Understanding Elastin-Like Polypeptide Block Copolymer Self-assembly Behavior

Hassouneh, Wafa Saadat

January 2013

<p>Elastin-like polypeptides (ELPs) are thermally responsive polymers composed of the pentapeptide repeat Valine-Proline-Glycine-X-Glycine where X is any amino acid except proline. ELP diblocks have been engineered by creating two ELP blocks with hydrophilic and hydrophobic guest residues. The hydrophobic block desolvates at a lower temperature and forms the core of a micelle while the still hydrated hydrophilic block forms the corona. ELP micelles are promising drug delivery vehicles for cancer therapeutics. ELP diblocks offer a unique method to display targeting proteins multivalently on micelles to improve tumor cell uptake. As ELPs are genetically encoded, proteins can be seamlessly fused at the genetic level to the ELP diblock. The protein ELP diblock fusions can be synthesized as one polypeptide chain that is of precise molecular weight and highly monodisperse, and no post-synthesis modification is necessary. Self-assembly behavior of ELP diblocks is known to tolerate fusion to small peptides (< 10 amino acids) but their self-assembly behavior has not be examined when fused to proteins that are 100-200 amino acids. Here, we hypothesize that molecular weight of the protein and the surface properties of the protein will be factors in determining its effect on ELP diblock self-assembly. In addition, the ELP block lengths and composition are hypothesized to be factors in the self-assembly behavior of protein ELP diblock fusions. This hypothesis is tested by fusing four proteins with different properties to various ELP diblocks and characterizing their self-assembly behavior. The proteins were found to dominate the self-assembly behavior. Proteins that disrupted self-assembly did so for all ELP diblock lengths and compositions. Protein that did not disrupt self-assembly behavior affected the thermal behavior of the hydrophilic block. Hydrophilic proteins increased the micelle-to-aggregate transition temperature while hydrophobic proteins decreased it. We also sought to understand the self-assembly of ELP diblocks on a theoretical basis. A previously developed model for the self-assembly of synthetic polymers was applied to our polypeptide system. Two parameters, solvent quality of the corona and surface tension of the hydrophobic block, were experimentally measured and used to fit the model. Predictions of micelle radius and aggregation numbers were in good agreement with experimental data. However, the corona was found to be unstretched compared to its Gaussian size by this model. Therefore, a new model was developed describing what is termed as weak micelles in which the corona is not stretched but rather close to Gaussian size. The weak micelle model prediction were also in good agreement with experimental data suggesting that ELP micelles are in the crossover regime between the previous model and the new model.</p> / Dissertation

Biomedical engineering

block copolymer

Elastin-like polypeptides

micelles

multivalent display

protein fusion

self-assembly

Characterization of Ethylene/α-Olefin Copolymers Made with a Single-Site Catalyst Using Crystallization Elution Fractionation

Alkhazaal, Abdulaal

January 2011

A new analytical technique to measure the chemical composition distribution (CCD) of polyolefins, crystallization elution fractionation (CEF), was introduced in 2006 during the First International Conference on Polyolefin Characterization. CEF is a faster and higher resolution alternative to the previous polyolefin CCD analytical techniques such as temperature rising elution fractionation (TREF) and crystallization elution fractionation (CRYSTAF) (Monrabal et al., 2007). Crystallization elution fractionation is a liquid chromatography technique used to determine the CCD of polyolefins by combining a new separation procedure, dynamic crystallization, and TREF. In a typical CEF experiment, a polymer solution is loaded in the CEF column at high temperature, the polymer is allowed to crystallize by lowering the solution temperature, and then the precipitated polymer is eluted by a solvent flowing through the column as the temperature is raised. CEF needs to be calibrated to provide quantitative CCD results. A CEF calibration curve consists of a mathematical relationship between elution temperature determined by CEF and comonomer fraction in the copolymer that could be estimated by Fourier transform infrared spectroscopy (FTIR) and carbon-13 nuclear magnetic resonance (13C NMR). Different comonomer types in ethylene/α-olefin copolymers will have distinct calibration curves. The main objective of this thesis is to obtain CEF calibration curves for several different ethylene/α-olefin copolymers and to investigate which factors influence these calibration curves. A series of homogeneous ethylene/α-olefin copolymers (1-hexene, 1-octene and 1-dodecene) with different comonomer fractions were synthesized under controlled conditions to create CEF calibration standards. Their average chemical compositions were determined by 13C NMR and FTIR and then used to establish CEF calibration curves relating elution temperature and comonomer molar fraction in the copolymer.

