Sara Raposo

Development, characterization, and skin delivery studies of related ultradeformable vesicles: transfersomes, ethosomes, and transethosomes

Ultradeformable vesicles (UDV) have recently become a promising tool for the development of improved and innovative dermal and transdermal therapies. The aim of this work was to study three related UDV: transfersomes, ethosomes, and transethosomes for the incorporation of actives of distinct polarities, namely, vitamin E and caffeine, and to evaluate the effect of the carrier on skin permeation and penetration. These actives were incorporated in UDV formulations further characterized for vesicles imaging by transmission electron microscopy; mean vesicle size and polydispersity index by photon correlation spectroscopy; zeta potential by laser-Doppler anemometry; deformability by pressure-driven transport; and incorporation efficiency (IE) after actives quantification by high-performance liquid chromatography. Topical delivery studies were performed in order to compare UDV formulations regarding the release, skin permeation, and penetration profiles. All UDV formulations showed size values within the expected range, except transethosomes prepared by “transfersomal method”, for which size was smaller than 100 nm in contrast to that obtained for vesicles prepared by “ethosomal method”. Zeta potential was negative and higher for formulations containing sodium cholate. The IE was much higher for vitamin E- than caffeine-loaded UDV as expected. For flux measurements, the following order was obtained: transethosomes (TE) > ethosomes (E) ≥ transfersomes (T). This result was consistent with the release and skin penetration profiles for Vitamin E-loaded UDV. However, the releasing results were totally the opposite for caffeine-loaded UDV, which might be explained by the solubility and thermodynamic activity of this active in each formulation instead of the UDV deformability attending to the higher non-incorporated fraction of caffeine. Anyway, a high skin penetration and permeation for all caffeine-loaded UDV were obtained. Transethosomes were more deformable than ethosomes and transfersomes due to the presence of both ethanol and surfactant in their composition. All these UDV were suitable for a deeper skin penetration, especially transethosomes.

Advanced systems for glucocorticoids' dermal delivery

Introduction: Although the skin provides a natural physical barrier against particle penetration, there are opportunities to deliver therapeutic agents through this barrier. With rapid developments in materials science, pharmaceutics, and biotechnology, new systems have emerged for topical glucocorticoids (TG) delivery. Despite being a mature class of drugs, TG are still the most frequently prescribed drugs by dermatologists, explaining the interest on this field. Areas covered: Over the years, research has focused on strategies to optimize the potency of steroids while minimizing adverse effects. Several attempts have been made to increase the safety of TG treatment, including new application schedules, special vehicles, and new synthesized agents. This paper gives an overview on the conventional and advanced vehicles used to deliver TG, including strategies to improve the delivery and accumulation of TG. The therapeutic advantages of TG delivery to the epidermis are discussed with a special focus on new drug-delivery systems for topical application. Expert opinion: New technologies have been developed for TG delivery, and studies are currently underway in order to obtain improved benefit/risk ratio. A rationale development approach that integrates simple formulations would help to develop vehicles with these features.

Safety assessment and biological effects of a new cold processed SilEmulsion for dermatological purpose.

It is of crucial importance to evaluate the safety profile of the ingredients used in dermatological emulsions. A suitable equilibrium between safety and efficacy is a pivotal concern before the marketing of a dermatological product. The aim was to assess the safety and biological effects of a new cold processed silicone-based emulsion (SilEmulsion). The hazard, exposure, and dose-response assessment were used to characterize the risk for each ingredient. EpiSkin assay and human repeat insult patch tests were performed to compare the theoretical safety assessment to in vitro and in vivo data. The efficacy of the SilEmulsion was studied using biophysical measurements in human volunteers during 21 days. According to the safety assessment of the ingredients, 1,5-pentanediol was an ingredient of special concern since its margin of safety was below the threshold of 100 (36.53). EpiSkin assay showed that the tissue viability after the application of the SilEmulsion was 92 ± 6% and, thus considered nonirritant to the skin. The human studies confirmed that the SilEmulsion was not a skin irritant and did not induce any sensitization on the volunteers, being safe for human use. Moreover, biological effects demonstrated that the SilEmulsion increased both the skin hydration and skin surface lipids.

