M.L. González-Rodríguez

Alginate/chitosan particulate systems for sodium diclofenac release

Alginate/chitosan particles were prepared by ionic gelation (Ca2+ and Al3+) for the sodium diclofenac release. The systems were characterized by electron microscopy and differential scanning calorimetry. The ability to release the active substance was examined as a function of some technological parameters and pH of dissolution medium. The release of sodium diclofenac is prevented at acidic pH, while is complete in a few minutes when pH is raised up to 6.4 and 7.2. The alginate/chitosan ratio and the nature of the gelifying cation allow a control of the release rate of the drug. The release mechanism was briefly discussed.

Characterization of Ibuproxam Binary and Ternary Dispersions with Hydrophilic Carriers

This work investigates the possibility of increasing the dissolution properties of ibuproxam (a poorly water‐soluble anti‐inflammatory drug) using hydrophilic carriers such as polyvinylpyrrolidone (PVP), polyethylene glycol (PEG), or urea, alone or in combination. Phase‐solubility studies showed that the carrier solubilizing power was in the order PEG > PVP > urea and evidenced a synergistic effect in drug solubility improvement when using carrier combinations. Binary and ternary systems, at 20/80 or 20/40/40 (w/w) drug/carrier(s) ratios, prepared by coevaporation of their ethanolic solutions or by cogrinding physical mixtures in a high‐energy vibrational micromill, were characterized by differential scanning calorimetry (DSC), hot stage microscopy (HSM), and scanning electron microscopy (SEM) analyses. The results of dissolution tests (USP paddle method), in terms of Dissolution Efficiency, indicated that ternary systems were up to 35% more effective than the corresponding binary preparations and coevaporated products were up to 45% more efficacious than the corresponding coground ones. The IBUX‐PEG‐PVP coevaporated was the best product, allowing a more than three‐times increase in Dissolution Efficiency with respect to drug alone; moreover, t50% ( > 60 min for pure ibuproxam) was < 10 min, and 90% dissolution was achieved after 30 min, whereas only 40% was obtained after 60 min for pure drug. The best performance of this system was attributed to a joined effect of the strong amorphizing power of PVP (as demonstrated by solid state analyses) with the high solubilizing efficacy of PEG (as emerged from phase‐solubility studies). The drug dissolution rate from solid dispersions remained practically unchanged after one‐year storage at room temperature in closed containers.

New "drug-in cyclodextrin-in deformable liposomes" formulations to improve the therapeutic efficacy of local anaesthetics.

The combined approach of cyclodextrin complexation and entrapment in liposomes was investigated to develop a topical formulation of local anaesthetics. For both benzocaine (BZC) and butamben (BTM), hydroxypropyl-beta-cyclodextrin (HPbetaCD) was a better partner than betaCD; drug-HPbetaCD coevaporated products showed the best solubility and dissolution properties, and were selected for loading into liposomes. Addition of stearylamine to the phosphatidylcholine-cholesterol mixture of the vesicle bilayer allowed obtainment of deformable liposomes with improved permeation and in vivo drug anaesthetic effect (P<0.05). Double-loaded deformable liposomes were obtained by adding the drug-HPbetaCD complex at its maximum aqueous solubility in the vesicles hydrophilic phase, and the remaining amount up to 1% as free drug in the lipophilic phase. The properties of double-loaded liposomes were compared with those of classic single-loaded ones, obtained by adding 1% free drug in the aqueous or lipophilic phase of the vesicles. Size, charge, morphology and entrapment efficiency of the different batches were investigated, respectively, by light scattering, confocal laser scanning microscopy and dialysis, while their therapeutic efficacy was evaluated in vivo on rabbits. For both drugs, double-loaded liposomes, exploiting the favourable effects of drug-CD complexation, allowed a significant (P<0.05) enhancement of intensity and duration of anaesthetic effect with respect to those single-loaded.

Charged liposomes as carriers to enhance the permeation through the skin

Introduction: In recent years, there has been increased interest in developing charged liposomes as carriers for transdermal drug delivery. It is necessary to modify the basic composition of the liposomes in order to enhance the penetration properties of the vesicles through the skin. Charged liposomes offer several advantages compared with previous drug delivery systems. Areas covered: This paper provides a brief overview of the different drug delivery systems that exist which aim to improve the permeation of drugs through the skin, focusing on the use of charged liposomes for transdermal delivery. We propose a classification of such liposomes based on the origin of the charge given to the vesicles. Expert opinion: Despite the advances that are occurring in the design of charged liposomes for transdermal drug delivery, the long-term stability continues to be a drawback in such systems. The presence of charge on the surface of the vesicles favors the electrostatic repulsion among them, creating a ζ potential positive or negative that prevents their aggregation and flocculation. However, there is loss of the encapsulated drug, which limits the in vivo use of these systems. It should be emphasized that charged liposomes are indeed a promising candidate for use in gene therapy and vaccine targeting, in a great diversity of diseases, for which drugs are administered by the percutaneous route.

