Search Results (599)

Background: The dissolution of oral solid dosage forms is a key determinant of drug bioavailability, yet traditional testing methods do not capture the real-time surface dynamics of drug release. This study introduces a novel framework combining surface dissolution imaging (SDi2) with an interpretable, dual-wavelength convolutional neural network (CNN) to predict and understand dissolution behavior. Methods: Eight tablet formulations containing acetylsalicylic acid, sodium salicylate, or salicylamide, combined with either lactose or methylcellulose, were analyzed under two distinct, compendial conditions (pH 1.2 and pH 6.8). Results: Our final CNN model, which synergistically processes spectral images (280 nm for API release and 520 nm for structural changes), temporal data, and formulation composition, accurately predicted dissolution profiles, achieving a coefficient of determination of 0.89 and a root mean square error (RMSE) of 11.57. To overcome the “black-box” nature of deep learning, we employed Gradient-weighted Class Activation Mapping (Grad-CAM) to interpret the model’s predictions. The analysis revealed that the model focused on tablet edges at 280 nm, consistent with surface dissolution, and on bulk regions at 520 nm, reflecting structural changes including erosion and gel-layer growth. Conclusions: These findings suggest that integrating real-time imaging with explainable AI methods can support better understanding of dissolution processes in pharmaceutical formulation development. Full article

This work evaluated the influence of oil type (sunflower vs. fish oil) and hydroxypropyl methylcellulose (HPMC) concentration on the properties of oleogels obtained by the emulsion-templated method. Oil-in-water emulsions were prepared and air-dried to produce oleogels containing 2.9–5.8% (w/w) HPMC. All oleogels exhibited solid-like behaviour, with viscoelastic moduli increasing with polymer concentration, and showed a high thermal stability. At a comparable HPMC content, fish oil oleogels developed stiffer networks than those obtained with sunflower oil. Texture analysis indicated a linear increase in hardness with HPMC content across both oils, while cohesiveness and adhesiveness were more influenced by oil nature. Oil-binding capacity (OBC) increased markedly with polymer content, exceeding 90% in most systems. However, fish oil oleogels consistently showed lower retention. Colour parameters were only slightly affected by HPMC concentration and were mainly determined by the intrinsic colour of each oil. Overall, both oil type and polymer concentration were shown to be critical factors determining the structural, mechanical, and functional characteristics of HPMC-based oleogels, providing useful information for the development of structured lipid systems as potential substitutes for conventional solid fats. Full article

The development of effective topical drug delivery systems remains a key challenge in wound management, particularly for bioactive compounds with limited skin permeability. In this study, a nanostructured bigel system incorporating sodium humate-loaded ultra-deformable vesicles (UDVs) was developed and evaluated for wound healing applications. Sodium humate-loaded UDVs were prepared using a thin-layer hydration method, and the influence of key technological parameters (phospholipid/glycerol concentrations, sonication time) on vesicle size and encapsulation efficiency was investigated. An optimized UDV formulation characterized by small particle size, high stability, and high drug encapsulation efficiency was selected and incorporated into a bigel composed of hydroxypropyl methylcellulose hydrogel and andiroba oil oleogel. The developed bigels were characterized in terms of microstructure, physical stability, pH, spreadability, and rheological behavior, demonstrating suitable properties for dermal application. In vivo wound healing evaluation in rat wound models revealed that bigels containing sodium humate-loaded UDVs significantly enhanced wound closure and tissue regeneration compared to control and reference treatments. Histopathological analysis confirmed improved granulation tissue formation and complete epithelialization. Overall, the results demonstrate that the proposed UDV-loaded hybrid bigel represents a promising nanostructured platform for enhanced dermal delivery and wound healing therapy. Full article

