Photo-crosslinked and pH sensitive polymersomes for triggering the loading and release of cargo

Gaitzsch, Jens, Appelhans, Dietmar, Gräfe, David, Schwille, Petra, Voit, Brigitte

January 2011

Crosslinkable and pH-sensitive amphiphilic block copolymers are promising candidates to establish pH-stable and permeable vesicles for synthetic biology. Here, we report the fabrication of crosslinked and pH-stable polymersomes as swellable vesicles for the pH-dependent loading and release of small dye molecules. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

info:eu-repo/classification/ddc/540

ddc:540

Interest of Penta-block Copolymer in The Development of Microparticles for A Protein Sustained Release Application / Intérêt du copolymère penta-block dans le développement de microparticules pour une application à libération prolongée d'une protéine

Lê, Minh quân

05 July 2017

L'objectif de cette thèse est de préparer des microsphères chargées en une protéine modèle, le lysozyme, en utilisant un nouveau copolymère pentabloc. La libération de protéine à partir des microsphères obtenues doit être continue et complète sur une période d’au moins un mois. Des copolymères pentabloc PLGA-P188-PLGA et une protéine modèle, le lysozyme, ont été utilisés. La présence du bloc central P188 la masse molaire du segment PLGA, le type de solvant, la concentration en polymère, la vitesse d’agitation de l’émulsion et la teneur en tensioactif ont tous un effet sur la porosité des microsphères. La teneur en tensioactif et la vitesse d'agitation ont principalement contribué au contrôle de la taille des particules. En ajustant les caractéristiques du segment PLGA et les paramètres du procédé, la libération de la protéine a été améliorée. Une libération prolongée et complète de protéines sur 8 semaines a été obtenue en suivant le modèle d’Higuchi. La modulation du profil de libération de la protéine a été obtenue par un mélange physique de différentes microsphères. Cette stratégie peut-être appliquée à une seule protéine ou dans le cadre d’une thérapie combinée. / The aim of this thesis is to formulate protein-loaded microspheres with penta-block copolymers for a sustained and completed protein release for at least one month. A new PLGA-P188-PLGA penta-block copolymers were used. The presence of a P188 central block facilitated the control of particle morphology and size. LA/GA ratio, the molecular weight of PLGA segment, solvent type, polymer concentration, emulsifying speed and surfactant content all affected microsphere porosity.The surfactant concentration and agitation speed principally contributed to particle size control. By adjusting the polymer characteristics and the process parameters, the protein release was improved remarkably. An 8-week completed and sustained protein release complying with the Higuchi model was achieved. The physical mixing of different microparticles was then studied for modulating release profile.The achievement of protein delivery with controlled release profile raised its applicability, especially for one protein sustained release or combined therapy.

Libération prolongée de protéine

Copolymère pentabloc

Morphologie

Microencapsulation

Modulation de libération

Protein sustained release

Penta-Block copolymer

Morphology

Microencapsulation

Release modulation

615

Synthesis and Functionalization of Poly(ethylene oxide-b-ethyloxazoline) Diblock Copolymers with Phosphonate Ions

Chen, Alfred Yuen-Wei

29 October 2013

Poly(ethylene oxide) (PEO) and poly(2-ethyl-2-oxazoline) (PEOX) are biocompatible polymers that act as hydrophilic "stealth" drug carriers. As block copolymers, the PEOX group offers a wider variety of functionalization. The goal of this project was to synthesize a poly(ethylene oxide)-b-poly(2-ethyl-2-oxazoline) (PEO-b-PEOX) block copolymer and functionalize pendent groups of PEOX with phosphonic acid. This was achieved through cationic ring opening polymerization (CROP) of 2-ethyl-2-oxazoline monomer onto PEO. These polymerizations used tosylsulfonyl chloride as initiator. Size-exclusion chromatography (SEC) was used to determine the molecular weights of the block copolymers. Two samples of 1:2 and one sample of 1:3 of PEO-to-PEOX block copolymers were made. These samples underwent partial hydrolysis of the PEOX pendent groups to form the random block copolymer, poly(ethylene oxide)-b-poly(2-ethyl-2-oxazoline)-co-poly(ethyleneimine) (PEO-b-PEOX-co-PEI). These reactions showed that there was a degree of control based on the moles of acid. Diethyl vinyl phosphonate was attached to the nitrogen of PEI units via Michael addition where the phosphorylation left <1% of PEI units unattached. The ethyl groups on the phosphonates were further hydrolyzed off phosphonate with HCl acid leaving phosphonic acid. After each step of synthesis, structures and composition were confirmed using ¹H NMR. Due to the nature of the phosphonic acid, the polymer can be utilized in the incorporation and release of cationic drugs. / Master of Science

poly(ethylene oxide)

poly(2-ethyl-2-oxazoline)

ion encapsulation

phosphonate

phosphonic acid

nanoparticles

functionalized random copolymer

Droplets, Films and Edges: Studies of the Physical Character of Diblock Copolymers

Croll, Andrew B.

