Moisture Barrier Polymer Nanocomposites for Organic Device Encapsulation

Saravanan, S

January 2016

The advancement in smart technologies for organic conducting polymers as flexible substrates in LEDs, PVs and solid state lighting necessitates the development of ultra-high barrier films to protect the devices from moisture and oxygen. The current encapsulation methodology of using layers of plastics and inorganic oxides has several deficiencies. Alternatively, the use of single layer of polymer nanocomposites is a promising substitute for these inorganic based encapsulation layers. The use of polymer materials have the advantage of flexibility, active electrodes printability and easy to make the devices for large area applications. The nano-fillers with high aspect ratio as nanocomposites ingredient in polymers reinforces its mechanical strength and also acts as a scavenging material for moisture and increases the residence time and/or for the penetrating moisture in the film. Chapter 1 gives the basic overview in the field of barrier technology films and coatings from polymers and inorganic oxide as either mono/multi layer hermetic encapsulation methods. The understanding of both chemistry and physics behind the moisture permeation and its interaction with the film material was discussed. The inclusion of functional nano-fillers as moisture trapping agents in the film provide better device protection achieved. The methods and instruments to measure such ultra-low permeation within the films are discussed. Finally, the advantage of polymer based nanocomposites for low-permeable films with existing materials are briefly discussed in this chapter. In this thesis, we employed both thermoplastic and thermoset polymer nanocomposites as encapsulation layer for device sealing. The use of ion-containing polymers (ionomers) as a sealant layer was also studied. Chapter 2 presents the detailed experimental procedures with materials and methods used in this thesis along with the synthesis methodologies to make films from the polymer. In chapter 3, we used cyclic olefin copolymer COC (copolymer of ethylene and norbornene) as an encapsulation layer with silica and layered silicate nano-fillers. The compatibility between hydrophilic silica and hydrophobic COC was achieved by maleic anhydride grafted PE with anchoring on COC as a compatibilizer and then silica filler was added to make the nanocomposite films. FTIR spectroscopy confirms the bond formation of silica with COC/MA-g-PE. The mechanical (tensile and DMA) and thermal studies (DSC) suggested that there is an improvement observed when adding silica/silicate layers in the polymer matrix with increased tensile strength, storage modulus and Tg. The calcium degradation test show enhanced performance towards moisture impermeation in the film. Chapter 4 deals with the synthesis of PVB based nanocomposite film with silica/layered silicate as nanofillers in the base matrix with varying degree of acetalization in the film. The FTIR and NMR spectroscopy show the evidence for acetal link formation in the in-situ synthesized PVB with silica/silicate nanofillers with three different acetyl contents. The tensile and DMA studies show the observed improvement in mechanical strength (increased tensile strength, storage modulus) were due to the intercalation of clay galleries during PVB formation and the interaction of silica particles interactive bond formation with –OH groups of PVA in PVB. The higher clay/silica particles show agglomerated nature and reduction in film strength. Thermal studies (DSC) show that there is an improvement observed in Tg when adding silica/silicate layers in the polymer matrix with moderate to low acetal content. The calcium degradation test show enhanced performance towards moisture impermeation in the film. Chapter 5 describes the inclusion of ionic groups (ionomers) in PVB and its effects on moisture permeation and mechanical properties. PVB ionomer was synthesized using formyl benzene 2-sulfonic acid sodium salt and 2-carboxy benzaldehyde (both sulfonic and carboxylic acid sources) as co-aldehyde with butyraldehyde and PVA. These acid groups were neutralized with potassium, magnesium and zinc ions. The level of acid content in the films was maintained between 6 to 28 mol percent. The sulfonic acid films with zinc and magnesium ions of 14 mol% exhibit good mechanical strength and low moisture permeation. Chapter 6 deals with the epoxy terminated silicone polymer nanocomposites as moisture barrier coatings for device encapsulation. Both silica and clay silicate layers were used to reinforce the silicone matrix. The silica nanoparticles were grafted with amino-silane groups, this would help in better mixing of silica particles in the silicone matrix due to the amine groups interaction in curing with epoxy groups. The calcium degradation test was used to determine the WVTR of the nanocomposites and device encapsulation was employed to estimate the degradation after exposure to ambient environment. Chapter 7 presents the concluding remarks of the results presented. The benefits as well as limitations of the polymer nanocomposite film and the future developmental work to be carried out are discussed in this chapter.