Prevention of Photocarcinogenesis by Agonists of 5-HT1A and Antagonists of 5-HT2A Receptors

AbstractExposure to UV radiation is the principal cause of nonmelanoma skin cancer, a process in which serotonin (5-HT) is intimately involved. This review focuses on the potential of serotonin receptors, namely 5-HT1/2A, as therapeutic targets for prevention of photocarcinogenesis. UV-induced immunosuppression is triggered by a cascade of events initiated when cis-urocanic acid, a UV photoreceptor present in the skin, binds to the serotonin receptor. Serotonin receptor antagonists will therefore attempt to block this association, and in turn, prevent skin cancer induction. In addition, 5-HT2A receptor antagonists are also capable of regulating DNA repair, including the acceleration of nucleotide excision repair. At the same time, UV-induced formation of reactive oxygen species is also reduced by these agents. Since the involvement of serotonin in photocarcinogenesis process is somewhat underexplored as a pertinent therapeutic effect, this review intends to reveal the use of serotonergic drugs as an important strategy to prevent and/or inhibit photocarcinogenesis. Considering the emergency of developing novel therapeutic strategies for skin cancer management, the use of these agents, whose benefits have partially been studied, may be crucial especially if topically applied. Topical nanoformulations containing serotonin receptor agonists and/or antagonists also represent a pioneer concept in this area. Graphical Abstractᅟ

Mometasone furoate-loaded cold processed oil-in-water emulsions: in vitro and in vivo studies

Abstract Over the years, research has focused on strategies to increase benefit/risk ratio of corticoids. However, vehicles intended for topical glucocorticoids delivery with an improved benefit/risk ratio are still on demand. The aim of this work was the in vitro and in vivo characterization of cold processed oil-in-water (o/w) emulsions intended for mometasone furoate (MF) delivery to induce drug targeting to upper skin strata, decreasing adverse effects. Two o/w emulsions, containing 0.1% of MF, were developed differing in the glycol used (2-methyl-2,4-pentanediol – PT and ethoxydiglycol – TC emulsions). In vitro permeation studies revealed that these emulsions are suitable vehicles for the delivery of MF containing ingredients which are responsible for a drastically increased on the permeability coefficients of MF from a theoretical value of 1.18 × 10−4 cm/h to 5.20 × 10−4 ± 2.05 × 10−4 cm/h and 6.30 × 10−4 ± 2.94 × 10−4 cm/h, for PT and TC, respectively. The tape stripping results showed that the amount of drug that reached the viable skin layers was very low (1.99 %) and the amount that remained in the stratum corneum (SC) was 10.61%. The in vivo studies showed that the developed formulations decreased the edema and erythema in mice skin in more that 90%, assuring, at least, the same anti-inflammatory effect compared with the commercial cream. PT placebo demonstrated to contribute to restore the skin barrier by increasing the amount of lipids within the human skin.

Mometasone furoate hydrogel for scalp use: in vitro and in vivo evaluation

Abstract Dermatological inflammatory diseases often affect the scalp and the eyebrows. Common dosage forms available on the market for those situations are lotions; however, the presence of hair limits their use. Gels, for their consistency and adhesiveness, are a suitable alternative to the lotions in these situations. The aim of this study was to develop a new stable gel containing mometasone furoate (MF), with anti-inflammatory activity and a controlled delivery, to improve topical treatment of scalp dermatitis. Pharmaceutical development, physical and chemical characterization, stability, in vitro release and permeation studies and in vivo anti-inflammatory activity were performed. The gel presented an acidic pH and an apparent viscosity of 35 Pa.s. The microbiological analysis showed that the results were within the established specification limits. The release and the permeation profiles suggest that the drug is mainly retained in the upper skin layers. MF gel was tested in an animal model of cutaneous inflammation and presented similar anti-inflammatory activity compared to a commercially available MF dosage form. The gel was chemically, physically and microbiologically stable. The results suggest that the developed hydrogel formulation containing MF can be of actual value for improving the clinical effectiveness in the treatment of scalp dermatitis.

Useful In Vitro Techniques to Evaluate the Mucoadhesive Properties of Hyaluronic Acid-Based Ocular Delivery Systems

Polymer-based eye drops are the most used drug delivery system to treat dry eye disease (DED). Therefore, the mucoadhesion between the polymer and the ocular mucin is crucial to ensure the efficacy of the treatment. In this context, the present study aimed to evaluate the potential use of in vitro methods to study the mucoadhesion of eye drop solutions and, specifically to evaluate the efficacy of two hyaluronic acid-based formulations (HA), HA 0.15% and 0.30% (w/v) to treat DED. Rheology methods and zeta potential determination were used to study the mucoadhesive properties of both eye drop solutions. All results indicated that interactions occurred between the mucin and the HA, being stronger with HA 0.30%, due to the physical entanglements and hydrogen bounding. In vitro tests on ARPE-19 cell line were performed using a 2D and a 3D dry eye model and the results have shown that pre-treated cells with HA showed a morphology more similar to the hydrated cells in both products, with a high survival rate. The in vitro techniques used in this study have been shown to be suitable to evaluate and predict mucoadhesive properties and the efficacy of the eye drops on relief or treatment of DED. The results obtained from these methods may help in inferring possible in vivo effects.