Search Results (809)

Resveratrol (RSV) is a poorly water-soluble polyphenolic compound with various potential health benefits, but its pharmaceutical application is limited by low aqueous solubility and poor oral bioavailability. Additive manufacturing (AM), particularly fused deposition modeling (FDM) 3D printing, offers a flexible approach for fabricating oral dosage forms with customized geometry and internal architecture. In this study, hot-melt extrusion (HME) combined with fused deposition modeling (FDM) 3D printing was used to prepare RSV-loaded tablets with different infill patterns. Hydroxypropyl methylcellulose acetate succinate and hydroxypropyl cellulose were selected as polymeric carriers to prepare RSV-loaded filaments suitable for FDM printing. The effects of infill pattern on the solid-state characteristics, dimensional accuracy, mechanical properties, floating behavior, and in vitro drug release of the printed tablets were systematically investigated. Differential scanning calorimetry, powder X-ray diffraction, and polarized light microscopy indicated that RSV was mainly converted into an amorphous or molecularly dispersed state after HME and FDM processing. All designed tablets were successfully printed and showed acceptable shape fidelity, while different infill patterns resulted in variations in tablet weight, mechanical strength, floating duration, and release behavior. In vitro dissolution studies showed that the RSV release profiles were dependent on the internal infill architecture. Tablets with more complex infill patterns generally exhibited slower drug release, which may be related to differences in internal pore structure, medium penetration pathways, matrix hydration, and diffusion distance. Release kinetic analysis further suggested that RSV release from the printed tablets involved a combination of diffusion and polymer relaxation processes. These results demonstrate that infill pattern is an important structural parameter for modulating the mechanical performance and drug release behavior of FDM 3D-printed RSV tablets. This study provides useful guidance for the design of 3D-printed oral dosage forms with tunable release characteristics. Full article

Background/Objectives: Paclitaxel is a chemotherapy drug used to treat various tumours, but its use is often limited by an acute and chronic pain syndrome that is poorly managed. Naringin and its aglycone, naringenin, exhibit antioxidant, antitumour, anti-inflammatory, and antinociceptive effects, making them potential alternative treatments. However, their low water solubility limits their oral bioavailability in humans. Micronisation in a supercritical medium reduces particle size and enhances the dissolution of compounds, offering a possible solution. In this study, we investigated whether micronising naringin and naringenin via supercritical technology could improve their dissolution and oral efficacy against paclitaxel-induced pain syndrome. Methods: Micronisation was performed using supercritical CO₂. Molecular docking was used to analyse the binding of naringin and naringenin to TRPV1, a key target for pain relief. Swiss mice were used in capsaicin (TRPV1 agonist)-induced nociception and paclitaxel-caused acute and chronic pain models. We assessed mechanical, cold, and heat sensitivity, potential adverse effects, and TRPV1 mRNA expression. Results: Micronisation improved the apparent dissolution profile of molecules. Docking results showed that naringin and naringenin bind to TRPV1. Both micronised compounds reduced capsaicin-induced nociception without affecting locomotion or body temperature. Micronised naringin and naringenin alleviated mechanical and cold allodynia, as well as thermal hyperalgesia in both acute and chronic paclitaxel-induced pain, outperforming their conventional forms. They also downregulated TRPV1 mRNA expression in the mice’s sciatic nerve. Conclusions: Taken together, these results show that supercritical micronisation improved the apparent dissolution and oral antinociceptive efficacy of naringin and naringenin, emphasising their potential as promising alternatives for managing paclitaxel-induced pain, with TRPV1 being a probable contributor to the observed antinociceptive effects. Full article