Organic Device Encapsulation

Organic Conducting Polymers

Polymer Nanocomposites

Nanoparticles Geometry

Cyclic Olefin Copolymer (COC)

COC/clay Nanocomposites

Clay/cyclic Olefin Copolymer

Poly(vinyl butyral) Composite Films

Poly(vinyl butyral) Nanocomposite Films

Materials Engineering

Biodegradable Polymers for Drug Delivery and Tissue Engineering

Natarajan, Janeni

January 2017

Regeneration, a spontaneous response of bones in response to injuries, infections and fractures, is severely compromised in certain clinical circumstances. Unfortunately, several shortcomings are associated with the current treatment of bone grafting method such as donor shortage and immune response for allografts and donor morbidity for autografts. Thus, the development of clinical alternates is essential. One promising adjunct method is bone tissue engineering that includes the implantation of a scaffold containing the cells with the supplementation of suitable growth factors. Among the various classes of materials, biodegradable polymers are commonly preferred because their use does not necessitate a secondary surgery for their removal after the intended use. Commercially available polymers such as poly (lactic- co- glycolic acid) and polycaprolactone are expensive and degrade slowly. This motivates the development of novel synthetic biodegradable polymers that are affordable and can be tuned to tailor for specific biomedical applications. The primary aim of this thesis is to synthesize effective biodegradable polymers for drug delivery and bone tissue engineering. The properties of these polymers such as modulus, hydrophobicity and crosslinking etc. were tailored based on the variations in chemical bonds, chain lengths and the molar stoichiometric ratios of the monomers for specific clinical applications. Based on the above variations, degradation and release kinetics were tuned. The cytocompatibilty properties for these polymers were studied and suitable mineralization studies were conducted to determine their potential for bone regeneration.

Drug Delivery

Biodegradable Polymers

Tissue Engineering

Poly (ethylene erephthalate)

Castor Oil Sebacic Acid

Biodegradable Polymers

Polyanhydrides

Maltitol

Galactitol Polyester Elastomers

Poly (ester amide)s

Epoxidized Soybean Oil (ESO)

Poly (Galactitol Sebacate)

Bone Tissue Engineering

Galactitol

Nanoscience

Alfa-fosfato tricálcico obtido por reação via úmida para aplicação em cimentos ósseos e cimentos compósitos

Thürmer, Monica Beatriz

January 2014

Nos últimos anos, intensos estudos vêm sendo realizados no que se refere a substitutos ósseos biocompatíveis e absorvíveis, notadamente os cimentos ósseos de fosfato de cálcio, para cirurgias de reconstrução e em engenharia de tecidos. Porém os cimentos de fosfato de cálcio desenvolvidos apresentam baixa resistência mecânica quando comparados com os ossos do corpo humano. Neste contexto, a busca por alternativas para minimizar esse problema tem se intensificado. A obtenção de alfa-fosfato tricálcico por outras rotas de síntese, bem como o desenvolvimento de compósitos de fosfatos de cálcio e hidrogéis têm se destacado nesse ramo. O preparo destes compósitos permite combinar excelentes propriedades como: i) osteocondutividade e capacidade de formar ligações com o tecido ósseo proporcionado pelos fosfatos de cálcio e ii) facilidade de adesão e distribuição de células no interior de scaffolds, proporcionado pelo hidrogel. O objetivo do presente trabalho foi o desenvolvimento de uma nova metodologia de obtenção de alfa-fosfato tricálcico, o preparo de composições de cimentos de fosfato de cálcio e de hidrogéis, bem como a obtenção e caracterização de compósitos destes, visando o melhoramento das propriedades para aplicação como biomaterial Foi possível sintetizar alfa-fosfato tricálcico com elevado grau de pureza, utilizando-se o método de reação via úmida. Após estudos da ordem de adição e concentração dos reagentes foi possível definir os melhores parâmetros de síntese. Com isso verificou-se a influência do tempo de moagem nas propriedades dos cimentos, sendo constatado que para o fosfato de cálcio preparado pela metodologia proposta, não há necessidade de moagem adicional. Foram testadas formulações de hidrogéis utilizando N-vinil-2-pirrolidona e ou ácido acrílico, utilizando três iniciadores: azobisisobutironitrila, persulfato de amônio e 1- hidroxiciclohexil fenil cetona. Pela adição de formulações de hidrogéis ao cimento foi possível obter compósitos com maior absorção de água, mantendo as propriedades mecânicas, o que pode permitir uma melhor adesão celular ao implante sem comprometer sua estrutura. O ensaio de citotoxicidade in vitro demonstrou que o cimento sintetizado neste trabalho não apresentou efeito tóxico para as células. Mostrando, ainda, a adesão e proliferação de célulastronco mesenquimais e de uma linhagem de osteoblastos. / In the last years, intensive studies have been conducted regarding the biocompatible and resorbable bone substitutes, notably calcium phosphate bone cements, for reconstructive surgery and tissue engineering. However, the calcium phosphate cements developed exhibit low mechanical strength when compared with the bones of the human body. In this context, the search for alternatives to minimize this problem has intensified. The obtaining of alphatricalcium phosphate by others synthesis routes, as well as development of calcium phosphate and hydrogels composites has been prominent in this branch. The preparation of these composites allows to combine excellent properties such as: i) osteoconductivity and ability to form bonds with bone tissue, afforded by calcium phosphate and ii) ease of adhesion and distribution of cells in the scaffolds inside, provided by hydrogel. The aim of this work was the development of a new methodology to obtaining alpha-tricalcium phosphate, the preparation of calcium phosphate cements and hydrogels compositions, as well as the obtaining and characterization of composites of these, intended to improve the properties for application as biomaterial. It was possible to synthesize alpha-tricalcium phosphate with high purity using the wet method reaction After studies of the addition order and reagents concentration was possible to define the best synthesis parameters. With that it was verified the influence of milling time on the cements properties to being noted that for the calcium phosphate prepared by the proposed method, there is no need additional milling. Were tested hydrogel formulations using N-vinyl-2-pyrrolidone and/or acrylic acid, using three initiators: azobisisobutyronitrile, ammonium persulfate and 1-hydroxycyclohexyl phenyl ketone. By the addition of the hydrogel formulations to the cement was possible to obtain composites with higher water absorption by keeping the mechanical properties, which may permits better vascularization of the implant without compromising its structure. The in vitro cytotoxicity assay demonstrated that the cement synthesized in this work does not show any toxic effect on the cells. Also, showing the adhesion and proliferation of mesenchymal stem cells and an osteoblast line.

