Global ETD Search

31	Development of Novel hydrogels for protein drug delivery Mawad, Damia, Graduate School of Biomedical Engineering, Faculty of Engineering, UNSW January 2005 (has links) Introduction: Embolic agents are used to block blood flow of hypervascular tumours, ultimately resulting in target tissue necrosis. However, this therapy is limited by the formation of new blood vessels within the tumour, a process known as angiogenesis. Targeting angiogenesis led to the discovery of anti-angiogenic factors, large molecular weight proteins that can block the angiogenic process. The aim of this research is development of poly (vinyl alcohol) (PVA) aqueous solutions that cross-link in situ to form a hydrogel that functions as an embolic agent for delivery of macromolecular drugs. Methods: PVA (14 kDa, 83% hydrolysed), functionalised by 7 acrylamide groups per chain, was used to prepare 10, 15, and 20wt% non-degradable hydrogels, cured by UV or redox initiation. Structural properties were characterised and the release of FITCDextran (20kDa) was quantified. Degradable networks were then prepared by attaching to PVA (83% and 98 % hydrolysed) ester linkages with an acrylate end group. The effect on degradation profiles was assessed by varying parameters such as macromer concentration, cross-linking density, polymer backbone and curing method. To further enhance the technology, radiopaque degradable PVA was synthesised, and degradation profiles were determined. Cell growth inhibition of modified PVA and degradable products were also investigated. Results: Redox initiation resulted in non-degradable PVA networks of well-controlled structural properties. Increasing the solid content from 10 to 20wt% prolonged the release time from few hours to ~ 2 days but had no effect on the percent release, with only a maximum release of 65% achieved. Ester attachment to the PVA allowed flexibility in designing networks of variable swelling behaviors and degradation times allowing ease of tailoring for specific clinical requirements. Synthesis of radiopaque degradable PVA hydrogels was successful without affecting the polymer solubility in water or its ability to polymerize by redox. This suggested that this novel hydrogel is a potential liquid embolic with enhanced X-ray visibility. Degradable products had negligible cytotoxicity. Conclusion: Novel non-degradable and radiopaque degradable PVA hydrogels cured by redox initiation were developed in this research. The developed PVA hydrogels showed characteristics in vitro that are desirable for the in vivo application as release systems for anti-angiogenic factors. Drug delivery systems Drug targeting Polymers in medicine Drugs - Controlled release Polymeric drug delivery systems
32	Development of Novel hydrogels for protein drug delivery Mawad, Damia, Graduate School of Biomedical Engineering, Faculty of Engineering, UNSW January 2005 (has links) Introduction: Embolic agents are used to block blood flow of hypervascular tumours, ultimately resulting in target tissue necrosis. However, this therapy is limited by the formation of new blood vessels within the tumour, a process known as angiogenesis. Targeting angiogenesis led to the discovery of anti-angiogenic factors, large molecular weight proteins that can block the angiogenic process. The aim of this research is development of poly (vinyl alcohol) (PVA) aqueous solutions that cross-link in situ to form a hydrogel that functions as an embolic agent for delivery of macromolecular drugs. Methods: PVA (14 kDa, 83% hydrolysed), functionalised by 7 acrylamide groups per chain, was used to prepare 10, 15, and 20wt% non-degradable hydrogels, cured by UV or redox initiation. Structural properties were characterised and the release of FITCDextran (20kDa) was quantified. Degradable networks were then prepared by attaching to PVA (83% and 98 % hydrolysed) ester linkages with an acrylate end group. The effect on degradation profiles was assessed by varying parameters such as macromer concentration, cross-linking density, polymer backbone and curing method. To further enhance the technology, radiopaque degradable PVA was synthesised, and degradation profiles were determined. Cell growth