Effect of gastrointestinal transit on micro-environmental pH inside HPMC matrix tablets - in vitro study.

A commonly used approach to enhance the dissolution of drugs with pH-dependent solubility is the incorporation of pH modifiers. The aim of this study was to evaluate the duration and extent of pH modifying effect on the micro-environmental pH in HPMC matrix by applying two mechanistic approaches regarding hydrodynamic stress on the tested formulation (i.e. static dissolution apparatuses (USP2) and dynamic approaches including the Advanced gastric simulator (AGS) and the Intestinal model for simulation of peristaltic action (IMSPA)). Moreover, the aim of our research was also the preparation of sustained-release matrix systems with improved - enhanced drug dissolution. In our study, the occurrence of a pH gradient in the gel layer of the HPMC tablets was observed during simulation of their passage along different compartments of the GIT. The pH gradient was affected by the media composition and duration of tablet exposure to the surrounding media. Both dissolution methods were also used to evaluate the influence of the mechanical stress on the drug release kinetics. Micro-environmental pH (pHM) was evaluated, using two methods: the cryostatic method with a surface pH electrode, and with the incorporation of a pH sensitive dye (methyl orange) into the matrix tablets. Our study demonstrates a significantly higher dissolution rate due to mechanical stress during the bio-relevant simulation of GIT transit of the mechanically sensitive HPMC tablets with poorly soluble drugs. A considerably higher release rate was also observed from tablets with the weakly basic drugs dipyridamole and propranolol hydrochloride containing pH modifier in case of mechanically bio-relevant dissolution models compared to the USP2 apparatus. For the assessment of the pHM, the incorporation of a pH indicator dye in the HPMC tablet proved to be more suitable, while the cryostatic method was found to be useful only for a rough pHM estimation.

Polyethylene oxide matrix tablet swelling evolution: The impact of molecular mass and tablet composition.

This article describes the designing of matrix tablets composed of polyethylene oxides (PEOs) with relative molecular masses of 1 × 106, 2 × 106, and 4 × 106. Percolation thresholds were determined for all of the selected PEO formulations (18, 16, and 12 %, m/m), taking into consideration excipients and tablet surface area which significantly increased the percolation threshold. Moreover, the robustness of the gel layer in PEO matrix tablets was evaluated by magnetic resonance imaging under various mechanical stresses (no flow, 12 mL min-1, and 64 mL-1 of medium flow). Correlations between the percolation threshold and gel thickness (R2 = 0.86), gel thickness and the erosion coefficient (R2 = 0.96) was detected. Furthermore, small-angle X-ray scattering of the selected PEOs detected differences in polymer molecular complexity at the nanoscale. Finally, the ratio of the heat of coalescence to the heat of fusion has confirmed the PEO molecular mass-dependent percolation threshold.

Assessment of critical material attributes of polyethylene oxide for formulation of prolonged-release tablets.

Physicochemical evaluation of polyethylene oxide (PEO) polymers with various molecular weights was performed at molecular (polymeric dispersion) and bulk level (powders, polymeric films, and tablets) with the aim of specifying polymer critical material attributes with the main contribution to drug release from prolonged-release tablets (PRTs). For this purpose, grades of PEO with low, medium, and high viscosity were used for formulating PRTs with a good soluble drug substance (dose solubility volume 15 ml). The results revealed a good correlation (r2=0.88) between in vivo data (pharmacokinetic parameters: Cmax and AUC) and the elastic property of PEO films determined with the nanoindentation method, demonstrating that film level can also be used for the in vivo prediction of drug dissolution. The study confirmed that polymer molecular weight and its viscosity are the most important critical material attributes affecting drug dissolution (in vitro) and in vivo bioavailability (e.g. Cmax and AUC). Our research revealed that the nanoindentation technique can distinguish well between various types of polymers, classifying PEO as the most ductile and polyvinyl alcohol as the most brittle. Finally, our study provides an approach for the determination of exact physical attributes of PEO as a critical material attribute from clinically relevant data, and it therefore fulfills the basic principles of product development by Quality by Design.

Lamellar liquid crystals maintain keratinocytes' membrane fluidity: An AFM qualitative and quantitative study.

