Spelling suggestions: "subject:"cationic polymer"" "subject:"kationic polymer""
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Electrochemical detection of electroactive anion by capillary electrochromatagraphy using open tubular column modified by cationic polymer (PDADMAC)Huang, Yi-cheng 05 September 2004 (has links)
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pH-responsive polymer nanoparticles synthesized using ARGET ATRPForbes, Diane Christine 24 February 2015 (has links)
Polycationic nanoparticles were synthesized with an activators regenerated by electron transfer for atom transfer radical polymerization-based (ARGET ATRP-based) emulsion in water method and investigated for their utility as biomaterials for drug delivery. The polycationic nanoparticles were composed of 2-(diethylamino)ethyl methacrylate (DEAEMA) for pH-responsiveness, poly(ethylene glycol) methyl ether methacrylate (PEGMA) for improved biocompatibility, tert-butyl methacrylate (tBMA) to impart hydrophobicity, and a tetraethylene glycol dimethacrylate (TEGDMA) cross-linking agent for enhanced colloidal stability. Dynamic light scattering demonstrated pH-responsive swelling, and cell-based assays demonstrated pH-dependent membrane disruption. The polycationic nanoparticles demonstrated low toxicity to cells. The polycationic nanoparticles were evaluated for use as drug delivery biomaterials by investigating the interactions with the drug and cells. Delivery remains a major challenge for translating small interfering RNA (siRNA) to the clinic, and overcoming the delivery challenge requires effective siRNA delivery vehicles. The polycationic nanoparticles demonstrated efficient siRNA loading. Evidence of siRNA-induced knockdown in cells was observed following transfection with the polycationic nanoparticle/siRNA complexes. Imaging techniques confirmed enhanced siRNA internalization using the polycationic nanoparticle/siRNA complexes compared to naked siRNA. An array of polycationic nanoparticles synthesized using ARGET ATRP or UV-initiated polymerization methods was characterized to examine the effect of polymerization method on material properties and the connection to molecular structure. An improved understanding of molecular structure, and its connection to polymerization method and material characteristics, may aid the design of advanced materials. The ARGET ATRP polycationic nanoparticles demonstrated increased nanoscale homogeneity compared to the UV-initiated polymerization polycationic nanoparticles; increased nanoscale heterogeneity in the UV-initiated polymerization polycationic nanoparticles was associated with broader transitions. The polycationic nanoparticles promoted cellular uptake of siRNA and induced knockdown, thus demonstrating potential as siRNA delivery vehicles. The ARGET ATRP method provides an alternative route to creating polycationic nanoparticles with improved nanoscale homogeneity. / text
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Designing Antimicrobial Polymer Coating to Inhibit Pathogenic and Spoilage MicroorganismsHung, Anne Yu-Ting 21 March 2018 (has links)
Microbial cross-contamination remains an on-going challenge in the food sector despite implemented sanitation programs. Antimicrobial coatings with inherent self-sanitizing properties have been explored to enhance current cleaning practice and support food safety. Prior work has demonstrated successful incorporation of dual antimicrobial characters, cationic polymers and N-halamines, into one coating system. In addition to the rechargeable nature of N-halamines, the coating was reported to exhibit biocidal effects due to the inherently antimicrobial cationic moieties and the chlorinated N-halamines. However, while these polymer coatings were able to retain antimicrobial activity after repeated chlorination, signs of hydrolysis was observed for the N-halamine bonds, indicating potential issues for long-term usage. Herein, we introduced varied molecular weight cross-linkers in an adaption of the established fabrication method to evaluate cross-linker molecular weight (styrene maleic anhydride (SMA) of 6, 8, 120, 250 kDa) influence on surface properties of the coating.