inhibition of modified PVA and degradable products were also investigated. Results: Redox initiation resulted in non-degradable PVA networks of well-controlled structural properties. Increasing the solid content from 10 to 20wt% prolonged the release time from few hours to ~ 2 days but had no effect on the percent release, with only a maximum release of 65% achieved. Ester attachment to the PVA allowed flexibility in designing networks of variable swelling behaviors and degradation times allowing ease of tailoring for specific clinical requirements. Synthesis of radiopaque degradable PVA hydrogels was successful without affecting the polymer solubility in water or its ability to polymerize by redox. This suggested that this novel hydrogel is a potential liquid embolic with enhanced X-ray visibility. Degradable products had negligible cytotoxicity. Conclusion: Novel non-degradable and radiopaque degradable PVA hydrogels cured by redox initiation were developed in this research. The developed PVA hydrogels showed characteristics in vitro that are desirable for the in vivo application as release systems for anti-angiogenic factors. Drug delivery systems Drug targeting Polymers in medicine Drugs - Controlled release Polymeric drug delivery systems
33	Magnetically targeted deposition and retention of particles in the airways for drug delivery Ally, Javed Maqsud. January 2010 (has links) Thesis (Ph. D.)--University of Alberta, 2010. / Title from pdf file main screen (viewed on July 17, 2010). A thesis submitted to the Faculty of Graduate Studies and Research in partial fulfillment of the requirements for the degree of Doctor of Philosophy, [Department of] Mechanical Engineering, University of Alberta. Includes bibliographical references.
34	Efeito da combinação de sinvastatina com paclitaxel veiculado por nanoemulsão lipídica na aterosclerose induzida em coelhos / Effect of a combination of simvastatin and paclitaxel carried by a lipid nanoemulsion on induced atherosclerosis in rabbits. Tatiana Solano Vitório 21 February 2014 (has links) Em estudos prévios, mostramos que uma nanoemulsão lipídica (LDE) é reconhecida e se liga aos receptores de LDL após sua injeção na corrente sanguínea. Como tais receptores estão superexpressos em células com altas taxas de proliferação, como ocorre no câncer e na aterosclerose, a LDE pode ser utilizada como veículo para direcionar fármacos a essas células, diminuindo sua toxicidade e aumentando sua eficácia terapêutica. Anteriormente, reportamos que o tratamento com um derivado do paclitaxel, o oleato de paclitaxel, associado à LDE (PTX-LDE), reduziu em 60% a área lesionada de aortas de coelhos submetidos à dieta aterogênica, comparados a animais não tratados. No presente trabalho, avaliamos o efeito da associação de sinvastatina, medicamento hipolipemiante, e PTX-LDE, sobre a aterosclerose induzida por dieta em coelhos. Trinta e seis coelhos machos da raça Nova Zelândia foram submetidos à dieta enriquecida com 1% de colesterol durante oito semanas. A partir da quinta semana, os animais foram divididos em quatro grupos, de acordo com o tratamento: controle (solução salina EV), sinvastatina (2mg/kg/dia, VO), paclitaxel (PTX-LDE, 4mg/Kg/semana, EV), ou combinação de sinvastatina (2mg/Kg/dia, VO) com paclitaxel (PTX-LDE, 4mg/Kg/semana, EV). Após oito semanas, os animais foram sacrificados para análise das aortas. Em comparação aos controles, a área lesionada das aortas foi em torno de 60% menor, tanto no grupo paclitaxel, quanto no grupo da combinação, e em torno de 40% menor no grupo sinvastatina (p<0,05). A razão entre as camadas íntima/média foi menor nos grupos tratados, em relação ao grupo controle (controles, 0,35±0,22, sinvastatina, 0,10±0,07, paclitaxel, 0,06±0,16 e combinação, 0,09±0,05, p<0,0001). Os grupos combinação e sinvastatina apresentaram um aumento da porcentagem de colágeno nas lesões (combinação, 20% e sinvastatina, 22%), em comparação aos controles (11%) e ao grupo paclitaxel (12%), (p<0,0001). Houve uma diminuição da porcentagem de macrófagos na lesão em todos os grupos tratados (paclitaxel, 11%, sinvastatina, 8% e combinação, 5%), comparados ao grupo controle (30%), (p<0,0001). O grupo paclitaxel