease index decreased with increasing formulation concentration, and fruits treated with the eight formulations at 10% concentration exhibited significantly lower disease incidence (0–17%) and disease index (0–17%), with disease severity consistently scored as zero. The Allamanda formulation demonstrated strong antifungal activity with EC₅₀ and EC₉₅ values of 1.839 and 7.067 mg/mL (w/v), respectively, at the 95% confidence level. The optimized formulation AM8 remained stable for up to one year and showed superior disease control performance compared with the conventional fungicide benomyl. In addition, the formulation maintained fruit quality by preserving firmness, peel color, and soluble solids concentration, thereby extending papaya shelf life up to 30 days without adversely affecting the natural ripening process. These findings demonstrate the potential of Allamanda-based microemulsion formulations as sustainable biofungicides for postharvest control of papaya anthracnose and provide a promising alternative to conventional synthetic fungicides. Full article

The search for harmless alternative solutions to protect crops has become urgent and has recently attracted widespread attention from researchers around the world focusing on natural polyphenols, which represent a treasure chest of molecules with potent activities. Due to the low water solubility of polyphenols, microemulsions were selected as nanovectors. Curcumin and mangiferin solubility in different excipients was evaluated by HPLC. Microemulsion was developed using pseudo-ternary phase diagrams. Sizes and polydispersity of microemulsion globules were evaluated by dynamic light scattering. Activity against Fusarium verticillioides was evaluated by a microdilution method. Vitamin E acetate was selected as the oily phase, Transcutol P as cosurfactant and Tween 80 as surfactant. S_mix was composed of Transcutol P and Tween 80 in a 1:2 gravimetric ratio and combined with oil-phase vitamin E acetate at a weight ratio of 3:1. Microemulsions were loaded with 5 mg/mL of each polyphenol and recovery results were 99.5% and 99.3% for curcumin and mangiferin, respectively. Sizes of the lipid phase were 121.7 ± 29.2 nm and 172.6 ± 19.3 nm, respectively, for mangiferin and curcumin microemulsions. F. verticillioides was very susceptible to both microemulsions with a very high activity at a dose of 0.9 mg/mL (log-4 reduction), evidencing a possible use of these nanoformulations to protect crops from F. verticillioides. Full article

This study developed a microemulsion system based on diatomaceous earth (DE) for the topical delivery of resveratrol. The microemulsions were prepared using pseudo-ternary phase diagrams. A 4:1 ethanol:virgin coconut oil ratio resulted in a larger microemulsion region than a 3:1 ratio. Two formulations with oil (ethanol:virgin coconut oil, 3:1):Cremophor RH40:water ratios of 1:5:4 (ME1) and 2:5:3 (ME2) were selected for resveratrol loading and subsequently combined with DE at ratios of DE:microemulsion (DE:ME) 0.5:1, 0.5:2, and 0.5:3. The transmission electron microscopy images demonstrated the different microstructures of the microemulsions. Rheological analysis revealed an increase in storage modulus and a decrease in the linear viscoelastic region with increasing DE concentration, particularly in ME1. Differential scanning calorimetry showed disruption of boundary water following DE incorporation. Fourier-transform infrared spectroscopy indicated primarily physical interactions between resveratrol and the DE:ME system. DE:ME demonstrated high resveratrol content, approaching 100%. DE:ME1 0.5:2 significantly enhanced resveratrol permeation, resulting in a 3-fold increase compared with the microemulsion alone after 8 h. DE:ME1 0.5:2 and DE:ME2 0.5:3 enhanced the photostability of resveratrol and the formulations remained stable after storage at 40 °C for 6 months. The DE:ME system maintained its cellular uptake capability, preserved the biological activity of resveratrol, and exhibited low cytotoxicity in human keratinocytes, with cell viability remaining above 70%. These results highlight the potential of DE-based systems for incorporating microemulsions of low-water soluble photo-sensitizing substances in topical drug delivery applications. Full article

