11 research outputs found

    Efficient Transfer of Genes into Murine Cardiac Grafts by Starburst Polyamidoamine Dendrimers

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    Overview summary Plasmid-mediated gene therapy has been used to deliver immunosuppressive molecules into allografts to prolong graft survival. However, direct injection of naked plasmid DNA is inefficient because transgene expression is low and transient. This study investigated the ability of Starburst dendrimers to augment plasmid-mediated gene transfer efficiency in a murine cardiac transplantation model. The results demonstrate that dendrimers increased the efficiency of transfer and expression of exogenous DNA in cardiac grafts. Improved expression of an immunosuppressive cytokine viral interleukin-10 (vIL-10) by dendrimers significantly prolonged allograft survival. The dose of DNA, the charge ratio of DNA to dendrimer, and the size generation of the dendrimers were all critical for prolongation of allograft survival. Thus, the use of the Starburst dendrimer as a carrier molecule for plasmid-mediated gene transfer improved the efficiency of transfer and expression, providing further therapeutic value for treatment of cardiac allograft rejection.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/63156/1/hum.1998.9.4-553.pd

    Intravascular and Endobronchial DNA Delivery to Murine Lung Tissue Using a Novel, Nonviral Vector

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    Gene transfer to the lung can be achieved via either the airway or the pulmonary vasculature. We evaluated gene transfer and expression by intravascular and endobronchial routes, using DNA complexed with G9 PAMAM dendrimer or naked plasmid DNA. Intravascular tail vein delivery of dendrimer-complexed pCF1CAT plasmid resulted in high levels of transgene expression in the lung at 12 and 24 hr, followed by a second peak of expression 3 to 5 days after administration. After intravenous administration of the complexes, CAT expression was never observed in organs other than the lung. There were only minimal levels of CAT protein expressed in the lung after intravenous administration of naked plasmid DNA. Repeated intravascular doses of the dendrimer-complexed plasmid, administered four times at 4-day intervals, maintained expression at 15-25% of peak concentrations achieved after the initial dose. Endobronchial delivery of naked pCF1CAT plasmid produced significant amounts of CAT protein in the lung. Comparison of intratracheal and intranasal routes resulted in similar expression levels of CAT in the lung and trachea. However, in juxtaposition to vascular delivery, intranasal delivery of dendrimer-complexed plasmid DNA gave lower levels of CAT expression than that observed with naked plasmid DNA. In situ localization of CAT enzymatic activity suggested that vascular administration seemed to achieve expression in the lung parenchyma, mainly within the alveoli, while endobronchial administration primarily targeted bronchial epithelium. Our results show that intravenously administered G9 dendrimer is an effective vector for pulmonary gene transfer and that transgene expression can be prolonged by repeated administration of dendrimer-complexed DNA.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/63314/1/10430340050057468.pd

    Biosensors for Real-Time Monitoring of Radiation-Induced Biologic Effects in Space

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    This work seeks to develop cellular biosensors based on dendritic polymers. Nanoscale polymer structures less than 20 nm in diameter will be used as the basis of the biosensors. The structures will be designed to target into specific cells of an astronaut and be able to monitor health issues such as exposure to radiation. Multiple components can be assembled on the polymers including target directors, analytical devices (such as molecular probes), and reporting agents. The reporting will be accomplished through fluorescence signal monitoring, with the use of multispectral analysis for signal interpretation. These nanosensors could facilitate the success and increase the safety of extended space flight. The design and assembly of these devices has been pioneered at the Center for Biologic Nanotechnology in the University of Michigan. This period, synthesis of the test-bed biosensors continued. Studies were performed on the candidate fluorescent dyes to determine which might be suitable for the biosensor under development. Development continued on producing an artificial capillary bed as a tool for the use in the production of the fluorescence signal monitor. Work was also done on the in vitro multispectral analysis system, which uses the robotic microscope

    Polyplex Exposure Inhibits Cell Cycle, Increases Inflammatory Response, and Can Cause Protein Expression without Cell Division

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    We sought to evaluate the relationship between cell division and protein expression when using commercial poly­(ethylenimine) (PEI)-based polyplexes. The membrane dye PKH26 was used to assess cell division, and cyan fluorescent protein (CFP) was used to monitor protein expression. When analyzed at the whole population level, a greater number of cells divided than expressed protein, regardless of the level of protein expression observed, giving apparent consistency with the hypothesis that protein expression requires cells to pass through mitosis in order for the transgene to overcome the nuclear membrane. However, when the polyplex-exposed population was evaluated for the amount of division in the protein-expressing subpopulation, it was observed that substantial amounts of expression had occurred in the absence of division. Indeed, in HeLa S3 cells, this represented the majority of expressing cells. Of interest, the doubling time for both cell lines was slowed by ∼2-fold upon exposure to polyplexes. This change was not altered by the origin of the plasmid DNA (pDNA) transgene promoter (cytomegalovirus (CMV) or elongation factor-1 alpha (EF1α)). Gene expression arrays in polyplex-exposed HeLa S3 cells showed upregulation of cell cycle arrest genes and downregulation of genes related to mitosis. Chemokine, interleukin, and toll-like receptor genes were also upregulated, suggesting activation of proinflammatory pathways. In summary, we find evidence that a cell division-independent expression pathway exists, and that polyplex exposure slows cell division and increases inflammatory response

    The synthesis of control (GdIII-DOTA-G5) and FA targeted dendritic chelate (GdIII-DOTA-G5-FA)

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    After conjugation of 4.5 (on average) of folic acid molecules to G5 PAMAM dendrimer (), 50 of the primary amine groups were acetylated (), the remaining primary amines conjugated with bifunctional NCS-DOTA () and complexed with GdCl.6HO (). The structure of the DOTA-NCS used for conjugation of contrast agents (lower panel).<p><b>Copyright information:</b></p><p>Taken from "Targeted gadolinium-loaded dendrimer nanoparticles for tumor-specific magnetic resonance contrast enhancement"</p><p></p><p>International Journal of Nanomedicine 2008;3(2):201-210.</p><p>Published online Jan 2008</p><p>PMCID:PMC2527674.</p><p>© 2008 Swanson et al, publisher and licensee Dove Medical Press Ltd.</p
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