All antimicrobial polymer coatings exhibited similar FTIR spectra, with a prominent absorption band at ~1650 cm-1 suggesting successful cross-link of the polyethyleneimine and SMA. Surface concentration of primary amines ranged from 350-900 nmol/cm2, and N-halamines from 90-130 nmol/cm2. Surface energy decreased with increasing molecular weight of SMA, but were not statistically different from one another. In the end, optimal cross-linker molecular weight was determined based on antimicrobial performance, where the coated PPs with 6 kDa SMAs demonstrated enhanced biocidal effects against E. coli O157:H7 in its chlorinated form. Further, the antimicrobial coating demonstrated efficacy of ~3 to >5 log reductions of microbial load in its unchlorinated and chlorinated form against E. coli O157:H7, L. monocytogenes, and P. fluorescens. Storage studies support the stability of the chlorinated halamines, with full retention of chlorinated N-halamines over a 24 h study (representative of time between sanitation cycles). These results support the potential application of this antimicrobial polymer coating in food processing and handling operations, in support of reducing cross-contamination of spoilage and pathogenic microorganisms.
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N-isopropyl-acrylamide conjugated polyglycerol as a delivery vehicle for in vitro sirna transfectionNicolini, Anthony Michael 23 May 2011 (has links)
Gene expression knockdown using RNA interference has dramatically altered the ability to silence target genes without the need for a creation of a genetic knockout. The pitfalls surrounding successful siRNA gene expression knockdown fall in the broad category of delivery. This work focuses on the use of N-isopropyl-acrylamide conjugated polyglycerol (PGNIPAM) as a novel cationic vector of in vitro and possible in vivo delivery of siRNA. The hyper-branched structure of the PGNIPAM molecule bears a biocompatible core with cationic subunits on the surface, providing a less toxic alternative to other cationic polymers used in the past. Further PGNIPAM shows excellent binding and release characteristics over other comparable molecules and systems. Activity of the siRNA requires access to the cell cytoplasm, which in turn requires passage of the siRNA through the cell membrane and release into the internal environment with no degradation. PGNIPAM has shown the ability to traverse the endocytic pathway and release the siRNA directly into the cytoplasm where it can interact with cellular machinery. Knockdown of known oncogene survivin was observed in vitro both through mRNA expression reduction as well as through protein reduction in MDA-MB-231 human breast cancer cells. Additionally, early stage animal work with a human breast cancer model shows positive results for coupled treatment of tumors using siRNA against survivin and doxorubicin, an anticancer drug. PGNIPAM offers a safer alternative to other cationic delivery systems and has shown improvement over standard modes of knockdown from commercial products.
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EFFECTS OF CORE AND SHELL MODIFICATION TO TETHERED NANOASSEMBLIES ON SIRNA THERAPYRheiner, Steven 01 January 2017 (has links)
siRNA therapy is an emerging technique that reduces protein expression in cells by degrading their mRNAs via the RNA interference pathway (RNAi). Diseases such as cancer often proliferate due to increased protein expression and siRNA therapy offers a new method of treatment for those diseases. Although siRNA therapy has shown success in vitro, it often fails in vivo due to instability in the blood stream. To overcome this limitation, delivery vehicles are necessary for successful transfection of siRNA into target cells and cationic polymers have been widely studied for this purpose. However, complexes between siRNA and delivery vehicles made from cationic polymers exhibit stability issues in the blood stream which results in toxicity and low transfection. This work hypothesizes that improvement of vehicle/siRNA complex stability will improve siRNA transfection efficiency. To test this, the contributions and outcomes of poly(ethylene glycol) [PEG] shell and hydrophobic core modification to a polyethylenimine (PEI) based tethered nanoassemblies (TNAs) were examined. Initially, hydrophobic modification of palmitate (PAL) to the core of the TNA yielded improved transfection efficiency due to an enhanced endosomal escape capability. However, this modification also reduced the TNA/siRNA complex stability. This indicated that the core hydrophobicity must be balanced in order increase stability while increasing transfection efficiency. Additionally, TNAs made from PEG and PEI did not cause transfection in our initial study. The PEG shell density was found to be too great and thereby reduced transfection efficiency. Reducing the PEG density by lowering PEG molecular weight, reducing attachment percentage, and removing small PEI impurities from the synthesis stock increased overall transfection efficiency and unimolecularity of the TNA complexes. This indicated that the shell composition of the TNA must be tuned in order to improve particle design. Further study of the hydrophobically modification to TNAs yielded unintended effects on the transfection efficiency evaluation assay. These particles exhibited an siRNA independent reduction in the reporter protein used to observe transfection, or a false positive effect, that was not previously observed. It was found that this false positive was influence mainly by the hydrophobic group rather than the cationic polymer backbone. Cellular stress was observed in cells dosed with the hydrophobically modified TNAs which lead to over ubiquitination and rapid degradation of the luciferase protein. This demonstrated that core components of TNAs could cause cellular stress and influence interaction outside of the TNA. Overall, this work demonstrates that hydrophobic core and PEG shell modification require balancing and consideration to improve properties of future cationic polymer based siRNA delivery vehicle design.