Oral administration remains the most convenient and favored route for systemic delivery of small-molecule drugs, primarily due to patient compliance and the absence of invasive procedures. Yet, poor aqueous solubility, chemical/enzymatic instability, and limited permeability in the gastrointestinal (GI) tract often result in low bioavailability (BA) of many therapeutic agents. Polymeric micelles formed from the self-assembly of amphiphilic block copolymers have gained considerable attention as a nanotechnology-driven solution to overcome these challenges. Their hydrophobic core–hydrophilic shell structure enables efficient encapsulation of poorly soluble small molecule drugs, providing protection from acidic or enzymatic degradation while potentially enhancing drug transport across the intestinal epithelium. This review examines the design principles, formulation strategies, and in vivo performance of polymeric micelles for oral delivery of small molecule drugs. We discuss strategies to improve micelle stability in the GI environment, including optimization of core hydrophobicity, kinetic stabilization, and corona engineering, and compare polymeric micelles with established alternatives such as self-micro emulsifying drug delivery system (SMEDDS) and amorphous solid dispersions (ASDs) across critical performance parameters. Despite decades of preclinical progress, no oral polymeric micelle formulation has reached regulatory approval, underscoring the persistent challenge of maintaining micellar structural integrity under the dynamic conditions of the GI environment. This review therefore examines not only the promise but also the structural vulnerabilities of oral micelles, proposing a stability-centered framework for interpreting micelle function under GI conditions. Finally, we discuss current translational challenges and suggest directions for future research toward clinical application of oral polymeric micelle systems. Full article

The rational design of mixed micellar systems has emerged as a cornerstone of modern nanomedicine, offering unprecedented control over the solubility and bioavailability of challenging therapeutic agents. This review provides a comprehensive analysis of the physicochemical principles governing the assembly of amphiphilic drugs and surfactants into synergistic nanostructures. By articulating the transition from traditional guest/host solubilization to “drug-as-component” models, we highlight the critical role of molecular interactions in achieving therapeutic precision. It further outlines the experimental methodologies used to investigate these systems and elucidates how they enhance the solubility, stability, and bioavailability of poorly water-soluble drugs. Special emphasis is placed on the practical applications of synergy in reducing systemic toxicity and optimizing drug release kinetics, providing a roadmap for the development of next-generation nano-pharmaceuticals. The functionality of these systems is significantly influenced by the molecular interactions among their constituents; thus, quantitative analysis of these interactions might enhance the formulation of more effective pharmaceuticals. This review outlines the key physicochemical principles of mixed micelle formation, including thermodynamics and synergistic interactions of amphiphiles, while emphasizing their relevance in current research and practical pharmaceutical applications. Various experimental methods, such as surface tension measurement, conductometric and calorimetric tests, and spectroscopic techniques, are compared in terms of their conditions of application and performance in understanding micelle formation and micelle structure. We clearly point out that the interpretation and evaluation of the properties of colloidal systems containing drug molecules solubilized by mixed micelles and an amphiphilic drug incorporated into micelles must be discussed and evaluated separately. Understanding the limitations and characteristics of the physical/chemical principles applied is essential for the rational design of mixed micelle carriers tailored to specific therapeutic needs. Full article

Background: Polymeric drug-eluting films are promising platforms for local antibacterial delivery, but their release profiles depend strongly on the permeability and morphology of the barrier layer. Here, the previously proposed concept of additively manufactured PLACE (Printed Layered Adjustable Cargo Encapsulation) coatings was extended from "single orifice"-defined release toward porosity-assisted barrier control. Two conventional water-soluble porogens, polyethylene glycol (PEG) and polyvinylpyrrolidone (PVP), were compared with poly(2-ethyl-2-oxazoline) (PEOx), a hydrophilic polymer proposed as an alternative to PEG in biomedical formulations, but whose use as a leachable porogen has received little attention. Methods: Each porogen was introduced into the upper PLGA barrier of multilayer PLACE films. The resulting films were characterized for film formation, post-hydration morphology by SEM, release of methylene blue and vancomycin, and antibacterial activity against methicillin-resistant Staphylococcus aureus (MRSA). Results/Conclusions: PEG was poorly compatible with PLGA and mainly produced surface-localized defects rather than a barrier with controlled permeability suitable for prolonged delivery. PVP K17 provided sustained release at 10 wt.%, whereas 20 wt.% PVP caused burst-dominated release and stronger morphological disruption. PEOx formed developed porosity at lower loading and produced release regimes ranging from several days to approximately two weeks. Vancomycin-loaded films containing 5 wt.% PEOx enabled near-complete release over two weeks while preserving film integrity and showed pronounced early anti-MRSA activity. These results identify porogen selection as a key formulation step and support PEOx as a useful porogen for early high-output antibacterial PLACE coatings. Full article

