Global ETD Search

311	Dewetting of Polystyrene Thin Films on Organosilane Modified Surfaces Choi, Sung-Hwan 18 May 2006 (has links) No description available. Engineering, Chemical Polymer thin film Dewetting Surface Modification Surface Energy Organosilane Dewetting kinetics Dewetting suppression Rim instability Dynamic contact angle Aminopropyltriethoxysilane
312	Surface-Modified Phthalocyanine-Based Two-Dimensional Conjugated Metal–Organic Framework Films for Polarity-Selective Chemiresistive Sensing Wang, Mingchao, Zhang, Zhe, Zhong, Haixia, LI, Wei, Hambsch, Mike, Zhang, Panpan, Wang, Zhiyong, St. Petkov, Petko, Heine, Thomas, Mannsfeld, Stefan C. B., Feng, Xinliang, Dong, Renhao 03 November 2022 (has links) Surface-modification of phthalocyanine-based two-dimensional conjugated metal-organic framework (2D c-MOF) films by grafting aliphatic alkyl chains is developed for achieving high-performance polarity-selective chemiresistive sensing toward humidity and polar alcohols. 2D conjugated metal–organic frameworks (2D c-MOFs) are emerging as electroactive materials for chemiresistive sensors, but selective sensing with fast response/recovery is a challenge. Phthalocyanine-based Ni2[MPc(NH)8] 2D c-MOF films are presented as active layers for polarity-selective chemiresisitors toward water and volatile organic compounds (VOCs). Surface-hydrophobic modification by grafting aliphatic alkyl chains on 2D c-MOF films decreases diffused analytes into the MOF backbone, resulting in a considerably accelerated recovery progress (from ca. 50 to ca. 10 s) during humidity sensing. Toward VOCs, the sensors deliver a polarity-selective response among alcohols but no signal for low-polarity aprotic hydrocarbons. The octadecyltrimethoxysilane-modified Ni2[MPc(NH)8] based sensor displays high-performance methanol sensing with fast response (36 s)/recovery (13 s) and a detection limit as low as 10 ppm, surpassing reported room-temperature chemiresistors. info:eu-repo/classification/ddc/540 ddc:540
313	Surface-Modified Phthalocyanine-Based Two-Dimensional Conjugated Metal–Organic Framework Films for Polarity-Selective Chemiresistive Sensing Wang, Mingchao, Zhang, Zhe, Zhong, Haixia, Li, Wei, Hambsch, Mike, Zhang, Panpan, Wang, Zhiyong, St. Petkov, Petko, Heine, Thomas, Mannsfeld, Stefan C. B., Feng, Xinliang, Dong, Renhao 03 November 2022 (has links) This corrigendum corrects an omission from the Acknowledgement section. The research leading to the results published in this manuscript was also supported by the project CALIPSOplus under Grant Agreement 730872 from the EU Framework Programme for Research and Innovation HORIZON 2020. info:eu-repo/classification/ddc/540 ddc:540
314	Highly Efficient One-Step Protein Immobilization on Polymer Membranes Supported by Response Surface Methodology Schmidt, Martin, Abdul Latif, Amira, Prager, Andrea, Gläser, Roger, Schulze, Agnes 03 April 2023 (has links) Immobilization of proteins by covalent coupling to polymeric materials offers numerous excellent advantages for various applications, however, it is usually limited by coupling strategies, which are often too expensive or complex. In this study, an electron-beambased process for covalent coupling of the model protein bovine serum albumin (BSA) onto polyvinylidene fluoride (PVDF) flat sheet membranes was investigated. Immobilization can be performed in a clean, fast, and continuous mode of operation without any additional chemicals involved. Using the Design of Experiments (DoE) approach, nine process factors were investigated for their influence on graft yield and homogeneity. The parameters could be reduced to only four highly significant factors: BSA concentration, impregnation method, impregnation time, and electron beam irradiation dose. Subsequently, optimization of the process was performed using the Response Surface Methodology (RSM). A one-step method was developed, resulting in a high BSA grafting yield of 955 mgm−2 and a relative standard deviation of 3.6%. High efficiency was demonstrated by reusing the impregnation solution five times consecutively without reducing the final BSA grafting yield. Comprehensive characterization was conducted by X-ray photoelectron spectroscopy (XPS), Fourier-transform infrared spectroscopy (FTIR), and measurements of zeta potential, contact angle and surface free energy, as well as filtration performance. In addition, mechanical properties and morphology were examined using mercury porosimetry, tensile testing, and scanning electron microscopy (SEM). info:eu-repo/classification/ddc/540 ddc:540