Cimento de fosfato tricálcico

Hidrogéis

Biomateriais

Poly (N-vinyl-2-pyrrolidone)

Poly (acrylic acid)

Wet method reaction

Calcium phosphate

Calcium phosphate cements

Composite biomaterials

Charakterizace vyfukovaných fólií z měkčeného polylaktidu / Characterization of blowing films from softened polylactide

Kubíček, Václav

January 2020

The master's thesis focuses on preparation of blown films from polylactid acid (PLA) which was blended with selected polyesteres – poly(butylene adipate-co-terephtalate) (PBAT), polycaprolactone (PCL) and polybutylene succinate (PBS) – and thermoplastic starch (TPS) in amount of 30% in order to soften PLA films. The influence of the aditives on static and mechanical tensile properties, on structure, morphology and thermal properties of the films was determined and the obtained parameters were compared to properties of films prepared from neat PLA and high density polyethylene (HDPE). The results showed that the additives increased crystalinity of PLA and thus significantly influenced the properties of the films. In contrast to the film from neat PLA, softening in terms of lowering glass transition temperature occured only by adding PBS and TPS, in terms of increasing ductility only by adding PBAT. All PLA films showed nearly constant elastic modulus up to the beginning of glass transition enabling their potential application till 50 °C. Preparation of the film with TPS was problematic and the film showed the worst mechanical properties. Preparation of other films was without any problems. The most promising additive from the tested ones was PBAT which showed comparable mechanical properties as the film from HDPE.

Synthesis and Characterization of Novel Pol(arylene ethers) for Gas Separation and Water Desalination Membranes