Ethylene/α-olefin copolymer

Calibration curves

Chemical Engineering

Pyrolysis Mass Spectrometric Analysis Of Copolymer Of Polyacrylonitrile And Polythiophene

Oguz, Gulcan

01 June 2004

In the first part of this work, the structural and thermal characteristics of polyacrylonitrile, polyacrylonitrile films treated under the electrolysis conditions in the absence of thiophene, polythiophene and the mechanical mixture and a conducting copolymer of polyacrylonitrile/polythiophene have been studied by pyrolysis mass spectrometry technique. The thermal degradation of polyacrylonitrile occurs in three steps / evolution of HCN, monomer, low molecular weight oligomers due to random chain cleavages are followed by cyclization and dehydrogenation reactions yielding crosslinked and unsaturated segments. Pyrolysis of the treated polyacrylonitrile films indicated decrease in the yields of monomer and oligomers, and increase in the amount of products stabilized by cyclization reactions were detected. Polythiophene degrades in two steps / the loss of the dopant and degradation of polymer backbone. The evolution profiles of polythiophene based products from polythiophene/polyacrylonitrile showed nearly identical trends with those recorded during the pyrolysis of pure polythiophene. However, evolution of HCN and the degradation products due to the homolytic cleavages of the polymer backbone continued through out the pyrolysis indicating a significant increase in their production. Furthermore, the yield of thermal degradation products associated with decomposition of the unsaturated cyclic imine segments decreased. A careful analysis of the data pointed out presence of mixed dimers confirming copolymer formation. In the second part of this work, a poly(acrylonitrile-co-butadiene) sample involving monomer units having quite similar molecular weights have been analyzed to investigate the limits of the pyrolysis mass spectrometry technique. Pyrolysis of aged poly(acrylonitrile-co-butadiene) indicated oxidative degradation of the sample. Keywords: conducting copolymer, polyacrylonitrile, polythiophene, polybutadiene, direct pyrolysis mass spectrometry

QD Polymers, Macromolecules 380-388

Aqueous Micellar Gels of Multiresponsive Hydrophilic ABA Linear Triblock Copolymers

Woodcock, Jeremiah Wallace

01 December 2011

This dissertation presents the synthesis of a series of well-defined multiresponsive hydrophilic ABA linear triblock copolymers and the study of their aqueous micellar gels. By incorporating a small amount of stimuli-responsive groups into thermosensitive outer blocks of ABA triblock copolymers, the lower critical solution temperatures (LCST) of thermosensitive blocks can be modified by external stimuli. Consequently, the sol-gel transition temperatures (Tsol-gel) of their aqueous solutions can be altered. Chapter 1 describes the synthesis and solution behavior of a series of thermo- and light-sensitive triblock copolymers, poly(ethoxytri(ethylene glycol) acrylate-co-o-nitrobenzyl acrylate)-b-poly(ethylene oxide)-b-poly(ethoxytri(ethylene glycol) acrylate-co-o-nitrobenzyl acrylate), with different contents of light-responsive o-nitrobenzyl groups. Aqueous solutions of these block copolymers with a 10.0 wt% concentration exhibited thermo-induced sol-gel transitions. Upon UV irradiation, the hydrophobic o-nitrobenzyl groups were cleaved, resulting in an increase in the LCST and consequently gel-to-sol transitions. The UV-irradiated solutions again underwent temperature-induced sol-gel transitions but at higher temperatures. The change of Tsol-gel was, in general, larger for the copolymer with a higher o-nitrobenzyl content after UV irradiation. Chapter 2 presents the synthesis of thermo- and enzyme-responsive ABA triblock copolymers, poly(ethoxydi(ethylene glycol) acrylate-co-4-((dihydroxyphosphoryl)oxy)butyl acrylate)-b-poly(ethylene oxide)-b-poly(ethoxydi(ethylene glycol) acrylate-co-4-((dihydroxyphosphoryl)oxy)butyl acrylate), and the enzyme-induced formation of thermoreversible micellar gels from their moderately concentrated aqueous solutions at 37 °C. The dephosphorylation by acid phosphatase decreased the LCST of thermosensitive outer blocks from above to below 37 °C. The enzyme-induced gelation of 7.9 wt % aqueous polymer solutions at pH 4.4 was monitored by rheological measurements. The Tsol-gel decreased and the gel strength increased with the increase of reaction time. The gels formed were thermoreversible. Chapter 3 presents the synthesis of two thermo- and pH-sensitive tertiary amine-containing ABA triblock copolymers and the sol-gel transitions of their aqueous solutions with a 10 wt% concentration at different pH values. Chapter 4 describes the use of reversible addition-fragmentation chain transfer (RAFT) polymerization for the synthesis of well-defined thermosensitive polymethacrylates and polyacrylates. Eight chain transfer agents were synthesized. The RAFT polymerizations of alkoxyoligo(ethylene glycol) (meth)acrylates using these chain transfer agents were well controlled, producing well-defined polymers. A summary of this dissertation research and future work are presented in Chapter 5.