315	OSTE Microfluidic Technologies for Cell Encapsulation and Biomolecular Analysis Zhou, Xiamo January 2017 (has links) In novel drug delivery system, the encapsulation of therapeutic cells in microparticles has great promises for the treatment of a range of health con- ditions. Therefore, the encapsulation material and technology are of great importance to the validity and efficiency of the advanced medical therapy. Several unsolved challenges in regards to versatile microparticle synthesis ma- terials and methods form the main obstacle for a translation of novel cell therapy concepts from research to clinical practice. Thiol-ene based polymer systems have emerged and gained great popular- ity in material development in general and in biomedical applications specif- ically. The thiol-ene platform is broad and therefore of interest for a variety of applications. At the same time, many aspects of this material platform are largely unexplored, for example material and manufacturing technology developments for microfluidic applications . In this Ph.D. thesis, thiol-ene materials are explored for use in cell encap- sulation. The marriage of these two technology fields breeds the possibility for a novel microfluidic cell encapsulation approach using a novel encapsulation material. To this end, several new manufacturing technologies for thiol-ene and thiol-ene-epoxy droplet microfluidic devices were developed. Moreover, core-shell microparticle synthesis for cell encapsulation based on a novel co- synthesis concept using a thiol-ene based material was developed and inves- tigated. Finally, a thiol-ene-epoxy system was also used for the formation of microwells and microchannels that improve protein analysis on microarrays. The first part of the thesis presents the background and state-of-the-art technologies in regards to cell therapy, microfluidics, and thiol-ene based ma- terials. In the second part of the thesis, a novel manufacturing approach of thiol-ene-epoxy material as well as core-shell particle co-synthesis in micro- fluidics using thiol-ene based material are presented and characterized. The third part of the thesis presents the cell viability studies of encapsulated cells using the novel encapsulation material and method. In the final part of the thesis, two applications of thiol-ene-epoxy gaskets for protein detection mi- croarrays are presented. / Inkapsling av levande celler i mikrokapslar för terapeutiska ändamål är mycket lovande för frmatida behandling av många olika sjukdomar. Emeller- tid är en behandlings effektivitet i hög grad beroende av vilka material som används för inkapsling och vilken teknisk lösning som används för att ska- pa mikrokapslarna. För närvarande återstår det många utmaningar för att omvandla grundforskningresultat till klinisk verklighet, vilken kräver mer än- damålsenliga tillvägagångssätt för att tillverka mikrokapslar i material som är kompatibla med användningsområdena. De senaste åren har tiol-en baserade polymerer har blivit mycket använda för materialutveckling i stort och för biomedicinska tillämpningar i synnerhet. Med tiol-en kemi kan en mycket stor mängd helt olika syntetiska material framställas, vilket gör tiol-ener intressanta för en mängd applikationer. För närvarande är dock mycket inom denna materialklass outforskat, t.ex. inom material och tillverkningmetodik för mikrofluidiktillämpningar. I denna avhandling används tiol-ener för cellinkapsling. Sammanslagning av dessa teknologier möjliggör en ny typ av cellinkapsling med nya materi- alegenskaper. En mängd olika tillverkningssätt där tiol-en eller tiol-en-epoxi används för droplet-mikrofluidiksystem utvecklades. Core-shell mikrokapsel- syntes för cell-inkapsling baserat på en ny metod för samtidig syntes av både core och shell utvecklades och karaktäriserades. Slutligen utvecklades ett tiol- en-epoxi system för enkel integrering med proteinmikroarrayer på objektsglas. I avhandlingens första del presenteras bakgrund