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The Development of a Novel Polymer Based System for Gene DeliveryLe, Anh Van 18 November 2015 (has links)
Gene therapy involves the use of nucleic acids, either DNA or RNA for the treatment, cure, or prevention of human diseases. Synthetic cationic polymers are promising as a tool for gene delivery because of their high level of design flexibility for biomaterial construction and are capable of binding and condensing DNA through electrostatic interactions.
Our lab has developed a novel polymer (poly (polyethylene glycol-dodecanoate) (PEGD), a polyester of polyethylene glycol (PEG) and dodecanedioic acid (DDA). PEGD is a linear viscous polymer that self-assembles into a vesicle upon immersion in an aqueous solution. A copolymer of dodecanedioc acid and polyethylene glycol (PEG) was synthesized at a 1:1 ratio. Furmaric (FA) or itaconic acid (IA) was used to suppress DDA in the PEGD copolymer at an 80:20 ratio (DDA: furmaric/itaconic acid) to form the PEGDF/I variant. PEGDF/I are then modified through the Michael addition of Protamine Sulfate (PEGDF/I-PS) and Cys-Arg8 (PEGDF/I-CA) peptide to the carbon-carbon double bond on the polymer backbone to introduce a positive charge.
The modified PEGDF/I polymers were capable of binding and condensing DNA. Transfection of HEK 293 cells with pTurboGFP plasmid using modified PEGDF/I polymers was successful but showed varied efficiency. The PEGDF/I-CA polymer had around 30% transfection efficiency and was shown to be non-cytotoxic.
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The Investigation of Water-Soluble Polyurethanes that Mimic Antimicrobial PeptidesMankoci, Steven Gerald 24 May 2018 (has links)
No description available.
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Le rôle des matériaux hybrides à base d'argiles dans la protection des œuvres d'art / The role of clay-based hybrid materials in the protection of works of artGuillermin, David 08 October 2018 (has links)
Le travail de cette thèse s’intéresse à la stabilisation de plusieurs pigments hybrides.Une première partie traite de pigment obtenu à l’aide de l’acide carminique et de la montmorillonite, une argile commune. Un procédé d’inversion de la charge de surface de l’argile avec un polymère cationique, ou l’utilisation d’argiles modifiées par des polycations de Titane et d’Aluminium, permettent l’élaboration du pigment. La résistance des pigments à la photodégradation est alors testée. Les techniques couplées de RMN, DRX, FTIR et d’EPR permettent d’éclairer l’agencement des molécules organiques sur la surface minérale, et également de suivre le processus de dégradation du colorant.La description de pigments hybrides obtenus à l’aide d’un spiropyrane vient compléter l’étude. Le composé, qui joue le rôle de colorant organique, est ajouté à différentes matrices minérales : l’argile, modifiée ou non, ainsi que la co-précipitation avec des organo-silanes. Ces synthèses permettent d’observer la variété de couleur obtenus en mélangeant un même colorant avec plusieurs matrices de nature différente. / The work of this thesis focuses on the stabilization of several hybrid pigments.The first part deals with pigment obtained with carminic acid and montmorillonite, a common clay. A method of reversing the surface charge of the clay with a cationic polymer, or the use of clays modified with titanium and aluminum polycations, allows the elaboration of the pigment. The resistance of the pigments to photodegradation is then tested. Coupled NMR, DRX, FTIR and EPR techniques help to illuminate the arrangement of organic molecules on the mineral surface, and also to follow the dye degradation process.The description of hybrid pigments obtained using a spiropyran completes the study. The compound, which plays the role of organic dye, is added to different mineral matrices: clay, modified or not, and co-precipitation with organosilanes. These syntheses make it possible to observe the variety of color obtained by mixing the same dye with several matrices of different nature.
