Silvia Franzé

An insight into the skin penetration enhancement mechanism of N-methylpyrrolidone.

This work aims to elucidate the mechanism by which N-methylpyrrolidone (NMP) enhances the skin permeation of a compound by combining experimental data with molecular dynamic (MD) simulations. The addition of 10% NMP significantly increased the propranolol (PR) permeation through the human epidermis (∼ 15 μg/cm(2) vs ∼ 30 μg/cm(2)) while resulting inefficacious on hydrocortisone (HC) diffusion. No significant alterations in the stratum corneum structure were found after the in vitro treatment of human epidermis with NMP dispersed in mineral oil or water by attenuated total reflectance Fourier transform infrared (ATR-FTIR) analyses. MD simulations revealed the formation of a complex by H-bonds and the π-π stacking interactions between the NMPs amido group and the drugs aromatic systems. The size of the depicted NMP/PR clusters was in line with the hydrodynamic radius derived by dynamic light scattering analyses (∼ 2.00 nm). Conversely, no interaction, and consequently cluster formation, between NMP and HC occurred. These results suggest that NMP is effective in enhancing the drug permeation through human epidermis by a cotransport mechanism when NMP/drug interaction occurs.

Regenerated keratin membrane to match the in vitro drug diffusion through human epidermis

This work aimed to develop membranes made of regenerated keratin and ceramides (CERs) to match the barrier property of the human stratum corneum in in vitro percutaneous absorption studies. The membrane composition was optimized on the basis of the in vitro drug diffusion profiles of ibuprofen, propranolol and testosterone chosen as model drugs on the basis of their different diffusion and solubility properties. The data were compared to those obtained using human epidermis. The ATR-FTIR and SEM analyses revealed that CERs were suspended into the regenerated keratin matrix, even if a partial solubilization occurred. It resulted in the membranes being physically stable after exposure to aqueous buffer and/or mineral oil and the fluxes of ibuprofen and propranolol from these vehicles through membranes and human skin were of the same order of magnitude. The best relationship with human epidermis data was obtained with 180 μm-thick membrane containing 1% ceramide III and 1% ceramide VI. The data on the testosterone diffusion were affected by the exposure of the membrane to a water/ethanol solution over a prolonged period of time, indicating that such an organic solvent was able to modify the supermolecular organization of keratin and CERs. The keratin/CER membranes can represent a simplified model to assay the in vitro skin permeability study of small molecules.

Low molecular weight heparins copies: are they considered to be generics or biosimilars?

The protection rights of low molecular weight heparins (LMWHs) are expired or are expiring, so the extent and nature of the studies required to obtain a market authorization for LMWH copies represents a hot topic. FDA classifies LMWHs as semisynthetic drugs and their copies as generics whereas the EMA views them as biological medicines and consequently their copies as biosimilars. Consequently, FDA requires only in vivo pharmacodynamic studies, while EMA requires also clinical trials. The current work reviews the chemical composition and therapeutic indications of LMWHs available in the EU and USA markets to discuss the two different approaches. Because LMWHs show a high intrinsic variability and a complete characterization is not viable, a conservative approach is desirable.

Formulation and in vitro efficacy of liposomes containing the Hsp90 inhibitor 6BrCaQ in prostate cancer cells

6BrCaQ is a promising anti-cancer agent derived from novobiocin, which has been shown to inhibit Hsp90. 6BrCaQ was loaded into nanometer-scaled phospholipid vesicles (liposomes) suitable for drug delivery to solid tumors. The effective incorporation of the drug within the phospholipid bilayer was investigated by differential scanning calorimetry. Liposomal 6BrCaQ showed good activity on PC-3 cell lines in vitro in terms of apoptosis induction and cell growth arrest in G2/M. Liposomes containing 6BrCaQ were also shown to slow down migration of PC-3 cells in presence of chemokine ligand 2 and to synergize with doxorubicin. Several Hsp90 targeting molecules like geldanamycin induce accumulation of Hsp70, leading to cytoprotection and often correlated with poor prognosis. In this study, we did not report any Hsp70 induction after treatment with liposomal 6BrCaQ but a decrease in Hsp90 and CDK-4 protein expression, indicating an effect on the chaperon machinery. Liposomal encapsulation of 6BrCaQ revealed promising anti-cancer effects and a better understanding of its mechanism of action.

Influence of chemical and structural features of low molecular weight heparins (LMWHs) on skin penetration

Low molecular weight heparins (LMWHs) are obtained from unfractionated heparin (UFH) through different depolymerization methods (DM), which produce compounds having specific chemical features and biological activity. It is then supposed that LMWHs also exhibit different skin permeability properties. The current work aimed to get an insight on the in vitro passive diffusion through human epidermis of six commercially available LMWHs in comparison with UFH. The in vitro studies were performed using Franz diffusion cells. Heparins samples were assayed measuring the anti-factor Xa activity. Circular dichroism was used to evaluate the effect of the counter-ion (sodium or calcium) on the chain flexibility. The penetrated amounts after 24h (Q24) of sodium LMWHs were related to Mw by an exponential relationship (R=-0.758). The flux resulted dependent by DM following the rank order: β-elimination (8-11 mIU/cm(2)h range)>deaminative cleavage (5-7 mIU/cm(2)h range)>radical depolymerization (0.1mIU/cm(2)h). Finally, the calcium ion, reducing the chain flexibility, significantly affected the Q24 (0.001 ± 0.000 and 0.157 ± 0.049 IU/cm(2) for calcium and sodium nadroparin, respectively). Both the lower Mw and the introduction of new residues at the chain ends improved the skin penetration of LMWHs with respect to UFH (Q24=0.001 ± 0.001 IU/cm(2)), with bemiparin and enoxaparin being the most interesting compounds.

