Berberine-phospholipid nanoaggregate-embedded thiolated chitosan hydrogel for aphthous stomatitis treatment.

Aim: This study aimed to develop nanoaggregates of berberine-phospholipid complex incorporated into thiolated chitosan (TCS) hydrogel for the treatment of aphthous stomatitis. Methods: The berberine-phospholipid complex was formulated through the solvent evaporation technique and assembled into nanoaggregates. TCS was synthesized through the attachment of thioglycolic acid to chitosan (CS). Nanoaggregates-TCS was prepared by the incorporation of nanoaggregates into TCS and underwent in vitro and in vivo tests. Results: Nanoaggregates-TCS exhibited prolonged release of berberine. The mucoadhesive strength of nanoaggregates-TCS increased 1.75-fold compared with CS hydrogel. In vivo studies revealed the superior therapeutic efficacy of nanoaggregates-TCS compared with that of other groups. Conclusion: Due to prolonged drug release, appropriate residence time and anti-inflammatory effects, nanoaggregates-TCS is an effective system for the treatment of aphthous stomatitis.

Fabrication, in Vitro, and in Vivo Characterization of Mucoadhesive Berberine-Loaded Blended Wafers for Treatment of Chemotherapy-Induced Oral Mucositis.

This study aims to design and characterize berberine-loaded wafers for the treatment of chemotherapy-induced oral mucositis. Wafers were prepared by lyophilization of hydrogels of various ratios of chitosan (CS)/sodium alginate (SA) as well as CS/hydroxypropyl methylcellulose (HPMC). In vitro release, in vitro mucoadhesion, porosity, and swelling studies were conducted to select the optimized formulations. Moreover, scanning electron microscopy (SEM), X-ray diffraction (XRD), Fourier transform infrared spectroscopy (FTIR), and mechanical properties studies were also performed for further characterization. The efficacy of optimized berberine-loaded wafers in the treatment of oral mucositis was investigated in a 5FU-induced oral mucositis rat model. F2-CS-SA and F6-CS-HPMC wafers exhibited sustained release profile and excellent mucoadhesion strength. Therefore, these wafers were selected as the optimized formulations. SEM confirmed the porous structure of these wafers and is in agreement with the results of porosity and swelling studies. XRD and FTIR studies indicated that berberine was incorporated into the wafer matrix in the amorphous form. In vivo studies demonstrated that topical application of berberine-loaded optimized wafers reduced significantly the severity of 5FU-induced oral mucositis and decreased the expression of inflammatory markers (TNF-α and IL-1ß). The results of in vitro and in vivo studies revealed that berberine-loaded F2-CS-SA and F6-CS-HPMC wafers can be effective in the treatment of chemotherapy-related oral mucositis.

Green formulation of curcumin loaded lipid-based nanoparticles as a novel carrier for inhibition of post-angioplasty restenosis.

Restenosis is one of the major complications affecting outcomes of percutaneous coronary interventions. The aims of this study were to formulate curcumin (CUR) nanoparticles by using only lipidic ingredients in the absence of any organic solvent and to determine key formulation parameters using 2-level factorial design. CUR nanoparticles were prepared using triglyceride and egg phosphatidylcholine (EPC) by high-pressure homogenization (HPH) and fully characterized regarding drug loading, particle size, zeta potential, stability, drug release profile, conductivity, viscosity, refractive index, stability, morphology and FTIR analysis. The efficacy of CUR nanoparticles in inhibiting restenosis was investigated in a rat carotid artery model. Balloon-injured rats were randomly assigned to two control (saline and empty carrier) groups and CUR nanoparticle treated group. Arterial restenosis was assessed by histomorphometric, immunohistochemical and CT angiography analyses. Optimized CUR nanoparticles with almost 70% drug entrapment, an average particle size of 58 nm, PDI < 0.2, spherical nanostructures and sustained release profile were prepared. In morphometric analysis, neointimal area and neointima/media ratio significantly decreased in the animal group received CUR nanoparticles compared with control groups. Expression of Ki67 was markedly lower in the CUR nanoformulation group. CT angiograms confirmed patency of the artery in this group. These results suggest that the new strategy of intramural delivery of CUR lipid-based nanoparticles can be considered as a novel approach to prevent neointimal hyperplasia.

Green Formulation of Triglyceride/Phospholipid-Based Nanocarriers as a Novel Vehicle for Oral Coenzyme Q10 Delivery.