Despite extensive investigations of lamellar liquid crystals for dermal application, the effects of these systems at the cellular level are still not well elucidated. The key aim of this study was to determine the elasticity and morphological features of keratinocytes after exposure to a lamellar liquid crystal system (LLCS) using atomic force microscopy (AFM) as the method of choice. Prior to AFM assessment, a cell proliferation test and light plus fluorescence imaging were applied to determine the sub-toxic concentration of LLCS. According to the AFM results, slightly altered morphology was observed in the case of fixed keratinocytes, while an intact morphology was visualized on live cells. From the quantitative study, decreased Young's moduli were determined for fixed cells (i.e., 8.6 vs. 15.2 MPa and 1.3 vs. 2.9 MPa for ethanol or PFA-fixed LLCS-treated vs. control cells, respectively) and live cells (i.e., ranging from 0.6 to 2.8 for LLCS-treated vs. 1.1-4.5 MPa for untreated cells), clearly demonstrating increased cell elasticity. This is related to improved membrane fluidity as a consequence of interactions between the acyl chains of cell membrane phosphatidylcholine and those of LLCS. What seems to be of major importance is that the study confirms the potential clinical relevance of such systems in treatment of aged skin with characteristically more rigid epithelial cells.

Elucidating molecular properties of kappa-carrageenan as critical material attributes contributing to drug dissolution from pellets with a multivariate approach.

Multivariate data analysis (MVDA) and artificial neural networks (ANN) are supporting statistical methodologies required for successful development and manufacturing of drug products. To address this purpose, a complex dataset from 49 industrially produced capsules filled with pellets was first analyzed through the development of a multiple linear regression model focused on determining raw material attributes or process parameters with a significant impact on drug dissolution. Based on the model, the following molecular and micrometrics properties of κ-carrageenan have been identified as critical material attributes with the highest contribution to drug dissolution: molecular weight and polydispersity index, viscosity, content of potassium ions, wettability, particle size, and density. The process parameters identified to control the drug dissolution behavior of pellets were amount of granulation liquid, torque of dry blend, spheronization parameters, and yields after screening. To further scrutinize the dataset, an ANN model was subsequently built, incorporating 29 batches addressing drug particle size and process parameters such as torque during granulation and spheronization time as critical factors. Finally, this study demonstrates the ability of MVDA and ANN to allow prediction of the key performance drivers influencing the drug dissolution of industrially developed capsules filled with pellets and it highlights their complementary relationship.

Quantification and modeling of nanomechanical properties of chlorpropamide α, ß, and γ conformational polymorphs.

The nanomechanical properties of the α-, ß-, and γ- conformational polymorphs of chlorpropamide were determined by the dynamic contact module continuous stiffness measurement at nanoindenter. The mechanical anisotropy of the α-polymorph was confirmed by indenting different faces, and its deformational behavior was assigned as ductile. Based on the nanoindentation results, the ß and γ forms are moderately hard with plastic flow at contact points. The results revealed a correlation between Young's modulus and inter-planar interaction energy with regard to crystal orientation. Interpretation of the measurements was assisted by two- and three-dimensional periodic density functional theory (DFT) calculations, yielding inter-planar energies of polymorphs along the cell vectors and exhibiting a very good match with the experimental observations. The results suggest that the inter-planar interaction energy could serve as a first-order indicator for ranking the mechanical propensity of crystalline active ingredients. The study confirms the practical aspect of using the α- form for preparing chlorpropamide tablets with a direct compression procedure due to its substantial level of ductility.

Application of instrumented nanoindentation in preformulation studies of pharmaceutical active ingredients and excipients.

Nanoindentation allows quantitative determination of a material's response to stress such as elastic and plastic deformation or fracture tendency. Key instruments that have enabled great advances in nanomechanical studies are the instrumented nanoindenter and atomic force microscopy. The versatility of these instruments lies in their capability to measure local mechanical response, in very small volumes and depths, while monitoring time, displacement and force with high accuracy and precision. This review highlights the application of nanoindentation for mechanical characterization of pharmaceutical materials in the preformulation phase (primary investigation of crystalline active ingredients and excipients). With nanoindentation, mechanical response can be assessed with respect to crystal structure. The technique is valuable for mechanical screening of a material at an early development phase in order to predict and better control the processes in which a material is exposed to stress such as milling and compression.

Nanomechanical properties of selected single pharmaceutical crystals as a predictor of their bulk behaviour.

PURPOSE: The main goal of this research was to assess the mechanical properties of APIs' polymorphic forms at the single-crystal level (piroxicam, famotidine, nifedipine, olanzapine) in order to predict their bulk deformational attributes, which are critical for some pharmaceutical technology processes. METHODS: The mechanical properties of oriented single crystals were determined using instrumented nanoindentation (continuous stiffness measurement). All polymorphic forms investigated were previously identified using a combination of calorimetric and spectroscopic techniques. RESULTS: Mechanical properties such as Young's modulus and indentation hardness were consistent with the molecular packing of the polymorphic forms investigated with respect to crystal orientation. For mechanically interlocked structures, characteristic of most polymorphic forms, response of single crystals to indentation was isotropic. The material's bulk elastic properties can be successfully predicted by measuring Young's modulus of single crystals because a good linear correlation with a bulk parameter such as the tablets' elastic relaxation index was determined. CONCLUSIONS: The results confirm the idea that the intrinsic mechanical properties of pharmaceutical crystals (Young's modulus) largely control and anticipate their deformational behavior during tablet compression. Young's modulus and indentation hardness represent a very valuable and effective tool in preformulation studies for describing materials' mechanical attributes, which are important for technological processes in which materials are exposed to deformation.