och dagens bästa teknolo- gier för terapeutisk cellinkapsling, mikrofluidik och tiol-en baserade material. I avhandlingens andra del presenteras en ny tillverkningsmetod för mikro- strukturerade tiol-en-epoxi artiklar och samtidig syntes av core och shell för mikrokapslar med användande av mikrofluidik. I den tredje delen presenteras cellöverlevandsstudier för de celler som inkapslats med de nya materialen och de nyutvecklade metoderna. I den avslutande delen beskrivs två specifika fall där tiol-en-epoxi komponenter används för proteindetektion och mikroarrayer. / <p>QC 20171122</p> Microfluidics microfabrication cell encapsulation core-shell particle microparticle synthesis off-stoichiometry-thiol-ene OSTE OSTE+ lab-on-a-chip surface modification core-shell particle co-synthesis microar- ray micromixer bonding surface modification droplet microfluidics protein screening. Mikrofluidik mikrofabrikation cellinkapsling cores-shell kap- sel mikrokapselsyntes lab-on-chip ickestökiometrisk tiol-en OSTE OSTE+ ytmodifiering samtidig syntes av core-shellkapslar mikroarray mikromixer sammanfogning dropletmikrofluidik proteindetektion. Engineering and Technology Teknik och teknologier
316	Silica attached polymers and ligands for the selective removal of metal ions and radionuclides from aqueous solutions Holt, James D. January 2014 (has links) Surface functionalised silica materials have been prepared, followed by the extensive testing of their ability to remove metal ions from aqueous solutions. Modifications include ligand attachment and polymer grafting from the silica surface whilst the metals tested range from first row transition metals right through to the lanthanides and actinides. Characterisation of the materials produced has been of paramount importance for the understanding of the modification process and this is also extensively discussed. Atom transfer radical polymerisation (ATRP) has been used as the primary polymerisation method. Following polymerisation of 2-hydroxyethyl methacrylate (HEMA), post functionalisation was attempted. However, this was found to cause severe cross-linking and all attempts to attach ligands to this failed. Nonetheless, this process was transferred to grafting from silica surfaces and a novel approach to the characterisation of this material was implemented. (3-aminopropyl) triethoxysilane (APTES) was reacted with multiple forms of silica, primarily ZEOprep silica (average particle size 71.48 πm) and fumed silica (0.007 μm). This produced an amine coated surface to which 2-bromoisobutyryl bromide (BIBB) was attached, providing the required surface for radical polymerisation to proceed with a selected monomer. Solid State Nuclear Magnetic Resonance (SSNMR) has been utilised as the major characterisation technique for each step, leading to significant understanding of how this occurs. Thermogravimetric Analysis (TGA) and elemental analysis has supported this method at each stage whilst also enabling one to calculate the moles of APTES present, per gram of APTES-functionalised silica. For the ZEOprep silica this was calculated to be at up to 1.51 x 10-3 mol g-1 and for the fumed silica 1.63 x 10-3 mol g-1. As well as testing the selective nature of these materials, solutions of individual ions and radionuclides were used to measure the effectiveness of the materials for a specific ion. Rd values for these metals ions including solutions of Co(II), Ni(II), Cu(II), Cd2+, Eu(III) and [UO2]2+ have reached values ranging from 7.49 x 104 mL g-1 to as high as 2.17 x 109 mL g-1. These values are regarded as outstanding by other groups that have reported similar results and these are discussed in the report. This range includes values that were observed when competing Na+ and Ca2+ ions were present at 0.5 % and 1 % (w/w). pH testing was also investigated with the materials using a solution of europium ions to determine the most effective range and this was found to fall between pH 4 and 5. X-ray Photoelectron Spectroscopy (XPS) has been utilised to help gain an understanding of the binding between Cu(II) ions and APTES, suggesting that copper ions bind with oxygen atoms closer to the silica surface as well as the nitrogen atoms at the end of the ligand. Meanwhile STEM (Scanning Transmission