apresentou menor porcentagem de células musculares lisas na lesão (20%) em relação aos controles (33%), (p<0,0001), já na combinação, houve aumento dessa porcentagem (44%), (p<0,0001). A combinação com sinvastatina não aumentou a eficácia do tratamento com PTX-LDE na redução da área de lesões ateroscleróticas, porém, os efeitos adicionais sobre o perfil lipídico e na composição das lesões, observadas com o uso da combinação, são achados importantes, que sugerem benefícios no sentido de aumentar a estabilidade das placas ateroscleróticas, o que nos abre um caminho de pesquisa muito promissor. / In previous studies we have shown that a lipid nanoemulsion (LDE) is recognized and binds to LDL receptors after injection into the bloodstream. As those receptors are upregulated in cells with higher proliferation rates, as occurs in cancer and atherosclerosis, LDE can be used as a vehicle to direct drugs to those cells, diminishing toxicity and increasing therapeutic efficacy. Previously, we reported that treatment with antiproliferative agent paclitaxel derivative, paclitaxel oleate, associated with LDE (PTX-LDE), reduced by 60% the injured area of the aorta of rabbits subjected to atherogenic diet compared to untreated animals. In the current study we aim to test the effect of a combination of lipid-lowering drug simvastatin with PTX-LDE on diet-induced atherosclerosis in rabbits. Thirty-six male New Zealand rabbits were fed a 1% cholesterol diet for 8 weeks. Starting from week 5, animals were divided into four groups, according to the following treatments: controls (I.V. saline solution injections), simvastatin P.O. (2mg/kg/day), paclitaxel (PTX-LDE I.V. injections, 4mg/Kg/week), or paclitaxel-simvastatin combination (PTX-LDE I.V., 4mg/Kg/week + simvastatin P.O., 2mg/Kg/day). After 8 weeks, the animals were sacrificed for aorta evaluation. Compared to controls, the injured area was reduced by 60% in both paclitaxel and combination groups, and by 40% in simvastatin group (p<0,05). The intima/media ratio was reduced in treated groups, compared to control group (controls, 0,35±0,22, simvastatin, 0,10±0,07, paclitaxel, 0,06±0,16 and combination, 0,09±0,05, p<0,0001). Simvastatin and combination groups showed increased collagen content within the lesions (simvastatin, 22% and combination 20%), compared to controls (11%) and to paclitaxel group (12%), (p <0.0001). Macrophage content within the lesions was reduced in all treated groups (paclitaxel, 11%, simvastatin, 8% e combination, 5%), compared to controls (30%), (p <0.0001). The percentage of smooth muscle cells in the lesions was diminished in paclitaxel group (20%) compared to control group (33%), while the combination group showed increased percentage (44%) of smooth muscle cells in the lesions (p<0,0001). The combination of simvastatin did not improve the efficacy of the treatment with PTXLDE in reducing the area of atherosclerotic lesions, but the additional effects on lipid profile and lesion composition observed with the use of the combination are important findings that suggest benefits in order to enhance the stability of atherosclerotic plaques, which may lead us to a very promising research path. Aterosclerose Nanoemulsão lipídica Paclitaxel Sinvastatina Veiculação farmacológica Atherosclerosis Drug-targeting Lipid nanoemulsion Paclitaxel Simvastatin
35	Development of a targeted liposomal delivery system for encapsulated cantharidin to treat hepatocellular carcinoma Zhang, Xue 31 August 2017 (has links) Background: Despite increasing incidence and morbidity globally, hepatocellular carcinoma (HCC) remains a big challenge clinically. The difficulty to treat HCC is largely due to non-specific chemotherapy causing life-threatening toxicity and severe drug-related adverse effects. Extensive studies on targeted drug delivery systems (DDS) have revealed a great potential in specific delivery of chemotherapeutics for cancer treatment, which should be a way to overcome the limitations of conventional chemotherapy. Cantharidin (CTD) is a natural product from Chinese medicine showing a great potency but narrow therapeutic window with high toxicity. Its therapeutic potential is proposed to be improved with nanoliposomal