Effect of preparation technique on the properties and in vivo efficacy of benzocaine-loaded ethosomes

This study aimed to investigate the influence of the preparation conditions on the performance of an ethosomal formulation for topical delivery of the local anesthetic agent, benzocaine (BZC). Ethosomes were prepared with different techniques, such as thin-layer evaporation, freezing and thawing, reverse-phase evaporation, extrusion and sonication, obtaining, respectively, multilayer vesicles (MLVs), frozen and thawed MLV (FATMLV), large unilamellar vesicles (LUVs), and small unilamellar vesicles (SUVs). The obtained vesicles were characterized for morphology, size, zeta potential, and entrapment efficiency (EE%), and their stability was monitored during storage at 4°C. In vitro permeation properties from gels incorporating drug ethosomal dispersions were evaluated in vitro by using artificial lipophilic membranes, while their anesthetic effect was determined in vivo on rabbits. The results suggested that the vesicle preparation method plays an important role in affecting the properties and effectiveness of ethosomal formulations. MLVs and LUVs exhibited higher drug EE% and better stability than FATMLV and SUV vesicles. The In vitro drug permeation rate was directly related to the vesicle EE% and varied in the order MLV>LUV≈FATMLV>SUV. The therapeutic efficacy of BZC ethosomal formulations was significantly improved with respect to the corresponding BZC solution. The best results, in terms of enhanced intensity of anesthetic effect, were given by formulations containing MLVs and LUVs, and the order of effectiveness was MLV≈LUV>FATMLV≈SUV, rather similar to that found in permeation studies. On the contrary, unexpectedly, the effectiveness order in increasing the duration of drug action was SUV≥MLV>LUV≈FATMLV. The highest efficacy of SUVs was probably due to the more intimate contact with the epithelium due to their greatest surface area, which allowed the longest extension of drug therapeutic action. The overall results suggest that a suitably developed ethosomal formulation of BZC can be of actual value for improving its clinical effectiveness in topical anesthesia.

Characterization and dissolution properties of ketoprofen in binary and ternary solid dispersions with polyethylene glycol and surfactants.

The effect of incorporation of an anionic [sodium dodecyl sulfate (SDS) or dioctylsulfosuccinate (DSS)] or nonionic [Tween 60 (TW60)] surfactant on the properties of ketoprofen solid dispersions in polyethylene glycol 15000 (PEG) has been investigated. Physicochemical and morphological properties of the various solid systems were determined by differential scanning calorimetry, hot stage microscopy, X-ray powder diffraction analysis, and scanning electron microscopy. The results from dissolution studies, performed according to the USP 24 basket method, indicated that all ternary dispersed systems were significantly (p < 0.001) more efficacious than the corresponding binary ones, by virtue of the additive wetting and solubilizing effect due to the presence of the surfactant. The relative effectiveness of the incorporated surfactant was in the same order as found in phase-solubility studies (i.e., SDS > DSS > TW60). With regard to the solid dispersion preparation method, coevaporated products always gave better results than the corresponding cofused ones; however, this effect was statistically significant (p < 0.001) only in the initial phase of the dissolution process. The most effective solid dispersion was the 10-80-10 w/w drug-PEG-SDS ternary coevaporate, which allowed dissolution of 50% drug after only 6 min (in comparison with > 120 min for drug alone and 17 min for the binary coevaporate) and dissolution of about 100% drug after 30 min (in comparison with > 120 min for the binary coevaporate).

In vitro release of sodium diclofenac from a central core matrix tablet aimed for colonic drug delivery

The present study was aimed at developing a novel sodium diclofenac formulation for colonic release. The proposed delivery system consisted in a polymeric matrix tablet containing a drug central core purposely designed for obtaining a time-controlled release profile characterized by an initial phase of lag-time followed by a controlled release phase, according to zero order kinetics. The spheric central core was formed by a solid dispersion of the drug into the hydrophilic polymer PEG 4000, which enabled an improvement of drug dissolution properties with respect to other carriers such as lactose. Eudragit RS100 was used as inert polymeric matrix for the core coating, mixed (50:50, w/w) with sodium chloride and Emdex as channeling agents. Tablets containing the drug central core were prepared by direct compression, without any other excipient, and tested for dissolution properties according to the USP paddle method, under pH-gradient conditions. For both series of formulations, lag times increased with decreasing the channeling agent particle size, as a consequence of the smaller pores formed by its dissolution. However, formulations containing sodium chloride always showed longer lag times than the corresponding with Emdex and were more effective in providing prolonged zero-order release periods. This was mainly attributed to the plastic deformation properties under compression shown by sodium chloride, leading to a less porous, more compact network which more strictly controlled solvent penetration and drug dissolution and release rates. By varying the sodium chloride/Eudragit w/w ratio, it was possible to suitably modulate the length of both the lag time (for achieving colonic targeting) and zero-order release phases.