Olive mill wastewater (OMW) is an agro-industrial byproduct rich in polyphenols and other bioactive compounds with documented antioxidant and antimicrobial properties. In this study, purified OMW fractions (RO1 and MD2), previously characterized by high polyphenol content and strong antioxidant activity, were incorporated (10% w/w) into cellulose-based hydrogels intended for topical application. Hydrogels were prepared using carboxymethyl cellulose (CMC), hydroxyethyl cellulose (HEC), hydroxypropyl methylcellulose (HPMC), and methylcellulose (MC) at concentrations of 1.5–2.0% (w/w). The formulations were characterized in terms of organoleptic properties, pH, rheological behavior, swelling capacity, weight loss, antioxidant activity (DPPH assay), and microbiological activity against selected skin pathogens, including antibiotic-resistant strains. Rheological analysis confirmed pseudoplastic behavior suitable for topical administration. OMW-loaded hydrogels exhibited significant radical scavenging activity compared to blank formulations and demonstrated antimicrobial efficacy, supporting the preservation of OMW bioactivity within the polymeric network. The results highlight the potential of cellulose-based hydrogels as sustainable and biocompatible carriers for the valorization of OMW in dermatological applications, particularly for the management of oxidative stress and bacterial skin infections. Full article

Jojoba oil is a well-established skin-beneficial liquid wax with high value in topical formulations. Bigels, as preferred semi-solid dosage forms, serve as versatile platforms by incorporating hydrogels and oleogels to leverage their advantages and address their limitations. In this study, jojoba oil bigels were developed using sorbitan monostearate (20%, w/w) as an oleogelator and different hydrophilic bases, 1% Carbomer 940, 6% methylcellulose, or 20% Poloxamer 407 gel, with all concentrations expressed relative to the corresponding phase. Nine bigels were obtained by varying hydrogel-to-oleogel ratios (90:10–70:30). They were evaluated in terms of their organoleptic, microstructural, and textural characteristics. Both the hydrogel matrix type and the phase proportion impacted the studied properties. Carbomer bigels displayed the highest spreadability, methylcellulose formulations showed the greatest adhesiveness, and poloxamer systems exhibited maximum firmness and cohesiveness, with a comparatively more homogeneous phase distribution. The increase in oleogel content enhanced firmness and cohesiveness while modulating spreadability and adhesiveness in a hydrogel-dependent manner. Moreover, all designed formulations remained physically stable after centrifugation, but only those containing 80% carbomer gel or 70% or 80% poloxamer gel preserved their mechanical characteristics without significant changes after freeze-thawing. Besides identifying three promising biphasic dermal drug delivery platforms, these findings reinforce the tunability of bigels through the careful component selection. Full article

The development of new composite wound dressing films that can ensure a moist environment while preventing bacterial growth led this research to obtain novel ternary biopolymer films as a carrier for amygdalin. Due to their accessibility, biocompatibility, and versatility, κ–carrageenan, hydroxypropyl methylcellulose, and gelatin were selected as matrix components. This novel film composite was characterized by Fourier–transform Infrared (FTIR) spectroscopy, Thermogravimetric (TG) and Derivative Thermogravimetric (DTG) analysis, and was evaluated in vitro against E. coli and S. aureus. Thermogravimetric analysis showed that increasing the amygdalin content gradually shifted the T_onset and T_max values to higher temperatures, suggesting an improvement in the thermal stability of the composite matrix. In vitro results indicate that increasing the amygdalin concentration resulted in a bacteriostatic efficiency of up to 54% against E. coli, while exhibiting a plateau effect in bactericidal activity. In contrast, no bactericidal activity was observed against S. aureus cultures. Full article