Thermo Sensitive

random copolymer

Light responsive

enzyme triggered

monomer

NMR

Laboratory and Basic Science Research

Development of methoxy poly(ethylene glycol)-block-poly(caprolactone) amphiphilic diblock copolymer nanoparticulate formulations for the delivery of paclitaxel

Letchford, Kevin John

11 1900

The goal of this project was to develop a non-toxic amphiphilic diblock copolymer nanoparticulate drug delivery system that will solubilize paclitaxel (PTX) and retain the drug in plasma. Methoxy poly(ethylene glycol)-block-poly(ε-caprolactone) (MePEG-b-PCL) diblock copolymers loaded with PTX were characterized and their physicochemical properties were correlated with their performance as nanoparticulate drug delivery systems. A series of MePEG-b-PCL was synthesized with PCL blocks ranging from 2-104 repeat units and MePEG blocks of 17, 44 or 114 repeat units. All copolymers were water soluble and formed micelles except MePEG₁₁₄-b-PCL₁₀₄, which was water insoluble and formed nanospheres. Investigation of the effects of block length on the physicochemical properties of the nanoparticles was used to select appropriate copolymers for development as PTX nanoparticles. The critical micelle concentration, pyrene partition coefficient and diameter of nanoparticles were found to be dependent on the PCL block length. Copolymers based on a MePEG molecular weight of 750 g/mol were found to have temperature dependent phase behavior. Relationships between the concentration of micellized drug and the compatibility between the drug and core-forming block, as determined by the Flory-Huggins interaction parameter, and PCL block length were developed. Increases in the compatibility between PCL and the drug, as well as longer PCL block lengths resulted in increased drug solubilization. The physicochemical properties and drug delivery performance characteristics of MePEG₁₁₄-b-PCL₁₉ micelles and MePEG₁₁₄-b-PCL₁₀₄ nanospheres were compared. Nanospheres were larger, had a more viscous core, solubilized more PTX and released it slower, compared to micelles. No difference was seen in the hemocompatibility of the nanoparticles as assessed by plasma coagulation time and erythrocyte hemolysis. Micellar PTX had an in vitro plasma distribution similar to free drug. The majority of micellar PTX associated with the lipoprotein deficient plasma fraction (LPDP). In contrast, nanospheres were capable of retaining more of the encapsulated drug with significantly less PTX partitioning into the LPDP fraction. In conclusion, although both micelles and nanospheres were capable of solubilizing PTX and were hemocompatible, PTX nanospheres may offer the advantage of prolonged blood circulation, based on the in vitro plasma distribution data, which showed that nanospheres retained PTX more effectively.

Paclitaxel

Micelle

Nanosphere

Nanoparticle

Hemocompatibility

Solubilization

Plasma distribution

Flory Huggins interaction parameter

Biodegradable polymer

Block copolymer

Studies on Formation Mechanism of Higher-Order Structures in Aqueous Solutions of Associating Polymers / 会合性高分子水溶液における高次構造の形成機構に関する研究

Shibata, Motoki

23 March 2022

京都大学 / 新制・課程博士 / 博士(工学) / 甲第23921号 / 工博第5008号 / 新制||工||1782(附属図書館) / 京都大学大学院工学研究科高分子化学専攻 / (主査)教授 古賀 毅, 教授 中村 洋, 教授 竹中 幹人 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DGAM

associating polymer

higher-order structure

micelle

hydrogel

phase separation

random copolymer

methylcellulose

500

An investigation into the synthesis of poly(co-maleic anhydride/iso-butyl vinyl ether)with RAFT polymerisation.