Narang, Gurtej Singh

19 June 2018

This thesis focuses on the synthesis and characterization of various poly(arylene ether)s to improve the efficiency of gas separation and water desalination membranes. This class of polymers includes polymers such as poly(arylene ether sulfone), poly(arylene ether ketone) and poly(phenylene oxide) which offer excellent thermal and mechanical stability and usually have high enough rigidity to support gas separation and water desalination operations. Besides the plethora of properties offered by the homopolymers, these polymers can also be post-modified to cater to specific needs. For example, the polyphenylene oxides have been brominated to increase the permeability for gas separation applications. Blending is another viable method to impart desirable properties to polymers. Bisphenol A based poly(arylene ether ketone) (BPAPAEK) has been blended with commercially available poly(2,6-dimethylphenylene oxide)s (PPO) of different molecular weights in a fixed ratio (66/34 wt/wt) and in various ratios of a 22000 g/mol PPO. All the blends were UV crosslinked to minimize plasticization by condensable gases and analyzed for gel fractions, whereas, only the 22,000 g/mol blends were tested for transport properties since they yielded the highest gel fractions and exhibited the best mechanical properties. The crosslinking reduced the free volume and improved the selectivity with some drop in permeability. The blends with 90% of the 22000 g/mol PPO by weight was plotted closest to the upperbound. A phosphine oxide based poly(arylene ether ketone) (POPAEK) was blended with the various PPOs in a similar manner. The results were compared to the BPAPAEK based blends in terms of miscibility behavior and transport properties. It was found that the POPAEK based blends had higher permeability due to the higher fractional free volumes of the POPAEK. The POPAEK was more compatible with the PPOs than BPAPAEK as seen by analyzing various blend permeability models, mechanical properties and scanning electron microscope images. Moreover, blends with both the PAEKs displayed only a small drop in mechanical properties, such as the Young's modulus and the yield strength in comparison to the parent polymers. Hydroquinone based poly(arylene ether sulfone) oligomers were synthesized, post-sulfonated and chemically crosslinked to determine the effect of water uptake, fixed charge concentration and block length of oligomers on the salt permeability and the hydrated mechanical properties of the networks. The sulfonic acid groups were placed strategically and quantitatively on the hydroquinone units. The strategic placement of the acid groups may help in maintaining high rejection of monovalent ions in the presence of divalent ions, as shown in unpublished work by our group. It was found that the water uptake and fixed charge density had the opposite effects on the salt permeability. Also, the salt permeability varied differently for 5000g/mol and 10000g/mol block based networks. Another polymer that was investigated in this thesis was poly(2-ethyl-2-oxazoline) (PEtOx). An elaborate account of synthesis of monofunctional, heterobifunctional and telechelic poly(2-ethyl-2-oxazoline)s using different initiators including methyl triflate, activated alkyl halides (e.g., benzyl halides), and non-activated alkyl halides has been presented in this thesis. Endgroup functionalities and molecular weight distributions were studied by SEC, 1H NMR and titrations. The oligomers initiated with the benzyl or xylyl chloride had a PDI of 1.3-1.4 which is broader than expected for a living cationic ring opened polymer. This was attributed to the participation of covalent species which propagated slowly in the activated halide reactions. These oligomers were quantitatively terminated as proven by NMR and titrations. Due to the molecular weight distributions and quantitative termination these oligomers were deemed to be desirable for drug delivery applications. / PHD / This work pivots around the synthesis and characterization of different classes of polymers which are long molecules made by joining small molecules. The structure-property relationships of different polymers with respect to applications such as gas separation, water desalination and drug delivery were examined. The first two projects were focused of gas separation applications. Gas separation is an essential process used to recover the required gas from a mixture of gases. This process is used in a number of industries such as natural gas, hydrogen recovery and air dehumidification. In these projects, gas separation membranes were used to remove non combustible components of natural gas such as carbon dioxide and hydrogen sulfide. Two different types of poly(arylene ether ketone)s (PAEKs) (a kind of polymer) were blended with a commercial polymer called poly(phenylene oxide) (PPO) and crosslinked at the surfaces to improve the gas transport properties of the commercial polymer. PPOs have high gas permeability and a low selectivity. In other words even though the PPO membranes would alow the gasses to pass through easily, the efficiency of gas separation would be low. The blending with the PAEKs improved the selectivity of the PPOs without much loss in throughput. These blends of the two different PAEKs were compared for transport and other relavent properties. It was found that the transport properties of the commercial polymer were improved markedly without much loss in mechanical properties which are usually sacrificed upon blending of two uncomaptible polymers. Water desalination applications were looked into for a polymer class called polysulfones. About 40% of the world’s population lives in water stressed areas. In order to address the water crisis, there is a need to look beyond primitive methods such as distillation which are inefficient. Hence, the polymeric membrane separations which do not involve phase change (eg liquid to gas and then back to liquid in distillation) were examined. The currently used polyamide membranes have a rough surface because of the way they are made, making them prone to deposition of salt and organic matter. This deposition makes them inefficient. They are also prone to degradation by chlorine. The polysulfones membranes have a smoother surface less prone to these depositions. Their resistance to chlorine makes them more viable for water desalination applications. The polysulfones were post modified to introduce charges to make them more suitable for water desalination purposes. The charges repelled the ions of same polarity and made the polymer more hydrophilic. However, as the number of charges increased, the water uptake of the polymer increased which resulted in a decrease in the effectiveness of salt /ion rejection. To increase the charge density of the polymers by (the effectiveness of ion rejection), the polymer chains were crosslinked at the ends. For deleniating the structure property relationships, the amount of charges were varied and two sets of chain lengths were studied. The salt permeability decreased with increase in fixed charge concentration and decrease in water uptake. Poly(2-Oxazolines), were investigated as potential drug delivery vehicles. Polymeric drug delivery vehicles have been used to control the rate of release of drugs in the body to avoid side effects. Another advantage of polymeric drug delivery systems is making the water insoluble drugs more compatible with the fluids in the body. Currently, polyethylene oxides are being used as drug delivery vehicles. However, these polymers have been known to produce antibodies in some people. In this work, poly(2-oxazolines) which are known to be more compatible with human body than PEOs were prepared using different initiators and end cappers to prepare an elaborate repertoire of controlled molecular weight and controlled functionality oligomers for further modification.

gas separation

water desalination

electrodialysis

poly(arylene ether ketone)

phosphine oxide

poly(2

6 dimethylphenylene oxide)

polymer blends

UV crosslinking

poly(phenylene ether sulfone)

