Nanocapsules are vesicular drug carriers constituted of an oil core, a polymeric wall, and surfactants. A general understanding about the influence of the polymeric wall of nanocapsules on the release profiles of drugs is not known. So, this work was devoted to characterize formulations prepared without polymer or containing it at different concentrations. The indomethacin ethyl ester was used as model and the strategy was based on its interfacial alkaline hydrolysis simulating a sink condition for the release. The antiedematogenic activity in rats for ester-loaded-nanocarriers was also evaluated. The nanocapsules (NC) and nanoemulsion (NE) presented particle sizes below 300 nm, polydispersity lower than 1.2 and pH around 5. SAXS analyses showed that the sorbitan monostearate is dissolved in the oil and the polymer presents regions of crystallinity independently on the PCL concentration. TEM analyses showed droplets (NE) and spherical particles (NC). The time for the total disappearance of the ester varied from 12 h to 24 h depending on the polymer concentration. The biexponential model showed that the indomethacin ester was essentially entrapped within the nanocarriers in an extension of 85 to 95%. The half-lives varied from 147 to 289 min for the sustained phases and from 3 to 6 min for the burst phases. The ester-loaded-NC showed significant antiedematogenic activity, while the ester-loaded-NE did not inhibit the carrageenin-induced paw edema. The nanocapsules promoted the absorption of the indomethacin ethyl ester and the presence of the polymer is important to achieve the pharmacological effect.
To determine the association form of indomethacin in nanocapsules prepared with poly(eta-caprolactone) as polymer and a triglyceride as oil, two methods were studied. The indomethacin ethyl ester was prepared as control, which showed a higher affinity for the oil than the indomethacin. Two differently loaded nanocapsule formulations were prepared. For both formulations, a burst effect was detected using ethanol as release medium. Light scattering (PCS) and NMR analyses suggested the ethanol diffuses through the nanocapsule polymeric wall promoting the total release of indomethacin and its ester. The results showed the inability of this approach to determine the association form of indomethacin. On the other hand, the alkaline hydrolysis of indomethacin and its ester, followed by their disappearance (HPLC), were evaluated. The nanocapsule suspensions containing indomethacin or its ester were treated with 50 mM NaOH. The total disappearance of indomethacin associated with nanocapsules was determined after 2 min, whereas the ester associated with colloids was consumed during 24 h. The constant particle sizes (264 and 259 nm) during the hydrolysis reactions showed that neither the nanocapsules were dissolved nor the polymer sorbed water during the contact with NaOH aqueous solution. The ester rate hydrolysis was determined by its diffusion from the nanocapsules to the interface particle/water. Finally, the indomethacin association model considers the burst release of drug after the addition of NaOH by the formation of its carboxylate, followed by its hydrolysis in aqueous solution promoted by the excess of NaOH. The adsorption was the mechanism of indomethacin association with nanocapsules.
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