Lea, Santa Cinzia, Chemical Sciences & Engineering, Faculty of Engineering, UNSW

January 2006

Poly (co iso-butyl vinyl ether-alt-maleic anhydride), an alternating copolymer, was synthesised. For this class of copolymers the formation of an electron-donor complex is invoked to explain their microstructure in which the two comonomers strictly alternate. Due to its polarity, this copolymer constitutes a potential additive for imparting hydrophilic properties to a hydrophobic matrix. In order to obtain narrow molecular weight polymers and study the relation between the molecular weight of this additive and its ability to migrate to the host polymer surface, chain transfer agents were introduced in the system and also the Reversible Addition-Fragmentation chain Transfer (RAFT) process was employed. Free radical polymerisation was first carried out to allow for a comparison with the RAFT process and kinetics of copolymerisation was studied by NIR-FTIR and 1H NMR spectroscopy in order to analyse the rate of reaction of each comonomer. Dibenzyl trithiobenzoate, 3-benzyl sulfanyl thiocarbonyl sulfanyl-propionic acid and dibenzyl trithiobenzoate were used as RAFT agents. Results demonstrate that only benzyl dithiobenzoate is able to control the molecular weight of this copolymer and decrease its polydispersity index; possible reasons laying behind this result are discussed. It was also found that, in particular in the presence of benzyl dithiobenzoate, poly(iso-butyl vinyl ether) forms. This is an unusual phenomenon considering that the free radical polymerisation affords alternating copolymers and that iso-butyl vinyl ether is a monomer that polymerises through the cationic process. Experiments were carried out in various solvents in an attempt to counteract this side reaction, but no appreciable correlation between the properties of the solvents and the formation of homopolymer were found. Various hypothesis are considered, however it is likely that, in the conditions adopted, the presence of the RAFT agents alters the equilibrium constant of complex formation favouring the synthesis of the homopolymer. In addition to this side???reaction also inhibition of the copolymerisation reaction was at times encountered and an investigation into this phenomenon was also conducted.

RAFT

alternating copolymer.

Copolymères triblocs biodégradables PLA-b-PEG-b-PLA pour ingénierie tissulaire : Caractérisation et modélisation de l'évolution de leurs propriétés mécaniques au cours de leur dégradation par hydrolyse / Biodegradable PLA-b-PEG-b-PLA tribloc copolymers : Characterization and modelling of the evolution of their mechanical properties during hydrolytic degradation