The impact of relative humidity during electrospinning on the morphology and mechanical properties of nanofibers.

Electrospinning is an efficient and flexible method for nanofiber production, but it is influenced by many systemic, process, and environmental parameters that govern the electrospun product morphology. This study systematically investigates the influence of relative humidity (RH) on the electrospinning process. The results showed that the morphology of the electrospun product (shape and diameter) can be manipulated with precise regulation of RH during electrospinning. Because the diameter of nanofibers correlates with their rigidity, it was shown that RH control can lead to manipulation of material mechanical properties. Finally, based on the solution's rheological parameter-namely, phase shift angle-we were able to predict the loss of homogenous nanofiber structure in correlation with RH conditions during electrospinning. This research addresses the mechanism of RH impact on the electrospinning process and offers the background to exploit it in order to better control nanomaterial properties and alter its applicability.

The design trend in tissue-engineering scaffolds based on nanomechanical properties of individual electrospun nanofibers.

This paper especially highlights the finding that the mechanical properties of polymeric nanofibers can be tuned by changing the fiber size as well as the composition. For this purpose, the bending Young's modulus was determined using atomic force microscope by involving single-material (polyvinyl alcohol (PVA), polyethylene oxide (PEO 400K)) and composite nanofibers (polyvinyl alcohol/hyaluronic acid (PVA/HA), polyethylene oxide/chitosan (PEO 400K/CS)). The mechanical property, namely the bending Young's modulus, increases as the diameter of the fibers decreases from the bulk down to the nanometer regime (less than 200 nm). The ranking of increasing stiffness according to the AFM measurements of the three-point beam bending test are in agreement, and can be ranked: PEO 400K

Intracellular trafficking of solid lipid nanoparticles and their distribution between cells through tunneling nanotubes.

The intracellular fate of nanosized drug delivery systems is still not well understood. Various internalization pathways have been discovered, but knowledge of their intracellular trafficking is still incomplete. The aim of this study was to examine the internalization, pathways, and positioning taken by solid lipid nanoparticles (SLNs) in cells. SLNs were fluorescence labeled with a newly synthesized fluorescent probe, 14-DACA. The probe was strongly incorporated into the nanoparticle core under the influence of its long lipophilic chain, enabling superior visualization of SLNs under complex and dynamic intracellular conditions. The intracellular distribution of SLNs was studied qualitatively using a co-localization technique and quantitatively using fluorescence intensity profiles. SLNs were seen inside the cells as distinct bright blue dots that underwent dynamic movement and were finally positioned in the proximity of the nucleus. A few SLNs were shown to be present in mitochondria and between actin filaments, but none in the cell nucleus or lysosomes. SLNs are here reported to be present in tunneling nanotubes (TNTs), which could be a new route of SLN transfer between cells. More TNTs were observed in cells treated with SLNs. The presence of TNTs was additionally confirmed by atomic force microscopy analysis, which indicated that treated cells were more rough than control cells. Detailed investigation of the subcellular localization of SLNs and the evidence for their transfer and distribution via TNTs to the cells, which are not in direct contact with the source of SLNs, are important for understanding the mechanism of targeted drug delivery. Understanding the possible intercellular distribution of SLNs via TNTs can significantly influence approaches to treating organelle-specific diseases.

Circumscribed palmar hypokeratosis -- the first case from south-east Europe.

Circumscribed palmar or plantar hypokeratosis (CPH) is a rare condition, usually asymptomatic, consisting of a well-demarcated erythema with central depression and hyperkeratotic border which divides it from the normal skin. We report a 77-year-old woman with a characteristic lesion of circumscribed palmar hypokeratosis on the right palm. Clinically, the lesion simulated porokeratosis of Mibelli, but histologically there was no cornoid lamella, while the characteristic depression of epidermis, with sharp stair in stratum corneum between the normal and involved skin was present. This is the first case of CPH reported in south-east Europe. After 9-year follow-up and various treatment modalities, we confirmed resistance of CPH. Since malignant transformation has been documented, careful follow-up was recommended.