Preparation and characterization of spray-dried valsartan-loaded Eudragit® E PO solid dispersion microparticles

The purpose of this study was to develop the immediate release stomach-specific spray-dried formulation of valsartan (VAL) using Eudragit^® E PO (EPO) as the carrier for enhancing dissolution rate in a gastric environment. Enhanced solubility and dissolution in gastric pH was achieved by formulating the solid dispersion using a spray drying technique. Different combinations of drug–polymer–surfactant were dissolved in 10% ethanol solution and spray-dried in order to obtain solid dispersion microparticles. Use of the VAL–EPO solid dispersion microparticles resulted in significant improvement of the dissolution rate of the drug at pH 1.2 and pH 4.0, compared to the free drug powder and the commercial product. A hard gelatin capsule was filled with the VAL–EPO solid dispersion powder prior to the dissolution test. The increased dissolution of VAL from solid dispersion microparticles in gastric pH was attributed to the effect of EPO and most importantly the transformation of crystalline drugs to amorphous solid dispersion powder, which was clearly shown by scanning electron microscopy (SEM), differential scanning calorimetry (DSC), and powder X-ray diffraction (P-XRD) studies. Thus, VAL, a potential antihypertensive drug in the form of a solid dispersion microparticulate powder, can be effectively delivered in the immediate release dosage form for stomach-specific drug delivery.     

Eudragit®: a technology evaluation

Introduction: Eudragit is the brand name for a diverse range of polymethacrylate-based copolymers. It includes anionic, cationic, and neutral copolymers based on methacrylic acid and methacrylic/acrylic esters or their derivatives.

Areas covered: In this review, the physicochemical characteristics and applications of different grades of Eudragit in colon-specific/enteric-coated/sustained release drug delivery and taste masking have been addressed.

Expert opinion: Eudragits are amorphous polymers having glass transition temperatures between 9 to > 150^oC. Eudragits are non-biodegradable, nonabsorbable, and nontoxic. Anionic Eudragit L dissolves at pH > 6 and is used for enteric coating, while Eudragit S, soluble at pH > 7 is used for colon targeting. Studies in human volunteers have confirmed that pH drops from 7.0 at terminal ileum to 6.0 at ascending colon, and Eudragit S based systems sometimes fail to release the drug. To overcome the shortcoming, combination of Eudragit S and Eudragit L which ensures drug release at pH < 7 has been advocated. Eudragit RL and RS, having quaternary ammonium groups, are water insoluble, but swellable/permeable polymers which are suitable for the sustained release film coating applications. Cationic Eudragit E, insoluble at pH ≥ 5, can prevent drug release in saliva and finds application in taste masking.     

Influence of polymers ratio on insulin-loaded nanoparticles based on poly-ε-caprolactone and Eudragit® RS for oral administration

Nanoparticles loaded with two different commercial insulins (Actrapid^®, Novorapid^®) and based on different blends of a biodegradable polyester (poly-ε-caprolactone) and a polycationic non-biodegradable acrylic polymer (Eudragit^® RS) were characterized in vitro. The zeta potential was positive whenever Eudragit^® RS was part of the nanoparticles matrix. The encapsulation efficiency was ~ 96% except for Novorapid^®-loaded particles of poly-ε-caprolactone (only 35%). In vitro release studies revealed a burst release from nanoparticles, which may be of interest for oral delivery. Novorapid-loaded nanoparticles were orally administered to diabetic rats and allowed the glycemia to be decreased when compared with free nanoparticles.     