Breche, Quentin

15 November 2016

L’ingénierie tissulaire est une méthode de reconstruction d’organes et de tissus vivants. Elle consiste à ensemencer et faire coloniser un implant spécifique appelé scaffold par des cellules. Ce scaffold est un matériau architecturé doté d’une géométrie adaptée à l’organe à reconstruire. Sa fonction est de servir de guide et de support de régénération au tissu. Afin d’éviter les conséquences à long terme de la présence d’un implant synthétique dans l’organisme (risque de rejet, inflammation ...) l’idéal est d’utiliser un matériau biorésorbable qui, se dégradant au fur et à mesure de la reconstruction, laisse place aux néo-tissus formés. Les polymères biorésorbables sont, grâce à la vaste gamme de propriétés qu’ils proposent, les meilleurs candidats pour ce genre d’applications. Un polymère biorésorbable particulièrement intéressant est le PLA-b-PEG-b-PLA. En effet, celui-ci est biocompatible et possède, par sa structure tribloc, une potentielle vaste gamme de propriétés physiques et mécaniques. La réussite de la reconstruction tissulaire nécessite une parfaite connaissance du comportement mécanique du matériau constituant le scaffold ainsi que son évolution au cours de la dégradation.L’objectif de cette thèse est la caractérisation expérimentale et la modélisation du comportement mécanique des polymères PLA-b-PEG-b-PLA au cours de leur dégradation. L’intérêt est de fournir des outils de dimensionnement de scaffolds biorésorbables pour l’ingénierie tissulaire. Dans un premier temps, des essais de traction-relaxation ont été conduits sur un PLA-b-PEG-b-PLA à différents temps de dégradation. Afin de réaliser ces essais dans des conditions proches de celles rencontrées in vivo, un dispositif expérimental permettant d’accomplir des essais mécaniques en milieu immergé à une température de 37°C a été mis au point. A partir de ces essais, un modèle viscoélastique linéaire capable de prendre en compte la variation des propriétés mécaniques au cours de la dégradation pour de faibles déformations a été réalisé. Dans un second temps, afin de modéliser le comportement mécanique dans une gamme plus large de déformations, un modèle viscoélastique non-linéaire a été développé. Il s’agit d’un modèle quasi-linéaire viscoélastique adaptatif capable de prédire les courbes de traction-relaxation à différents niveaux de déformation ainsi que la perte de propriétés mécaniques au cours de la dégradation. Lors de la troisième partie, des PLA-b-PEG-b-PLA de compositions et masses molaires différentes ont été caractérisés afin d’étudier l’influence de la structure originelle du polymère sur leurs propriétés mécaniques et leur évolution au cours de la dégradation. La capacité du modèle viscoélastique linéaire précédemment développé à prédire le comportement des différents polymères a alors été discutée. Dans une dernière partie, le modèle viscoélastique linéaire dégradable a été utilisé pour simuler numériquement le comportement mécanique d’un tricot potentiellement utilisable en ingénierie tissulaire. / Tissue engineering is an interdisciplinary field that applies the principles of engineering and biological science toward the development of biological substitutes that restore, maintain or improve the development of a whole organ by tissue reconstruction. It consists in seeding an implant called scaffold with cells taken from the patient and cultivated in vitro. The cells will then colonize and recreate tissue that takes the shape of the scaffold. The scaffold is an architecture biomaterial specifically designed for a considered organ. The knowledge of mechanical properties of the scaffold is particularly important. Indeed, it often must be used as a mechanical substitute to the injured organ. Moreover, its mechanical properties must be compatible with those of the host tissue to allow a good tissue regeneration. The main advantage of using biodegradable materials is their degradation along the regeneration process. It means that the material no longer remains in the body at long term avoiding toxicity and inflammation risks. Among biodegradable materials, polymers are particularly interesting due to their large range of properties. A very good candidate for tissue engineering applications is the PLA-b-PEG-b-PLA biodegradable triblock copolymer. This polymer is biocompatible and possesses a good properties modulation. To allow a good tissue reconstruction, the knowledge of the mechanical properties of the scaffold as well as their evolution during degradation is essential.The aim of this work is to characterize experimentally and model the mechanical behavior of the PLA-b-PEG-b-PLA and its evolution during degradation. The interest is to provide tools to size and simulate biodegradable scaffolds for tissue engineering applications. At first, tensile-relaxation tests has been realized on the polymer during different degradation times. In order to realize the mechanical tests in conditions closed to in vivo ones, a specific experimental device has been designed that allows From this tests, a linear viscoelastic model able to take into account the variations of mechanical properties during degradation for small strain has been developed. Then, in order to model the mechanical behavior in a larger range of strain, a non-linear viscoelastic model was realized. In a third part, different polymers PLA-b-PEG-b-PLA with different initial composition has been mechanically characterized in order to study the influence of the original structure on mechanical properties and their evolution during degradation. To finish, the degradable linear viscoelastic model will be used to simulate numerically the mechanical behavior of a knitted textile for potential applications in tissue engineering.

Biodégradable

Copolymère

Dégradation

Hydrolyse

PLA

Ingénierie tissulaire

Biodegradable

Copolymer

Degradation

Hydrolysis

PLA

Tissue engineering

570.28

Vers l'industrialisation de l'auto-assemblage dirigé des copolymères à blocs : développement de procédés de lithographie compatibles avec les noeuds technologiques sub-10 nm pour des applications de type contacts / Towards the industrialization of directed self-assembly of block copolymers : development of lithographic processes compatible with sub-10 nm technology nodes for contact applications