encapsulation. To explore the potential of this liposomal delivery system for HCC treatment, in this study we developed and characterized liposomal carriers with CTD encapsulated and liposomal surface modified for targeted delivery to the HCC models in vitro and in vivo. Methods: In the present study, liposomal delivery system was developed with cantharidin (CTD) encapsulated as anticancer assembly for HCC treatment. Firstly, in order to demonstrate the feasibility of liposomal encapsulation for CTD, the plain liposomal CTD was prepared and the anticancer effects were evaluated in vitro and in vivo with comparison to the free CTD formulation (Chapter 2). Then, to achieve specific penetrability of the liposomal CTD for HCC, it was further modified with a cancer cell specific penetrating peptide BR2, and its superior penetrability was evaluated on both in vitro monolayer and 3D HepG2 cells including MTT assay, cellular uptake, internalization, tumor spheroid penetration and inhibition, and in vivo subcutaneous HCC mice model (Chapter 3). Finally, the dual-functionalized liposomes with BR2 and anti-carbonic anhydrase IX (CA IX) antibody were achieved for more efficient delivery with specific penetrating and targeting properties on orthotopic HCC model (Chapter 4). Results: The key results of the study are: (1) liposomal CTD can augment the anti-proliferative effects of CTD, and enhance the anticancer efficacy on subcutaneous HepG2-bearing nude mice, which might be due to the enhanced solubility of the drug as well as intracellular delivery (Chapter 2); (2) with BR2 penetrating peptide modification, the liposomal CTD can get into cancerous cells specifically and penetrate deeper in 3D tumor models. A better tumor growth inhibition was also seen in the subcutaneous HCC mice of BR2-modified liposomes treatment than that of the other group, which could be contributed to the passive targeting of liposomes as well as the specific penetrating properties induced by BR2 peptide (Chapter 3); (3) the dual-functionalized liposomes with BR2 peptide and anti-CA IX antibody modification can enhance the drug internalization into HepG2 cells and further improve the anticancer efficacy of drugs compared to other formulations on orthotopic HCC nude mice (Chapter 4). Conclusion: These results demonstrate 1) the liposomal delivery system as a powerful tool to improve anticancer effects of chemotherapeutic agent; 2) the usefulness of BR2 and CA IX modified-liposomal nano-delivery of CTD and their combination might be a potential modality for HCC treatment. The study paved a way for clinical translational medicine of this ligands-modified liposomal delivery system for targeted treatment of HCC.
36	Active targeting of cancer cells using gemcitabine conjugated platinum nanoparticles Odayar, Kriya January 2017 (has links) Submitted in fulfillment of the requirements of the Degree of Master's in Biotechnology, Durban University of Technology, 2017. / Nanotechnology is explained as the science of engineered materials and systems on a molecular scale. This innovation is currently used in a wide variety of applications which include using these nanoparticles as drug delivery vehicles. Such nanocarriers are relatively smaller than 100 nm in size with the ability to convey therapeutic drugs to a number of disease sites. Platinum-based nanoparticles have been extensively used in a number of applications namely catalysts, gas sensors, glucose sensors and cancer therapy. The properties of platinum nanoparticles (PtNP’s) typically depend on characteristics such as shape, particle size, elemental composition and structure, all of which can be manipulated and controlled in the fabrication process. Their unique size in the nanometer scale makes platinum nanoparticles an ideal candidate as targeted drug delivery vehicles. To target an anticancer drug to a diseased site is a distinctive feature of most studies, which aim to transfer an adequate dosage of the drug to cancer cells. Transport systems used as carriers of anticancer drugs offer numerous advantages, which include improved efficacy and a decrease in toxicity towards healthy cells when compared to standard drugs. The aim of this