Extrusion-based systems for topical and transdermal drug delivery.

INTRODUCTION: Although the administration of drugs on the skin is a safe and noninvasive therapeutic alternative, producing formulations capable of disrupting the cutaneous barriers is still a challenge. In this scenario, extrusion-based techniques have emerged as disruptive technologies to ensure unique drug-excipient interactions that facilitate drug skin diffusion for systemic or local effect and even mean the key to obtain viable industrial products. AREAS COVERED: This article presents a comprehensive overview of extrusion-based techniques in developing pharmaceutical dosage forms for topical or transdermal drug delivery. First, the theoretical basis of how extrusion-based techniques can optimize the permeation of drugs through the skin is examined. Then, the current state-of-the-art of drug products developed by extrusion-based techniques, specifically by hot-melt extrusion (HME) and fused deposition modeling (FDM) 3D printing, are discussed and contrasted with the current pharmaceutical processes. EXPERT OPINION: A wide variety of pharmaceutical products can be obtained using HME and FDM 3D printing, including new dosage forms designed for a perfect anatomical fit. Despite the limitations of pharmaceutical products produced with HME and FDM 3D printing regarding thermal stability and available excipients, the advantages in industrial adaptability and improved bioavailability allied with patient-match devices certainly deserve full attention and investment.

Hydroxypropyl-ß-cyclodextrin-complexed naringenin by solvent change precipitation for improving anti-inflammatory effect in vivo.

The flavonoid naringenin (NAR) exhibits an outstanding anti-inflammatory potential; however, stability problems and reduced solubility hinder its commercial insertion. This work aimed to obtain solid-state hydroxypropyl-ß-cyclodextrin (CD) inclusion complexes with NAR using, for the first time, the solvent change precipitation method. For this, molecular modeling and physicochemical characterizations were conducted, followed by in vitro and in vivo assays. The complexation method showed thermal and spectroscopic evidence of NAR inclusion complexes formation, suggesting an improvement of its stability. Additionally, 30 min-dissolution efficiency of the complex was 57.2 %, whereas NAR, as supplied, showed only 14.3 %, a four-fold enhancement. In vitro and in vivo performance attested the potent anti-inflammatory and antinociceptive profile of NAR with significant suppression of TNF-α production. Moreover, NAR complexation with CD improved its therapeutic effect, which showed similar activity to that achieved with NAR as supplied but employing only 1/5 of its dose.

The Influence of Matrix Technology on the Subdivision of Sustained Release Matrix Tablets.

The subdivision of sustained release tablets is a controversial issue, especially concerning its impact on dissolution profiles. The purpose of this study was to elucidate the behavior upon subdivision of this class of tablets. For this, three common sustained release matrices containing different technologies were selected, e.g., a tablet comprised of a multiple-unit particulate system (MUPS), a lipid matrix tablet, and a polymeric inert matrix tablet. These tablets were studied concerning their physicochemical performance, dissolution rate, and kinetic profile before and after their subdivision. When subdivision occurred in the scoreline, mass variation and mass loss were below the mean values described in the literature. The dissolution of tablets with inert matrices and some lipid tablets that had their matrices preserved along the dissolution was influenced directly by tablet surface area, which increased after the subdivision. Such a result implies possible clinical consequences, especially in the case of drugs with a narrow therapeutic window, such as clomipramine. Conversely, the subdivision of MUPS tablets did not interfere in the dissolution profile since the drug was released from the granules that resulted from tablet disintegration. Hence, MUPS technology is the most recommended to produce sustained release matrix tablets intended for dose adjustment upon subdivision.

Lipid nanoparticles as carriers of cyclodextrin inclusion complexes: A promising approach for cutaneous delivery of a volatile essential oil.

Solid inclusion complexes with cyclodextrins (CD) may be used to overcome volatility and solubility problems of essential oils of pharmacological interest. However, they lack the many dermatological advantages of lipid nanoparticles. This study intends to evaluate the ability of nanostructured lipid carriers (NLC) to encapsulate hydroxypropyl-ß-cyclodextrin inclusion complexes of Lippia origanoides essential oil (EO) and to maintain the desirable aspects of lipid colloids interaction with the skin, specifically follicular accumulation and controlled delivery. CD and NLC were also evaluated separately. Thymol (TML) was used as the essential oil marker and to produce control formulations. As expected, CD alone, though effective in overcoming volatility and low aqueous solubility of TML, were ineffective in controlling marker release (˜50% of EO released after 3 h, Hixson-Crowell kinetics). Even though NLC controlled drug release (˜20% EO released after 12 h, zero-order kinetics) enabling TML penetration into the skin (> 40 µg/cm2after 12 h), NLC alone were not efficient in preventing TML volatility, especially at higher temperatures (calculated shelf-life of 2 days at 35 °C). The combined approach resulted in a synergistic effect (˜20% EO released after 12 h; shelf life of 6 days). The lack of statistical difference of TML skin penetration from NLC and NLC-CD suggests the developed system maintained all skin interaction aspects of lipid colloids, including follicular accumulation forming a depot for controlled delivery. In conclusion, lipid nanoparticles demonstrated to be promising carriers for inclusion complexes of this particular volatile essential oil.

Preformulation studies of finasteride to design matrix systems for topical delivery.

A preformulation study with finasteride (FIN) was conducted to enable the development of a topical matrix system to treat androgenic alopecia. The compatibility of the drug with hidroxypropyl-ß-cyclodextrin (HPßCD) and the hydrophilic polymers Klucel EXF (KLU) and Soluplus (SOL) were evaluated according to a simplex centroid mixture design. An extensive analytical arsenal was used to encompass the stability of the drug in the different mixtures. The selected excipients showed to have intense thermal interaction with FIN, which was dependent on the composition of the sample, shifting FIN melting peak to reduced temperatures along with the decrease of its associated enthalpy. The mixture design allowed measuring the interactions between components, showing that KLU enhanced the ability of the drug to form inclusion complexes with HPßCD, while SOL exhibited the opposite effect. The stability of samples was preserved even after a thermal treatment used to simulate pharmaceutical processing. Indeed, no drug content decaying was observed, which corroborates the chemical stability of the systems as indicated by thermogravimetry, chromatographic, morphological and spectroscopic assays. The original crystalline phase of the drug (orthorhombic form I) did not change after the heating treatment of the samples, demonstrating its physical stability. Thus, these series of experiments may guide the development of delivery systems for topical use of FIN, showing which combinations and proportions of components can lead to better results in terms of stability and drug delivery.