Bouanani, Shayma

06 October 2017

La course à la compétitivité que se disputent les industriels du semi-conducteur implique d’augmenter le nombre de fonctionnalités par puce ainsi que de réduire leur coût unitaire, ce qui se traduit par une diminution continue de leur taille. Pour ce faire, le DSA (Directed Self-Assembly), ou auto-assemblage dirigé des copolymères à blocs associe les techniques de lithographie conventionnelle avec les propriétés d’organisation à l’échelle moléculaire des copolymères. Dans ce cadre, l’objectif global de cette thèse est d’évaluer le potentiel d’industrialisation du DSA par grapho-épitaxie pour des applications de type « shrink » et « multiplication » de contacts. Il s’agit en particulier de démontrer la capacité de cette technique à répondre au cahier des charges de l’ITRS en termes d’uniformité de CD, de désalignement et de taux de défauts. Une première étude concernant le « shrink de contact », basée sur l’impact des propriétés matériaux, d’affinité de surface et de tailles de guides permet de comprendre les mécanismes qui rentrent en jeu dans l’apparition de défauts d’assemblage. Une seconde partie de l’étude porte sur la multiplication de contact. Pour adresser cette application, deux types de guides ont été étudié : les guides elliptiques et les guides complexes dits « peanut ». L’étude de la fenêtre de procédé en termes de paramètres procédé comme le temps et la température de recuit, mais aussi de commensurabilité, a été menée. Une attention particulière a été portée sur l’impact de la variation du guide sur le pitch final obtenu en DSA, dont les données expérimentales ont été corrélées avec des résultats de simulation. Les critères de réussite sont basés sur les performances lithographiques qu’il faut juger à travers une métrologie de pointe. Le développement d’une métrologie spécifique pour mesurer l’erreur de placement des contacts ainsi que leur pitch a été conduite. / The competitiveness-chasing in which industrial manufactures are involved, leads to an exponential increase in the number of functionalities per chips, as well as reducing their unit cost, which results in a continuous decrease of their size. To achieve this, DSA (Directed Self-Assembly) of block copolymers, combines conventional lithography techniques with the molecular-scale organizational properties of copolymers. In this framework, the overall objective of this thesis is to evaluate the industrialization potential of the DSA process by graphoepitaxy for contact hole shrink and contact multiplication applications. In particular, it is necessary to demonstrate the ability of this technique to meet the ITRS specifications in terms of CD uniformity, misalignment and hole open yield. A first study on contact shrink, based on the impact of material properties, surface affinity and guiding feature size, allows us to understand the mechanisms involved in the appearance of defects. A second part of the study deals with contact multiplication. To address this application, two types of guides have been studied: elliptical guiding patterns and more complex ones called "peanut". The study of the process window in terms of process parameters such as annealing time and temperature, but also commensurability was conducted. Particular attention was paid to guide size variation and its impact on DSA final pitch. Experimental data from this study were correlated with simulations. The success criteria are based on the lithographic performances that must be judged through advanced metrology. The development of a specific metrology to measure the placement error of contacts as well as their pitch was conducted.

Auto-Assemblage

Copolymère à bloc

Lithographie

Métrologie

Self-Assembly

Block copolymer

Lithography

Metrology

620

Temperature-Responsive Hydrogels with Controlled Water Content and Their Development Toward Drug Delivery and Embolization Applications

January 2012

abstract: Aqueous solutions of temperature-responsive copolymers based on N-isopropylacrylamide (NIPAAm) hold promise for medical applications because they can be delivered as liquids and quickly form gels in the body without organic solvents or chemical reaction. However, their gelation is often followed by phase-separation and shrinking. Gel shrinking and water loss is a major limitation to using NIPAAm-based gels for nearly any biomedical application. In this work, a graft copolymer design was used to synthesize polymers which combine the convenient injectability of poly(NIPAAm) with gel water content controlled by hydrophilic side-chain grafts based on Jeffamine® M-1000 acrylamide (JAAm). The first segment of this work describes the synthesis and characterization of poly(NIPAAm-co-JAAm) copolymers which demonstrates controlled swelling that is nearly independent of LCST. The graft copolymer design was then used to produce a degradable antimicrobial-eluting gel for prevention of prosthetic joint infection. The resorbable graft copolymer gels were shown to have three unique characteristics which demonstrate their suitability for this application. First, antimicrobial release is sustained and complete within 1 week. Second, the gels behave like viscoelastic fluids, enabling complete surface coverage of an implant without disrupting fixation or movement. Finally, the gels degrade rapidly within 1-6 weeks, which may enable their use in interfaces where bone healing takes place. Graft copolymer hydrogels were also developed which undergo Michael addition in situ with poly(ethylene glycol) diacrylate to form elastic gels for endovascular embolization of saccular aneurysms. Inclusion of JAAm grafts led to weaker physical crosslinking and faster, more complete chemical crosslinking. JAAm grafts prolonged the delivery window of the system from 30 seconds to 220 seconds, provided improved gel swelling, and resulted in stronger, more elastic gels within 30 minutes after delivery. / Dissertation/Thesis / Ph.D. Bioengineering 2012

Biomedical engineering

Polymer chemistry

Medicine

graft copolymer

hydrogel

injectable

N-isopropylacrylamide