January 2008

Block copolymers, long chain molecules of two distinct chemical species joined covalently to one another, have long been known to form organized structures on the nanoscopic level. For example, if the two chains are the same length a lamellar structure results . In this work we show how this internal structure causes distinct deviation from 'normal' fluid behavior. We begin with the observation of block copolymer droplets with atomic force microscopy. We note the droplets form nearly conical shapes in stark contrast to the usual spherical cap. These droplets are found t o spread at an incredibly slow speed, and to have interesting instabilities in their wetting layer. We move on to studies of completely wet substrates (i.e. thin films) near the order-disorder transition of the material. Here we directly observe, with optical microscopy, a change in the fundamental spacing of the diblock's internal structure. This represents a superior method of measurement of the Flory-Huggins interaction parameter, which we verify in several ways. We also use the change in lamellar thickness to drive diffusion from one layer to another, and by similar measurements we can determine the kinetics of diffusion between the lamellar layers. In the last study we measure the lamellar edges on a gradient thickness sample with optical microscopy. In so doing we can directly observe surface induced ordering, and for the first time, can precisely resolve the near surface ordering dynamics. / Thesis / Doctor of Philosophy (PhD)

block copolymer

fluid

droplets

optical microscopy

atomic force microscopy

Flory-Huggins interaction parameter

thin films

lamellar edges

Surface Modification of PLGA Electrospun Scaffolds for Wound Healing and Drug Delivery Applications

Iselin, Jacob A.

January 2008

No description available.

Biomedical Research

Engineering

Polymers

Electrospin

PLGA

surface modification

collagen

fibronectin

PEG-grafted chitosan

PLGA-PEG-PLGA triblock copolymer

Additively Manufactured Cyclic Olefin Copolymer Tissue Culture Devices With Transparent Windows Using Fused Filament Fabrication

Saliba, Rabih

13 July 2022

No description available.

Chemical Engineering

Additive Manufacturing

Transparent Windows

Cyclic Olefin Copolymer

Fused Filament Fabrication

Organ-on-Chip

Lab-on-Chip

Microfluidic

Non-Oxide Porous Ceramics from Polymer Precursor

Yang, Xueping

01 January 2014

Non-oxide porous ceramics exhibit many unique and superior properties, such as better high-temperature stability, improved chemical inertness/corrosive resistance, as well as wide band-gap semiconducting behavior, which lead to numerous potential applications in catalysis, high temperature electronic and photonic devices, and micro-electromechanical systems. Currently, most mesoporous non-oxide ceramics (e.g. SiC) are formed by two-step templating methods, which are hard to adjust the pore sizes, and require a harmful etching step or a high temperature treatment to remove the templates. In this dissertation, we report a novel technique for synthesizing hierarchically mesoporous non-oxide SiC ceramic from a block copolymer precursor. The copolymer precursors with vairing block length were synthesized by reversible addition fragmentation chain transfer polymerization. The block copolymers self-assemble into nano-scaled micelles with a core-shell structure in toluene. With different operation processes, hollow SiC nanospheres and bulk mesoporous SiC ceramics were synthesized after the subsequent pyrolysis of precorsur micelles. The resultant SiC ceramics have potential applications in catalysis, solar cells, separation, and purification processes.The polymer synthesis and pyrolysis process will investigated by NMR, FTIR, GPC, TEM, and TGA/DSC. The morphology and structure of synthesised SiC hollow spheres and mesoporous ceramics were analyzed by SEM, TGA/DSC and BET/BJH analysis. Besides forming core shell micelles in selective solvent Toluene, we found that PVSZ-b-PS could also exhibit this property in the air water interface. By inducing the Langmuir-Blodgett deposition, a precursor monolayer with homogeously distributed povinylsilazane particles deposited on silicon wafer synthesized by spreading the diblock copolymer PVSZ-b-PS in the air water interface. After the pyrolysis process, orderly arranging SiC nano particles formed from the polymer precursor monolayer doped on the surface of silicon wafer, which shows great potential as an optoelectronic material. The deposition process and the relationship between compress pressure and monolayer morphology were studies, and the structure of monolayer and SiC dots were investigated by AFM, SEM.