post sulfonation

fixed charge concentration

Poly(N-vinylpyrrolidone) - Poly(γ-benzyl-L-glutamate) conjugates

Jacobs, Jaco

03 1900

Thesis (MSc)--Stellenbosch University, 2012. / ENGLISH ABSTRACT: The combination of natural and synthetic polymers allow for the synthesis of advanced hybrid copolymers. These hybrid copolymers have applications in biomedical areas, one such area being in drug delivery systems (DDS). In this study, a modular approach was used to prepare amphiphilic block copolymers with the ability to self-assemble into three dimensional structures. Reversible addition-fragmentation chain transfer (RAFT) was the synthetic tool used to mediate the polymerization of N-vinylpyrrolidone. RAFT is a versatile method to prepare polymers with control over molecular weight and dispersity. A xanthate chain transfer agent (CTA) was used to obtain the hydrophilic poly(N-vinylpyrrolidone) (PVP) block. An aldehyde functionality could be introduced due to the lability of the xanthate moiety, the procedure of which was effectively optimized to produce quantitative conversion. A dixanthate CTA was synthesized to produce a PVP chain which after the modification reaction, resulted in a α,ω-telechelic polymer. A polypeptide was synthesized via the ring-opening polymerization of Ncarboxyanhydrides (ROP NCA). The living and controllable ROP of NCAs is a method which results in polypeptides, but without a well-defined amino acid order. Poly(γ- benzyl-L-glutamate) (PBLG) was synthesized with a narrow dispersity (Đ = 1.10 – 1.15) using conditions that promote the retention of a terminal primary amine. A protected cysteine functionality was introduced via the terminal amine PBLG chain-end, using peptide synthesis techniques. This resulted in the conjugation of the aldehyde functional PVP and the cysteine terminal PBLG using a covalent, non-reducible thiazolidine linkage. The deprotection of the cysteine, more specifically the deprotection of the thiol was a non-trivial procedure. The thiol protecting acetamidomethyl (Acm) group could not be cleaved using traditional methods, but instead a modified procedure was developed to effectively remove the Acm group while inhibiting hydrolysis of the benzyl esters. It was determined that the conjugation reaction could effectively proceed in N,Ndimethylformamide (DMF) at a slightly elevated temperature and so continued to prepare the amphiphilic hybrid block copolymers, PVP-b-PBLG. A structurally different PBLG chain, namely PBLG-b-Cys was conjugated to the ω-aldehyde PVP and the conjugation efficiency was compared to our PBLG-Cys block. In the case of PBLG-b- Cys the in situ deprotection and conjugation as well as a two-step deprotection and conjugation reaction with PVP resulted in very low conjugation efficiency. The cysteine end-functional PBLG resulted in near quantitative conjugation with PVP. The critical micelle concentration (CMC) for PVP90-b-PBLG54 was determined to be 6 μg/mL, using fluorescence spectroscopy. Particle sizes were determined with TEM and DLS and found to range from 25 nm to 120 nm depending on the polymer block lengths as well as hydrophobic/hydrophilic block length ratios. Furthermore, when the micelles were subjected to an increased acidic environment, the labile benzyl ester bonds were hydrolyzed. This was observed with TEM where the particle sizes increased 10-fold to form vesicular structures. Hydrolysis was further confirmed with ATR-FTIR and 1H-NMR spectroscopy. Cytotoxicity tests confirmed that the copolymer micelles had good cell compatibility at high concentrations such as 0.9 mg/mL. Investigation into drug loading using a pyrene probe confirmed the viability of using PVP-b-PBLG as a responsive DDS. / AFRIKAANSE OPSOMMING: Die kombinasie van natuurlike en sintetiese polimere maak dit moontlik vir die sintese van gevorderde hibried kopolimere. Hierdie kopolimere het aanwending in biomediese gebiede, een so 'n gebied is in medisinale vervoer sisteme (MVS). 'n Modulêre benadering is in hierdie studie gebruik om amfifiliese blok kopolimere te berei. Omkeerbare addisie-fragmentasie kettingoordrag (OAFO) is gebruik as die sintetiese tegniek vir die polimerisasie van N-vinielpirolidoon (NVP). OAFO is 'n veelsydige metode om polimere te berei met beheer oor molekulêre gewig en dispersiteit (Đ). 'n Xantaat kettingoordrag agent (KOA) is gebruik om die hidrofiliese poli(N-vinielpirolidoon) (PVP) blok te sintetiseer. ‘n Aldehied endgroep was deur die terminale xantaat funksionaliteit berei, ‘n proses wat geoptimiseer is tot kwantitatiewe omsetting. 'n Di-xantaat KOA is gesintetiseer om, na modifikasie, 'n α, ω-telecheliese polimeer te produseer. Die polipeptied was gesintetiseer deur middel van ’n ringopening polimerisasie van Nkarboksianhidriede (ROP NKA). Die lewende en beheerbare ROP van NKAe is 'n metode wat lei tot polipeptiede sonder ’n gedefinieerde aminosuur volgorde. Poli(γ- benzyl-L-glutamaat) met 'n lae dispersiteit (Đ = 1.10 – 1.15), is gesintetiseer deur gebruik te maak van kondisies wat die behoud van 'n terminale primêre amien bevorder. 'n Beskermde sistien-funksionaliteit is ingebou via die terminale amien met behulp van peptiedsintese tegnieke. Die tiol beskerming van die asetamidometiel (Asm) groep kon nie gekleef word deur gebruik te maak van tradisionele metodes nie, maar ‘n nuwe proses is ontwikkel om die Asm groep te kleef sowel as om die hidrolise van die bensiel esters te inhibeer. Die koppelings reaksie het effektief verloop in DMF by 'n effens verhoogde temperatuur en sodoende is die amfifiliese hibried blok-kopolimere, PVP-b-PBLG berei. Twee verskillende PBLG kettings is gekoppel aan die ω-aldehied PVP en die koppeling doeltreffendheid is vergelyk. Daar is bevind dat net die sistien end-funksionele PBLG tot kwantitatiewe konjugasie kon lei. Die kritiese misel konsentrasie is bepaal vir PVP90-b-PBLG54 as 6 μg/mL met behulp van fluoressensie spektroskopie. Die deeltjie-groottes is bepaal met TEM en DLS en wissel van 25 nm tot 120 nm, afhangende van die polimeer bloklengtes sowel as hidrofobiese / hidrofiliese blok lengte verhoudings. Die miselle is blootgestel aan 'n verhoogde suur omgewing, wat tot die hidrolise van die bensiel ester groepe gelei het. TEM het getoon dat die deeltjie-groottes met 10-voud vergroot het tot vesikulêre strukture. Hidrolise is verder bevestig met ATR-FTIR en 1H-KMR spektroskopie. Sitotoksiese toetse het bevestig dat die miselle geen of min toksisiteit toon teenoor eukariotiese selle nie, selfs teen 'n hoë konsentrasies soos 0.9 mg/ml. Die medisinale behoud vermoë is met behulp van pireen bevestig en dus ook die potensiaal van PVP-b-PBLG as ‘n moontlike MVS.