study was to determine the effect of platinum nanoparticles, gemcitabine and gemcitabine conjugated platinum nanoparticles (Hybrids) against cancer cells and healthy cells and to determine the mode of cell death and cell death pathways using flow cytometry. Platinum nanoparticles were synthesized via the reduction of hexachloroplatinic acid using sodium borohydride in the presence of capping agents. Synthesized platinum nanoparticles and the hybrids were characterized by observing peaks at 301 nm and 379 nm respectively using UV-visible spectroscopy. TEM images revealed that the PtNP’s and the conjugate compounds were spherical in shape with core sizes of 1.14 nm - 1.65 nm and 1.53 - 2.66 nm respectively. The bioactivity platinum nanoparticles, gemcitabine and the hybrids were investigated using MCF7 and Melanoma cancer cells at different concentrations from 0.10 to 100 µg/ml. Results indicated that conjugated nanoparticles induced the highest cell inhibition against both cell lines compared to gemcitabine and platinum nanoparticles. Bioactivity against PBMC (peripheral blood mononuclear) cells indicated that all three compounds show little or no effect towards the healthy cell line compared to the control. Melanoma cell line was used to determine the mode of cell death. Apoptosis was detected using Annexin V-FITC to detect membrane changes, JC-1 to detect a loss in mitochondrial membrane potential and caspase-3 assay kits. Results indicated that a significant amount of cell death was caused by cleavage of caspase-3. Nanoparticle drug delivery is an area that has shown significant promise in cancer treatment. Interaction of nanoparticles with human cells is an interesting topic for understanding toxicity and developing potential drug candidates. Imagine, something that is atleast or more than 80,000 times smaller than the edge of the ridge on a fingertip and unlocks a new wilderness into cancer research. Nanotechnology, known as the science of minute, is changing the approach to cancer and especially future diagnosis and treatment. Nanotechnology permits scientists to fabricate new apparatuses that are definitely smaller than cells, giving them the chance to attack tumor diseased cells. This innovation not just empowers practitioners to recognize malignancies prior but additionally holds the guarantee of halting cancer growth before it further develops. This progressive approach is so exact, specialists will in future be able to outline a unique treatment for an individual’s own restorative and hereditary profile. Researchers are designing nanoparticles that detect and destroy diseased cells and this optimistic innovation could be personalized for targeted drug delivery, enhanced imaging and ongoing affirmation of cancer cell death. The National Cancer Institute remains hopeful that facilitated development, nanotechnology will drastically change cancer treatment. / M Biotechnology Nanotechnology Nanoparticles Drug targeting Cancer cells Antineoplastic agents Cancer--Chemotherapy
37	Biological network models for inferring mechanism of action, characterizing cellular phenotypes, and predicting drug response Griffin, Paula Jean 13 February 2016 (has links) A primary challenge in the analysis of high-throughput biological data is the abundance of correlated variables. A small change to a gene's expression or a protein's binding availability can cause significant downstream effects. The existence of such chain reactions presents challenges in numerous areas of analysis. By leveraging knowledge of the network interactions that underlie this type of data, we can often enable better understanding of biological phenomena. This dissertation will examine network-based statistical approaches to the problems of mechanism-of-action inference, characterization of gene expression changes, and prediction of drug response. First, we develop a method for multi-target perturbation detection in multi-omics biological data. We estimate a joint Gaussian graphical model across multiple data types using penalized regression, and filter for network effects. Next, we apply a set of likelihood ratio tests to identify the most likely site of the original perturbation. We also present