Poly(ethylene glycol)-block-poly(ε-caprolactone) (PEG-b-PCL) copolymer micelles have emerged as promising drug delivery systems for enhancing the solubility and bioavailability of poorly water-soluble benzimidazole drugs. In this study, we prepared and characterized PEG-b-PCL micelles to encapsulate poorly water-soluble anthelmintics such as albendazole (ABZ) and fenbendazole (FBZ), with a focus on comparing their encapsulation behaviour, release profiles, and biological activity in cancer therapy. Drug-loaded micelles were analysed using dynamic light scattering (DLS), which revealed uniform nanosized micelles with a narrow polydispersity index (PDI). The morphology and size of both empty and drug-loaded micelles were examined using transmission electron microscopy (TEM), confirming that the micelles were spherical and consistent in size. Both drugs were efficiently encapsulated within the micellar core, demonstrating a high loading capacity. The release profiles of PEG-b-PCL micelles containing albendazole (ABZ) and fenbendazole (FBZ) at pH 7.4 were also evaluated. FBZ exhibited slower release kinetics compared to ABZ, likely due to its higher lipophilicity and stronger interactions with the hydrophobic PCL core, resulting in enhanced retention within the micelles. In contrast, ABZ had faster release kinetics. Finally, the in vitro MTT assays performed on the highly invasive triple-negative breast cancer (TNBC) cell line revealed the potential of these micelles as effective drug delivery systems. Full article

Background/Objectives: Lipid-based nanocarriers have emerged as promising systems for improving the delivery of poorly soluble drugs by enhancing stability, bioavailability, and controlled release. This work aimed to formulate solid lipid nanoparticles (SLN) and nanostructured lipid carriers (NLC) containing ciprofloxacin (CIP) using solvent-free procedures. Methods: The systems were extensively characterized using dynamic light scattering (DLS), transmission electron microscopy (TEM), and atomic force microscopy (AFM) to study the nanoparticles in the solid state. Furthermore, in vitro drug release was evaluated, and mathematical modeling was applied to analyze the resulting release kinetics. Additionally, storage stability was assessed at 4 °C and 25 °C over a period of 8 months. Results: The results indicated that SLN with an average size of ~50 nm (SLN 50) and NLC with mean diameters of ~25, 50, and 100 nm (NLC 25, NLC 50 and NLC 100 respectively) were successfully prepared. DLS measurements showed narrow particle size distributions (PdI ≤ 0.2) and negative zeta potentials ranging from −3.7 to −7.7 mV. Encapsulation efficiencies were remarkably high for most systems, reaching ~98% for SLN 50, NLC 50, and NLC 100, while the smallest formulation (NLC 25) showed a lower efficiency (~80%). Both TEM and AFM confirmed the formation of spherical nanoscale structures consistent with the sizes determined by DLS. Release studies revealed a strong influence of particle size on kinetics: NLC 25 exhibited rapid release (~95% within 30 min), whereas NLC 100 showed a sustained profile (<20% after 6 h). Dissolution profiles were accurately described by the Lumped-Gonzo kinetic model (R² > 0.98), enabling estimation of dissolution efficiency. Conclusions: These findings confirm that lipid-based nanocarriers can be engineered to precisely control CIP release. Full article