Ozone layer depletion exacerbates UV-induced skin damage, including oxidative stress and DNA lesions, thereby increasing the risk of photoaging and malignant transformation. Natural extracts have gained increasing attention as a photoprotective ingredient in cosmeceutical products. Kaempferia galanga, a species in the Zingiberaceae family traditionally used for skin-related treatment and listed in the CosIng database, exhibits multiple biologically relevant properties; however, its anti-photoaging and anti-photo-senescence effects in human dermal fibroblasts remain unexplored. This study investigated the in vitro photoprotective effects of K. galanga extract against UVB-induced photoaging and cellular senescence in human dermal fibroblasts. The ethanolic extract of K. galanga rhizomes (EKGRs) contained ethyl p-methoxycinnamate (EPMC) as a major constituent (33.7 ± 3.7% (w/w) of the crude extract), identified by HPLC-UV. Additionally, EKGR exhibited significant protective effects in UVB-irradiated fibroblasts. EKGR showed no cytotoxicity at concentrations up to 50.0 µg/mL, as determined by the MTT assay. EKGR pretreatment significantly reduced UVB-induced cellular senescence in human dermal fibroblasts compared with UVB-exposed cells (22.2 ± 2.7% vs. 36.7 ± 8.0%). Furthermore, pretreatment with EKGR prior to UVB exposure resulted in a significant increase in pro-collagen type I production (37,075.1 ± 7532.2 pg/mL) and a concomitant decrease in MMP-1 secretion (25,754.1 ± 4042.0 pg/mL) relative to UVB-exposed cells (26,845.8 ± 1454.6 and 39,910.8 ± 6035.1 pg/mL, respectively). To demonstrate formulation feasibility, EKGR was incorporated into an oil-in-water microemulsion, which exhibited concentration-dependent SPF enhancement. Collectively, these findings demonstrate the photoprotective efficacy of EPMC-rich EKGR and highlight its potential as a cosmeceutical ingredient for mitigating UVB-induced photo-senescence and skin aging, with an additional SPF boosting effect. To our knowledge, this study provides the first evidence of EKGR-mediated protection against UVB-induced cellular senescence in human dermal fibroblasts. Full article

As oil and gas development increasingly targets low and ultra-low permeability reservoirs, conventional recovery techniques often prove insufficient for mobilizing residual oil. Surfactant flooding, a key chemical enhanced oil recovery (EOR) technology, thus requires careful system optimization and mechanistic investigation. This study focuses on low-permeability reservoirs in the Changqing Oilfield, evaluating three surfactant systems—YHS-Z1 (a 7:3 mass ratio blend of hydroxypropyl sulfobetaine and cocamide), YHS-Z2 (a polyether carboxylate, a nonionic-anionic composite) and a middle-phase microemulsion system (Heavy alkylbenzene sulfonate and hydroxysulfobetaine were combined with a mass ratio of 7:3)—through a series of experiments including interfacial tension measurement, contact angle analysis, static and dynamic oil displacement tests, as well as emulsion transport/retention index assessments, to comprehensively characterize their oil displacement properties. Based on the experimental data, this study constructed four classical regression models: Ridge Regression, Random Forest (RF), Gradient Boosting Regression (GBR), and Support Vector Regression (SVR), and conducted a comparative analysis of their predictive performance. The results demonstrate that the Random Forest (RF) model achieved the optimal prediction performance, with a Mean Absolute Error (MAE) of 1.8245, a Mean Absolute Percentage Error (MAPE) of 4.78%, and a coefficient of determination (R²) of 0.9428 on the training set. Further analysis using the SHapley Additive exPlanations (SHAP) algorithm revealed that the retention index is the primary global factor (accounting for 49.79% of the variance), while significant intergroup differences exist in the primary factors across different surfactant systems. Concurrently, single-factor and multi-factor sensitivity analyses were conducted to elucidate synergistic effects and threshold behaviors among parameters. The optimal parameter combination, identified via a random search method, achieved a predicted recovery factor of 45.61%, representing a 6.57% improvement over the highest experimental value. This study demonstrates that machine learning methods can effectively identify the dominant factors in oil displacement and enable synergistic parameter optimization, thereby providing a theoretical foundation for the efficient development of surfactant flooding in low-permeability reservoirs. Full article