Development of Enteric-coated Timed-release Matrix Tablets for Colon Targeting

A new oral drug delivery system for colon targeting has been developed based on enteric-coated matrix tablets which suitably exploits both pH-sensitive and time-dependent functions. Matrix-tablets were prepared by direct compression of mixtures of hydroxyethylcellulose (HEC), a hydrophilic swellable polymer, with the inert insoluble ethylcellulose (EC) or micro-crystalline cellulose (MCC) polymers, in which theophylline, selected as model drug, was dispersed. Eudragit S100, a methacrylic acid copolymer soluble at pH 7, was used as pH-sensitive coating polymer. The influence of varying the cellulose-derivative combinations and their relative ratios as well as the level of the coating polymer was investigated. Surface morphology of the tablets was monitored by SEM analysis before and after the release test. The results of release studies, performed according to the USP basket method using a sequence of dissolution media simulating the gastrointestinal physiological pH variation, indicated that the Eudragit S100 enteric-coated matrix tablets were successful in achieving gastric resistance and timed-release of the drug, assuring an adequate lag time for the intended colonic targeting, followed by a controlled-release phase. The enteric-coating level emerged as the critical factor in determining the duration of the lag-phase, whereas the release rate mainly depended on the matrix composition. Formulations with higher HEC content showed a faster drug release rate than those with greater content in inert polymer and the MCC–HEC combinations were more effective than the corresponding EC–HEC ones. The best results were given by the 27% coated 1:0.3:0.7 (w/w) drug/MCC/HEC tablets, which, after a 260 min lag time, regularly released the drug, achieving about 90% of release after 10 h.

Positively and negatively charged liposomes as carriers for transdermal delivery of sumatriptan: in vitro characterization.

Background: The influence of liposome composition, lamellarity, preparation method, and charge on the encapsulation efficiency, size, polydispersity, and surface charge of sumatriptan liposomes was studied. For this purpose, we studied multilamellar, unilamellar, and frozen and thawed liposomes. Positively or negatively charged liposomes were obtained using both phosphatidylcholine and cholesterol, in combination with stearylamine or dicetylphosphate. Liposomal formulations were characterized by confocal laser scanning microscopy and optical microscopy for vesicle formation, morphology, and lamellarity by dynamic laser light scattering for size distribution and polydispersity, and electrophoretic mobility for zeta potential determination. To obtain more information about the sumatriptan encapsulation, dynamic dialysis technique was employed. The sumatriptan amount was quantified by high-performance liquid chromatography. Results: Overall obtained results showed that liposomes may be interesting carriers for sumatriptan succinate. Statistical analysis evidenced that the preparation method does not affect the evaluated characterization parameters. However, the presence of charge inducer agents modified these characteristics. Highest loading efficiency of sumatriptan was exhibited for positively charged liposomes containing 6.58:10.34:3.73 mmolar ratio for phosphatidylcholine : cholesterol : stearylamine. The mean size was affected by the charge inducer, being smaller in positively charged liposomes. Logically, surface charge of liposomes varied as a function of the employed charged agent. Also, interesting results were obtained when vesicles were loaded with sumatriptan, showing a statistical significance between all pairs, comparing the formulations with and without drug. Conclusion: Results obtained revealed that the presence of sumatriptan into the vesicles has a different behavior in negatively and positively charged liposomes.

Preparation and characterization by morphological analysis of diclofenac/PEG 4000 granules obtained using three different techniques.

The steam granulation is a new wet granulation technique, which involves the use of steam water instead of traditional liquid water as granulation liquid. The aim of this work was to evaluate the possibility of using this new technique to prepare diclofenac-polyethylene glycol 4000 accelerated-release granules. Steam granules were prepared in a laboratory scale high-shear mixer, and their properties were then compared to those of granules, having the same composition, obtained by traditional granulation techniques (wet and melt granulation). The results showed that, selecting the proper process parameters, it was possible to obtain granules using all the three methods; however, the total process time was significantly shorter for steam granulation (30 min) in comparison to traditional wet granulation (70 min), due to the lower amount of used water. The morphological characterization of steam, water and melt granules, performed by scanning electron microscopy (SEM) and image analysis, revealed that steam granules had a more spherical shape and a larger surface area with respect to water and melt ones, suggesting a possible difference in dissolution behavior. Moreover, differential scanning calorimetry (DSC) and X-ray powder diffraction analysis evidenced the transformation of the drug from its originally crystalline form into the amorphous one. Finally, the in vitro dissolution tests showed an increased dissolution rate of the drug from the granules (in particular steam granules) in comparison to pure drug and physical mixture. In conclusion, the results of this study suggested that the steam granulation technique could be considered an interesting alternative to traditional wet granulation to improve the dissolution rate of diclofenac.