Non oxide ceramics

diblock copolymer

polymer derived ceramics

hierarchical mesopores

hollow nanospheres

ceramic thin film

Engineering

Materials Science and Engineering

Characterization of Self-Assembled Functional Polymeric Nanostructures: I. Magnetic Nanostructures from Metallopolymers II. Zwitterionic Polymer Vesicles in Ionic Liquid

Maddikeri, Raghavendra Raj

01 February 2013

Two diverse projects illustrate the application of various materials characterization techniques to investigate the structure and properties of nanostructured functional materials formed in both bulk as well as in solutions. In the first project, ordered magnetic nanostructures were formed within polymer matrix by novel metallopolymers. The novel metal-functionalized block copolymers (BCPs) enabled the confinement of cobalt metal ions within nanostructured BCP domains, which upon simple heat treatment resulted in room temperature ferromagnetic (RTFM) materials. On the contrary, cobalt functionalized homopolymer having similar chemical structure and higher loading of metal-ion are unstructured and exhibited superparamagnetic (SPM) behavior at room temperature. Based on a series of detailed investigations, using various materials characterization techniques, it was hypothesized that the SPM cobalt particles within BCP microdomains exhibited a collective behavior due to increased dipolar interactions between them under the nanoconfinement of cylindrical domains in BCP, resulting in RTFM behavior. On contrary, the same SPM cobalt particles formed within homopolymer, without any confinement exhibited SPM behavior either due to lack of interactions or random interactions between them. To further support this hypothesis, a series of BCPs were prepared in which the BCP morphology was varied between the cylindrical, lamellar, and inverted cylindrical phases and their magnetic properties were compared. All these BCPs, which are nanostructured, exhibited RTFM behavior, further supporting the proposed hypothesis. Different dimensionality or degree of nanoconfinement in BCP morphologies affected the magnetization reversal processes in these BCPs, yielding different macroscopic magnetic properties. Most strongly constrained cylindrical morphology has shown best magnetic properties (highest coercivity) among other BCP morphologies. Inverted cylindrical morphology, in which a 3-D matrix is confined between the non-magnetic cylinders, had second highest and lamellar morphology with least confinement among BCPs, exhibited lowest coercivity. The proposed hypothesis was further tested by systematically varying the dipolar interactions between the SPM cobalt nanoparticles by reducing the density of cobalt within the cylindrical domains and varying the dimensions of the cylindrical domains (i.e. diameter). A series of novel ferrocene-cobalt containing block copolymers were developed and cobalt density within the cylindrical domains of BCP was varied by changing the chemical composition of the metal functionalized block. Further, the diameter of the cylindrical domains was varied by varying the molecular weight of the cobalt-containing BCPs. These studies allowed us to understand the fundamental correlations between the self-assembled nanostructures and their macroscopic magnetic properties. In the second part of the thesis, a novel amphiphilic block copolymer (ABC), composed of a hydrophilic zwitterionic block and a hydrophobic PS block, was synthesized by ROMP. The formation of zwitterionic vesicles in an ionic liquid, as well as in PBS buffer, was confirmed by TEM and DLS characterization. The dispersion of vesicles within ionic liquid enabled the usage of conventional, room temperature TEM to visualize them in their solution state. This technique of materials characterization could be extended for the visualization of other hydrophilic soft matter.

Diblock Copolymer

Functional Polymers

Magnetic Materials

Materials Characterization

Metal-functionalized polymers

Self-assembly

Materials Science and Engineering

Polymer Science

Controlled polymerization for drug delivery to the eye

Prosperi-Porta, Graeme

January 2015

ABSTRACT Effective drug delivery to ocular tissues is an unmet challenge that has significant potential to improve the treatment of ocular diseases. Whether the intended drug delivery target is the anterior or posterior segment, the eye’s efficient natural protection mechanisms prevent effective and sustained drug delivery. Anatomical and physiological barriers including the rapid tear turnover that effectively washes away topically applied drugs, the impermeable characteristics of the cornea, conjunctiva, and sclera, and the tight junctions in the blood-ocular barriers make conventional drug delivery methods ineffective. New materials that are able to overcome these barriers are essential to improving the sustained delivery of ophthalmic therapeutics to the intended targets within the eye. This thesis will explore two polymeric drug delivery systems that have the potential to improve therapeutic delivery to ocular tissues. Chapter 1 will discuss the anatomical and physiological barriers to ophthalmic drug delivery and overview current research in this area. Chapter 2 will discuss the synthesis of N-isopropylacrylamide-based copolymers with adjustable gelation temperatures based on composition and molecular weight. Chapter 3 will discuss further development of these copolymers into an injectable, thermoresponsive, and resorbable polymeric drug delivery system intended for the treatment of diseases in the posterior segment. Chapter 4 will discuss the development of mucoadhesive polymeric micelle nanoparticles based on phenylboronic acid intended for topical administration of ophthalmic therapeutics. Finally, Chapter 5 will provide an overview of potential future work on these materials that could further develop and broaden their therapeutic use. / Thesis / Master of Science in Biomedical Engineering

Confined crystallization, crystalline phase deformation and their effects on the properties of crystalline polymers

Wang, Haopeng

January 2009

No description available.

Chemical Engineering

Materials Science

Plastics

Polymers

Confined crystallization

nanolayer

coextrusion

gas permeability

olefin block copolymer

free volume