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Effects of Microparticulate Drug Delivery Systems : Tissue Responses and Transcellular TransportRagnarsson, Eva January 2005 (has links)
<p>Over the past decade, the development of macromolecular drugs based on peptides, proteins and nucleic acids has increased the interest in microparticulate drug delivery, i.e., the delivery of drug systems in the nanometer and micrometer ranges. However, little is known so far about the effect that microparticulate systems have on various tissues after administration. Additionally, the knowledge of mechanisms responsible for the uptake and transport of microparticles across the human intestine is incomplete and requires further investigation to improve both the safety profiles and the efficiency of these drug delivery systems.</p><p>This thesis is comprised of two parts. The first one investigates gene expression responses obtained from DNA arrays in local and distal tissues after microparticulate drug delivery. The second part focuses on the mechanisms responsible for the transport of microparticles across epithelial cells lining the intestine.</p><p>The results presented in the first part demonstrated that gene expression analysis offers a detailed picture of the tissue responses after intramuscular or pulmonary administration of microparticulate drug delivery systems compared to the traditional techniques used for such evaluations. In addition, DNA arrays provided a useful and sensitive tool for the initial characterization and evaluation of both local and distal tissue responses, making it possible to distinguish between gene expression patterns related to each studied delivery system.</p><p>The results presented in the second part demonstrated that the surface properties of the microparticle were important for the extent of transport across an <i>in vitro</i> model of the follicle-associated epithelium (FAE), comprised of intestinal epithelial cells specialized in particle transport (M cells). Another important finding was that the enteropathogen bacterium, <i>Yersinia pseudotuberculosis</i>, induced microparticle transport across the normal intestinal epithelium, represented by Caco-2 cells and excised human ileal tissue. This transport was most probably mediated by an increased capacity for macropinocytosis in the epithelial cells.</p>
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Effects of Microparticulate Drug Delivery Systems : Tissue Responses and Transcellular TransportRagnarsson, Eva January 2005 (has links)
Over the past decade, the development of macromolecular drugs based on peptides, proteins and nucleic acids has increased the interest in microparticulate drug delivery, i.e., the delivery of drug systems in the nanometer and micrometer ranges. However, little is known so far about the effect that microparticulate systems have on various tissues after administration. Additionally, the knowledge of mechanisms responsible for the uptake and transport of microparticles across the human intestine is incomplete and requires further investigation to improve both the safety profiles and the efficiency of these drug delivery systems. This thesis is comprised of two parts. The first one investigates gene expression responses obtained from DNA arrays in local and distal tissues after microparticulate drug delivery. The second part focuses on the mechanisms responsible for the transport of microparticles across epithelial cells lining the intestine. The results presented in the first part demonstrated that gene expression analysis offers a detailed picture of the tissue responses after intramuscular or pulmonary administration of microparticulate drug delivery systems compared to the traditional techniques used for such evaluations. In addition, DNA arrays provided a useful and sensitive tool for the initial characterization and evaluation of both local and distal tissue responses, making it possible to distinguish between gene expression patterns related to each studied delivery system. The results presented in the second part demonstrated that the surface properties of the microparticle were important for the extent of transport across an in vitro model of the follicle-associated epithelium (FAE), comprised of intestinal epithelial cells specialized in particle transport (M cells). Another important finding was that the enteropathogen bacterium, Yersinia pseudotuberculosis, induced microparticle transport across the normal intestinal epithelium, represented by Caco-2 cells and excised human ileal tissue. This transport was most probably mediated by an increased capacity for macropinocytosis in the epithelial cells.
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