Vesa-Pekka Lehto

Drug permeation across intestinal epithelial cells using porous silicon nanoparticles

Mesoporous silicon particles hold great potential in improving the solubility of otherwise poorly soluble drugs. To effectively translate this feature into the clinic, especially via oral or parenteral administration, a thorough understanding of the interactions of the micro- and nanosized material with the physiological environment during the delivery process is required. In the present study, the behaviour of thermally oxidized porous silicon particles of different sizes interacting with Caco-2 cells (both non-differentiated and polarized monolayers) was investigated in order to establish their fate in a model of intestinal epithelial cell barrier. Particle interactions and TNF-α were measured in RAW 264.7 macrophages, while cell viabilities, reactive oxygen species and nitric oxide levels, together with transmission electron microscope images of the polarized monolayers, were assessed with both the Caco-2 cells and RAW 264.7 macrophages. The results showed a concentration and size dependent influence on cell viability and ROS-, NO- and TNF-α levels. There was no evidence of the porous nanoparticles crossing the Caco-2 cell monolayers, yet increased permeation of the loaded poorly soluble drug, griseofulvin, was shown.

Multifunctional porous silicon for therapeutic drug delivery and imaging

Major challenges in drug formulation are the poor solid state stability of drug molecules, poor dissolution/solubility and/or poor pharmacokinetic properties (bioavailability), which may lead to unreliable in vitro-in vivo (IVIV) correlation. To improve current therapeutical strategies, novel means to deliver poorly water soluble active pharmaceutical ingredients, as well as to target them to specific sites or cells in the body are needed. Biomedical applications of porous silicon (PSi) have been actively investigated during the last 10 years, especially in the areas of drug delivery and imaging, due to the biocompatibility and biodegradability of PSi materials, which makes them a potential candidate for controlled drug release. In addition, the unique pore sizes and easily functionalized surface properties of PSi materials allow high drug payloads and controlled kinetics from the drug release formulations. Modification of the PSi surface properties also facilitates biofunctionalization of the surface and the possibility to attach targeting moieties (e.g., antibodies and peptides), thus enabling effective targeting of the payload. In this review, we briefly address the production methodologies of PSi, and we will mainly present and discuss several examples about the biocompatibility of PSi, the most recent in vitro and in vivo applications of PSi as a carrier in drug/protein/peptide delivery and tissue engineering, as well as PSi as a platform for drug targeting and imaging.

Mesoporous materials as controlled drug delivery formulations

In the last twenty years mesoporous materials (e.g., silica, silicon, and to a lesser extent titanium) have been extensively investigated as possible carriers for controlled drug delivery purposes. The great benefits of these materials are their high surface areas and pore volumes with tunable pore sizes and easily functionalized pore surface properties, which allow high drug payloads and from very rapid to slow release kinetics for controlled drug release formulations. The present review focuses on recent research on the exploitation of mesoporous silica and silicon based materials for controlled drug release applications. In particular, fabrication processes of these materials, drug loading and drug release profiles and mechanisms, as well as further functionalization of the porous surface structures of the materials are surveyed. Several examples of drug delivery formulations, together with drug release mechanisms, such as sustained release and stimuli-responsive controlled-release, are also presented herein.

¹⁸F-labeled modified porous silicon particles for investigation of drug delivery carrier distribution in vivo with positron emission tomography.

Because of its biocompatibility and ability to accommodate a variety of payloads from poorly soluble drugs to biomolecules, porous silicon (PSi) is a lucrative material for the development of carriers for particle-mediated drug delivery. We report a successful direct one-step (18)F-radiolabeling of three types of PSi microparticles, thermally hydrocarbonized THCPSi, thermally oxidized TOPSi, and thermally carbonized TCPSi for the investigation of their biodistribution in vivo with positron emission tomography as part of their evaluation as carriers for particle-mediated drug delivery. FTIR and XPS characterization of the PSi materials after carrier-added (18)F/(19)F-radiolabeling reveals that depending on the material the (18)F-labeling is likely to be accomplished either by substitution for surface silyl hydrogen or silyl fluoride or by nucleophilic attack of (18)F(-) to Si-O-Si bridges. With the selected (18)F-radiolabeling method, good to excellent in vitro radiolabel stability in simulated gastric and intestinal fluids and in plasma is achieved for all the particle types studied. Finally, a preliminary evaluation of (18)F-THCPSi microparticle biodistribution in the rat gastrointestinal tract after oral administration is reported, illustrating the utility of using (18)F-radiolabeled PSi as imaging probes for PSi-based drug delivery carrier distribution in vivo.