Electron Microscope) has been used to show how effectively the surface area of the material is used by imaging the europium ions over a sample of APTES-functionalised fumed silica. Ligands and polymers have been focussed on to build a catalogue of functional materials and this has been achieved in collaboration with PhosphonicS Ltd. The most significant finding from these selective investigations was that uranyl ions were found to be the most readily removed. Cu(II) and Eu(III) ions were also removed relatively effectively whilst Co(II), Ni(II), Zn2+ and Cd2+ proved the most challenging but certainly not impossible. [UO2]2+ concentrations were reduced from 17.1 ppm to 1.6 ppm after 4 weeks with use of the ligand SEA (2-aminoethyl sulfide ethyl silica), even with six other metal ions present at similar initial concentrations and a starting pH of 4.67 by adding just 50 mg of the material to a 45 mL solution. 541
317	Großflächige Oberflächenmodifizierung mittels Plasmatechnologie bei Atmosphärendruck / Large-scale surface modification by means of atmospheric pressure plasma technology Kotte, Liliana 23 May 2016 (has links) (PDF) Die Oberflächenmodifizierung mittels Plasma bei Atmosphärendruck ist eine bekannte und etablierte Technologie. Sie gewinnt aktuell aufgrund der rasant wachsenden Markt- und Entwicklungsnachfrage im Automotive- und Luftfahrttechnikbereich mit deren hohen Anforderungen an Neuentwicklungen auf dem Gebiet der Leichtbau-Komposite immer mehr an Bedeutung. Forderungen, die oftmals an die eingesetzten Plasmaquellen gestellt werden, sind (a) die Behandlungsmöglichkeit großer Oberflächen bei (b) gleichzeitig variierenden Arbeitsabständen von einigen Zentimetern für die Bearbeitung fertiger Bauteilgruppen, (c) die Einsatzmöglichkeit verschiedenster Prozessgase für die Erzeugung einer Vielzahl von spezifischen funktionellen Oberflächengruppen sowie (d) die Integration der Plasmaquelle in die Prozesskette z. B. in Form der Installation an einem Roboterarm. Diese Anforderungen werden derzeit nur durch die LARGE-Plasmaquelle (Long Arc Generator), eine lineare Gleichspannungslichtbogen-Plasmaquelle, erfüllt. Mit ihr sind Flächen auf einer Breite bis zu 350 mm bei Prozessgeschwindigkeiten von bis zu 100 m min-1 bearbeitbar. Ziel der vorliegenden Arbeit war es, die Einsatzgebiete der LARGE-Plasmatechnologie aufzuzeigen und sie zur Industriereife für großflächige Oberflächenmodifizierungen zu entwickeln. Dazu erfolgte eine Optimierung und Weiterentwicklung der Plasmaquelle, konkret dem Elektroden- und Gasverteilerdesign sowie der Stromversorgung. So wurde dem Stromgenerator erstmalig ein PPS-Modul (Puls-Power-Supply-Modul) zur Reglung des Stromes zugeschaltet. Mit diesem wird der Lichtbogenstrom in eine hochfrequente 20 kHz-Schwingung versetzt. Der Strom schwankt dadurch um eine Amplitude von ± 5 – 20 A. Das verhindert ein Festbrennen des Lichtbogenfußpunktes auf der Elektrode und führt so zur Stabilisierung des Lichtbogens. Durch die Plasmaquellenoptimierung und –weiterentwicklung konnte der Argonanteil vollständig reduziert und erstmals 100 % Druckluft als Plasmagas verwendet werden. Um das Potenzial der LARGE-Plasmaquelle für die großflächige Oberflächenmodifizierung zu demonstrieren, wurden vier konkrete Anwendungen aus der Industrie ausgewählt. So wurden zum einen zwei Beispiele aus der Luftfahrttechnik zum strukturellen Kleben mit epoxidharzbasiertem Klebstoffsystem betrachtet und systematisch untersucht: die SiO2-Schichtabscheidung zur Verbesserung der Haftung der Titanlegierungen Ti-6Al-4V und Ti-15V-3Cr-3Sn-3Al und die Plasmabehandlung von CFK zur Umwandlung von silikonbasierten Trennmittelrückständen zur Verbesserung der Adhäsion beim Kleben. Es konnte gezeigt werden, dass mit der LARGE-Plasmatechnologie zwei Materialgruppen erfolgreich plasmabehandelt werden können. Damit ist sie derzeit das einzige Plasmaverfahren bei Atmosphärendruck, mit dem SiO2-Haftvermittlerschichten auf Titanlegierungen sowie eine Trennmittelmodifizierung auf CFK-Oberflächen mit einem variablen Arbeitsbereich von 2 - 6 cm erfolgreich abgeschieden bzw. umgewandelt werden können. Zum anderen wurden zwei Beispiele aus dem Automotivbereich untersucht und der erfolgreiche Einsatz der LARGE-Plasmatechnologie demonstriert: die