Development of novel analytical methodologies based on biomolecular conformational changes

Lee, May May

January 2003

No description available.

543

Studium produkce extracelulárních polymerů pomocí mikroorganismu Aureobasidium pullulans / Production of extracellular polymeric substances by Aureobasidium pullulans

Horáček, Pavel

January 2013

The diploma thesis is focused on the study of the influence of cultivation conditions and arrangement for the production of extracellular polymeric substances by using yeast-like microorganism Aureobasidium pullulans. In the theoretical part a brief description of A. pullulans, its use in biotechnology and produced exobiopolymers, especially pullulan and poly-L-malic acid are presented. The first aim of the experimental part was to set the most appropriate cultivation conditions for A. pullulans CCM 8182. Growth and production properties in optimum conditions were compared with cultivation on waste substrates - oat bran, buckwheat husks, apple fiber and others. Waste substrates can be used as cheap nutrient sources which enable reducing cost of potential biotechnological production. As a further part of this work, optimization of HPLC/RI method for analysis of exobiopolymers has been done. Optimal mobile phase composition and chromatography conditions were proposed. Column Roa organic acid H+ was the most suitable for simultaneous separartion of glucose and malic acid. Before HPLC analysis hydrolysis of polymers was done. Sulphuric acid (5 mmol/L) was used as a mobile phase at flow rate 0.5 mL/min and temperature 60 °C. The highest production of pullulan occurred using oat bran as a substarate (13.03 g/L) at an initial pH 7.5. Maximum production of poly-L-malic acid was observed during the cultivation on apple peels (2.89 g/L) at pH 6. It was found that the higher production of poly-L-malic acid occurred at pH 6, while higher production of pullulan was at pH 7.5.

Synthesis and characterization of Alendronate functionalized Poly (l-lactide) polymers for engineering bone tumor targeting nanoparticles

Sriadibhatla, Soma Sekhar

January 1900

Master of Science / Department of Chemistry / Santosh Aryal / Nanomedicine-based therapeutics have exhibited clear benefits when compared to unmodified drugs, which include improved pharmacokinetics, drug retention, targeting efficiency, and minimizes toxicity. Every year thousands of bone cancer cases are diagnosed in the United States. Moreover, development of bone metastasis occurs in over 80% to 90% of various cancers that metastasize and signals the entry of the disease into an incurable phase. Cancer in bones can cause pain, fractures, hypercalcemia, and compression of the spinal cord, due to deposits that can erode into the bone using bone-absorbing cells. Bisphosphonates are drugs that reduce the activity of bone-absorbing cells and targets overexpressed calcium. They are characterized pharmacologically to inhibit bone resorption, skeletal distribution, and renal elimination. In addition, they can target bone microenvironment and bind strongly with calcium. The goal of this thesis is to engineer targeted nanomedicine drug with the ability to spatiotemporally control therapeutics delivery to the bone. Herein we synthesized biopolymers with functional end group moieties as alendronate (a molecular member of bisphosphate), which can target overexpressed calcium ions at the vicinity of the bone lesion where bone resorption takes place. In order to achieve our goal, a ring opening polymerization of cyclic L-lactide initiated by ALE in the presence of catalytic amount of stannous octoate was conducted in an inert environment. Thus, formed polymers are characterized for their chemistry and physicochemical properties using various analytical tools. These polymers were characterized by nuclear magnetic resonance (¹H-NMR) and Fourier Transfer Infrared Spectrometer (FT-IR), which shows monomer conversion and the presence of amide and phosphate moiety. Thereafter we engineered bone-homing polymeric nanoparticles of 80nm diameter by nanoprecipitation for controlled delivery of Dox, a first line anticancer drug used in clinics. The in-vitro results show that the nanoparticles have the ability to accumulate and internalized into the bone cancer cells, deliver drugs efficiently, and are least toxic. Therefore, innovative and efficient bisphosphonate functionalized Poly-l-lactide polymers were synthesized to target bone microenvironment.