Fabrication and evaluation of Eudragit® polymeric films for transdermal delivery of piroxicam

The aims of this work were to develop and characterize the prolonged release piroxicam transdermal patch as a prototype to substitute oral formulations, to reduce side effects and improve patient compliance. The patches were composed of film formers (Eudragit^®) as a matrix backbone, with PVC as a backing membrane and PEG200 used as a plasticizer. Results from X-ray diffraction patterns and Fourier transform-infrared spectroscopy indicated that loading piroxicam into films changed the drug crystallinity from needle to an amorphous or dissolved form. Piroxicam films were prepared using Eudragit^® RL100 and Eudragit^® RS100 as film formers at various ratios from 1:0 to 1:3. Films prepared solely by Eudragit^® RL100 showed the toughest and softest film, while other formulations containing Eudragit^® RS100 were hard and brittle. Drug release kinetic data from the films fitted with the Higuchi model, and the piroxicam release mechanism was diffusion controlled. Among all formulation tested, Eudragit^® RL100 films showed the highest drug release rate and the highest drug permeation flux across human epidermal membrane. Increasing drug loading led to an increase in drug release rate. Eudragit^® can be used as a film former for the fabrication of piroxicam films.     

Evaluation of HPβCD-PEG microparticles for salmon calcitonin administration via pulmonary delivery

For therapeutic peptides, the lung represents an attractive, noninvasive route into the bloodstream. To achieve optimal bioavailability and control their fast rate of absorption, peptides can be protected by coprocessing with polymers such as polyethylene glycol (PEG). Here, we formulated and characterized salmon calcitonin (sCT)-loaded microparticles using linear or branched PEG (L-PEG or B-PEG) and hydroxypropyl-beta-cyclodextrin (HPβCD) for pulmonary administration. Mixtures of sCT, L-PEG or B-PEG and HPβCD were co-spray dried. Based on the particle properties, the best PEG:HPβCD ratio was 1:1 w:w for both PEGs. In the sCT-loaded particles, the L-PEG was more crystalline than B-PEG. Thus, L-PEG-based particles had lower surface free energy and better aerodynamic behavior than B-PEG-based particles. However, B-PEG-based particles provided better protection against chemical degradation of sCT. A decrease in sCT permeability, measured across Calu-3 bronchial epithelial monolayers, occurred when the PEG and HPβCD concentrations were both 1.6 wt %. This was attributed to an increase in buffer viscosity, caused by the two excipients. sCT pharmacokinetic profiles in Wistar rats were evaluated using a 2-compartment model after iv injection or lung insufflation. The maximal sCT plasma concentration was reached within 3 min following nebulization of sCT solution. L-PEG and B-PEG-based microparticles were able to increase T(max) to 20 ± 1 min and 18 ± 8 min, respectively. Furthermore, sCT absolute bioavailability after L-PEG-based microparticle aerosolization at 100 μg/kg was 2.3 times greater than for the nebulized sCT solution.     

A rheological study of semisolid preparations of Eudragit ®

The present work studies the rheology of semisolid preparations of acrylic polymers of Eudragit^©, specifically RS 30 D, RL 30 D and NE 30 D. The parameters of shear deformation were obtained from experimental data and those of compression deformation were determined using previously obtained linear equations relating shear and compression stresses. The results, which were statistically significant, show a linear relationship between the coefficient of regression of these equations and the apparent viscosities of the different semisolid preparations, and between the independent term and the consistency index of each, and corroborate the previously demonstrated linear relationship between shear and compression stresses. The effect of the volume of the spindle used in the viscosimeter was observed in all cases. The equations relating both types of stress, obtained from semisolid preparations of Carbomer^® 940, can be used to determine the compression stresses of other semisolid preparations in this case, Eudragit^®.     