Plasmafunktionalisierung von Polypropylen zur Verbesserung der Adhäsion von wasserbasierten Lacken sowie die Plasmafeinreinigung und Entfettung von Aluminium. Auf der Grundlage der Ergebnisse dieser Arbeit zur großflächigen Atmosphärendruck-Oberflächenmodifizierung wurde ein Mobiler LARGE für den Einsatz vor Ort aufgebaut. Mit ihm wird die Marktreife und Konkurrenzfähigkeit dieser Plasmaquelle demonstriert. Atmosphärendruck Plasmatechnologie Oberflächenmodifizierung SiO2-Haftvermittlerschichten Plasmafeinreinigung CFK-Plasmamodifizierung PP-Plasmamodifizierung atmospheric pressure plasma technology surface modification SiO2 adhesion films plasma fine cleaning plasma modification of cfrp plasma modification of polypropylene ddc:620 rvk:ZM 7680
318	Experimental Studies on CO2 Capture Using Absorbent in a Polypropylene Hollow Fiber Membrane Contactor Lu, Yuexia January 2011 (has links) In recent years, membrane gas absorption technology has been considered as one of the promising alternatives to conventional techniques for CO2 capture due to its favorable mass transfer performance. As a hybrid approach of chemical absorption and membrane separation, it exhibits a number of advantages, such as operational flexibility, compact structure, high surface-area-to-volume ratio, linear scale up, modularity and predictable performance. One of the main challenges of membrane gas absorption technology is the membrane wetting by absorbent over prolonged operating time, which may significantly decrease the mass transfer coefficients of the membrane module. In this thesis, the experimental was set up to investigate the dependency of CO2 removal efficiency and mass transfer rate on various operating parameters, such as the gas and liquid flow rates, absorbent type and concentration and volume fraction CO2 at the feed gas inlet. In addition, the simultaneous removal of SO2 and CO2 was investigated to evaluate the feasibility of simultaneous desulphurization and decarbonization in the same membrane contactor. During 14 days of continuous operation, it was observed that the CO2 mass transfer rate decreased significantly following the operating time, which was attributed to partial membrane wetting. To better understand the wetting mechanism of membrane pores during their prolonged contact with absorbents, immersion experiments for up to 90 days were carried out. Various membrane characterization methods were used to illustrate the wetting process before and after the membrane fibers were exposed to the absorbents. The characterization results showed that the absorbent molecules diffused into the polypropylene polymer during the contact with the membrane, resulting in the swelling of the membrane. In addition, the effects of operating parameters such as immersion time and absorbent type on the membrane wetting were investigated in detail. Finally, based on the analysis results, methods to smooth the membrane wetting were discussed. It was suggested that improving the hydrophobicity of polypropylene membrane by surface modification may be an effective way to improve the long-term operating performance of membrane contactors. Therefore, the polypropylene hollow fibers were modified by depositing a thin superhydrophobic coating on the membrane surface to improve their hydrophobicity. The mixture of cyclohexanone and methylethyl ketone was considered as the best non-solvent to achieve the fiber surface with good homogeneity and acceptably high hydrophobicity. In the long-period operation, the modified membrane contactor exhibited more stable and efficient performance than the untreated one. Hence, surface treatment provides a feasibility of improving the system stability for CO2 capture from the view of long-term operation. / En av de tekniker som under senare framhållits som ett lovande alternativ till konventionell CO2-avskiljning är membran-gas-absorptionstekniken på grund av god prestanda vad gäller masstransport. Det blandade angreppssättet med både kemisk absorption och membranseparation har en rad fördelar, såsom driftflexibilitet, kompakt konstruktion, högt yt-volymsförhållande, linjär uppskalning, modularitet och förutsägbar prestanda. En av de viktigaste utmaningarna för membran-gas-absorptionstekniken är vätningen av membranet