Nanocarriers to Enhance the Accumulation of Vitamin K1 into the Skin.

ABSTRACTPurposeVitamin K1 (VK1) is a molecule abundant in some species of leaf vegetables with beneficial effects in humans following administration on the skin. This work investigates the possibility to use formulations based on lipid vesicles, namely liposomes, transfersomes and ethosomes, suitable to be administered on the skin by nebulization and alternative to fat semisolid preparations present on the market.MethodsLipid vesicles encapsulating VK1 were prepared and characterized. Ex-vivo experiments on Franz cells were carried out to study the VK1 accumulation/permeation in/through the skin. Vesicles interaction with the skin was investigated by confocal laser scanning microscopy (CLSM) and attenuated total reflection Fourier transform infrared (ATR-FTIR) spectroscopy.ResultsAll developed carriers were stable following long-term storage and were not altered following nebulization. In ex-vivo experiments, vesicles with the highest deformability index, namely transfersomes and ethosomes, led to an enhanced VK1 accumulation/permeation into/through the skin. Interestingly, the nebulization of the vesicles led to a further increase of VK1 accumulation into the skin.ConclusionsIn conclusion, to achieve a local effect of VK1 on the skin, the topical nebulization of VK1-containing transfersomes could offer a good compromise between a high VK1 penetration into the skin and a limited permeation through it.

The role of the conformational profile of polysaccharides on skin penetration: the case of hyaluronan and its sulfates.

The literature data suggest the capacity of biomacromolecules to permeate the human skin, even though such a transdermal permeation appears to be governed by physicochemical parameters which are significantly different compared to those ruling the skin permeation of small molecules. On these grounds, the present study was undertaken to investigate the in vitro diffusion properties through the human epidermis of hyaluronic acid and their sulfates. Low‐ and medium‐molecular‐weight hyaluronic acids and the corresponding derivatives at two degrees of sulfation were then tested. In vitro studies evidenced that the sulfated polymers permeate better than the corresponding hyaluronic acid, despite their vastly greater polarity, while the observed permeation markedly decreases when increasing the polymers molecular weight regardless of the sulfation degree. Using a fluorescent‐labeled polysaccharide, it was also evidenced that hyaluronans have a great affinity for corneocytes and likely cross the stratum corneum mainly through a transcellular route. The molecular‐dynamics study revealed how the observed permeations for the investigated polysaccharides can be rationalized by monitoring their conformational profiles, since the permeation was found to be directly related to their capacity to assume extended and flexible conformations.

Orodispersible dosage forms: biopharmaceutical improvements and regulatory requirements

Orodispersible dosage forms have a growing presence in the pharmaceutical market because their administration can improve the bioavailability of some drugs and their prescription can ameliorate patient adherence and/or compliance. Here, we review the main features of orodispersible tablets, including oral lyophilisates, and orodispersible films along with their main production technologies. We summarize the bioavailability data and critically discussed their potential to improve patient adherence and/or compliance. We revisit this information in light of both the European Union (EU) and US regulatory frameworks, focusing on the differences in the definitions of such dosage forms and the requirements for marketing authorization.

Innovation in Phytotherapy: Is a New Regulation the Feasible Perspective in Europe?

Classical multicomponent preparations mostly derived from traditional usages in Western and Eastern phytotherapy have been under-evaluated for a long time as potential new pharmaceutical products. The regulatory scenario, in particular at the European level, has only recently considered these aspects proposing harmonized guidelines for the pharmaceutical registration of traditional herbal products. Nevertheless, a specific regulation for innovative products based on the combination of precious knowledge arising from traditional usages and modern scientific advancements is still missing. In this paper, we propose a critical review of the current situation with the specific aim of contributing to create a more favorable regulatory environment for the pharmaceutical registration of new and innovative herbal medicinal products.

Caffeic Acid-PLGA Conjugate to Design Protein Drug Delivery Systems Stable to Irradiation

This work reports the feasibility of caffeic acid grafted PLGA (g-CA-PLGA) to design biodegradable sterile microspheres for the delivery of proteins. Ovalbumin (OVA) was selected as model compound because of its sensitiveness of γ-radiation. The adopted grafting procedure allowed us to obtain a material with good free radical scavenging properties, without a significant modification of Mw and Tg of the starting PLGA (Mw PLGA = 26.3 ± 1.3 kDa vs. Mw g-CA-PLGA = 22.8 ± 0.7 kDa; Tg PLGA = 47.7 ± 0.8 °C vs. Tg g-CA-PLGA = 47.4 ± 0.2 °C). By using a W1/O/W2 technique, g-CA-PLGA improved the encapsulation efficiency (EE), suggesting that the presence of caffeic residues improved the compatibility between components (EEPLGA = 35.0% ± 0.7% vs. EEg-CA-PLGA = 95.6% ± 2.7%). Microspheres particle size distribution ranged from 15 to 50 µm. The zeta-potential values of placebo and loaded microspheres were −25 mV and −15 mV, respectively. The irradiation of g-CA-PLGA at the dose of 25 kGy caused a less than 1% variation of Mw and the degradation patterns of the non-irradiated and irradiated microspheres were superimposable. The OVA content in g-CA-PLGA microspheres decreased to a lower extent with respect to PLGA microspheres. These results suggest that g-CA-PLGA is a promising biodegradable material to microencapsulate biological drugs.