Emulsification/internal gelation as a method for preparation of diclofenac sodium–sodium alginate microparticles

Emulsification/internal gelation has been suggested as an alternative to extrusion/external gelation in the encapsulation of several compounds including non-steroidal anti-inflammatory drugs such as diclofenac sodium. The objective of the present study was a trial to formulate diclofenac sodium as controlled release microparticles that might be administered once or twice daily. This could be achieved via emulsification/internal gelation technique applying Box-Behnken design to choose these formulae. Box-Behnken design determined fifteen formulae containing specified amounts of the independent variables, which included stirring speed in rpm (X1), drug:polymer ratio (X2) and the surfactant span 80% (X3). The dependent variables studied were cumulative percent release after two hours (Y1), four hours (Y2) and eight hours (Y3). The prepared microparticles were characterized for their production yield, sizes, shapes and morphology, entrapment efficiency and Diclofenac sodium in vitro release as well. The results showed that the production yield of the prepared diclofenac sodium microparticles was found to be between 79.55% and 97.41%. The formulated microparticles exhibited acceptable drug content values that lie in the range 66.20–96.36%. Also, the data obtained revealed that increasing the mixing speed (X1) generally resulted in decreased microparticle size. In addition, scanning electron microscope images of the microparticles illustrated that the formula contains lower span concentration (1%) in combination with lower stirring speed (200 rpm) which showed wrinkled, but smooth surfaces. However, by increasing surfactant concentration, microspheres’ surfaces become smoother and slightly porous. Kinetic treatment of the in vitro release from drug-loaded microparticles indicated that the zero order is the drug release mechanism for the most formulae.     

Eudragit® S100 coated calcium pectinate microspheres of curcumin for colon targeting

Currently, colon-specific drug delivery systems have been investigated for drugs that can exert their bioactivities in the colon. In this study, Eudragit? S100 coated calcium pectinate microsphere, a pH-dependent and enzyme-dependent system, as colon-specific delivery carrier for curcumin was investigated. Curcumin-loaded calcium pectinate microspheres were prepared by emulsification-linkage method, and the preparation technology was optimised by uniform experimental design. The morphology of microspheres was observed under scanning electron microscopy. Interactions between drug and polymers were investigated with differential scanning calorimetry (DSC) and X-ray diffraction. In?vitro drug release studies were performed in simulated colonic fluid in the presence of Pectinex Ultra SP-L or 1% (w/v) rat caecal content, and the results indicated that the release of curcumin was significantly increased in the presence of 1% (w/v) rat caecal contents. It could be concluded that Eudragit? S100 coated calcium pectinate microsphere was a potential carrier for colon delivery of curcumin.     

Design and in vitro evaluation of gentamicin–Eudragit microspheres intended for intra-ocular administration

The conditions of preparation of gentamicin sulfate microspheres with high drug loading and a particle size less than 5?µm, using a double-emulsion-solvent evaporation technique, intended for intra-ocular administration are described. The microspheres were prepared from poly methacrylate (Eudragit RS and RL) polymers cross-linked with polyvinyl alcohol. The parameters that improved the incorporation efficiency of gentamicin in the microspheres and controlled the particle size and surface morphology were investigated. Modifying the secondary aqueous phase by partially saturating it with various concentrations of either KCl or gentamicin increased the incorporation efficiency of the drug and affected the mean diameters of the microspheres. However, these characteristics were not altered when the initial drug loading was increased in the formulations. The modified gentamicin microspheres exhibited a smooth surface with an incorporation efficiency rate of 12.59% and a mean diameter of 4.06?µm. The antimicrobial efficiency of gentamicin released from the modified particles against selected Gram-positive and -negative organisms including Escherichia coli, Staphylococcus aureus and Pseudomonas aeruginosa confirmed that the entrapped gentamicin seemed to remain unaltered by the encapsulation process.     

Properties of theophylline tablets dry powder coated with Eudragit® E PO and Eudragit® L 100-55

