In Vivo Absorption of Didanosine Formulated in Pellets Composed of Chitosan Microspheres

Materials and Methods

Materials. Didanosine-buffered tablets were provided by Farmanguinhos (Rio de Janeiro, Brazil); commercial gastro-resistant granules, Videx® EC, were donated as a gift from Single Health System (Campinas, Brazil); didanosine was provided by Labogen Química Fina e Biotecnologia S.A. (Indaiatuba, Brazil); Kollicoat® MAE 100P was donated as a gift from BASF (São Paulo, Brazil); acetic acid and sodium TPP were purchased from Synth (São Paulo, Brazil). Chitosan (approx. MW 296.6 kDa and deacetylation 82.83±3.63%) was obtained from Polymar (Fortaleza, Brazil). MicrocrystaIline cellulose was obtained from Henrifarma (Campinas/SP, Brazil). Distilled water was purified by a Milli-Q system (Millipore®, São Paulo/SP, Brazil).

Preparation and characterization of chitosan microspheres. The chitosan microspheres were prepared by ionotropic gelation of chitosan and sodium TPP as cross-linking agent, according to Santana et al. 2008 (17). Briefly, the microspheres were formed by dropping an aqueous solution composed of TPP (2 g/l), magnesium hydroxide (6 g/l) and didanosine (39 g/l) to an aqueous solution of chitosan (2.0% w/v) previously acidified with acetic acid (pH=5.5). The solutions were mixed under stirring (2,000 rpm) at 25°C.

The microspheres were characterized by the mean diameter and distribution through dynamic light scattering technique using a Malvern Autosizer 4700, (United Kingdom, UK, Malvern), and by the zeta potential using a Malvern Zetasizer 3000HSA (United Kingdom, UK, Malvern). The morphology and the surface of the freeze-dried microspheres were analyzed by scanning electron microscopy (LEO, LEO 440i model, ElectronMicroscopy/Oxford (Cambridge, England). The efficiency of the microspheres for incorporation of didanosine was calculated as the ratio of the difference between the initial amount of drug used in the preparation and the free drug present in the supernatant aqueous phase after centrifugation, to the total mass of drug. The results are shown as percentages.

Production, coating and characterization of the pellets. The pellets were prepared by extrusion and spheronization, according to Severino et al. (20). Briefly, the previously prepared microspheres were dried in an oven at 40°C until 75% humidity. The same chitosan 4.8% (by mass) and microcrystalline cellulose 4.8% (by mass) were added as excipient to the wet mass of the microspheres for the production of the pellets. The formulation was then extruded at 20 rpm using a Caleva extruder (20 model, Sturminster Newton, England). The extrudates were spheronized at 100 rpm for 5 min in a Caleva Spheronizer 120. The pellets were dried in a fluidized bed (Würster, Uniglatt, Glatt, Binzen, Germany) at 50°C inlet air temperature.

The pellets were also initially coated using Kollidon® VA 64 polymer using an aqueous solution 10% (m/v), and dried for 30 min to prevent aggregation, due to the porous surface of the granules. Kollidon® also facilitated the subsequent coverage, forming an impermeable surface by sticking a thin film of the gastro-resistant polymer. A second coating, the gastro-resistant coating, was employed as an alcoholic solution containing 30% (w/v) with Kollicot 100® MAE P, 1.5% (w/v) propylenoglycol, 0.5% (w/v) magnesium trisilicate and 0.5% (w/v) titanic dioxide. Both processes were performed in a Würster-type fluidized bed operating at an air flow rate of 6 m3/h, under inlet air temperature of 50°C and 0.9 bar. The dispersion was fed at 0.5 g/min through a peristaltic pump (Watson Marlow, Barueri, São Paulo, Brazil)

The pellets were characterized by size parameters through Feret diameter, sphericity and elongation measurements. Morphology was visualized by photograph obtained from a stereoscope (Motic, SMZ-161 model, British Columbia, Canada).

Animal protocols. The protocol used for didanosine pharmacokinetic evaluation was previously approved by the Ethics in Research Committee of University of Rio Grande do Sul (#2007760). A previous pilot study was carried out to demonstrate the applicability of the designed experimental protocol. Subsequently, the complete study was performed in male adult dogs (10 kg) which were previously vermifuged a week before the experiment and maintained individually. The dogs were fasted for 12 h before drug administration and received water and food 2 h later. Didanosine was evaluated using the three formulations: MCGs, tablets and the gastro-resistant Videx® EC. Each formulation was administered orally as a single dose of 500 mg didanosine to nine dogs. Blood samples (2 ml) were collected from the cephalic vase of the dog foot in heparinized VACUETTE® (Campinas/SP, Brazil) tubes before (time 0) and at 0.25, 0.5, 0.75, 1, 2, 4, 6, 8, 10, 12, 18, 24 e 36 h after administration. The blood cells were removed by centrifugation for 10 min at 91 RCFxforce and the separated plasma was stored at −20°C until assayed.

The pharmacokinetic parameters were determined by the non-compartmental approach. The elimination rate constant (k_el) was calculated by the log-linear regression of didanosine concentration during the elimination phase and the half-life (t_1/2) was calculated as 0.693/kel. The maximum concentration of didanosine in the plasma (C_max) and the corresponding time (t_max) were obtained by visual inspection of the concentration–time profiles. The area under the plasma concentration versus time curve (AUC_0–t) from time zero to the time of last measured concentration (Clast) was calculated by the log-linear trapezoidal rule. The AUC zero to infinity (AUC_0–∞) was obtained by the addition of AUC_0–t and the extrapolated area determined by C_last/k_el. The adsorbed fraction of drug in the bloodstream, considered the same bioavailable fraction (Fr_el) was calculated as AUC/(administered dose) and the corresponding medium oral clearance was CL/F_el, where CL is the clearance rate. The extrapolated area under the concentration–time curve (AUMC) was the volume taken from each of n samples to form a pooled sample, which is proportional to t_n(t_n+1 − t_n−1), except at t₀ where the aliquot volume is 0 and at tlast (the last time of collected sample). AUMC was calculated by C_pooled × T²/2, where T is the overall experimental time (t_last − t₀). The ratio between AUMC and AUC yields the mean residence time.

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Figure 1.

Morphologies of the chitosan microspheres encapsulating ddI (a) and the chitosan granules covered with the gastro-resistant polymer Kollidon® VA 64(b).

Analytical procedures in plasma. The protocol used for the analysis of didanosine in plasma was based on the analytical methodology described by Severino et al. (21). Previously, the samples were submitted to an extraction in a solid phase mounted in the Prospekt 2™ equipment (Spark Holland, Emmen-SPE, the Netherlands). The online SPE system was composed by the following modules: automated cartridge exchange (ACE) module for disposable cartridge exchange, high-pressure dispenser (HPD) for handling of solvents and an auto sampler Triathlon. The SPE cartridges were specified as BondElut C₁₈, 40-90 μm of size particles and 10 mm×2 mm i.d. The samples were analyzed by high-performance liquid chromatography using a complete Shimadzu system (Shimadzu, Italia, Milan, Italy). The analytical column C18 (15 cm ×4 mm V04-745), was preceded by a guard column ACE® 5C18, V03-417, Analítica®. All samples and standard solutions were eluted at 28°C in a 1.0 ml/min flow rate, using a mixture of 0.02 M potassium phosphate buffer (KH₂PO₄), acetonitrile (96:4, v/v) and sulfonic acid heptane 0.5% (w/v) as the mobile phase, at pH 6.5 adjusted with triethylamine. Didanosine in the injected samples (50 μl) was detected at 250 nm wavelength.