Osvaldo Albuquerque Cavalcanti

Polysaccharides as Excipients for Colon-Specific Coatings. Permeability and Swelling Properties of Casted Films

ABSTRACT Oligosaccharides such as inulin (In) and polysaccharides such as galactomannans, combined with polymethacrylates on isolated films for film coatings, were obtained from aqueous-based solvents and investigated as potential vehicles for colonic drug delivery. These compositions, which are susceptible to fermentation by colonic microflora, constitute promising excipients for the development of new colon-specific therapeutic systems. The characteristics of several compositions have been demonstrated in permeability and swelling studies on isolated films composed of a polymethacrylate associated with In or galactomannans of mesquite seed gum (MSG). Results reported prove a dependency of the properties of mixed films on the polymethacrylate–polysaccharide concentration ratio and on the composition of the dissolution media. An increase in permeability through the mixed films was observed in a simulated colonic environment for the following compositions: Eudragit®RS30D–MSG 70 : 30 w/w; Eudragit® RS30D–In 90 : 10 w/w; Eudragit®RS30D–In 76 : 24 w/w.

Influência do sulfato de condroitina na formação de filmes isolados de polimetacrilato: avaliação do índice de intumescimento e permeabilidade ao vapor d'água

Natural or modified chondroitin sulfate was incorporated in to polymethacrylate to obtain isolated films. The addition of polysaccharide to synthetic polymers occurred at different rates. Isolated films were micro and macroscopically characterized and swelling index and water vapor transmission were determined. Results indicated changed transparency and flexibility, coupled to their dependence on increase in polysaccharide concentration. A similar occurrence was reported in the permeability to water vapor and swelling degree. Films composed of modified chondroitin sulfate, 90:10 concentration, showed hydration levels, permeability and morphological properties which allow them to be applied as excipients in the development of new drug delivery systems.

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 (Is) 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.

Development and characterization of crosslinked hyaluronic acid polymeric films for use in coating processes.

The aim of this work was to develop and characterize new hyaluronic acid-based responsive materials for film coating of solid dosage forms. Crosslinking of hyaluronic acid with trisodium trimetaphosphate was performed under controlled alkaline aqueous environment. The films were produced through casting process by mixing crosslinked or bare biopolymer in aqueous dispersion of ethylcellulose, at different proportions. Films were further characterized regarding morphology by scanning electron microscopy, robustness by permeation to water vapor transmission, and ability to hydrate in simulated gastric and intestinal physiological fluids. The safety and biocompatibility of films were assessed against Caco-2 and HT29-MTX intestinal cells. The permeation to water vapor transmission was favored by increasing hyaluronic acid content in the final formulation. When in simulated gastric fluid, films exhibited lower hydration ability compared to more extensive hydration in simulated intestinal fluids. Simultaneously, in simulated intestinal fluids, films partially lost weight, revealing ability for preventing drug release at gastric pH, but tailoring the release at higher intestinal pH. The physiochemical characterization suggests thermal stability of films and physical interaction between compounds of formulation. Lastly, cytotoxicity tests demonstrated that films and individual components of the formulations, when incubated for 4h, were safe for intestinal cells Overall, these evidences suggest that hyaluronic acid-based responsive films, applied as coating material of oral solid dosage forms, can prevent the premature release of drugs in harsh stomach conditions, but control the release it in gastrointestinal tract distal portion, assuring safety to intestinal mucosa.

Avaliação da pectina fosfatada aplicada na formação de filmes isolados: Material candidato a novos sistemas para liberação modificada de fármacos

Phosphated pectin (Pect-TMFT) together with α-gluco-oligossacaride (Bioecolians®) were incorporated into aqueous dispersion of polymethacrylate (Eudragit® RS 30 D) to obtain free films by the casting process (50oC) in Teflon® plate. Pect-TMFT and Bioecolians® were added into dispersions of Eudragit ® RS 30 D at different rates: 90:05:05, 80:10:10 and 70:20:10 (4% p/v). Triethyl citrate (TEC) was used as plasticizer (20% of mass of the polymethacrylate). The proposed dispersions showed film formation ability. The free films were characterized by the determination of water vapour transmission (WVT), by the swelling index (Ii%) in fluids of gastric simulation (FGS) and intestinal (FIS) and by scanning electron microscopy (SEM). The increase of modified polysaccharide and Bioecolians® in the films favored their permeability to the water vapour and their hydration degree when in FIS (pH = 6.8). In that way, the obtained film in the concentration 70:20:10, can prevent the premature release of the drug in the up GIT when applied to develop oral solid systems coating. Besides, the presence of Pect-TMFT and Bioecolians® can contribute to the specific membrane degradation by colonic microflora enzymes, making possible a modified release kinetics of drugs even with the existence of inter-individual variations of pH.