med absorbenten under långa drifttider, vilket väsentligt kan minska membranmodulens masstransportkoefficienter. I avhandlingen har en rad olika driftparametrars påverkan på CO2-reningsgraden och massöverföringshastigheten undersökts. Driftparametrar inkluderar gas- och vätskeflöden, typ av absorbent och koncentration och volymfraktion av CO2 vid gasinloppet. Avskiljning av SO2 och CO2 har dessutom undersökts för att utvärdera möjligheten att samtidigt, i samma membranenhet, avlägsna svavel och kol. Under 14 dagars kontinuerlig drift konstaterades det att massöverföringshastigheten för CO2 minskade avsevärt med drifttiden, vilket hänfördes till partiell vätning av membranet. För att bättre förstå mekanismerna för vätning av membranporer under långvarig kontakt med absorbenter genomfördes doppningsexperiment i upp till 90 dagar. Olika metoder för karakterisering av membran användes för att illustrera vätningsprocessen före och efter det att membranfibrerna exponerades för absorbenterna. Resultaten av karakteriseringen visade att absorbentmolekylerna spreds in i polypropenpolymeren under kontakten med membranet, vilket ledde till att membranet svällde. Dessutom undersöktes effekterna av driftsparametrar såsom nedsänkningstid och typ av absorbent i detalj. Slutligen, på grundval av analysresultaten, diskuterades metoder för att underlätta vätningen av membran. Att förbättra polypropylenmembranets hydrofobicitet genom modifiering av ytan föreslogs kunna vara ett effektivt sätt att förbättra den långsiktiga driftprestandan för membranenheter. Därför modifierades de ihåliga fibrerna av polyproylen med ett tunt lager av en superhydrofob beläggning på membranets yta för att förbättra hydrofobiciteten. En blandning av cyklohexanon och metyletylketon ansågs vara det bästa icke-lösningsmedlet för att få en fiber yta med god homogenitet och acceptabelt hög hydrofobicitet. Under lång driftperiod, uppvisade den modifierade membranenheten stabilare och effektivare prestanda än den obehandlade. Därför erbjuder ytbehandling en möjlighet till att förbättra systemets stabilitet för CO2-avskiljning när det gäller långsiktig drift. / VR-SIDA Swedish Research Links Programme CO2-avskiljning samtidig avskiljning av CO2 och SO2 ihålig fiber membran gas absorption vätning ytmodifiering
319	Oberflächenmodifizierung von textilem ultrahochmolekularen Polyethylen mittels Dielektrischer Barriereentladung / Surface modification of textile ultra-high-molecular-weight polyethylene via dielectric barrier discharge Bartusch, Matthias 06 September 2016 (has links) (PDF) Textiles ultrahochmolekulares Polyethylen (UHMWPE) besitzt, aufgrund seiner außerordentlich hohen Molmasse und einem kristallinen Anteil von mehr als 80 %, exzellente spezifische Reißfestigkeiten sowie sehr gute Beständigkeiten gegenüber biologischen, chemischen und physikalischen Einflüssen, wodurch es sich für den Einsatz in Schutztextilien, als textiler Träger für funktionelle Partikel, zur Faserverstärkung in Kunststoffen für hochbelastbare Bauteile und auch zur Herstellung hochwertiger, technischer Textilmembranen anbietet. Voraussetzung für diese Applikationen ist ein hohes Wechselwirkungsvermögen der Fasergrenzflächen. Im Rahmen dieser Dissertationsschrift wurden systematisch die Möglichkeiten zur Oberflächenaktivierung von textilem UHMWPE mittels Atmosphärendruckplasma (ADP) untersucht und Eigenschafts-Wirkungsbeziehungen verschiedener Einflussparameter, u. a. Plasmaleistung, Elektrodenabstand, Behandlungsintensität, aufgeklärt. Dabei lag ein besonderes Augenmerk auf den textilen Eigenheiten des Materials und der dadurch stark beeinflussten Durchdringung des Plasmas. Entsprechend wurden umfangreiche Messreihen zu chemischen und physikalischen Veränderungen der Faseroberfläche erstellt, um schließlich eine industrielle Nutzbarkeit der ADP-Behandlung ableiten zu können. Hierzu wurden auch zwei weitere Verfahren vergleichend begutachtet und in Kooperation mit dem Leibniz-Institut für Polymerforschung Dresden e.V. eine mögliche Anwendung aktivierter UMHWPE-Garne als Träger für magnetisierbare Nanopartikel betrachtet. Polyethylen UHMW PE Hochleistungsfaser Textil Atmosphärendruckplasma Dielektrische Barrierentladung DBD Plasma Oberflächemodifikation polyethylene UHMW PE high-performance fiber textile atmospheric pressure plasma dielectric barrier discharge DBD plasma surface modification ddc:540 rvk:VK 8007 Faser Atmosphärendruckplasma Polyethylene Modifizierung Oberfläche