The aim of the present study was to investigate the influence of Eudragit^® E PO on the drug release mechanism of Eudragit^® L 100-55 film coatings applied to theophylline tablets by a dry powder coating technique. The process was entirely liquid-free. Calculation of the Flory-Huggins interaction parameter based on solubility parameters suggested immiscibility of the two copolymers. MDSC thermograms were characterized by two glass transitions for the investigated Eudragit^® E PO/Eudragit^® L 100-55 ratios and confirmed incomplete miscibility of the copolymers at processing conditions. FT-IR analysis was employed to study binding interactions of the polymers. Due to the higher affinity of the plasticizer, triethyl citrate, for Eudragit^® E PO compared to Eudragit^® L 100-55, redistribution of the plasticizer was observed during the curing phase of the process. Plasticizer migration also affected the initial phase of drug release from powder-coated theophylline tablets that were stored for four weeks. Drug release from powder-coated tablets was dependent on the polymer blend ratio, coating thickness, and the pH of the dissolution medium. A broad range of pH dependent theophylline release profiles were obtained as a function of the polymer blend ratio. The particle size of the coating powder influenced the microstructure of the film coating.     

A pH/enzyme-responsive polymer film consisting of Eudragit® FS 30 D and arabinoxylane as a potential material formulation for colon-specific drug delivery system

Polymer film based on pH-dependent Eudragit^® FS 30 D acrylic polymer in association with arabinoxylane, a polysaccharide issued from gum psyllium, was produced by way of solvent casting. Physical-chemical characterization of the polymer film samples was performed by means of thermogravimetry (TGA), differential scanning calorimetry (DSC), and scanning electron microscopy (SEM). Furthermore, water-equilibrium swelling index (I_s) and weight loss of the films in KCl buffer solution of pH 1.2, in KH₂PO₄ buffer solution of pH 5.0, or in KH₂PO₄ buffer solution of pH 5.0 consisting of 4% enzyme Pectinex^® 3X-L (w/v) were also carried out for the film characterization. No chemical interactions between the Eudragit^® FS 30 D and the arabinoxylane polymer chains were evidenced, thus suggesting that the film-forming polymer structure was obtained from a physical mixture of both polymers. The arabinoxylane-loader films showed a more pronounced weight loss after their immersion in buffer solution containing enzyme Pectinex^® 3X-L. The introduction of the arabinoxylane makes the film more susceptible to undergo an enzymatic degradation. This meant that the enzyme-dependent propriety issued from the arabinoxylane has been imprinted into the film formulation. This type of polymer film is an interesting system for applications in colon-specific drug delivery system.     

Dry Powder Coating of Pellets with Micronized Eudragit® RS for Extended Drug Release

PURPOSE: To develop a novel powder coating technology for extended-release pellets based on the acrylic polymer, Eudragit RS. METHODS: A mixture of micronized Eudragit RS plus talc and a liquid feed (plasticizer plus binder solution) were sprayed separately onto propranolol hydrochloride-loaded pellets in a fluidized bed coater. The coated pellets were heat-cured under different conditions (40 degrees C to 60 degrees C, 2 h to 24 h). The coalescence (film formation) of the polymer particles was studied via the determination of the glass transition and the minimum polymer-softening temperatures (MST). The coated pellets were characterized with respect to their morphologic, release, and stability properties. RESULTS: The optimum plasticizer type and concentration and process temperatures could be identified by the determination of the MST. High concentrations of plasticizer (40% based on the polymer) and a thermal treatment were necessary to achieve complete film formation and extended drug release. Curing the pellets resulted in release profiles, which did not change during storage for 3 years. The coated pellets had a smooth, continuous surface and a dense film structure after curing. CONCLUSIONS: This novel coating technique avoids the use of organic polymer solutions or latex dispersions, has short processing times, and results in stable extended-release profiles.     