a conditional testing procedure to allow for detection of secondary perturbations. Second, we address the problem of characterization of cellular phenotypes via Bayesian regression in the Gene Ontology (GO). In our model, we use the structure of the GO to assign changes in gene expression to functional groups, and to model the covariance between these groups. In addition to describing changes in expression, we use these functional activity estimates to predict the expression of unobserved genes. We further determine when such predictions are likely to be inaccurate by identifying GO terms with poor agreement to gene-level estimates. In a case study, we identify GO terms relevant to changes in the growth rate of S. cerevisiae. Lastly, we consider the prediction of drug sensitivity in cancer cell lines based on pathway-level activity estimates from ASSIGN, a Bayesian factor analysis model. We use penalized regression to predict response to various cancer treatments based on cancer subtype, pathway activity, and 2-way interactions thereof. We also present network representations of these interaction models and examine common patterns in their structure across treatments. Biostatistics Bayesian hierarchical models Gaussian graphical models Biological networks Drug targeting Mechanism-of-action inference Multi-omics
38	Design and synthesis of quinoxaline derivatives for medicinal application against breast cancer cells Lekgau, Karabo January 2021 (has links) Thesis (M.Sc.(Chemistry)) -- University of Limpopo, 2020 / Breast cancer is a malignant tumour that starts in the cells of the breast. Many studies revealed aromatase (CYP19A1) and cyclin-dependent kinase 2 (CDK2) as possible therapeutic targets regarding breast cancer treatment, because they play crucial roles in anti-apoptotic processes during cell proliferation. Quinoxaline derivatives have attracted a great deal of attention due to their biological activities against fungi, virus, bacteria and cancer. Computer modelling was employed in order to reduce time and cost by searching the library of molecules and identifying those which are likely to bind to the drug target. A library of new one hundred (100) nitro and amino quinoxaline alkyne derivatives were successfully designed and screened against target proteins (CYP19A1 and CDK2) using virtual screening technique and thirteen (13) molecules were identified to be hit compounds against both targets with the docking score ranging from -6.143 to -8.372 kcal/mol as a measure of binding affinity. The hit compounds were subjected to IFD in order to identify tight binding through intermolecular interactions with active site residues of the binding pocket of the target proteins. All identified nitro and amino quinoxaline alkyne derivatives were successfully synthesised in a multi-step reaction sequence and their spectroscopic analysis (NMR, FTIR and MS) were in good agreement with the proposed structures in a good to moderate yield. The newly synthesised novel amino and nitro-quinoxaline derivatives were evaluated for anti-proliferative activity against breast cancer (MCF-7). Compound 59 showed to possess good inhibition against MCF-7 with an IC50 of 9.102 μM, whereas compounds 34, 54, 56 and 61 showed promising activity against MCF-7 with an IC50 value of < 50 μM. However, the MTT assay results showed that 59 was found to be toxic with an IC50 value of 0.205 μM against Raw 264.7 cell line. The dose response investigations showed that 31 and 34 have the promising anti-cancer activity against CYP19A and the correlation between molecular modelling (in-silico) and CYP19A inhibition activities (in- vitro), was established as compounds 31 and 34 were identified to bind to the drug target (CYP19A) with the docking score of -8.372 and 7.630 kcal/mol respectively. All the synthesized compounds were evaluated for the antitubercular activity against Mtb H37Rv strain as a secondary study. Compounds 57-62 with nitro-quinoxaline derivatives exhibited stronger inhibitory effects on Mtb H37Rv strain. In addition, compounds 60 and 62 were found to be most active against Mtb H37Rv with the high activity at MIC90 of <0.65 and <0.64 μM respectively. All active compounds are currently investigated for their cytotoxicity which have not been investigated before / National Research Foundation (NRF) and SASOL Inzalo Foundation Cancer cells Molecules Anti-apoptotic Computer modelling Quinoxaline Breast cancer Drug targeting Body marking