Avaliação da pectina-HPMC no processo de revestimento por compressão: I - Estudo da propriedade de intumescimento em núcleos revestidos

In this study, core tablets of dry theophylline were compressed coated using the system pectin-HPMC for controlled drug delivery. The methodology applied produced coated tablets with suitable physical characteristics according to Brazil Pharmacopeia 4th edition. The physical properties were evaluated for different ratios (80:20, 60:40, 50:50, 40:60, 20:80, 0:100) of pectin-HPMC, respectively, and the swelling test was carried out in simulated gastric fluid (pH 1.2) and in simulated intestinal fluid (pH 6.8). The method applied gave origin to coated tablets with high expectation in the kinetics control of drug release. From the statistics analyses of the results obtained, it was observed that results were not significant between different ratios.

Exploitation of lipid-polymeric matrices at nanoscale for drug delivery applications

ABSTRACT Introduction: Progress in drug delivery and a better quality of life for patients, relies on the development of new and suitable drug carrier systems, with unequivocal therapeutic benefits, low systemic toxicity and reduced side effects. Lipid-polymeric nanoparticles have been explored to produce nanocarriers due to their features and applications such as high drug entrapment, physical-chemical stability and controlled release properties. Areas covered: In this review, we describe several hybrid nanoparticles obtained from mixing a polymer with a lipid matrix. This association can potentiate the efficacy of drug delivery systems, due to the enhancement of encapsulation efficiency and loading capacity, tailoring the drug release according to the therapeutic purpose, and improving the drug uptake by targeting it to specific receptors. Contrary to lipid nanoparticles, these hybrid nanoparticles can decrease the initial burst release and promote a more sustained and localized release of the drug. Expert Opinion: Lipid-polymeric nanoparticles are versatile vehicles for drug delivery by different administration routes in the treatment of multiple diseases. Different solid lipids, polymers, surfactants and techniques for producing these carriers have been investigated, revealing the importance of their composition to achieve optimal characteristics to drug delivery.

ANÁLISES FÍSICO-QUÍMICAS DE BIOFILMES DE SULFATO DE CONDROITOINA MODIFICADO

Numerous investigations are dedicated to the research and development of new polymer materials destined for innovation in pharmaceutical forms. The application of these technological resources has allowed the commercialization of new therapeutic systems for modified drug release. This investigation aimed to evaluate the association of modified chondroitin sulfate with an insoluble polymer, Eudragit® RS 30 D, widely available in the pharmaceutical market. Isolated films were prepared by the evaporation process using a Teflon® plate. The aqueous dispersions (4% m/v) of synthetic polymer received the addition of modified chondroitin sulfate at different ratios. The interactions of the polymer chains in the blends were physicochemically characterized by means of Fourier transform infrared spectroscopy, thermal analyses, differential scanning calorimetry, thermogravimetry and scanning electron microscopy combined with hydration and assays in alkaline pH. The results showed appropriate properties of the coating materials for solid oral forms intended for drug deliver in specific environments.

Avaliação das propriedades de intumescimento e permeabilidade de filmes isolados de polimetacrilato contendo polissacarídeo da raiz de Lótus (Nelumbo nucifera)

Polysaccharides such as extracted from Lotus root (Nelumbo nucifera) combined with polymethacrylates on isolated films for film coating was studied as potential vehicles for colonic drug delivery, susceptible to fermentation by micro flora. For the preparation we used the association of Eudragit®RS 30D and polysaccharides in different concentrations (100:0, 90:10, 80:20, 70:30) in aqueous-based solvents. In the present study, the films were characterized by swelling studies and water vapor transmission studies. These tests demonstrated that different associations do not present significant differences, showing that the physico-chemical properties of EudragitâRS 30D are not altered and this material will be able to be applied for film formation in coating for colonic drug delivery system development.

Development and characterization of lipid-polymeric nanoparticles for oral insulin delivery

ABSTRACT Introduction: The oral route is widely accepted as the most physiological path for exogenous administration of insulin, as it closely mimic the endogenous insulin pathway. Thus, in this work it is proposed an innovative lipid-polymeric nanocarrier to delivery insulin orally. Areas covered: Nanoparticles were produced through a modified solvent emulsification-evaporation method, using ethyl palmitate and hydroxypropylmethylcellulose acetate succinate as matrix. Lipid-polymeric nanoparticles were around 300 nm in size, negatively charged (−20 mV) and associated insulin with efficiency higher than 80%. Differential scanning calorimetry suggested thermal stability of nanoparticles. In vitro release assays under simulated gastrointestinal conditions resulted in 9% and 14% of insulin released at pH 1.2 during 2 h and at pH 6.8 for 6 h, respectively, demonstrating the ability of those nanoparticles to protect insulin against premature degradation. Importantly, nanoparticles were observed to be safe at potential therapeutic concentrations as did not originate cytotoxicity to intestinal epithelial cells. Lastly, the permeability of nanoencapsulated insulin through Caco-2 monolayers and a triple Caco-2/HT29-MTX/Raji B cell model correlated well with slow release kinetics, and fosters the effectiveness of nanoparticles to promote intestinal absorption of peptidic drugs. Expert opinion: Lipid-polymeric nanoparticles were developed to encapsulate and carry insulin through intestine. Overall, nanoparticles provide insulin stability and intestinal permeability.