• Refine Query
  • Source
  • Publication year
  • to
  • Language
  • 201
  • 101
  • 61
  • 21
  • 15
  • 15
  • 14
  • 12
  • 11
  • 4
  • 4
  • 2
  • 2
  • 2
  • 2
  • Tagged with
  • 520
  • 338
  • 118
  • 44
  • 41
  • 39
  • 39
  • 38
  • 38
  • 37
  • 36
  • 35
  • 33
  • 29
  • 28
  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
311

SURFACE FUNCTIONALIZATION OF MELT COEXTRUDED FIBERS FOR BIOMEDICAL APPLICATIONS

Kim, Si Eun 08 February 2017 (has links)
No description available.
312

EFFECTS OF POLYMER COMPOSITIONS AND SCAFFOLD SURFACE FUNCTIONALIZATION ON WOUND HEALING

Tseng, Yen-Ming 03 August 2022 (has links)
No description available.
313

Synthesis, Characterization and Evaluation of Central Nervous System Targeted Metallocarborane Complexes

Louie, Anika S. 10 1900 (has links)
<p>A series of new methodologies to link a neurotransmitter receptor targeting vector (WAY) to carboranes and the preparation of the corresponding metallocarboranes (M = Re, <sup>99m</sup>Tc) as a new class of organometallic CNS imaging probes is described. WAY-carboranes (<strong>5</strong>, <strong>6</strong>, <strong>16</strong>) and the corresponding metallocarboranes (M = Re (<strong>12</strong>, <strong>13</strong>, <strong>22a</strong>, <strong>22b</strong>), <sup>99m</sup>Tc (<strong>14a</strong>, <strong>15</strong>, <strong>23</strong>)) were synthesized in yields ranging from 10-95%. The first observed 3,1,2 versus 2,1,8 rhenacarborane isomerization process was discovered for <strong>12</strong> where isomerization and complexation occurred simultaneously. Re-carboranes <strong>22a</strong> and <strong>22b</strong> had similar carbon-carbon cage configuration where electronic effects was the driving force behind isomerization.</p> <p>The lipophilicities of <sup>99m</sup>Tc-carboranes (<strong>14a</strong>, <strong>15</strong>, <strong>23)</strong> were within the ideal range to cross the BBB (log P = 2.4-2.6). <em>In vitro</em> binding data showed that <strong>22b</strong> has high affinity for alpha-adrenergic receptors (K<sub>i</sub> = 17-39 nM) resulting in the first organometallic complex to effectively bind to this class of receptors. SPECT images of <strong>14a</strong> in rats showed no brain uptake, while quantitative biodistribution studies indicated modest, non-negligible brain uptake in the hypothalamus region.</p> <p>The neutral [M(CO)<sub>2</sub>(NO)(C<sub>2</sub>B<sub>9</sub>H<sub>10</sub>R)] analogues (<strong>30</strong>, <strong>34</strong>, <strong>37</strong>) were prepared to address the limited brain uptake of the [M(CO)<sub>3</sub>(C<sub>2</sub>B<sub>9</sub>H<sub>10</sub>R)]<sup>-</sup> complexes. Reactivity differences between Re and <sup>99m</sup>Tc were noted during nitrosation conditions where the initial products from the reaction led to nitration of the phenyl group in addition to nitrosation of the metal core. The fluorescence properties of <strong>29</strong> were measured.</p> <p>Low yields and multistep syntheses associated with the preparation of substituted carborane led to the development of a carborane-alkyne platform. Alkyne-carboranes (<strong>53</strong>-<strong>55</strong>) were developed and conjugated to WAY-azide (<strong>46</strong>) using “click” chemistry. The metallocarboranes (M = Re (<strong>69</strong>-<strong>71</strong>), <sup>99m</sup>Tc (<strong>72</strong>-<strong>74</strong>)) were generated in yields ranging from 45-71%.</p> / Doctor of Philosophy (PhD)
314

Addressing Antibiotic Resistance: The Discovery of Novel Ketolide Antibiotics Through Structure Based Design and In Situ Click Chemistry