Nanostructured porous silicon microparticles enable sustained peptide (Melanotan II) delivery

Peptide molecules can improve the treatment of a number of pathological conditions, but due to their physicochemical properties, their delivery is very challenging. The study aim was to determine whether nanostructured porous silicon could sustain the release and prolong the duration of action of a model peptide Melanotan II (MTII). Thermally hydrocarbonized nanoporous silicon (THCPSi) microparticles (38-53 μm) were loaded with MTII. The pore diameter, volume, specific surface area and loading degree of the microparticles were analyzed, and the peptide release was evaluated in vitro. The effects of MTII on heart rate and water consumption were investigated in vivo after subcutaneous administration of the MTII loaded microparticles. A peptide loading degree of 15% w/w was obtained. In vitro studies (PBS, pH 7.4, 37 °C) indicated sustained release of MTII from the THCPSi microparticles. In vivo, MTII loaded THCPSi induced an increase in the heart rate 2 h later than MTII solution, and the effect lasted 1 h longer. In addition, MTII loaded THCPSi changed the water consumption after 150 min, when the immediate effect of MTII solution was already diminished. The present study demonstrates that MTII loading into nanosized PSi pore structure enables sustained delivery of an active peptide.

Physicochemical stability of high indomethacin payload ordered mesoporous silica MCM-41 and SBA-15 microparticles

Stability of high indomethacin (IMC) content formulations based on ordered mesoporous silica MCM-41 and SBA-15 materials was studied before and after a 3 month storage in stressed conditions (30°C/56% RH). Overall, the physical stability of the samples was found satisfactory after the storage. However, some issues with the chemical stability were noted, especially with the MCM-41 based samples. The stability issues were evident from the decreased HPLC loading degrees of the drug after stressing as well as from the observed extra peaks in the HPLC chromatograms of the drug in the stressed samples. Drug release from the mesoporous formulations before stressing was rapid at pH 1.2 in comparison to bulk crystalline IMC. The release profiles also remained similar after stressing. Even faster and close to complete IMC release was achieved when the pH was raised from 1.2 to 6.8. To our knowledge, this is the first report of chemical stability issues of drugs in mesoporous silica drug formulations. The present results encourage further study of the factors affecting the chemical stability of drugs in mesoporous silica MCM-41 and SBA-15 formulations in order to realize their potential in oral drug delivery.

Fast‐dissolving sublingual solid dispersion and cyclodextrin complex increase the absorption of perphenazine in rabbits

Objectivesu2002 The sublingual administration route as well as solid dispersion formation with macrogol 8000 and complexation with β‐cyclodextrin (β‐CyD) were investigated as ways for improving the absorption of perphenazine, a poorly water‐soluble drug subjected to substantial first‐pass metabolism.

In Vitro Dissolution Methods for Hydrophilic and Hydrophobic Porous Silicon Microparticles

Porous silicon (PSi) is an innovative inorganic material that has been recently developed for various drug delivery systems. For example, hydrophilic and hydrophobic PSi microparticles have been utilized to improve the dissolution rate of poorly soluble drugs and to sustain peptide delivery. Previously, the well-plate method has been demonstrated to be a suitable in vitro dissolution method for hydrophilic PSi particles but it was not applicable to poorly wetting hydrophobic thermally hydrocarbonized PSi (THCPSi) particles. In this work, three different in vitro dissolution techniques, namely centrifuge, USP Apparatus 1 (basket) and well-plate methods were compared by using hydrophilic thermally carbonized PSi (TCPSi) microparticles loaded with poorly soluble ibuprofen or freely soluble antipyrine. All the methods showed a fast and complete or nearly complete release of both model compounds from the TCPSi microparticles indicating that all methods described in vitro dissolution equally. Based on these results, the centrifuge method was chosen to study the release of a peptide (ghrelin antagonist) from the THCPSi microparticles since it requires small sample amounts and achieves good particle suspendability. Sustained peptide release from the THCPSi microparticles was observed, which is in agreement with an earlier in vivo study. In conclusion, the centrifuge method was demonstrated to be a suitable tool for the evaluation of drug release from hydrophobic THCPSi particles, and the sustained peptide release from THCPSi microparticles was detected.