39	Developing Thyronamine Analog Pharmaceuticals Targeting TAAR1 to Treat Methamphetamine Addiction Wahl, Troy Andrew 19 July 2013 (has links) As a part of the overall program in the Grandy laboratory at Oregon Health & Science University (OHSU), studying the underlying chemical biology of methamphetamine (Meth) addiction, this dissertation reports on the development of six new thyronamine analogs which were synthesized and assayed against trace amine associated receptor 1 (TAAR1), giving preliminary results consistent with the analogs being inverse agonists. Due to highly variable TAAR1 expression levels in the assays, based on inter-assay response to control Meth stimulation as well as other possible factors, kinetic models were developed to qualitatively explain the assay results. The models set approximate limits on the analogs' binding and disassociation rates relative to those of Meth. Analysis of the assays also provides more evidence of TAAR1's basal activity. Based on the models, the conversion rate of ligand-free inactive TAAR1 to ligand-free active TAAR1 is less than 6% of the binding rate of Meth to TAAR1. The models also suggest that the inverse agonists bind to the inactive ligand-free form of TAAR1 between 10 and 100 times faster than Meth binds to the inactive ligand-free form of TAAR1. Three of the new analogs, G5-110s8, G5-112s5, and G5-114s5, bind to the ligand-free active form of TAAR1 faster than they bind to the inactive ligand-free form of TAAR1. The models do not suggest an upper limit on the binding rate of those 3 analogs to the ligand-free active form of TAAR1. A control assay lacking TAAR1 revealed an electrophysiological off-target effect caused by G5-109s8. Also, a novel synthetic route was developed for ET-92, the lead compound for this project, which reduced the number of synthetic steps from 14 to 5 and improved the overall yield from 15.3% to 18.3% (77.4 mg) with the hope that further improvements in yield are possible. Methamphetamine abuse -- Treatment Biogenic amines -- Receptors Drug targeting -- Research Chemicals and Drugs Medicinal-Pharmaceutical Chemistry
40	In Vitro Toxizität der Nanopartikel Graphen und Siliciumdioxid für die Medikamentenapplikation / In vitro toxicity of the nanoparticles Graphene and Silicon dioxide for drug targeting Gegg, Tanja Susanne January 2023 (has links) (PDF) Graphen und Siliciumdioxid Nanopartikel sind als Trägersubstanz für Medikamente beim Drug Targeting von Interesse. Diese Arbeit ist eine toxikologische Untersuchung der Nanopartikel Graphen und Siliciumdioxid im Zellmodell. Dabei wurden Graphen Nanopartikel mit einer Dicke von 6 bis 8 nm und einer Breite von 15 µm verwendet. Die verwendeten Siliciumdioxid Nanopartikel waren kugelförmig und porös mit einer Partikel-Größe von 5 bis 20 nm. Die dosisabhängige Toxizität (Konzentrationen 0,01 mg/ml, 0,1 mg/ml und 1 mg/ml, Inkubation über 24 Stunden) gegenüber 5 verschiedenen Zelllinien (cerebEND, Caco-2, Hep G2, HEK-293, H441) wurde geprüft. Dabei kamen Zellviabilitätstests (CellTiter-Glo Assay, EZ4U-Test) zum Einsatz. Zudem wurde mit den Apoptose-Markern Bax und Caspase-3 auf Gen- und Proteinebene (Polymerasekettenreaktion und Western Blot) überprüft, ob eine Apoptose eingeleitet wurde. Zur Untersuchung der Zellviabilität wurde der CellTiter-Glo Assay verwendet. Für Graphen Nanopartikel zeigte sich ab einer Konzentration von 1 mg/ml bei den Zelllinien HEK-293 und H441 ein statistisch signifikanter Abfall der Zellviabilität. CerebEND und Hep G2 Zellen reagierten auf Graphen Nanopartikel ab einer Konzentration von 1 mg/ml ebenfalls mit einem deutlichen Abfall der Zellviabilität, diese Ergebnisse waren jedoch nicht statistisch signifikant. Die Zelllinie Caco-2 zeigte sich von den Graphen Nanopartikeln unbeeindruckt, es kam zu keiner statistisch signifikanten Veränderung der Zellviabilität. Siliciumdioxid Nanopartikel bewirkten ab einer Konzentration von 1 mg/ml einen statistisch