Spray-dried raloxifene submicron particles for pulmonary delivery: Development and in vivo pharmacokinetic evaluation in rats.

Raloxifene hydrochloride (RH) is a selective oestrogen receptor modulator used for the treatment of osteoporosis. Even though 60% of an oral dose is quickly absorbed via the gastrointestinal tract, the absolute bioavailability of RH is only 2-3% in humans due to extensive first-pass metabolism. Various approaches to improve RH bioavailability have been reported over the past few years; however, none have focused on the development of products for pulmonary administration. Therefore, in this study, submicron particles containing RH were produced for pulmonary administration with the aim to limit first-pass metabolism. Powders were produced by vibrational atomisation spray drying with a high process yield (>80%). The drug content was between 440 and 890 mg·g-1, and powders had a high encapsulation efficiency (>95%), mean particle size of 400-700 nm, low residual moisture (<2%) and spherical shape. These powders showed an improved drug dissolution rate compared to the raw RH material. Moreover, they presented high dose uniformity (95-100%), a high in vitro respirable fraction (>55%) and adequate mass median aerodynamic diameter for pulmonary delivery (<5 µm). The pharmacokinetic study in male Wistar rats demonstrated an absolute bioavailability of 47.20% after pulmonary administration of the particles. Therefore, these submicron-sized powders are promising for pulmonary RH delivery as a dry powder medicine.

LC-UV method to assay raloxifene hydrochloride in rat plasma and its application to a pharmacokinetic study

A specific, precise, and accurate LC-UV method was developed and validated to assay raloxifene hydrochloride in rat plasma. Raloxifene was analyzed after liquid-liquid extraction and quantified by reversed phase liquid chromatography (C18 column) using acetonitrile and ammonium acetate buffer 0.05 M (pH 4.0) as mobile phase at a flow rate of 1 mL.min-1 and UV detection at 287 nm. Retention times of raloxifene and internal standard (dexamethasone) were approximately 11 min and 14 min, respectively. Linearity was checked for a concentration range between 25 ng.mL-1 and 1000 ng.mL-1. Intra- and inter-day precision had relative standard deviation lower than 10% and 15%, respectively. Recovery from plasma was higher than 90%. Accuracy values were 98.21%, 99.70%, and 102.70% for lower, medium, and upper limits of quantification, respectively. Limit of quantification was 25 ng.mL-1. Drug stability was analyzed at room temperature using plasma kept in a freezer at -80 °C for 45 days after processing for 6 h and three freeze-thaw cycles. The advantages of the method developed include stability under different conditions and low limit of quantification. Its applicability was confirmed by the analysis of raloxifene levels in plasma samples in a designed pharmacokinetic study in rats after intravenous administration (5 mg.kg-1).

Nanoencapsulation of Clobetasol Propionate Decreases Its Penetration to Skin Layers Without Changing Its Relative Skin Distribution.

An immunosuppressive effect with drug release control and higher NTPDase activity in the treatment of contact dermatitis was previously reported for a hydrogel containing 0.05% clobetasol propionate-loaded lipid-core nanocapsules (HG-LNC-CP) compared to a hydrogel containing the non-encapsulated drug (HG-CP). In order to investigate the factors underlying this different performance, we evaluated the in vitro skin permeation/penetration of CP from both formulations (HG-LNC-CP and HG-CP). CP did not permeate to the receptor medium during the experiment (24 h), but penetrated into the stratum corneum and viable skin (epidermis and dermis) in significant amounts after 24 h, regardless the type of the formulation. Comparing both formulations, although the relative amount of CP in each skin layer was not affected by the nanoencapsulation, HG-LNC-CP was able to reduce in 5.8, 6.9 and 3.7 times the amount of CP released into the stratum corneum, epidermis and dermis respectively. In this way, the higher effect of HG-LNC-CP previously observed could be due to the controlled drug penetration rate into the skin layers. Moreover, HG-LNC-CP reduces the chances of the corticosteroid to be absorbed systemically as the amount of CP reaching the dermis was reduced. The study reinforces the HG-LNC-CP as a promising dermatological nanomedicine for the treatment of skin disorders.

Controlled release of raloxifene by nanoencapsulation: effect on in vitro antiproliferative activity of human breast cancer cells.

Raloxifene hydrochloride (RH) is considered to be an antiproliferative agent of mammary tissue. The aim of this study was to investigate the effect of the encapsulation of RH in polymeric nanocapsules with anionic or cationic surface on its release profile and antiproliferative activity. They were prepared by interfacial deposition of preformed polymer, followed by wide physicochemical characterization. The in vitro RH release was assessed by the dialysis membrane method and the data analyzed by mathematical modeling. The antiproliferative effect on MCF-7 cell viability was investigated by 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide assay as well as by counting viable cells. They had high encapsulation efficiency, low polydispersity, and nanometric mean size. Nanocapsules prepared with Eudragit(®) RS100 and Eudragit(®) S100 presented positive and negative zeta potentials, respectively. Drug release studies demonstrated controlled release of RH from anionic nanocapsules, which could be explained due to a stronger interaction of the drug to these nanocapsules and the larger amount of entrapped drug. On the other hand, this control was not observed from cationic nanocapsules due to the larger amount of drug adsorbed onto their surface. MCF-7 cell viability studies and cell counting showed that RH-loaded Eudragit(®) RS100 nanocapsules promote the best antiproliferative activity after 24 hours of treatment, whereas the best activity was observed for RH-loaded Eudragit(®) S100 nanocapsules after 72 hours. Furthermore, the combined treatment of these formulations improved the antiproliferative effect during the entire treatment.

An experimental model of contact dermatitis: evaluation of the oxidative profile of Wistar rats treated with free and nanoencapsulated clobetasol.

OBJECTIVE: An experimental animal model of contact dermatitis (CD) was used to investigate the effects of free and nanoencapsulated clobetasol propionate on the skin and on the oxidative profile of liver tissue. METHODS: Female Wistar rats were divided into six groups, each containing eight rats. The first group, control (C), was sensitized with solid vaseline. Group 2, (CD), was sensitized with 5% NiSO(4). Groups 3 and 4 were sensitized with 5% NiSO(4) and treated with free (FC) and nanoencapsulated (NC) clobetasol (0.42 mg/g), respectively, daily for 5 days. Group 5 was treated with nanoencapsulated clobetasol (0.42 mg/g) on days 1, 3, and 5 (C135) and group 6 received a hydrogel containing empty nanoparticles (NP) daily for 5 days. Thiobarbituric acid reactive substances (TBARS), carbonyl levels, non-protein sulfhydryl groups (NPSH) and catalase activity were measured in liver homogenates. RESULTS: A significant increase was observed in the levels of TBARS, NPSH, and catalase activity for the groups CD and NP. DISCUSSION: Our results suggest that both NiSO(4) sensitization and NP administration induced oxidation of cellular lipids and activated the antioxidant enzyme catalase to protect from this damage. These results also indicated that daily treatment with the free and nanoencapsulated clobetasol, as well as treatment with the nanoencapsulated clobetasol every other day, were able to prevent these redox alterations and protect against histological damage.