Glassford, Ian Michael January 2016 (has links)
Antibiotic resistance has become and will continue to be a major medical issue of the 21st century. If not addressed, the potential for a post-antibiotic era could become a reality, one that the world has not been familiar with since the early 1900’s. Multidrug-resistant hospital-acquired bacterial infections already account for close to 2 million cases and 23,000 deaths in the United States, along with 20 billion dollars of additional medical spending each year. The CDC released a report in 2013 regarding the seriousness of antibiotic resistance and providing a snapshot of costs and mortality rates of the most serious antibiotic resistant bacteria, which includes 17 drug resistant bacteria, such as carbapenem-resistant Enterobacteriaceae, vancomycin-resistant Enterococcus and Staphylococcus aureus, and multidrug-resistant Acinetobacter and Pseudomonas aeruginosa. The development of antibiotic resistance is part of bacteria’s normal evolutionary process and thus impossible to completely stop. To ensure a future where resistant bacteria do not run rampant throughout society, there is a great need for new antibiotics and accordingly, methods to facilitate their discovery Macrolides are a class of antibiotics that target the bacterial ribosome. Since their discovery in the 1950’s medicinal chemistry has created semi-synthetic analogues of natural product macrolides to address poor pharmacokinetics and resistance. Modern X-Ray crystallography has allowed the chemist access to high resolution images of the bacterial ribosome bound to antibiotics including macrolides which has ushered in an era of structure-based design of novel antibiotics. These crystal structures suggest that the C-4 methyl group of third generation ketolide antibiotic telithromycin can sterically clash with a mutated rRNA residue causing loss of binding and providing a structural basis for resistance. The Andrade lab hypothesized that the replacement of this methyl group with hydrogen would alleviate the steric clash and allow the antibiotic to retain activity. To this end, the Andrade lab set out on a synthetic program to synthesize four desmethyl analogues of telithromycin by total synthesis that would directly test the steric clash hypothesis and also provide structure-activity relationships about these methyl groups which have not been assessed in the past. Following will contain highlights of the total synthesis of (-)-4,8,10-didesmethyl telithromycin, (-)-4,10-didesmethyl telithromycin, and (-)-4,8-desmethyl telithromycin and my journey toward the total synthesis of (-)-4-desmethyl telithromycin Traditional combinatorial chemistry uses chemical synthesis to make all possible molecules from various fragments. These molecules then need to be purified, characterized, and tested against the biological target of interest. While high-throughput assay technologies (i.e., automation) has streamlined this process to some extent, the process remains expensive when considering the costs of labor, reagents, and solvent to synthesize, purify, and characterize all library members. Unlike traditional combinatorial chemistry, in situ click chemistry directly employs the macromolecular target to template and synthesize its own inhibitor. In situ click chemistry makes use of the Huisgen cycloaddition of alkyne and azides to form 1,2,3-triazoles, which normally reacts slowly at room temperature in the absence of a catalyst. If azide and alkyne pairs can come together in a target binding pocket the activation energy of the reaction can be lowered and products detected by LC-MS. Compounds found in this way generally show tighter binding than the individual fragments. Described in the second part of this dissertation is the development of the first in situ click methodology targeting the bacterial ribosome. Using the triazole containing third generation ketolide solithromycin as a template we were able to successfully show that in situ click chemistry was able to predict the tightest binding compounds. / Chemistry
315

High Throughput Screening of Nanoparticle Flotation Collectors

Abarca, Carla January 2017 (has links)
Carla Abarca Ph.D. Thesis / The selective separation of valuable minerals by froth flotation is a critical unit operation in mineral processing. Froth flotation is based on the ability of chemical reagents, called collectors, to selectively lower the surface energy of valuable mineral particles, facilitating attachment of the modified mineral particles to air bubbles in the flotation cell. The mineral laden bubbles rise to the surface forming a froth phase that can be isolated. Novel cationic polystyrene nanoparticle collectors have been developed recently to be used as effective flotation collectors, aiming to recover challenging nickel sulfide ores that respond poorly to conventional molecular flotation collectors. However, optimizing nanoparticle flotation collectors is a challenge. An effective nanoparticle collector candidate