Background/Objectives: Heliotropium indicum (H. indicum) is a medicinal plant traditionally used for conditions associated with inflammation, but its active antinociceptive constituents remain poorly defined. This study evaluated the antinociceptive activity of the aerial parts of H. indicum through a bioassay-guided approach and explored the mechanism of action of the active compound isolated in the formalin test. Methods: Three extracts of H. indicum (hexane, dichloromethane, and methanol) were evaluated in male Swiss albino CD-1 mice using the formalin test. The most active extract was fractionated, and its major fractions were screened for antinociceptive activity. Based on the active fraction and previous phytochemical data, (E)-ethyl-12-cyclohexyl-4,5-dihydroxydodec-2-enoate (ECDE) was selected for further pharmacological evaluation in the same model. Antagonist pretreatments were used to investigate the involvement of opioid, serotonergic, gamma-aminobutyric acid (GABA_A), and Nitric Oxide (NO)–soluble Guanylyl Cyclase (sGC) pathways. Results: The three extracts reduced nociceptive behavior, mainly during phase II of the formalin test, whereas the dichloromethane extract showed the broadest activity profile and was selected for fractionation. The six fractions significantly reduced phase II nociception, and fraction F5 was selected for purification. ECDE produced a clear dose-dependent antinociceptive effect in phase II, with minimal effect on phase I, and its efficacy was compared with that of ketorolac, a standard antinociceptive drug. Dose–response analysis estimated a DE₅₀ of 0.76 mg/kg for ECDE. Pretreatment with N-nitro-L-arginine methyl ester (L-NAME) and [1,2,4]oxadiazolo [4,3-a]quinoxalin-1-one (ODQ) significantly attenuated the effect of ECDE, whereas naloxone, methiothepin, and bicuculline did not. Conclusions: ECDE was identified in H. indicum as one of the compounds contributing to this effect. Its activity appears to be directed mainly toward inflammatory nociception and to depend, at least in part, on the NO–sGC pathway. Full article

The cornea and conjunctiva are particularly susceptible to injury and adverse effects, either induced by topically applied drugs or excipients used in ophthalmic formulations. Surfactants and cosurfactants are important for producing topical eye formulations of poorly water-soluble drugs, yet they have not been always used in concentrations that are nontoxic and non-irritating to the ocular surface. This study systematically compared the cytotoxicity and ocular irritation potential of commonly used ophthalmic surfactants and cosurfactants under standardized experimental conditions using complementary in vitro and ex vivo ocular safety models. The ocular irritation of Tween 80, Cremophor EL, polyethylene glycol 400 (PEG 400) and propylene glycol (PG) was examined using the HET-CAM (conjunctival) and BCOP (corneal) eye assays. The toxic effect of the four excipients after 24 h on HLE-B3 cell growth was investigated and found to be dose-dependent. The highest tolerable concentrations of Tween 80 and Cremophor EL were 0.25% (w/w), whereas PEG 400 and PG were non-toxic at 5% (w/w). Tween 80 and Cremophor EL at 0.25% (w/w) and PEG 400 and PG at 5% (w/w) were all devoid of conjunctival and corneal irritation. This study systematically compared the cytotoxicity and ocular irritation potential of commonly used ophthalmic surfactants and cosurfactants under standardized experimental conditions using complementary in vitro and ex vivo ocular safety models. Interestingly, there is strong agreement between the results obtained using the HET-CAM and BCOP assays, where both have been successfully used to evaluate the potential for ocular irritation caused by the aforementioned excipients. Full article

Achieving precise control over anticancer drug release remains one of the key challenges in modern pharmaceutical development, as it directly determines therapeutic efficacy, systemic toxicity, and patient outcomes. This review critically evaluates recent advances in three major formulation strategies: polymeric solid dispersions, cyclodextrin-based inclusion complexes, and metal–organic frameworks (MOFs), with a particular focus on their capacity to tailor anticancer drug release. Over the past decade, polymeric solid dispersions and cyclodextrin-based carriers have played a central role in improving the dissolution and bioavailability of poorly water-soluble anticancer agents, while also enabling modified release profiles through rational formulation design. Increasing structural complexity, including ternary systems and supramolecular assemblies, reflects a shift toward more controllable delivery platforms. In recent years, MOFs have emerged as highly adaptable porous materials capable of supporting controlled and stimuli-responsive release. The integration of imaging agents, magnetic components, and photothermal functionalities has further enabled the design of multifunctional and theranostic platforms. Taken together, these technologies reflect a shift from conventional solubility enhancement toward structurally engineered systems designed to achieve predictable and controlled drug release. Continued advances in material design and formulation strategies are expected to further refine release kinetics and support the development of next-generation anticancer therapies aligned with the growing demand for precision medicine. Full article