The paper presents the results of a study focused on technological parameters that ensure the effectiveness of using concrete powders obtained from crushed concrete waste as an active mineral additive in construction mixtures used for 3D printing. The efficiency of using a complex polyfunctional additive to cement pastes and mortars based on it is experimentally demonstrated. This additive includes a naphthalene–formaldehyde-based superplasticizer and a water-retaining additive, hydroxyethyl methylcellulose. Using the mathematical experiment planning methodology, polynomial models of the cement pastes and mortars’ mechanical properties were obtained. The models showed a positive effect of the complex additive on the cement pastes’ normal consistency and viscosity. Additionally, the results of the study demonstrate the possibility of regulating the cement pastes’ setting time and the plastic strength of mortars based on them using a complex additive. Analysis of the experimental–statistical models shows that using the complex additive allows regulation of water separation as well as the compressive and flexural strength of cement–sand mortars based on the investigated cement pastes within the required limits. Improving the key properties of building mixtures containing crushed concrete waste for 3D printing using complex polyfunctional modifier additives opens up new opportunities for increasing their economic and environmental efficiency. Full article

To effectively prevent and control coal spontaneous combustion, a novel heat-sensitive hydrogel for mine fire prevention and extinguishment was developed using hydroxypropyl methylcellulose (HPMC) and the organic flame-retardant, sodium alginate (SA). The hydrogel was prepared through single-factor variable control and material compounding. First, the optimal formulation of the hydrogel was determined using analytical instruments and techniques, including a viscometer, vacuum drying oven, and the inverted test tube method. Subsequently, its microstructural characteristics were examined using scanning electron microscopy (SEM) and infrared spectroscopy (FTIR). Finally, a fire suppression test platform was established to perform comparative experiments, verifying the hydrogel’s fire prevention, extinguishing, and cooling performance. Experimental results demonstrated that the optimal hydrogel formulation consists of 2.5 wt% HPMC and 0.3 wt% SA. At this ratio, the hydrogel exhibits excellent fluidity and water retention, ensuring prolonged coverage and wetting of coal surfaces. The gel undergoes a sol–gel phase transition at 58 °C, enabling it to fill voids, bind and reinforce coal particles, and reduce exposed surface area. After drying, the hydrogel forms a uniformly smooth surface capable of both coating the coal body and encapsulating individual coal particles. Following the hydrogel treatment, the coal sample retains its original functional groups, indicating that no chemical reactions occur during mixing. Compared with traditional inhibitors, the hydrogel demonstrates superior fire suppression performance, more effectively covering and encapsulating burning coal. It rapidly reduces the temperature to 28 °C by the cooling effect of water evaporation from the hydrogel, and it maintains thermal stability, achieving outstanding fire-extinguishing efficiency. Full article

Buprenorphine (BUP) is widely used in the treatment of neonatal opioid withdrawal syndrome (NOWS). However, the most compounded formulation contains 30% ethanol, despite regulatory and clinical concerns regarding ethanol exposure in pediatric patients. Thus, this research aimed to develop an ethanol-free sublingual (SL) gel formulation of BUP that would be safe, stable, and suitable for NOWS. Multiple polymers were screened as gelling agents, with hydroxypropyl methylcellulose (HPMC) emerging as the ideal base polymer for the formulation due to its optimal pH, rheological characteristics, and stability. The formulated gels were stored at room temperature and refrigerated conditions for 30 days and evaluated for stability using pH, rheology, and liquid chromatography-mass spectrometry. BUP content was between 90–110% of the labeled amount of the dosage form (75 µg/mL) at all time-points, and the pH remained close to physiological values. Release studies demonstrated a drug release of 23–24% for SL gels without surfactants stored at room temperature and refrigerated conditions, respectively. Incorporation of non-ionic surfactants (Tween 20 and Tween 80) significantly increased drug release to 33% and 40%, respectively, reflecting enhanced solubilization and improved mucosal penetration. The ethanol-free formulation demonstrated physicochemical stability and favorable release characteristics suitable for neonatal administration. These findings represent a meaningful advance in the development of safer pediatric formulations for NOWS. Full article