should meet three requirements: (1) it should be colloidally stable in the flotation media; (2) it should be hydrophobic enough to change the mineral surface and induce an air bubble-mineral particle attachment; and (3) specifically and strongly bind to metal-rich minerals. Producing nanoparticles that are simultaneously colloidally stable and sufficiently hydrophobic presents a problematic task. Thus, a delicate balance of nanoparticle properties is required for commercially viable nanoparticle collectors. This thesis presents a promising approach for discovering and characterizing novel nanoparticle collectors by using high throughput screening techniques. Developed was a workflow for fast fabrication and testing of nanoparticle candidates, including: (1) parallel production of large nanoparticle libraries covering a range of surface chemistries, (2) a high throughput colloidal stability assay to determine whether a nanoparticle type is stable in flotation conditions; (3) an automated contact angle assay to reject nanoparticles that are not hydrophobic enough to induce efficient bubble-particle attachment, and; (4) a laboratory flotation test in sodium carbonate (pH~10) with the best nanoparticle candidates. The automated colloidal stability assay was based on the optical characterization of diluted nanoparticle dispersions in multiwell plates, yielding critical coagulation concentrations (CCCs) of sodium carbonate. To pass this screening test, the CCC of candidate nanoparticles must be greater than the effective carbonate concentration in commercial flotation cells. Since the nanoparticle size affects the intrinsic light scattering properties of the nanoparticles, two routes were developed. The colloid stability assay was suitable for nanoparticles ranging between 50 nm and 500 nm, since nanoparticle size. The automated contact angle assay used a miniature 16-well plate format where flat glass slides were exposed to 200 μL nanoparticle dispersions. The cationic nanoparticles formed a saturated adsorbed monolayer on the glass, and after rinsing and drying, the water contact angle was automatically measured. Effective nanoparticle candidates had contact angles greater than 50 degrees, a criterion developed with model experiments. During the development of the automated workflow platform, a series of nanoparticles with methyl-ended PEG-methacrylate monomers were prepared. Although the PEG chains greatly enhanced colloidal stability, the particles were too hydrophilic to be effective collectors. Interestingly, nanoparticles with long PEG chains acted as froth modifiers, giving wetter and more robust foams as well as increased entrainment of materials that did not adhere to bubbles. Conventional laboratory scale latex synthesis methodologies are far too inefficient to generate large library of candidate nanoparticles. Instead, we started with a few parent nanoparticle types and then used Click chemistry to generate a large range of surface chemistries. Specifically copper-mediated azide alkyne cycloaddition reaction was used to functionalize the surface of azide nanoparticles with different chemical groups, ranging from hydrophilic amine-terminated PEG chains, to hydrophobic hexane-terminated materials. The Click library exhibited an extensive range of critical coagulation concentrations and contact angle values. For example, for a given parent azide nanoparticle, the contact angles ranged from 62 to 101 degrees, depending upon the density and type of click reagent. A novel paper chromatographic method was developed for the quantitative determination surface azide. This assay was critical for determining the surface density of functional groups from the click reactions. Overall, high throughput screening techniques were designed and applied to the development of nanoparticle collectors for froth flotation. Automated screening assays of critical coagulation concentration and contact angle proved to be effective in obtaining flotation domain maps, and finding the most promising nanoparticle collectors for froth flotation. I believe the work in this thesis is one of the first reported uses of high throughput methodologies for the development of mineral flotation reagents. / Thesis / Doctor of Philosophy (PhD) / Novel cationic polystyrene nanoparticle collectors have been developed to be used as effective flotation collectors, aiming to recover challenging nickel sulfide ores that respond poorly to conventional molecular flotation collectors. However, optimizing nanoparticle flotation collectors is a challenge. This thesis presents a promising approach for discovering and characterizing novel nanoparticle collectors by using high throughput screening techniques and click chemistry. Development of nanoparticle libraries and automated screening assays of critical coagulation concentration and contact angle proved to be effective in obtaining flotation domain maps, and finding the most promising nanoparticle collectors for froth flotation.
316