This study presents a promising strategy for the fabrication of a novel chitosan-based nanogel-in-oil system by integrating the development of a water-in-oil (W/O) microemulsion containing chitosan as a template, followed by crosslinking with genipin, a natural crosslinking agent, via emulsion crosslinking. To develop the W/O microemulsion template, nanometer-sized internal aqueous droplets were successfully formed in cottonseed oil, a vegetable oil, using a blend of nonionic surfactants, polysorbate 80 and sorbitan monooleate. A pseudoternary phase diagram was constructed to investigate the phase behavior of systems composed of chitosan solution, mixed surfactant, and cottonseed oil. Compositions falling within the monophasic region were selected for further formulation optimization. The microemulsions were characterized for droplet size, size distribution, electrical conductivity, and viscosity. The optimal microemulsion exhibited W/O characteristics with the lowest viscosity. Dynamic light scattering (DLS) analysis confirmed the presence of uniformly distributed nanometer-sized droplets, as evidenced by a Z-average diameter of 92.9 ± 2.3 nm and a PDI of 0.100 ± 0.072. The microemulsion system demonstrated physical stability, as confirmed by centrifugal testing. Crosslinking of chitosan with genipin was monitored by fluorescence intensity measurements of the crosslinking products. Fourier transform infrared spectroscopy further confirmed the formation of genipin-crosslinked chitosan structure. DLS and transmission electron microscopy revealed that the nanogels possessed nanoscale dimensions and discrete spherical morphologies. Overall, this approach demonstrates a viable route for producing a nanogel-in-oil system by combining microemulsion templating with emulsion crosslinking. Full article

Spodoptera frugiperda (J.E. Smith) (Lepidoptera: Noctuidae) is an agricultural pest of global economic importance. Its ability to reproduce, adapt, and develop resistance necessitates the creation of effective and environmentally friendly alternative control strategies. This study aimed to evaluate the larvicidal activity of three nanoformulations (NFs) based on the essential oil (70% safrole) of Piper auritum Kunth (Piperales: Piperaceae), nanoemulsion (NE), microemulsion (ME), and silver nanoparticles (AgNPs), against second-instar larvae of S. frugiperda. The NFs were prepared using a combination of low- and high-energy methods, using Tween 80 and Span 80 as stabilizing agents. The droplet sizes of the NFs ranged from 19 to 48 nm. Stability analysis of the formulations maintained for 60 days in open systems at room temperature allowed the identification of remaining oxidized sesquiterpenes and phenylpropanoids. In in vitro bioassays, the NE demonstrated the highest larvicidal activity, with an LD₅₀ of 0.97 µg cm⁻², outperforming the other formulations by a factor of ten. Observations of morphological damage to larval and pupal tissues, along with deformation of adult specimens, confirming the toxicity of the NFs. These findings highlight the potential of essential oil-based NFs derived from P. auritum as sustainable biopesticides for integrated pest management. Full article

The development of polymer-based systems is central to the design of next-generation drug delivery carriers, as polymers enable versatile tuning of physicochemical properties and responsiveness. In this work, we introduce a 3D printing-based strategy for the fabrication of multicompartment capsules that integrate multiple polymers within a unique one-step process. This approach allows precise spatial organization and structural complexity, yielding capsules with customizable features such as compartmentalization, polymer-specific responsiveness, and localized release control. In particular, pH-triggered release can be programmed across distinct polymeric regions of the capsules, enabling site-specific delivery along different intestinal segments, including the small intestine and colon. The use of 3D printing thus provides a scalable and adaptable platform to generate multifunctional polymer-based carriers with finely tunable drug release profiles, paving the way for new directions in polymer-enabled controlled delivery technologies. Full article

Background: Photoaging, induced by chronic ultraviolet (UV) exposure, is a multifactorial skin disorder characterized by oxidative stress, inflammation, and extracellular matrix degradation. Ganoderma lucidum glycoprotein (Gl-Gp) exhibits potent antioxidant activity, but its topical application is limited by poor transdermal permeability. This study aimed to develop a microemulsion-based system to enhance Gl-Gp delivery and evaluate its anti-photoaging efficacy. Methods: Gl-Gp was extracted and purified from G. lucidum fruiting bodies and structurally characterized for O-glycosidic linkages and O-GlcNAc modifications. Fourier-transform infrared (FT-IR) spectroscopy further confirmed the polysaccharide–protein complex structure of Gl-Gp. A water-in-oil Gl-Gp microemulsion was prepared and assessed in vitro for antioxidant and cytoprotective effects in HaCaT cells, including reactive oxygen species (ROS) reduction, mitochondrial membrane potential stabilization, and apoptosis inhibition. Transdermal penetration was compared with aqueous Gl-Gp. In vivo efficacy was evaluated in a UV-induced rat model by measuring skin morphology, histology, oxidative stress markers, matrix metalloproteinases, and proinflammatory cytokines. Results: The microemulsion enhanced Gl-Gp stability and transdermal delivery. In vitro, it reduced ROS, preserved mitochondrial function, and decreased apoptosis in HaCaT cells. In rats, topical application attenuated erythema and epidermal hyperplasia, promoted dermal restoration, increased SOD and GSH-Px activities, and decreased MDA, hydroxyproline, MMPs, and inflammatory mediators. Conclusions: The Gl-Gp microemulsion exerts antioxidant, anti-inflammatory, and anti-collagen-degrading effects, representing a promising strategy for transdermal delivery and topical prevention of photoaging. Full article