Gypsum is one of the main binding materials used in the construction industry. Its properties can be modified by the addition of chemical admixtures that may influence the hydration process and the microstructure of the hardened material. An important group of such admixtures comprises cellulose ethers. The aim of this study was to conduct an in-depth analysis of the effects of hydroxyethyl methylcellulose (HEMC) on the hydration and mechanical properties of gypsum. HEMC was applied in various amounts (ranging from 0.5 to 7% by mass of gypsum); the water-to-gypsum ratio was 0.75. The hydration process was investigated using calorimetry, thermal analysis, and infrared spectroscopy. Compressive and bending strength tests were also performed. The results of calorimetric measurements show that the presence of HEMC led to delayed hydration and prolonged gypsum crystallization, particularly at higher admixture dosages. No formation of new phases in the gypsum paste was observed in the presence of HEMC. However, the admixture modified the microstructure of the hardened material, as reflected by increased compressive and bending strength. This effect is most likely associated with the slower precipitation of gypsum crystals in the presence of HEMC. Full article

Background: Synthetic vascular scaffolds often exhibit limited mechanical performance and low hydrophilicity, which compromise early vascular integration and increase susceptibility to bacterial colonization. This study developed 3D-printed scaffolds based on poly(L-co-D,L-lactide)–poly(trimethylene carbonate) (PLDLA–TMC) with polyethylene glycol 400 (PEG) to modulate mechanical and interfacial properties and coated with poly(hexamethylene biguanide) (PHMB) to confer antibacterial activity. Methods: PLDLA–TMC scaffolds modified with PEG 400 and coated with PHMB were prepared and systematically characterized to assess their structural, thermal, mechanical, and antimicrobial properties. PHMB coatings (3%, 6%, and 12% w/w in hydroxypropyl methylcellulose, HPMC) were applied and evaluated for drug release, cytotoxicity, and activity against Staphylococcus aureus. Biocompatibility was tested in an endothelial cell and myoblast co-culture. Results: Incorporation of 2% PEG increased the tensile strength from 0.14 ± 0.10 MPa for scaffolds containing 0.5% PEG to 0.79 ± 0.12 MPa and promotes a more elastic scaffold behavior. PHMB at 12% caused cytotoxicity (7.70 ± 0.37% cell viability). The 3% PHMB coating produced a 12.5 ± 0.1 mm inhibition zone but exhibited burst release within 1 h, whereas the 6% coating maintained cell viability (72.95 ± 1.10%), produced a 13.1 ± 0.2 mm inhibition zone, and provided sustained antimicrobial release over 7 days. Scaffolds supported organized adhesion and proliferation of endothelial cells and myoblasts. Conclusions: 3D-printed PLDLA–TMC scaffolds containing 2% PEG and coated with 6% PHMB combined improved mechanical performance, sustained antimicrobial release, antibacterial activity, and biocompatibility in an in vitro vascular model. Full article

Autologous serum (AS) tears are an effective therapeutic option for advanced DED, mimicking the biochemical composition of natural tears. However, the absence of universally accepted guidelines has resulted in variability in AS tear concentration, diluents, processing of collected blood, and storage conditions, raising questions regarding the optimal parameters for AS tear use. This perspective provides a framework to inform clinical implementation and to guide future research on AS tear therapy optimization. PubMed, Scopus, and the Cochrane Library were searched for English-language articles from January 2022 through September 2025 using the terms “autologous serum,” “dry eye disease,” “dry eye syndrome,” “dry eye,” and “DED.” Evidence suggests that AS tears diluted to 20% are widely used for moderate DED, whereas higher concentrations may provide faster, more pronounced and more durable improvements, particularly in severe cases. Levofloxacin-containing eye drops, artificial tears without emphasis on a specific component, sodium hyaluronate (SH)-containing eye drops, cyclosporine A (CsA)-containing ultra-nano emulsions, and methylcellulose have been investigated as alternatives to conventional diluents. Standardization of clotting, centrifugation and storage parameters is expected to enhance efficacy of AS tears and ensure stability of growth factors. Combination with estrogen replacement therapy in perimenopausal women or with topical insulin eye drops, as well as perioperative prophylactic use in patients with graft-versus-host disease (GVHD)-associated dry eye undergoing cataract surgery, represent emerging applications of AS tears that demonstrate potential to improve therapeutic outcomes. Overall, this perspective highlights the need for consensus protocols, supports severity-based concentration tailoring, and notes that diluents and processing methods require further refinement. Full article