Chemical Modification of Cellulose Esters for Oral Drug Delivery

Meng, Xiangtao 20 June 2016 (has links)
Polymer functional groups have critical impacts upon physical, chemical and mechanical properties, and thus affect the specific applications of the polymer. Functionalization of cellulose esters and ethers has been under extensive investigation for applications including drug delivery, cosmetics, food ingredients, and automobile coating. In oral delivery of poorly water-soluble drugs, amorphous solid dispersion (ASD) formulations have been used, prepared by forming miscible blends of polymers and drugs to inhibit crystallization and enhance bioavailability of the drug. The Edgar and Taylor groups have revealed that some cellulose omega-carboxyalkanoates were highly effective as ASD polymers, with the pendant carboxylic acid groups providing both specific polymer-drug interactions and pH-triggered release through swelling of the ionized polymer matrix. While a variety of functional groups such as hydroxyl and amide groups are also of interest, cellulose functionalization has relied heavily on classical methods such as esterification and etherification for appending functional groups. These methods, although they have been very useful, are limited in two respects. First, they typically employ harsh reaction conditions. Secondly, each synthetic pathway is only applicable for one or a narrow group of functionalities due to restrictions imposed by the required reaction conditions. To this end, there is a great impetus to identify novel reactions in cellulose modification that are mild, efficient and ideally modular. In the initial effort to design and synthesize cellulose esters for oral drug delivery, we developed several new methods in cellulose functionalization, which can overcome drawbacks of conventional synthetic pathways, provide novel cellulose derivatives that are otherwise inaccessible, and present a platform for structure-property relationship study. Cellulose omega-hydroxyalkanoates were previously difficult to access as the hydroxyl groups, if not protected, react with carboxylic acid/carbonyl during a typical esterification reaction or ring opening of lactones, producing cellulose-g-polyester and homopolyester. We demonstrated the viability of chemoselective olefin hydroboration-oxidation in the synthesis of cellulose omega]-hydroxyesters in the presence of ester groups. Cellulose esters with terminally olefinic side chains were transformed to the target products by two-step, one-pot hydroboration-oxidation reactions, using 9-borabicyclo[3.3.1]nonane (9-BBN) as hydroboration agent, followed by oxidizing the organoborane intermediate to a primary alcohol using mildly alkaline H2O2. The use of 9-BBN as hydroboration agent and sodium acetate as base catalyst in oxidation successfully avoided cleavage of ester linkages by borane reduction and base catalyzed hydrolysis. With the impetus of modular and efficient synthesis, we introduced olefin cross-metathesis (CM) in polysaccharide functionalization. Using Grubbs type catalyst, cellulose esters with terminally olefinic side chains were reacted with various CM partners including acrylic acid, acrylates and acrylamides to afford families of functionalized cellulose esters. Molar excesses of CM partners were used in order to suppress potential crosslinking caused by self-metathesis between terminally olefinic side chains. Amide CM partners can chelate with the ruthenium catalyst and cause low conversions in conventional solvents such as THF. While the inherent reactivity toward CM and tendency of acrylamides to chelate Ru is influenced by the acrylamide N-substituents, employing acetic acid as a solvent significantly improved the conversion of certain acrylamides. We observed that the CM products are prone to crosslinking during storage, and found that the crosslinking is likely caused by free radical abstraction of gamma-hydrogen of the alpha, beta-unsaturation and subsequent recombination. We further demonstrated successful hydrogenation of these alpha, beta-unsaturated acids, esters, and amides, thereby eliminating the potential for radical-induced crosslinking during storage. The alpha, beta-unsaturation on CM products can cause crosslinking due to gamma-H abstraction and recombination if not reduced immediately after reaction. Instead of eliminating the double bond by hydrogenation, we described a method to make use of these reactive conjugated olefins by post-CM thiol-Michael addition. Under amine catalysis, different CM products and thiols were combined and reacted. Using proper thiols and catalyst, complete conversion can be achieved under mild reaction conditions. The combination of the two modular reactions creates versatile access to multi-functionalized cellulose derivatives. Compared with conventional reactions, these reactions enable click or click-like conjugation of functional groups onto cellulose backbone. The modular profile of the reactions enables clean and informative structure-property relationship studies for ASD. These approaches also provide opportunities for the synthesis of chemically and architecturally diverse cellulosic polymers that are otherwise difficult to access, opening doors for many other applications such as antimicrobial, antifouling, in vivo drug delivery, and bioconjugation. We believe that the cellulose functionalization approaches we pioneered can be expanded to the modification of other polysaccharides and polymers, and that these reactions will become useful tools in the toolbox of polymer/polysaccharide chemists. / Ph. D.
317