signifikanten Abfall der Zellviabilität bei den Zelllinien cerebEND, HEK-293 und H441. HepG2 Zellen zeigten bei 1 mg/ml Siliciumdioxid einen deutlichen aber statistisch nicht signifikanten Abfall der Zellviabilität. Die Zelllinie Caco-2 erwies sich auch bei Siliciumdioxid Nanopartikel als äußerst robust und zeigte keine statistisch signifikanten Veränderungen der Zellviabilität. Messungen der Zellviabilität auf Grundlage von Adsorptionsmessung, wie beim EZ4U-Test, hatten sich als ungeeignet erwiesen, da die Eigenfarbe der Nanopartikel Graphen und Siliciumdioxid mit dieser Messung interferierte. Zudem wurde geprüft, ob die bei einem Teil der Zelllinien eingetretene toxische Wirkung der Nanopartikel ab einer Konzentration von 1 mg/ml durch Nekrose oder durch Apoptose zustande kam. Die Polymerasekettenreaktion zeigte mit einer einzigen Ausnahme keine statistisch signifikante Erhöhung der Genexpression für Bax und Caspase-3 und gab somit auch keine Hinweise auf die Einleitung einer Apoptose. Im Western Blot zeigte sich keine statistisch signifikante Erhöhung der Proteinexpression von Bax und Caspase-3. Zudem konnte im Western Blot auch keine aktivierte Caspase-3 nachgewiesen werden. Somit lagen auf Grundlage von Polymerasekettenreaktion und Western Blot keine Hinweise auf das Eintreten einer Apoptose vor. Die toxische Wirkung der Nanopartikel Graphen und Siliciumdioxid, die bei einem Teil der Zelllinien ab einer Konzentration von 1 mg/ml nachgewiesen werden konnte, beruhte demnach auf Nekrose. / Graphene and silicon dioxide nanoparticles are of interest as drug carriers for controlled drug delivery systems. This thesis is an evaluation of the toxic properties of the nanoparticles Graphene and Silicon dioxide based on tests on cell culture. The Graphene nanoplatelets were 6 to 8 nm thick and 15 µm wide. The Silicon dioxide nanoparticles were spherical and porous with a particle size of 5 to 20 nm. The dose dependent toxicity (concentrations 0,01 mg/ml, 0,1 mg/ml und 1 mg/ml, incubation over 24 hours) was tested on 5 different cell lines (cerebEND, Caco-2, Hep G2, HEK-293, H441). I used cell viability test (CellTiter-Glo Assay, EZ4U-test). In addition, I used PCR (Polymerase chain reaction) and western blot to detect the apoptosis markers Bax and Caspase-3, to see if the nanoparticles cause an apoptosis or a necrosis. For investigating the cell viability, I used the CellTiter-Glo Assay. Graphene nanoplatelets showed from a concentration of 1 mg/ml for the cell lines HEK-293 und H441 a statistically significant decrease of cell viability. CerebEND and Hep G2 cells reacted on Graphene nanoplatelets from a concentration of 1 mg/ml with a clearly decrease in cell viability, but these results were not statistically significant. The cell line Coco-2 showed no decrease in cell viability after the incubation with Graphene nanoplatelets. Silicon dioxide nanoparticles showed from a concentration of 1 mg/ml a statistic significant decrease of cell viability in the cell lines cerebEND, HEK-293 and H441. The Hep G2 cells showed a decrease in cell viability as well, but the results were not statistically significant. The cell line Caco-2 showed no decrease in cell viability after the incubation with Silicon dioxide nanoparticles. Cell viability tests based on the messurement of adsorption like the EZ4U-test, proved not suitable for this setting, because the own color of the nanoparticles interfered with the measurement. In addition, I tested if the nanoparticles caused an apoptosis or a necrosis. The PCR showed with one exception no statistically significant increase in the gene expression of Bax and Caspase-3 and therefore no proof of apoptosis. The western blot showed no statistically significant increase in the protein expression of Bax and Caspase-3. And it detected no activated Caspase-3. There was based on PCR and western blot no sign for the cells to enter in apoptosis. The toxic properties of the nanoparticles Graphene and Silicon dioxide, that was shown in a part of the cell lines from a concentration of 1 mg/ml, was therefore based on necrosis. Nanopartikel Toxizität Graphen Siliciumdioxid Drug Targeting Targeted drug delivery Zellkultur ddc:610

Search results