320	POLYMERIC BONDED PHASES FOR PROTEIN EXTRACTION AND INTACT GLYCOPROTEIN ANALYSIS Edwin Jhovany Alzate Rodriguez (7010366) 12 August 2019 (has links) Polymer brushes are extremely versatile materials, as monomer choice allows the user to design a material with the desired physiochemical properties. Given the wide variety in monomer functionality, polymers can be fine-tuned for a specific application. In this work, polymer brushes bound to a silica support are designed and utilized to enhance performance of protein extraction and chromatographic separations. <br> The effectiveness of an analytical method is strongly affected by matrix composition, however, the presence of species other than the target analyte is usually unavoidable. An excellent technique will be able to identify and/or quantify the analyte even when its concentration is low compared with interfering molecules. Protein analysis is particularly challenging, since many proteins of clinical and scientific significance are present in complicated matrices such as plasma or cell lysates. <br>A common method to specifically separate a protein from a complicated matrix is solid phase extraction. In this method, a species (such as an antibody) with high specificity towards the target is immobilized onto a solid substrate (commonly beads or small particles for greater surface area). Next, the target is collected onto the surface, bound by the species. The solid substrate is rinsed of the liquid matrix, before elution of the target. Only the active species should interact with the analyte, and the surface should be otherwise inactive. However, nonspecific interactions lead to binding/adsorption of undesirable compounds. Therefore, an optimal substrate for protein extraction must be 1) easily and completely removable from the liquid phase, 2) have a high concentration of active sites for specific binding, and 3) exhibit low nonspecific binding. As part of this work, commercial magnetic particles were coated with a nonporous silica layer that tolerates the acid bath and silane coating necessary to attach a polymer layer. On the silane coating, a polymer layer was covalently bound; this layer contains epoxide active groups for immobilizing antibodies. These antibodies bind to the target molecule with high specificity, and low nonspecific binding. Obtained particles were evaluated for protein extraction, where antibodies as well as specifically engineered drug compounds were successfully bound to the particle surface.<br>Glycosylation influences several physiopathological processes in proteins. Glycans can act as receptors, modify protein solubility, and participate in folding conformation. Altered glycosylation is a common feature in tumorous cells. As such, many modifications in glycoproteins have been related to cancer, including increased branching of N-glycans or augmented units of sialic acid. Therefore, characterization of glycoproteins is important not only as a diagnostic tool, but also to monitor patients’ response to treatment. Furthermore, it is important in the growing field of monoclonal antibodies as drug carriers. <br>Among different methods used for glycosylation analysis, Hydrophilic Interaction Liquid Chromatography (HILIC) has showed important advantages over time-consuming digestion-MS based techniques. An adequate HILIC stationary phase can be used to rapidly differentiate glycoforms present in a sample. In the second part of this work, a polymer brush based bonded phase was developed as a HILIC stationary phase. The new polymer improved the separation of a model glycoprotein compared with a commercial HILIC column, while also exhibiting enhanced stability over a previous bonded phase synthetized in our group.<br><br> Chemical Characterisation of Materials Colloid and Surface Chemistry polymer bonded phase surface modification polyacrylamides polymethacrylates AGET ATRP silanes protein separation extraction analysis HPLC HILIC chromatography glycans glycosylation immunoprecipitation drug

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