Non-covalent Intermolecular Interactions in Polymer Design: Segmented Copolymers to Non-viral Gene Delivery Vectors

Buckwalter, Daniel James 01 June 2013 (has links)
Non-covalent intermolecular interactions play a large role in determining the properties of a given system, from segmented copolymers to interactions of functionalized polymers with non-viral nucleic acids delivery vehicles. The ability to control the intermolecular interactions of a given system allow for tailoring of that system to yield a desired outcome, whether it is a copolymers mechanical properties or the colloidal stability of a pDNA-delivery vector complex. Each chemical system relies on one or more types of intermolecular interaction such as hydrogen bonding, cooperative À-À stacking, electrostatic interactions, van der waals forces, metal-ligand coordination, or hydrophobic/solvophobic effects. The following research describes the tailoring of specific intermolecular interactions aimed at altering the physical properties of segmented copolymers and non-viral gene delivery vectors. Amide containing segmented copolymers relies heavily on hydrogen bonding intermolecular interactions for physical crosslinking to impart the necessary microphase separated morphology responsible for a copolymers physical properties. Amide containing hard segments are composed of various chemical structures from crystalline aramids to amorphous alkyl amides with each structure possessing unique intermolecular interactions. Variations to either of the copolymer segments alters the copolymers physical properties allowing for tuning of a copolymers properties for a particular application. The synthetic strategies, structure-property relationships, and physical properties of amide containing segmented copolymers are thoroughly reported in the literature. Each class of segmented copolymer that contain amide hydrogen bonding groups exhibits a wide range of tunable properties desirable for many applications. The segmented copolymers discussed here include poly(ether-block-amide)s, poly(ether ester amide)s, poly(ester amide)s, poly(oxamide)s, PDMS polyamides, and polyamides containing urethane, urea, or imide groups. The structure-property relationships (SPR) of poly(oxamide) segmented copolymers is not well understood with only one report currently found in literature. The effects of oxamide spacing in the hard segment and molecular weight of the soft segments in PDMS poly(oxamide) segmented copolymers demonstrated the changes in physical properties associated with minor structural variations. The optically clear PDMS poly(oxamide) copolymers possessed good mechanical properties after bulk polymerization of ethyl oxalate terminated PDMS oligomers with alkyl diamines or varied length. FTIR spectroscopy experiments revealed an ordered hydrogen bonding carbonyl stretching band for each copolymer and as the spacing between oxamide groups increased, the temperature at which the hard segment order was disrupted decreased. The increased spacing between oxamide groups also led to a decrease in the flow temperature observed with dynamic mechanical analysis. Copolymer tensile properties decrease with increased oxamide spacing as well as the hysteresis. The structure-property investigations of PDMS poly(oxamide) segmented copolymers showed that the shortest oxamide spacing resulted in materials with optimal mechanical properties. A new class of non-chain extended segmented copolymers that contained both urea and oxamide hydrogen bonding groups in the hard segment were synthesized. PDMS poly(urea oxamide) (PDMS-UOx) copolymers displayed thermoplastic elastomer behavior with enhanced physical properties compared to PDMS polyurea (PDMS-U) controls. Synthesis of a difunctional oxamic hydrazide terminated PDMS oligomer through a two-step end capping procedure with diethyl oxalate and hydrazine proved highly efficient. Solution polymerization of the oxamic hydrazide PDMS oligomers with HMDI afforded the desired PDMS-UOx segmented copolymer, which yielded optically clear, tough elastomeric films. Dynamic mechanical analysis showed a large temperature insensitive rubbery plateau that extended up to 186 ÚC for PDMS-UOx copolymers and demonstrated increased rubbery plateau ranges of up to 120 ÚC when compared to the respective PDMS-U control. The increase in thermomechanical properties with the presence of oxamide groups in the hard segment was due to the increased hydrogen bonding, which resulted in a higher degree of microphase separation. DMA, SAXS, and AFM confirmed better phase separation of the PDMS-UOx copolymers compared to PDMS-U controls and DSC and WAXD verified the amorphous character of PDMS-UOx. Oxamide incorporation showed a profound effect on the physical properties of PDMS-UOx copolymers compared to the controls and demonstrated promise for potential commercial applications. Two novel segmented copolymers based on a poly(propylene glycol) (PPG) that contained two or three oxamide groups in the hard segment were synthesized. Synthesis of non-chain extended PPG poly(trioxamide) (PPG-TriOx) and PPG poly(urea oxamide) (PPG-UOx) segmented copolymers utilized the two-step end-capping procedure with diethyl oxalate and hydrazine then subsequent polymerization with oxalyl chloride or HMDI, respectively. The physical properties of the PPG-TriOx and PPG-UOx copolymers were compared to those of PPG poly(urea) (PPG-U) and poly(oxamide) (PPG-Ox) copolymers. FTIR studies suggested the presence of an ordered hydrogen bonded hard segment for PGG-TriOx and PPG-Ox copolymers with PPG-TriOx possessing a lower energy ordered hydrogen bonding structure. PPG-UOx copolymers exhibited a larger rubbery plateau and higher moduli compared to PPG-U copolymers and also a dramatic increase in the tensile properties with the increased hydrogen bonding. The described copolymers provided a good example of the utility of this new step-growth polymerization chemistry for producing segmented copolymers with strong hydrogen bonding capabilities. Non-viral nucleic acid delivery has become a hot field in the past 15 years due to increased safety, compared to viral vectors, and ability to synthetically alter the material properties. Altering a synthetic non-viral delivery vector allows for custom tailoring of a delivery vector for various therapeutic applications depending on the target disease. The types of non-viral delivery vectors are diverse, however the lack of understanding of the endocytic mechanisms, endosomal escape, and nucleic acid trafficking is not well understood. This lack of understanding into these complex processes limits the effective design of non-viral nucleic acid delivery vehicles to take advantage of the cellular machinery, as in the case of viral vectors. Mechanisms for cellular internalization of polymer-nucleic acid complexes are important for the future design of nucleic acid delivery vehicles. It is well known that the mammalian cell surface is covered with glycosaminoglycans (GAG) that carry a negative charge. In an effort to probe the effect of GAG charge density on the affinity of cationic poly(glcoamidoamine) (PGAA)-pDNA complexes, quartz crystal microbalance was employed to measure the mass of GAGs that associated with a polyplex monolayer. Affinity of six different GAGs that varied in the charge density were measured for polyplexes formed with poly(galactaramidopentaethylenetetramine) (G4) cationic polymers and pDNA. Results showed that the affinity of GAGs for G4 polyplexes was not completely dependent on the electrostatic interactions indicating that other factors contribute to the GAG-polyplex interactions. The results provided some insight into the interactions of polyplexes with cell surface GAGs and the role they play in cellular internalization. Two adamantane terminated polymers were investigated to study the non-covalent inclusion complexation with click cluster non-viral nucleic acid delivery vehicles for passive targeting of the click cluster-pDNA complexes (polyplex). Incorporation of adamantyl terminated poly(ethylene glycol) (Ad-PEG) and poly(2-deoxy-2-methacrylamido glucopyranose) (Ad-pMAG) polymers into the polyplex formulation revealed increased colloidal stability under physiological salt concentrations. Ad-pMAG polyplexes resulted in lower cellular uptake for HeLa cells and not two glioblastoma cell lines indicating the pMAG corona imparts some cell line specificity to the polyplexes. Ad-pMAG provided favorable biological properties when incorporated into the polyplexes as well as increased polyplex physical properties. / Ph. D.
318