Enhancement of felodipine dissolution rate through its incorporation into Eudragit® E-PHB polymeric microparticles: in vitro characterization and investigation of absorption in rats

In this study, felodipine was incorporated into microparticles prepared with Eudragit? E and it blended with poly(3-hydroxybutyrate) (PHB) using the emulsion-solvent evaporation technique, with the aim of improving the dissolution rate of the drug. The formulation prepared with Eudragit? E showed irregular and fragmented microparticles, with a loading efficiency (LE) of 82.6%. When the microparticles were prepared with a blend of Eudragit? E and PHB, they had a spherical form with a LE of 103.9%. X-ray diffraction and differential thermal analysis indicated a reduction in the crystallinity of felodipine after its incorporation into the microparticles, which caused a significant increase in the felodipine dissolution rate. An investigation into the absorption in rats was carried out using high-performance liquid chromatography analysis of the blood collected 20 and 60 min after the animals were administered felodipine [30 mg/Kg, orally (p.o.)] or felodipine microparticles (30 mg/Kg, p.o.). Animals that were given felodipine showed mean plasmatic levels of 0.0125 (±0.00156) and 0.0240 (±0.0069) μg mL(-1) after 20 and 60 min, respectively, whereas animals that received microparticles containing felodipine showed respective mean plasmatic levels of 0.0651 (±0.0120) and 0.0369 (±0.0145) μg mL(-1) . Our data suggest that the incorporation into microparticles significantly enhanced the release of felodipine, improving its absorption in rats.     

Determination of analytical error function for β-blockers as a possible weighting method for the estimation of the regression parameters

Three analytical methods have been developed and validated for the quantification of β-blockers (celiprolol, bisoprolol and oxprenolol) using high performance liquid chromatography (HPLC) with UV detection. The methods were determined to be linear, precise and accurate (RSDs were lower than 5%), which allowed the quantitation of β-blockers assayed at concentrations in the range 25-0.78 μg ml⁻¹. After validation of reversed-phase HPLC methods, their analytical error functions were established by a rapid, simple and economical procedure. The discrimination of the best function for each active principle was performed by an appropriate polynomial statistical analysis, yielding SD (μg ml⁻¹) = 0.0295 + 0.0124C − 3.88 × 10⁻⁴C² for celiprolol, 0.0199 + 0.011 C − 1.27 × 10⁻⁵C³ for bisoprolol; and 0.0183 + 0.0089C − 9.68 × 10⁻⁶C³ for oxprenolol. These analytical error functions are an alternative to the weighting methods used in parameter estimation of β-blockers.     

Physical characterization of carteolol: Eudragit® L binding interaction

Eudragit® L 30D was used as a carrier to prepare carteolol polymeric complexes in order to obtain controlled release dosage forms. The polyanionic form of the polymer, neutralized at different degrees, reacts readily with carteolol hydrochloride to give water-insoluble complexes. Carteolol complexes were characterized by differential scanning calorimetry, IR, ¹H- and ¹³C-NMR spectroscopy. In fact, results indicated that there were intermolecular associations between the polymer and the drug consisting in ammonium salt interactions. Maximum carteolol content was found to be 22% in the complexes.     

In situ amorphisation of indomethacin with Eudragit® E during dissolution

In this study, the possibility of utilising in situ crystalline-to-amorphous transformation for the delivery of poorly water soluble drugs was investigated. Compacts of physical mixtures of γ-indomethacin (IMC) and Eudragit® E in 3:1, 1:1 and 1:3 (w/w) ratios were subjected to dissolution testing at pH 6.8 at which IMC but not the polymer is soluble. Compacts changed their colour from white to yellow indicating amorphisation of IMC.X-ray powder diffractometry (XRPD) confirmed the amorphisation and only one glass transition temperature was observed (58.1 °C, 54.4 °C, and 50.1 °C for the 3:1, 1:1 and 1:3 (w/w) drug-to-polymer ratios, respectively). Furthermore, principal component analysis of infrared spectra resulted in clustering of in situ transformed samples together with quench cooled glass solutions for each respective ratio. Subsequent dissolution testing of in situ transformed samples at pH 4.1, at which the polymer is soluble but not IMC, led to a higher dissolution rate than for quench cooled glass solution at 3:1 and 1:1 ratios, but not for the 1:3 ratio.This study showed that crystalline drug can be transformed into amorphous material in situ in the presence of a polymer, leading to the possibility of administering drugs in the amorphous state without physical instability problems during storage.