Poly(N-vinylpyrrolidone)

Poly(γ-benzyl-L-glutamate)

Block copolymers

Drug delivery systems (DDS)

Polymerization

Dissertations -- Polymer science

Theses -- Polymer science

Chemistry and Polymer Science

Electrically conductive textile coatings with PEDOT:PSS

Åkerfeldt, Maria

January 2015

In smart textiles, electrical conductivity is often required for several functions, especially contacting (electroding) and interconnecting. This thesis explores electrically conductive textile surfaces made by combining conventional textile coating methods with the intrinsically conductive polymer complex poly(3,4-ethylene dioxythiophene)-poly(styrene sulfonate) (PEDOT:PSS). PEDOT:PSS was used in textile coating formulations including polymer binder, ethylene glycol (EG) and rheology modifier. Shear viscometry was used to identify suitable viscosities of the formulations for each coating method. The coating methods were knife coating, pad coating and screen printing. The first part of the work studied the influence of composition of the coating formulation, the amount of coating and the film formation process on the surface resistivity and the surface appearance of knife-coated textiles. The electrical resistivity was largely affected by the amount of PEDOT:PSS in the coating and indicated percolation behaviour within the system. Addition of a high-boiling solvent, i.e. EG, decreased the surface resistivity with more than four orders of magnitude. Studies of tear strength and bending rigidity showed that textiles coated with formulations containing larger amounts of PEDOT:PSS and EG were softer, more ductile and stronger than those coated with formulations containing more binder. The coated textiles were found to be durable to abrasion and cyclic strain, as well as quite resilient to the harsh treatment of shear flexing. Washing increased the surface resistivity, but the samples remained conductive after five wash cycles. The second part of the work focused on using the coatings to transfer the voltage signal from piezoelectric textile fibres; the coatings were first applied using pad coating as the outer electrode on a woven sensor and then as screen-printed interconnections in a sensing glove based on stretchy, warp-knitted fabric. Sensor data from the glove was successfully used as input to a microcontroller running a robot gripper. These applications showed the viability of the concept and that the coatings could be made very flexible and integrated into the textile garment without substantial loss of the textile characteristics. The industrial feasibility of the approach was also verified through the variations of coating methods.

textile coating

conductive coating

conjugated polymers

ICP

PEDOT:PSS

textile properties

textile sensor

printed electronics

Smart textiles

poly(3

Untersuchungen zur Inhibierung der Expression der Poly(ADP-ribose)Polymerase (PARP) nach Infektion mit Toxoplasma gondii / Analysis of the expression inhibition of the poly(ADP-ribose) polymerase (PARP) after infection with T. gondii

Gais, Andrea Nadja

30 October 2008

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

Toxoplasma gondii

Poly(ADP-ribose) Polymerase

Parasit-Wirt Interaktionen

Toxoplasma gondii

poly(ADP-ribose) polymerase

parasite-host interactions

42.36

W

Development and characterization of polymeric nanoparticles(NPs) made from functionalized poly (D,L- lactide) (PLA)polymers