Site-specific biomolecule modification for directed surface attachment / Ortsspezifische Biomolekülmodifikation zur gezielten Oberflächenanbindung

van Dorp, Joel January 2024 (has links) (PDF)
Site-directed bioorthogonal conjugation techniques have substantially advanced research in numerous areas. Their exceptional value reflects in the extent of applications, that have been realized with spacial-controlled bioorthogonal reactions. Specific labeling of surfaces, proteins, and other biomolecule allows for new generations of drug delivery, tracking, and analyzing systems. With the continuous advance and refinement of available methods, this field of research will become even more relevant in the time to come. Yet, as individual as the desired purpose is, as different can be the most suitable modification strategy. In this thesis, two different bioconjugation approaches, namely CuAAC and factor XIIIa mediated ligation, are used in distinct application fields, featuring eGFP as a model protein showcasing the advantages as well as the challenges of each technique. The introduction of a unique accessible functionality is the most critical feature of a site-specific reaction, and the first considerable hurdle to clear. While most surfaces, peptides, or small molecules might require less expenditure to modulate, equipping large biomolecules like proteins with additional traits requires careful consideration to preserve the molecule’s stability and function. Therefore, the first section of this project comprises the engineering of eGFP via rational design. Initially, wild-type eGFP was subcloned, expressed, and characterized to serve as a reference value for the designed variants. Subsequently, eGFP was mutated and expressed to display a recognition site for factor XIIIa. Additionally, a second mutant harbored a TAG-codon to enable amber codon suppression and consequently the incorporation of the alkyne bearing unnatural amino acid Plk to support a CuAAC reaction. Fluorescence spectroscopy was used to confirm that the fluorescent properties of all expressed muteins were identically equal to wild-type eGFP, which is a reliable marker for the intact barrel structure of the protein. Trypsin digestion and HPLC were deployed to confirm each protein variant's correct sequence and mass. The second part of this work focuses on the conjugation of cargo molecules deploying the chosen approaches. Solid-phase peptide synthesis was used to create a peptide that served as a lysine donor substrate in the crosslinking mechanism of FXIIIa. Additionally, the peptide was provided with a cysteine moiety to allow for highly flexible and simple loading of desired cargo molecules via conventional thiol-Michael addition, thus establishing an adaptive labeling platform. The effective ligation was critically reviewed and confirmed by monitoring the exact mass changes by HPLC. Protocols for attaching payloads such as biotin and PEG to the linker peptide were elaborated. While the biotin construct was successfully conjugated to the model protein, the eGFP-PEG linkage was not achieved judging by SDS-PAGE analysis. Furthermore, featuring isolated peptide sequences, the properties of the FXIIIa-mediated reaction were characterized in detail. Relative substrate turnover, saturation concentrations, by-product formation, and incubation time were comprehensively analyzed through HPLC to identify optimal reaction conditions. CuAAC was successfully used to label the Plk-eGFP mutein with Azide-biotin, demonstrated by western blot imaging. Within the last part of this study, the application of the conjugation systems was extended to different surfaces. As regular surfaces do not allow for immediate decoration, supplementary functionalization techniques like gold-thiol interaction and silanization on metal oxides were deployed. That way gold-segmented nanowires and Janus particles were loaded with enoxaparin and DNA, respectively. Nickel and cobalt nanowires were modified with silanes that served as linker molecules for subsequent small molecule attachment or PEGylation. Finally, the eGFP muteins were bound to a particle surface in a site-specific manner. Beads displaying amino groups were utilized to demonstrate the effective use of FXIIIa in surface modification. Moreover, the bead’s functional moieties were converted to azides to enable CuAAC “Click Chemistry” and direct comparison. Each modification was analyzed and confirmed through fluorescence microscopy. / Techniken zur ortsspezifischen bioorthogonalen Konjugation von Biomolekülen haben die Forschung in zahlreichen Bereichen erheblich vorangebracht. Ihr außerordentlicher Wert spiegelt sich in der