Evolution of the microstructure and the drug release upon annealing the drug loaded lipid-surfactant microspheres.

The present study investigates the drug release-governing microstructural properties of melt spray congealed microspheres encapsulating the drug crystals in the matrix of glyceryl behenate and poloxamer (pore former). The solid-state, morphology, and micromeritics of the microspheres were characterized, before and after annealing, using calorimetry, X-ray scattering, porosimetry, scanning electron microscopy, and, NMR diffusometry. The in vitro drug release from and water uptake by the microspheres were obtained. The extent and the rate of drug release from the microspheres increased with a high poloxamer content and at higher annealing temperature and RH. All the drug release profiles were describable using the Higuchi release kinetics pointing towards the diffusion controlled release, both before and after annealing. The annealing process led to the polymorphic conversion of lipid and the increase in the pore size, predominantly at a higher temperature and humidity and for a high poloxamer content. The poloxamer domain increased from an initial 300 nm, up to 2000 nm upon annealing. The water diffusion rate inside the annealed microsphere was twice as fast as for unannealed counterparts. The findings relate the overall phase and pore structure change of the microsphere to the increased drug release induced by annealing. This work serves as a basis for the rational understanding of the modification of the in vitro performance by annealing, a widely used post-process for solid lipid products.

Novel approach for overcoming the stability challenges of lipid-based excipients. Part 1: Screening of solid-state and physical properties of polyglycerol esters of fatty acids as advanced pharmaceutical excipients.

The major challenge of conventional lipid-based excipients (LBE) for drug delivery is their unstable solid state, affecting the stability of pharmaceutical product. Polyglycerol esters of fatty acids (PGFAs) are oligomeric hydroxyethers of glycerol fully or partially esterified with fatty acids. Tuning the number of polyglycerol moieties, fatty acids chain length and free hydroxyl groups per molecule results in diverse physicochemical properties, e.g. HLB, melting point, and wettability, which makes these molecules attractive candidates as novel LBE for different pharmaceutical applications. In this first part of our studies the solid state of PGFAs and the stability thereof were profiled on molecular, nano, and microstructural level and the resulting properties as LBE. DSC analysis confirmed the single phase system of PGFAs without phase separation. WAXS patterns revealed the absence of polymorphism and the direct crystallization into a stable α-form; without transition to more dense configurations. SAXS patterns exposed the lamellar arrangement. The lamellae stacks were characterized by the crystallite thickness and growth. The nano, microstructure and physicochemical properties of PGFAs remained stable during storage. The stable solid state and the broad functionality of PGFAs offer a novel approach to overcome the challenges faced by conventional LBE for advanced pharmaceutical applications. Examples for such applications are presented in the next parts of this study.

Designing optimal formulations for hot-melt coating.

Hot-melt coating (HMC) as a solvent-free technology grants faster and more economic coating processes with reduced risk of dissolving the drug during the process. Moreover, traditional coating equipment can be modified to enable the HMC process. Despite the indubitable advantages and feasibility of the process, HMC is not well-known to pharmaceutical industry and its employment is still limited. The main aspect hindering the widespread application of this technique is the need of materials alternative to the conventional polymeric coatings. The current work reviews the published HMC formulations and describes the properties that have led to their selection. As these materials are mainly solid lipid excipients, attention should be paid to their crystallization and solid state behavior, and their impact on the performance of coated drug products, particularly on the stable drug release profile. Although different drug release profiles can be easily tailored, much development work is needed to respond to the unmet requirements of a stable formulation. Ensuring stable solid-state behavior and providing a mechanistic understanding of the macroscopic properties are essential steps towards fulfilling these requirements and establishing of HMC as advanced coating technology for manufacturing of pharmaceutical products.

Microphase separation in solid lipid dosage forms as the cause of drug release instability.

Although lipid excipients are of increasing interest for development of taste-masked and modified release formulations, the drug release instability and the lack of mechanistic understanding in that regard still prevent their larger-scale application. In this work, we investigated the physical stability of a binary (tripalmitin/polysorbate 65) lipid coating formulation with a known stable polymorphism. The coating composition was characterized using DSC to construct the phase diagram of binary system and polarized light microscopy to display the microstructure organization. The water uptake and the erosion of slabs cast from the coating formulations were investigated post-production and after storage. Subsequently, N-acetylcysteine particles were coated with the selected formulations and the drug release stability was investigated. Additionally, microstructure characterization was performed via SEM and X-ray diffraction. The drug release instability was explained by polysorbate 65 and tripalmitin phase growth during storage, especially at 40°C, suggesting that polysorbate 65 can leak out of tripalmitin spherulitic structures, creating lipophilic and impermeable tripalmitin regions. The growth of polysorbate 65 phase leads to larger hydrophilic channels with reduced tortuosity. This work indicates that for obtaining stable drug release profiles from advanced lipid formulations, microphase separation should be prevented during storage.

Improving the granule strength of roller-compacted ibuprofen sodium for hot-melt coating processing.

Solvent-free hot-melt coating processing is a novel and cost-efficient approach to manufacturing taste-masked multiparticulate systems. However, most API powders are fine and cohesive and not processable by hot-melt coating. The aim of this study was to produce dense and abrasion-resistant granules with high drug content (>80%) via roller compaction for hot-melt coating process optimization. The selected API was ibuprofen sodium dihydrate, a salt of ibuprofen with improved bioavailability and poor intrinsic compactibility. The formulation and roller compaction process were developed for the production of granules with 94%w/w of API and low friability (∼30%), using sorbitol and isomalt as excipients. The strong bonding mechanism relied on powder jamming prior to the rollers and was investigated via scanning electron microscopy, differential scanning calorimetry and small and wide angle X-ray scattering. It was shown that sorbitol crystals are solubilized during roller compaction and recrystallize as sorbitol hydrate, acting as strong solid bridges. The robustness of the roller compaction process and the re-compaction of fines were investigated. A statistical design of experiments was conducted to evaluate the hot-melt coating process for taste masking of ibuprofen sodium granules. Taste masking required coating ratios higher than 40%w/w of granule batch, emphasizing the need for high-drug-content and abrasion-resistant granules.