This investigation addressed challenges in the delivery of poorly soluble drugs, and the colloidal processing of polymer–ceramic composites by fabrication of advanced supramolecular hydrogels. Polygalacturonic acid (PGA) polymer and 18β-glycyrrhetinic acid (GA) drug, both characterized by poor aqueous solubility, were selected as model building blocks for supramolecular hydrogels. Meglumine (MG) served as a multifunctional component in the gels, acting as a building block as well as an alkalizing and solubilizing agent for PGA and GA. Investigations revealed gel formation mechanisms, which were based on the electrostatic interactions of deprotonated anionic carboxylic groups of PGA and GA with protonated amino groups of MG and the hydrogen bonding of PGA polymer and GA molecules. The feasibility of the fabrication of PGA-MG and GA-MG gels opened an avenue for the fabrication of PGA-GA-MG gels. The composite gels provided a platform for drug delivery, and the kinetics of drug release from the composite gels containing MG excipient were investigated. Composite gels were obtained from colloidal dispersions, containing bioceramics, such as hydroxyapatite, silica, and titania, and bioglass in the PGA solutions in the presence of MG. The results of this investigation pave the way for the fabrication of novel supramolecular and composite gels loaded with various functional materials. Full article

Background/Objectives: Amlodipine is an antihypertensive agent characterized by low aqueous solubility and variable oral bioavailability. This study aimed to formulate and characterize amlodipine–alginate nanoplexes and to incorporate the optimized system into an oral film dosage form. Methods: Nanoplexes were prepared via ionic complexation employing alginates (ALG) with diverse physicochemical properties, including low (LV) and medium (MV)-viscosity grades, as well as alginates with varying M/G ratios. The nanoplexes were thoroughly characterized employing a comprehensive set of analytical techniques. In addition, intermolecular interactions were examined using computational simulation studies. Results: The nanoplexes demonstrated high encapsulation efficiencies (>80%), with MV alginate yielding particles with greater drug loading but larger mean diameters compared with that prepared using LV alginate. Computational simulation studies revealed favorable interaction energies between the drug and the polyelectrolyte, particularly within microenvironments enriched in guluronic acid–rich repeat regions. These interactions were corroborated by infrared spectroscopy, while differential scanning calorimetry and X-ray diffraction analysis confirmed the amorphous solid state of amlodipine within the nanoplexes. Dissolution studies demonstrated an inverse relationship between alginate viscosity and drug release rate, with formulations based on LV alginate exhibiting rapid drug release. The final hydroxypropylmethylcellulose film incorporating ALG-MV nanoplexes exhibited adequate mechanical integrity and achieved approximately 95% drug release within 30 min. Conclusions: The developed film presenting a viable approach to enhance the delivery of amlodipine. Overall, this approach constitutes a significant advancement in the delivery of poorly soluble drugs through the integration of nanostructured systems with flexible oral film platforms. Full article

The low water solubility of numerous drug candidates and phytochemicals continues to pose a significant challenge in pharmaceutical development, greatly limiting their bioavailability and therapeutic performance. This review presents a detailed overview of formulation strategies aimed at improving the solubility and dissolution of poorly aqueous-soluble compounds. The biopharmaceutics classification system and the relevance of in vitro–in vivo correlation, as well as key challenges in formulation development, are briefed. Solid-state and particle engineering approaches, including micronization, supercritical fluid technology, electrospinning, and cryogenic techniques, are discussed. Extensive critical examination of amorphous solid dispersions and their preparation methods, as well as crystallization inhibition strategies, is covered. Cocrystallization is highlighted as a promising approach, with emphasis on design principles and preparation methods. Various solubilization techniques, such as pH modification, cosolvency, hydrotropy, micellar solubilization, and cyclodextrin-based complexation, including advanced hybrid systems, are also explored. Emerging solvent platforms, such as deep eutectic systems and lipid-based and nanotechnology-driven approaches, are reviewed for their role in improving solubility and drug delivery. Additionally, enabling technologies such as liquisolid systems and hydrophilic polymers are addressed. Despite notable progress, limitations such as scalability, reproducibility, regulatory constraints, and long-term safety persist. Overall, this review provides integrated insights into formulation design approaches to enhance the solubility and therapeutic efficacy of poorly soluble drugs. Full article