Vielzahl der Anwendungen wider, die mit bioorthogonalen Reaktionen realisiert werden konnten. Die kontrollierte Bestückung von Oberflächen, Proteinen und anderen Biomolekülen ermöglicht neue Generationen von Systemen zur Arzneimittelapplikation als auch zu Tracking- und Analyseverfahren. Mit der kontinuierlichen Weiterentwicklung und Verfeinerung der verfügbaren Methoden wird dieses Forschungsgebiet in Zukunft noch mehr an Bedeutung gewinnen. Doch so individuell wie der gewünschte Zweck ist, so unterschiedlich kann auch die am besten geeignete Modifikationsstrategie sein. In dieser Arbeit werden zwei verschiedene Biokonjugationsansätze, nämlich CuAAC und Faktor-XIIIa-vermittelte Ligation, in unterschiedlichen Anwendungsbereichen eingesetzt, wobei eGFP als Modellprotein dient, um sowohl die Vorteile als auch die Herausforderungen der jeweiligen Technik aufzuzeigen. Die Einführung einer genau abgrenzbaren Funktionalität ist das wichtigste Merkmal einer ortsspezifischen Reaktion und die erste große Hürde, die es zu nehmen gilt. Während die meisten Oberflächen, Peptide oder kleinen Moleküle mit geringem Aufwand moduliert werden können, erfordert das Ausstatten von Proteinen mit zusätzlichen Merkmalen sorgfältige Überlegung und weitreichende Kenntnis, um die Stabilität und Funktion der Molekülstruktur zu erhalten. Der erste Abschnitt dieses Projekts umfasst daher das Protein-Engineering von eGFP durch rationales Design. Zunächst wurde der Wildtyp von eGFP subkloniert, exprimiert und charakterisiert, um als Referenzwert für die entworfenen Varianten zu dienen. Anschließend wurde eGFP so mutiert und exprimiert, dass es eine Erkennungsstelle für Faktor XIIIa aufweist. Zusätzlich enthielt eine zweite Mutante ein TAG-Codon, um die Unterdrückung des Amber-Codons und damit den Einbau der Alkin-tragenden unnatürlichen Aminosäure Plk zu ermöglichen, um wiederum eine CuAAC-Reaktion zu unterstützen. Mit Hilfe von Fluoreszenzspektroskopie wurde bestätigt, dass die Fluoreszenzeigenschaften aller exprimierten Muteine identisch mit denen des Wildtyps eGFP sind, was ein zuverlässiger Marker für die intakte Barrel-Struktur des Proteins ist. Trypsinverdau und HPLC wurden eingesetzt, um die korrekte Sequenz und Masse der einzelnen Proteinvarianten zu bestätigen. Der zweite Teil dieser Arbeit konzentriert sich auf die Konjugation von „Cargo-Molekülen“ unter Verwendung der gewählten Ansätze. Mittels Festphasen-Peptidsynthese wurde ein Peptid hergestellt, das als Lysin-Donor-Substrat im Vernetzungsmechanismus von FXIIIa diente. Zusätzlich wurde das Peptid mit einem Cystein-Element versehen, um eine hochflexible und einfache Beladung mit gewünschten Frachtmolekülen durch konventionelle Thiol-Michael-Addition zu ermöglichen und so eine adaptive Koppelungsplattform zu schaffen. Die effektive Ligation wurde durch die Überwachung der genauen Massenänderungen mittels HPLC kritisch überprüft und bestätigt. Es wurden Protokolle für die Anbringung von Nutzlasten wie Biotin und PEG an das Linker-Peptid ausgearbeitet. Während das Biotin-Konstrukt erfolgreich an das Modellprotein konjugiert wurde, konnte die eGFP-PEG-Bindung nach Auswertung der SDS-PAGE-Analyse nicht erreicht werden. Darüber hinaus wurden anhand der isolierten Peptidsequenzen die Eigenschaften der FXIIIa-vermittelten Reaktion im Detail charakterisiert. Relativer Substratumsatz, Sättigungskonzentrationen, Nebenproduktbildung und Inkubationszeit wurden mittels HPLC umfassend analysiert, um optimale Reaktionsbedingungen zu ermitteln. CuAAC wurde erfolgreich zur Markierung des Plk-eGFP-Muteins mit Azid-Biotin eingesetzt, was durch Western-Blot-Darstellung nachgewiesen wurde. Im letzten Teil dieser Arbeit wurde die Anwendung der Konjugationssysteme auf verschiedene Oberflächen übertragen. Da normale Oberflächen keine unmittelbare Dekoration erlauben, wurden zusätzliche Funktionalisierungstechniken wie Gold-Thiol-Wechselwirkung und Silanisierung auf Metalloxiden eingesetzt. Auf diese Weise wurden goldsegmentierte Nanowires und Januspartikel mit Enoxaparin bzw. DNA beladen. Nickel- und Kobalt-Nanowires wurden mit Silanen modifiziert, die als Verbindungsmoleküle für die anschließende Anlagerung kleiner Moleküle oder PEGylierung dienten. Schließlich wurden die eGFP-Muteine ortsspezifisch an eine Partikeloberfläche gebunden. Beads mit Aminogruppen wurden verwendet, um den effektiven Einsatz von FXIIIa bei der Oberflächenmodifikation zu demonstrieren. Darüber hinaus wurden die funktionellen Einheiten der Beads in Azide umgewandelt, um eine CuAAC-„Klickchemie" und somit einen direkten Vergleich zu ermöglichen. Jede Modifikation wurde mit Hilfe der Fluoreszenzmikroskopie analysiert und bestätigt.
319