Background and Objectives: Age-related macular degeneration (AMD) is an age-associated retinal disorder characterized by blood–retinal barrier (BRB) breakdown and pathological angiogenesis, leading to vascular leakage. The intravitreal administration of anti-VEGF agents remains the most effective treatment for neovascular AMD. However, repetitive intravitreal injections have risks, causing side effects such as cataracts, bleeding, retina damage, and, in severe cases, post-injection endophthalmitis. Hence, the development of innovative drug delivery systems is essential to minimize the risks and discomfort associated with intravitreal injections. Materials and Methods: We developed a microemulsion (ME)-based topical drug delivery system incorporating α-linolenic acid (ALA). In brief, pseudo-ternary phase diagrams were constructed by the water titration method using different combinations of surfactants and cosurfactants (S_mix-Cremophor RH 40: Span 80: Transcutol P in ratios of 1:1.05, 1:1:1, 1:1:1.5) containing ALA as the oil phase. Three blank microemulsions (ME1, ME2, and ME3) were prepared and characterized based on the optimized pseudo-ternary phase equilibrium with a S_mix ratio of 1:1:1. Results: ME3, with an average particle size of 38.59 nm, was selected as the optimized formulation for developing drug-loaded ME containing Fenofibrate, Axitinib, and Sirolimus. The drug-loaded ME showed particle size (46.94–56.39 nm) and in vitro release displayed sustained and longer time drug release for 240 h. The irritation and antiangiogenic activities were evaluated using the hen’s egg chorioallantoic membrane (HET-CAM) assay employing the optimized ME loaded with each drug. Among the three drug-loaded ME, the Sirolimus ME showed a reduction in blood vessel sprouting in the HET-CAM assay, indicating strong antiangiogenic activity. Treatment with the optimized blank ME and Sirolimus ME significantly (p < 0.05) reduced COX-2 protein expression in LPS-stimulated RAW 264.7 cells, suggesting their potential anti-inflammatory effects. Conclusions: Overall, we suggest that the α-linolenic acid-based Sirolimus microemulsion may serve as a promising topical therapeutic approach for managing AMD and offering a potential alternative to invasive intravitreal injections. Full article

Objectives: The current work aimed to formulate and optimize a self-emulsifying microemulsion drug delivery system (SEME) for acemetacin (ACM) to increase ACM’s aqueous solubility, improve oral bioavailability, and reduce gastrointestinal complications. Methods: Screening of components capable of enhancing ACM solubility was performed. Pseudo-ternary phase diagrams were performed to choose the optimal formulation ratio. The ACM-SEME formulation’s composition was optimized using D-optimal design. Oil, S_mix, and water percentages were used as independent variables, while globule size, polydispersity index, ACM content, and in vitro ACM release after 90 min were used as dependent variables. Also, thermodynamic stability and transmittance percentage tests were studied. Zeta potential was assessed for the optimized ACM-SEME formulation, which was then subjected to spray drying. The dried ACM-SEME was characterized using field-emission scanning electron microscope, Fourier-transform infrared spectroscopy, X-ray diffraction, and differential scanning calorimetry. The dried ACM-SEME formulation was filled into hard gelatin capsules and coated with Eudragit L100 to achieve pH-dependent release. Results: The antinociceptive activity of ACM-SEME was evaluated in vivo using Eddy’s hot plate test in rats, revealing a significant prolongation of the noxious time threshold compared to control groups. Ex vivo permeation studies across rat intestinal tissue confirmed the enhanced permeation potential of the ACM-SEME. Conclusions: It was concluded that the developed ACM-SEME system demonstrated improved physicochemical properties, enhanced release behavior, and superior therapeutic performance, highlighting its potential as a safer and more effective oral delivery platform for ACM. Full article