This study was aimed to develop a novel nanocarrier for coenzyme Q10 (CoQ10) by a green process that prevented the use of surfactants and organic solvents. Triglyceride/phospholipid-based nanocarriers were developed through high-pressure homogenization (an industrial feasible process), and a 25-1 fractional factorial design was adopted to assess the influences of formulation variables on the considered responses, including vesicle size, entrapment efficiency, loading capacity, and solubility of the vehicles in simulated gastrointestinal fluids. The optimized formulation was further in-depth characterized in terms of morphology, release behavior, biocompatibility (Caco-2 cell cytotoxicity and histological examination), thermal behavior, and Fourier transform infrared analysis. Optimal nanocarriers were found to have mean particle size of 75 nm, narrow particle distribution, and CoQ10 entrapment of 95%. The optimized formulation was stable upon incubation in simulated gastrointestinal fluids without considerable leakage of cargo, which was in agreement with their sustained release behavior. Microscopic observations also confirmed nanosized nature of the vesicles and revealed their spherical shape. Moreover, toxicity evaluations at the cellular and tissue levels revealed their nontoxic nature. In conclusion, triglyceride/phospholipid-based nanocarriers proved to be a green safe vehicle for delivery of CoQ10 with industrial-scale production capability and could provide a new horizon for delivery of hydrophobic nutraceuticals. PRACTICAL APPLICATION: Green nanostructure formulation approaches have recently gained tremendous attraction for their safe profile especially when it comes to supplements, which are generally recommended for daily use. However, their sufficient association with cargoes and industrial-scale production have remained considerable challenges. This study focuses on the development of lipid-based nanocarriers for CoQ10 by an industrial feasible process that prevents the use of any surfactants or organic solvents.

EGFR targeted thermosensitive liposomes: A novel multifunctional platform for simultaneous tumor targeted and stimulus responsive drug delivery.

The epidermal growth factor receptor (EGFR) is a promising target for anti-cancer therapy. The aim of this study was to design thermosensitive liposomes (TSL), functionalized with anti-EGFR ligands for targeted delivery and localized triggered release of chemotherapy. For targeting, EGFR specific peptide (GE11) and Fab' fragments of cetuximab were used and the effect of ligand density on in vitro tumor targeting was investigated. Ligand conjugation did not significantly change the physicochemical characteristics of liposomes. Fab'-decorated TSL (Fab'-TSL) can specifically and more efficiently bind to the EGFR overexpressed cancer cells as compared to GE11 modified TSL. Calcein labeled Fab'-TSL showed adequate stability at 37°C in serum (<4% calcein released after 1h) and a temperature dependent release at above 40°C. FACS analysis and live cell imaging showed efficient and EGFR mediated cellular association as well as dramatic intracellular cargo release upon hyperthermia. Fab'-conjugation and hyperthermia induced enhanced tumor cell cytotoxicity of doxorubicin loaded TSL. The relative cytotoxicity of Fab'-TSL was also correlated to EGFR density on the tumor cells. These results suggest that Fab'-TSL showed great potential for combinational targeted and triggered release drug delivery.

A novel two-step mild hyperthermia for advanced liposomal chemotherapy.

Liposomal chemotherapy brings the advantage of minimizing systemic toxicity towards healthy organs and tissues, while has the drawbacks of limited nanoparticle accumulation and low drug bioavailability at targeted tumors. The aim of our study is to apply a clinically available mild hyperthermia (HT) treatment with thermosensitive liposomes (TSL) to tackle both issues. A two-step HT approach was combined with systemic administration of doxorubicin (Dox) TSL, in a first step to maximize nanoparticle accumulation in tumors and second step to actively trigger Dox release. The therapeutic activity of the two-step approach was compared to a one-step HT triggering intravascular Dox release from circulating TSL. Whereas the intravascular drug release approach requires fast releasing Dox-TSL (Dox-fTSL), the TSL formulation used in the two-step approach is fine-tuned to prolong Dox retention at physiological temperature in circulation, while releasing their drug content at mild HT at a slower rate (Dox-sTSL). Cytotoxicity assays show that a first-step HT at 41°C for 1h causes no drug resistance on murine BFS-1 sarcoma, human BLM melanoma cell lines and Human Umbilical Vein Endothelial Cells (HUVEC) towards subsequent exposure to Dox. However, HT sensitizes HUVEC towards Dox at higher concentrations (10-100µM). After 2h of intratumoral Dox-TSL accumulation, HT at 42°C for 1h was applied to trigger Dox release from Dox-sTSL. Quantification of intratumoral Dox accumulation revealed that the two-step HT approach increased TSL accumulation and Dox bioavailability reaching levels comparable to the intravascular release approach. The two-step HT in combination with Dox-sTSL delayed tumor growth for 12days compared to PBS group, however, was less effective compared to intravascular Dox release from Dox-fTSL using one-step HT. The two-step approach focuses on interstitial drug release upon mild HT, instead of intravascular drug release. This novel two-step approach represents an attractive alternative for the treatment of large and deep seated tumors, which are difficult to heat precisely and require loco-regional HT of the tumor area and accumulated Dox-sTSL therein to obtain a precise intratumoral drug delivery.