Amphiphilic block copolymer self-assemblies of poly(NVP)-b-poly(MDO-co-vinyl esters) : tunable dimensions and functionalities

Hedir, G.G., Pitto-Barry, Anaïs, Dove, A.P., O'Reilly, R.K. 10 October 2015 (has links)
No / Functional, degradable polymers were synthesized via the copolymerization of vinyl acetate (VAc) and 2-methylene-1,3-dioxepane (MDO) using a macro-xanthate CTA, poly(N-vinylpyrrolidone), resulting in the formation of amphiphilic block copolymers of poly(NVP)-b-poly(MDO-co-VAc). The behavior of the block copolymers in water was investigated and resulted in the formation of self-assembled nanoparticles containing a hydrophobic core and a hydrophilic corona. The size of the resultant nanoparticles was able to be tuned with variation of the hydrophilic and hydrophobic segments of the core and corona by changing the incorporation of the macro-CTA as well as the monomer composition in the copolymers, as observed by Dynamic Light Scattering, Static Light Scattering, and Transmission Electron Microscopy analyses. The concept was further applied to a VAc derivative monomer, vinyl bromobutanoate, to incorporate further functionalities such as fluorescent dithiomaleimide groups throughout the polymer backbone using azidation and “click” chemistry as postpolymerization tools to create fluorescently labeled nanoparticles. / University of Warwick, BP, The Royal Society
320

Ecology and management of wireworms (Coleoptera: Elateridae) in conventional and organic production systems

Nikoukar, Atoosa 12 June 2024 (has links)
Wireworms are the subterranean larval stage of click beetles (Coleoptera: Elateridae), generalist herbivores that feed on a wide range of crops and cause serious damage. Wireworm management is challenging due to their long life cycle, subterranean habitat, wide range of host plants, and lack of effective chemical approach in most crops. Thus, developing an effective alternative control approach is an urgent need. The overall aim of this research study was to evaluate alternative [to insecticides] tactics that could be used as components of effective IPM strategies against wireworms. In Chapter 1 we provide an overview of wireworm's biology and management practices. In Chapter 2 we focused on biological control to evaluate the efficacy of entomopathogenic nematodes and fungi as single and mixed application against Limonius californicus and L. infuscatus in organic vegetable farms. The results showed the higher efficacy of commercial EPN, Steinernema feltiae, against Limonius species than entomopathogenic fungi. In Chapter 3, we focused on cultural control as a component of integrated pest management for wireworm control. We evaluated the efficacy of brown and yellow mustard and their byproducts, including defatted seed meal and seed meal concentrated extract against Limonius spp. Our finding indicated the effectiveness of brown mustard concentrated extract on reducing the wireworm population. However, it has a negative impact on the field-residing entomopathogenic nematodes. In Chapter 4, in the component of cultural control, we evaluated the wireworm, L. californicus, preference to three different crops, pea, bean, and wheat, for identifying an effective trap crop. We also quantified CO2 and organic volatile compounds released from each plant's root and evaluated the wireworm response toward the synthetic volatiles. Detailed results are provided in chapter 4. Finally, we looked at the novel new technology of RNA interference to find the effective target genes in wireworms for application as bioinsecticides and/or transgenic plants to control wireworms. In the concluding chapter, Chapter 6, we summarized our findings on the efficacy of different management tactics, biological, cultural, and molecular, to control Limonius species in cereals and organic production systems. / Doctor of Philosophy / Wireworms, the larval stage of click beetles (Coleoptera: Elateridae), are belowground pests that feed on a wide range of crops such as potatoes, cereals, vegetables, and sugar beet and can cause serious economic damage. Wireworm management is challenging because they live for long periods in the soil and feed on almost all crops. Moreover, most insecticides available for wireworm control, such as neonicotinoids, are not effective in reducing wireworm populations and just serve as feeding deterrents. Thus, developing an effective alternative control approach is an urgent need. The overall aim of this research study was to evaluate alternative [to insecticides] tactics that could be used as components of effective IPM strategies against wireworms. In Chapter 1 we provide an overview of wireworm's biology and management practices. In Chapter 2 we focused on biological control to evaluate the efficacy of entomopathogenic nematodes and fungi when applied individually and in combination with each other against sugar beet wireworm in organic vegetable farms. The results showed the commercial nematode, Steinernema feltiae was more effective in reducing sugar beet wireworm than fungi. In Chapter 3, we focused on cultural control as a component of integrated pest management for wireworm control. We evaluated the efficacy of brown and yellow mustard and their byproducts including defatted seed meal and seed meal concentrated extract against sugar beet wireworms in spring wheat. Our finding indicated the effectiveness of brown mustard concentrated extract in reducing the wireworm population. In Chapter 4, in the component of cultural control, we evaluated the sugar beet wireworm preference for three different crops, pea, bean, and wheat, for identifying an effective trap crop. We also quantified CO2 and organic volaille compounds released from each plant's root and evaluated the wireworm response toward the synthetic volatiles. Detailed results are provided in chapter 4. Finally, we looked at the novel new technology of RNA interference to find the effective target genes in wireworms for application as bioinsecticides and/or transgenic plants to control wireworms. In the concluding chapter, Chapter 6, we summarized our findings on the efficacy of different management tactics, biological, cultural, and molecular, to control wireworm species in cereals and organic production systems.

Page generated in 0.0358 seconds