Essa, Sherief

11 1900

Les nanoparticules polymériques biodégradable (NPs) sont apparues ces dernières années comme des systèmes prometteurs pour le ciblage et la libération contrôlée de médicaments. La première partie de cette étude visait à développer des NPs biodégradables préparées à partir de copolymères fonctionnalisés de l’acide lactique (poly (D,L)lactide ou PLA). Les polymères ont été étudiés comme systèmes de libération de médicaments dans le but d'améliorer les performances des NPs de PLA conventionnelles. L'effet de la fonctionnalisation du PLA par insertion de groupements chimiques dans la chaîne du polymère sur les propriétés physico-chimiques des NPs a été étudié. En outre, l'effet de l'architecture du polymère (mode d'organisation des chaînes de polymère dans le copolymère obtenu) sur divers aspects de l’administration de médicament a également été étudié. Pour atteindre ces objectifs, divers copolymères à base de PLA ont été synthétisés. Plus précisément il s’agit de 1) copolymères du poly (éthylène glycol) (PEG) greffées sur la chaîne de PLA à 2.5% et 7% mol. / mol. de monomères d'acide lactique (PEG2.5%-g-PLA et PEG7%-g-PLA, respectivement), 2) des groupements d’acide palmitique greffés sur le squelette de PLA à une densité de greffage de 2,5% (palmitique acid2.5%-g-PLA), 3) de copolymère « multibloc » de PLA et de PEG, (PLA-PEG-PLA)n. Dans la deuxième partie, l'effet des différentes densités de greffage sur les propriétés des NPs de PEG-g-PLA (propriétés physico-chimiques et biologiques) a été étudié pour déterminer la densité optimale de greffage PEG nécessaire pour développer la furtivité (« long circulating NPs »). Enfin, les copolymères de PLA fonctionnalisé avec du PEG ayant montré les résultats les plus satisfaisants en regard des divers aspects d’administration de médicaments, (tels que taille et de distribution de taille, charge de surface, chargement de drogue, libération contrôlée de médicaments) ont été sélectionnés pour l'encapsulation de l'itraconazole (ITZ). Le but est dans ce cas d’améliorer sa solubilité dans l'eau, sa biodisponibilité et donc son activité antifongique. Les NPs ont d'abord été préparées à partir de copolymères fonctionnalisés de PLA, puis ensuite analysés pour leurs paramètres physico-chimiques majeurs tels que l'efficacité d'encapsulation, la taille et distribution de taille, la charge de surface, les propriétés thermiques, la chimie de surface, le pourcentage de poly (alcool vinylique) (PVA) adsorbé à la surface, et le profil de libération de médicament. L'analyse de la chimie de surface par la spectroscopie de photoélectrons rayon X (XPS) et la microscopie à force atomique (AFM) ont été utilisés pour étudier l'organisation des chaînes de copolymère dans la formulation des NPs. De manière générale, les copolymères de PLA fonctionnalisés avec le PEG ont montré une amélioration du comportement de libération de médicaments en termes de taille et distribution de taille étroite, d’amélioration de l'efficacité de chargement, de diminution de l'adsorption des protéines plasmatiques sur leurs surfaces, de diminution de l’internalisation par les cellules de type macrophages, et enfin une meilleure activité antifongique des NPs chargées avec ITZ. En ce qui concerne l'analyse de la chimie de surface, l'imagerie de phase en AFM et les résultats de l’XPS ont montré la possibilité de la présence de davantage de chaînes de PEG à la surface des NPs faites de PEG-g-PLA que de NPS faites à partie de (PLA-PEG-PLA)n. Nos résultats démontrent que les propriétés des NPs peuvent être modifiées à la fois par le choix approprié de la composition en polymère mais aussi par l'architecture de ceux-ci. Les résultats suggèrent également que les copolymères de PEG-g-PLA pourraient être utilisés efficacement pour préparer des transporteurs nanométriques améliorant les propriétés de certains médicaments,notamment la solubilité, la stabilité et la biodisponibilité. / Biodegradable polymeric nanoparticles (NPs) have emerged as promising drug delivery carriers for the controlled drug release and targeting. The first part of this study aimed to develop biodegradable NPs from functionalized copolymers of poly (D,L-Lactide) (PLA). Those copolymers were explored as drug delivery systems in attempt to improve the drug delivery performance of conventional PLA NPs. The effect of PLA functionalization (insertion of chemical substituents onto PLA backbone) on the physicochemical properties of the obtained NPs was investigated. Moreover, the effect of polymer architecture (mode of organization of polymer chains in the resultant copolymer) on various drug delivery aspects was also studied. To reach those goals, various PLA based copolymers namely poly(ethylene glycol) (PEG) grafted on PLA backbone at 2.5% & 7% mol/mol of lactic acid monomers (PEG2.5%-g-PLA and PEG7%-g-PLA, respectively), palmitic acid grafted on PLA backbone at 2.5% grafting density (palmitic acid2.5%-g-PLA), and multiblock copolymer of PLA and PEG, (PLA-PEG-PLA)n were synthesized. In the second part, the effect of different PEG grafting densities over PLA backbone on the properties of PEG-g-PLA NPs either physicochemical or biological properties was investigated to reveal the optimal PEG grafting density required to develop stealth particles (long circulating NPs). Finally, functionalized PEG/PLA copolymers that showed the most satisfactory results in terms of various drug delivery aspects, such as size and size distribution, surface charge, drug loading, and controlled drug release were selected for encapsulation of itraconazole (ITZ) to improve its aqueous solubility, bioavailability and hence its antifungal activity. NPs were first prepared from functionalized PLA copolymers then analyzed for their major physicochemical parameters such as encapsulation efficiency, size and size distribution, surface charge, thermal properties, surface chemistry, % poly(vinyl alcohol) (PVA) adsorbed at the surface of NPs, and drug release pattern. Surface chemistry analysis using x-ray photoelectron spectroscopy (XPS), and atomic force microscopy (AFM) phase imaging were used to study the chain organization behavior of each functionalized copolymer during NPs formulation. Generally speaking, functionalized PEG/PLA copolymers showed improved drug delivery behavior in terms of narrow size and size distribution, enhanced loading efficiency, less plasma protein adsorption onto their surfaces and less macrophage uptake, and finally better antifungal activity for ITZ loaded NPs. For the surface chemistry analysis, AFM phase imaging and XPS studies revealed the possibility of existence of more PEG chains at the surface of PEG-g-PLA NPs than (PLA-PEG-PLA)n during NPs formation. Our results demonstrate that properties of PLA-based NPs can be tuned by proper selection of both polymer composition and polymer architecture. Results also suggest that PEG-g-PLA copolymers could be used efficiently as a nanocarrier to improve various drug properties e.g. solubility, stability, and bioavailability.

