Browsing by Subject "diffusion"
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(2016)Posterior eye segment diseases, such as age-related macular degeneration, are leading causes of preventable visual impairment in the developed countries. Direct intravitreal injections are currently routinely used to deliver therapeutic agents most efficiently to posterior eye segment. Regular injections can however cause ocular complications and some drugs may also be toxic to ocular tissues at high local concentrations of free drug. Different nano-sized particulate systems have been extensively studied as possible drug delivery systems for intravitreal administration offering sustained, local drug action with controlled release. The vitreous gel can form a barrier for diffusion of particles due to its macromolecular structure and composition. Furthermore, ageing and different disease states cause changes in the vitreous structure possibly resulting in shift in the intravitreal movement of particulate systems. In the literature part of this Master's thesis ocular drug delivery is reviewed with main focus on drug targeting in the posterior eye segment. In the experimental work liposomes with different lipid compositions and surface charges were prepared as model particulate systems to evaluate the intravitreal diffusion of nanoparticles with confocal microscope. Furthermore, the influence of aging on the intravitreal diffusion was modeled by enzymatic degradation of the vitreous gel structure. It is discovered that vitreous gel hinders the movement of nanoparticles. Level of hindrance depends on particle's characteristics. 100-200 nm anionic particles move quite freely in the negatively charged vitreous gel. Similarly sized cationic particles are immobile in the vitreous due to electrostatic interactions between surface of the cationic particle and anionic glycosaminoglycans in the vitreous. 1 µm anionic and cationic particles are sterically trapped inside the vitreous meshwork created by the 3-dimensional biopolymer network of the vitreal macromolecules. Vitreous liquefaction increases the diffusion rate of nanoparticles but the clinical impact on ocular pharmacokinetics needs further research.
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(2016)Nanofibrillar cellulose (NFC) can form hydrogels with high water content (> 98 %). It has been studied for drug release, and it has been used as a cell culture matrix, due to its similar structure to extracellular matrix (ECM). In addition it has been found that they has no cytotoxicity. Iontophoresis is the application of an electric current over a defined area for the purpose of enhancing permeation across a membrane for ionized drug species. The aim in the experimental work in this Master's thesis is twofold. First, to find out the suitable drug loading concentrations into NFC hydrogels, which can provide a good release profile, a release study with two model drugs, propranolol and ketoprofen, loaded into three types of NFC hydrogels at three different concentrations, was carried out for this purpose. Second, to see if NFC hydrogels are applicable as a drug reservoir in iontophoretic transdermal drug delivery applications, an iontophoresis study was carried out using porcine ear skin model in vitro for human skin with propranolol loaded into NFC hydrogel of type A. In addition, Stella models were used as an aid to find suitable ways to predict the release and permeation behaviour of models drugs in the abovementioned context. The UPLC results from the release study show for both model drugs, the wt. % released had linear correlation with squareroot of time. At 6 hours, more than 70 wt. % propranolol was released from hydrogel reservoir. For ketoprofen, the release varied between 30 - 87 wt. %, where higher initial loading concentrations produced a decrease in the wt. % released from hydrogel. The iontophoresis study did not show a significant difference between the tested current densities (0.50 mA/cm2; 0.25 mA/cm2) produced on the wt. % of drug released. Simulation models could be run with the mathematical equations for diffusion controlled drug release. In conclusion, the NFC hydrogels show potential as drug reservoir for drug release. Additional experimental data using other types of drug reservoirs should be obtained for a better understanding of the suitability of NFC hydrogels as a drug reservoir in iontophoretic transdermal drug delivery.
Now showing items 1-2 of 2