Background: Baicalein (BA) is a poorly soluble flavonoid with limited oral bioavailability. This study aimed to enhance the solubility and nasal absorption of the compound using a dual-carrier system that combines cyclodextrin inclusion complexes and thermosensitive hydrogels. Methods: The inclusion complexes of BA with hydroxypropyl-β-cyclodextrin (HP-β-CD) or sulfobutyl-β-cyclodextrin (SBE-β-CD), namely BA-HP-β-CD and BA-SBE-β-CD, were prepared via solution stirring and characterized by solubility, dissolution, scanning electron microscopy (SEM), Fourier transform infrared spectroscopy (FTIR), X-ray diffraction (XRD), thermogravimetric analysis-differential scanning calorimetry (TG-DSC), and Madin-Darby canine kidney (MDCK) cell permeation. The optimal complexes were incorporated into chitosan/β-glycerophosphate thermosensitive hydrogels (BA/HP-Gel and BA/SBE-Gel), followed by evaluations of gelation properties, in vitro release, and in vivo pharmacokinetics in rats. Results: The water solubility of BA-HP-β-CD and BA-SBE-β-CD increased 572 and 582 times, with MDCK permeability enhanced by 5.3 and 2.9 times, respectively. Both hydrogels showed rapid solution-gel transition at nasal temperature and sustained release. Following intranasal administration, BA/HP-Gel and BA/SBE-Gel achieved relative bioavailabilities of 623.5% and 697.8%, respectively, compared with BA-Gel. Conclusions: The dual-carrier platform effectively improved BA solubility, permeability, and nasal bioavailability, offering a promising strategy for nasal delivery of poorly soluble drugs. Full article

Background/Objectives: Supramolecular hydrogels formed by low-molecular-weight gelators present a chemically heterogeneous transport environment whose molecular-scale dynamics remain poorly understood. This study aimed to investigate how drug physicochemistry governs transport within a liquid-crystalline C18ADPA hydrogel at the molecular scale. Methods: Pulsed-field gradient NMR spectroscopy was used to measure self-diffusion coefficients of five model drugs (5-fluorouracil, acetylcholine, paracetamol, prednisolone, and amphotericin B) spanning a broad range of size, polarity, and charge state, in both free solution and the hydrogel matrix at pH 5.37. Results: Observed drug diffusion coefficients deviated substantially from classical obstruction theory predictions, demonstrating that transport is governed by host–guest chemical affinity rather than molecular size. The three water-soluble drugs exhibited bimodal diffusion, with relative amplitudes providing a direct estimate of bound and free drug fractions. Prednisolone co-diffused with the gelator scaffold, consistent with hydrophobic bilayer partitioning, while amphotericin B diffused at rates consistent with the structured interfacial water layer. The gel pH (5.37) emerged as an active determinant of transport: drug charge states at this pH from permanent cation (acetylcholine) to near-zwitterion (amphotericin B) correlated directly with the observed transport behavior. The near-zwitterionic character of amphotericin B at pH 5.37, arising from its carboxyl pKa (~5.5), suggests a previously unreported electrostatic interfacial trapping mechanism. Conclusions: The liquid-crystalline bilayer architecture creates chemically distinct microdomains that selectively recruit drugs based on hydrophobicity, hydrogen-bonding capacity, and pH-dependent charge state, providing a molecular-scale framework for rational formulation design in supramolecular drug delivery. Full article