Quantitative methods to detect phospholipids at the oil-water interface.

Phospholipids are the main constituents of cell membranes and act as natural stabilizers of milk fat globules. Phospholipids are used in a wide range of applications, e.g. as emulsifiers in cosmetic, pharmaceutical and food products. While processed emulsion droplets are usually stabilized by a monolayer of phospholipids, cell membranes have a phospholipid bilayer structure and milk fat globules are stabilized by a complex phospholipid trilayer membrane. Despite the broad relevance of phospholipids, there are still many scientific challenges in understanding how their behavior at the fluid-fluid interface affects microstructure, stability, and physico-chemical properties of natural and industrial products. Most of these challenges arise from the experimental difficulties related to the investigation of the molecular arrangement of phospholipids in situ at the fluid-fluid interface and the quantification of their partitioning between the bulk phase and the interface, both under static and flow conditions. This task is further complicated by the presence of other surface-active components, such as proteins, that can interact with phospholipids and compete for space at the interface. Here, we review the methodologies available from the literature to detect and quantify phospholipids, focusing on oil-water interfaces, and highlight current limitations and future perspectives.

Swelling-induced structural changes and microparticle uptake of gelatin gels probed by NMR and CLSM.

Gelatin gels are increasingly involved in many industrial applications due to several advantages including cost efficiency and biocompatibility. Generally, their production requires the use of aqueous solvents, which cause significant swelling, due to the ability of solvent molecules to penetrate through the gel microstructure and increase its volume. Since swelling mechanisms and their effect on the gel structure are not fully understood, further investigations are required. In this work, we combine macroscopic measurements of the swelling ratio (SR) with Nuclear Magnetic Resonance (NMR) and Confocal Laser Scanning Microscopy (CLSM) to investigate changes in the gelatin structure as a function of both polymer concentration and swelling time. SR values increase as a function of time until a maximum is reached and then show a slight drop for all the gelatin concentrations after 24 h swelling time, probably due to a network relaxation process. NMR allows determination of mass transport and molecular dynamics of water inside the gelatin pores, while CLSM is used to visualize the penetration of tracers (polystyrene microbeads) with a diameter much larger than the gel pores. Structural parameters, such as average pore size and tortuosity, are estimated. In particular, the pore size decreases for higher polymer concentration and increases during swelling, until reaching a maximum, and then dropping at longer times. The penetration of tracers provides evidence of the heterogeneity of the gel structure and shows that single microcarriers can be loaded in gelatin gels upon swelling.

Transport efficiency in transdermal drug delivery: What is the role of fluid microstructure?

Interaction of microstructured fluids with skin is ubiquitous in everyday life, from the use of cosmetics, lotions, and drugs, to personal care with detergents or soaps. The formulation of microstructured fluids is crucial for the control of the transdermal transport. In biomedical applications transdermal delivery is an efficient approach, alternative to traditional routes like oral and parenteral administration, for local release of drugs. Poor skin permeability, mainly due to its outer layer, which acts as the first barrier against the entry of external compounds, greatly limits the applicability of transdermal delivery. In this review, we focus on recent studies on the improvement of skin transport efficiency by using microemulsions (ME). Quantitative techniques, which are able to investigate both skin morphology and penetration processes, are also reviewed. ME are increasingly used as transdermal systems due to their low preparation cost, stability and high bioavailability. ME may act as penetration enhancers for many active principles, but ME microstructure should be chosen appropriately considering several factors such as ratio and type of ingredients and physic-chemical properties of the active components. ME microstructure is strongly affected by the flow conditions applied during processing, or during spreading and rubbing onto skin. Although the role played by ME microstructure has been generally recognized, the skin transport mechanisms associated with different ME microstructures are still to be elucidated and further investigations are required to fully exploit the potential of ME in transdermal delivery.