Acide poly(lactique)

Architecture

Organisation de la chaîne

PEG-PLA

Poly (D,L lactide)

Architecture

Chain organization

PEG-PLA

Etude des micelles biorésorbables formées par auto-assemblage des copolymères à blocks polylactide/poly(éthylène glycol) pour la délivrance contrôlée de principes actifs / Bioresorbable micelles by self-assembly of polylactide/poly(ethylene glycol)block copolymers for controlled drug delivery

Yang, Liu

20 December 2010

Des copolymères à blocs polylactide-poly(éthylène glycol) (PLA-PEG) ont été synthétisés par polymérisation par ouverture de cycle du L- ou D-lactide en présence de PEG mono- ou dihydroxylé. La masse molaire, la composition, la cristallisation et les propriétés thermiques des copolymères ont été caractérisées à l'aide de la DSC, NMR, GPC, etc. Des micelles biorésorbables ont été obtenues par la méthode dissolution directe sans utiliser de solvants organiques. Des mesures de tension de surface ont permis de déterminer la concentration micellaire critique des copolymères. Les résultats montrent que les micelles mélange L/D sont plus stables que les micelles seules en raison de l'effet stéréocomplexation entre les blocs L-PLA et D-PLA. Les comportements d'agrégation des micelles en milieu aqueux ont été étudiés en détail. Il apparaît que les micelles mélange présentent un nombre d'agrégation inférieur à celui des micelles seules. La dégradation hydrolytique des micelles a été étudiée dans les conditions in vitro. Le paclitaxel a été utilisé comme modèle de principes actifs pour évaluer les comportements in vitro et in vivo des micelles. Les méthodes dissolutio n directe et dialyse conduisent à des résultats comparables en ce qui concerne l'efficacité d'encapsulation et la teneur en principe actif. Les micelles mélange L/D présentent une meilleure capacité d'encapsulation que les micelles seules. Les expériences in vivo montrent que le paclitaxel est distribué dans tous les organes avec concentrations élevées après injection des micelles chargées. En comparaison avec la formulation clinique et les micelles par dialyse, les micelles chargées en paclitaxel par dissolution directe présentent un effet antitumeur plus important. / A series of polylactide-poly(ethylene glycol) (PLA-PEG) block copolymers were synthesized by ring-opening polymerization of L- or D-lactide in the presence of mono- or dihydroxyl PEG. The molar mass, composition, crystallization and thermal properties were characterized by using DSC, NMR, GPC, etc. Bioresorbable micelles were obtained by direct dissolution method without using any organic solvents. Surface tension measurements were used to determine the critical micellar concentration of the copolymers. The results show that L/D mixed micelles are more stable than single ones due to strong stereocomplexation effect between L-PLA and D-PLA blocks. The aggregation behavior of micelles in aqueous medium was investigated in detail. It appears that mixed micelles present lower aggregation number than single ones. The hydrolytic degradation of the micelles was investigated under in vitro conditions. Paclitaxel was used as a model drug to investigate the in vitro and in vivo behavior of micelles as drug delivery system. The direct dissolution method yields comparable drug encapsulation efficiency and loading content as the traditional dialysis method. The drug encapsulation ability is higher for L/D mixed copolymer micelles than single micelles due to stereocomplexation. In vivo experiments show that paclitaxel is widely distributed and kept at high concentration levels in various tissues after administration of drug-loaded micelles. Compared with the current clinical formulation and micelles by dialysis, paclitaxel-loaded micelles by direct dissolution exhibit the highest antitumor ability.

Polylactide

Poly(éthylène glycol)

Micelle

Dégradation hydrolytique

Stéréocomplexation

Polylactide

Poly(ethylene glycol)

Micelle

Hydrolytic degradation

Controlled drug release

Stereocomplexation