The functional properties of high-pressure processing (HPP)-assisted protein hydrolysate from tamarind kernel powder (TKP-HD) and the physicochemical characteristics of its foam-mat powder were studied. TKP-HD consisted of more non-polar than polar amino acids, with higher solubility at pH 5 and 7 than soy protein isolate (SPI) but lower than egg white (EW). The water-binding capacity of TKP-HD increased at pH 5 while TKP-HD had a higher foaming capacity than SPI at pH 5, and the highest oil-binding capacity. The physicochemical properties of TKP-HD after foam-mat drying were investigated using 1 and 1.5% (w/w) hydroxypropyl methylcellulose (HPMC), with drying at 60, 70, and 80 °C. Samples with 1.5% HPMC had lower water activity than those with 1% HPMC at all drying temperatures. The sample with 1% HPMC had higher antioxidant capacity at 60 °C than at 70 °C, but this decreased at 1.5% HPMC. Samples with 1.5% HPMC and dried at 60 °C recorded the highest solubility and viscosity, with increased porosity of the powder structure. The most suitable foam-mat drying conditions for TKP-HD were the addition of 1.5% HPMC and drying at 60 °C. Full article

Conventional gelatin capsules deliver a rapid drug release in the stomach, which is suboptimal for therapies requiring controlled and delayed release, emphasizing the need for customizable drug delivery systems for precision medicine. This study’s objective was to optimize 3D-printed capsule shells formulated with pH-responsive polymer blends—hydroxypropyl methylcellulose acetate succinate (HPMC-AS), PEG-4000, and PVA—to achieve controlled and sustained drug release, comparing profiles against a commercial enteric capsule. Capsule shells were produced via fused filament fabrication (FFF) at two ratios (80:15:5 and 70:20:10), filled with acetaminophen (250 mg), and tested using a two-stage dissolution method (simulated gastric fluid (SGF) for 2 h followed by simulated intestinal fluid (SIF) for 4–5 h). Results showed negligible drug release in SGF (≤5%) for both printed and commercial capsules. However, in SIF, the commercial capsule released its payload rapidly (>80% within 15 min), while the 3D-printed capsules achieved a prolonged, gradual release. The higher HPMC-AS content significantly extended the release duration. All capsules met the pharmacopeial weight uniformity criteria. In conclusion, the 3D-printed shells provided a controllable, sustained drug release profile, underscoring 3D printing’s potential to create tunable, patient-specific dosage forms. Full article

Neutral electrolyzed water (NW) is widely used in dentistry because of its strong bactericidal activity and high biosafety; however, its clinical application is limited by short retention time in the oral cavity and by the difficulty in maintaining and adjusting the available chlorine concentration (ACC) on-site. This study aimed to develop an on-demand NW-containing hydrogel (NWJ) that allows adjustment of ACC immediately before use while maintaining antimicrobial efficacy and handling properties. A methylcellulose–agar composite gel was prepared as a base gel and mixed with high-concentration NW to obtain prototype NWJs with target ACCs ranging 20–100 mg/L. Physicochemical properties (pH and ACC), time-dependent changes in ACC, bactericidal activity against Streptococcus mutans, and gel spreadability were evaluated. The base gel showed improved resistance to syneresis compared with an agar-only gel. All NWJs maintained a pH of approximately 6–7, exceeding the critical pH for enamel demineralization. Loss of ACC during gel preparation was less than 5%, and gradual ACC reduction was observed. Complete bactericidal activity was achieved at ACCs of 10 mg/L or higher, and gelation did not compromise antibacterial efficacy. These findings demonstrate that the developed NWJ provides a practical platform for clinical application of NW in dentistry. Full article