Poly(l-lactide)

Nanomedicine

Bone tumor

Drug delivery

Targeting

Bisphosphonates

Synthesis, characterisation and invitro evaluation of PLLA-co-succinic anhydride networks

George, Karina Anne

January 2006

The biocompatibility and the in vivo degradation of poly(L-lactide), (PLLA)- based materials has prompted much interest in the development of these materials into scaffolds for tissue engineering applications. PLLA-based polymers have been available for use in craniomaxillofacial surgery since 1991. Usually, a plate or sheet of the polymer is placed in or over a defect in the bone. Ideally the bone will use the polymer as a support to repair the defect and as the polymer degrades, the bone will continually remodel, so that the loss of mass and mechanical strength of the polymer correlates with the increase in the mass and strength of the new bone. However, this is an ideal situation, and is not always observed in practice. The aim of this work is to develop PLLA-based materials that should encourage bone growth onto the material and allow control over the rate of degradation. PLLA-co-succinic anhydride networks were synthesised and the mineralisation and degradation of these materials were evaluated in vitro. The synthesis of these networks, involved the polymerisation of 4-arm star PLLA polymers, which were coupled through their end groups with succinic anhydride. The low molecular weight star PLLA polymers were synthesised using calcium hydride and pentaerythritol as initiator and co-initiator respectively. Calcium hydride was preferred to stannous octoate in this study as there is concern over the release of tin-containing when the polymer is implanted. As only very limited studies have been directed into the polymerisation and resulting polymers formed using calcium hydride, this was a major focus of the study. The identification of hydrogen in the reaction tubes was evidence that calcium alkoxide, formed from the reaction of pentaerythritol and calcium hydride, is the actual initiating species for the ring opening polymerisation. In situ FT-Raman spectroscopy was used as a tool to monitor the reaction process and was found to be a convenient and reliable method for obtaining information about the polymerisation kinetics. Analysis of the FTRaman kinetic curves, along with analysis of products by GPC, polarimetry and NMR spectroscopy showed that the polymerisation was 'quasi-living' depending on the ratio of pentaerythritol and calcium hydride in the system. Furthermore, both the degree of transesterification and racemisation of polymers synthesised in optimised reactions were low. The PLLA-co-succinic anhydride networks were synthesised by coupling of hydroxyl-terminated PLLA star polymers with succinic anhydride (one-pot reaction) and by coupling hydroxyl-terminated PLLA stars with succinic anhydride-terminated PLLA star polymers (two-pot reaction), using a carbodiimide, EDC to mediate the esterification. The one-pot reaction produced polymers with high gel fractions and high conversion of functional groups in the gel, whereas the gel fraction and conversion of functional groups was lower in the two-pot reaction. For the networks synthesised in the one-pot reaction, the molecular weight between crosslinks was controlled by the length of the PLLA polymer arms. The networks synthesised were characterised by FTIR-ATR spectroscopy, SEM, contact angle and by swelling. The extent of mineralisation of the PLLA-co-succinic anhydride networks in simulated body fluid (SBF) after 14 days was greater than the mineral deposition on the high molecular weight PLLA reference polymer. The degradation of the networks was carried out under accelerated conditions in 0.1 M NaOH at 37 degrees Celsius. All networks degraded much more slowly than the high molecular weight linear PLLA reference sample. The rate of degradation was found to be dependent on the crystallinity of the polymer chains, with the more crystalline networks degrading at a faster rate, while the location of the degradation, surface or bulk, was controlled by the crosslink density, showing that the degradation is 'tuneable'.

craniomaxillofacial surgery

poly(L-lactide)

(PLLA)- based materials

Fabrication of Micro and Nanoparticles of Paclitaxel-loaded Poly L Lactide for Controlled Release using Supercritical Antisolvent Method: Effects of Thermodynamics and Hydrodynamics

Lee, Lai Yeng, Smith, Kenneth A., Wang, Chi-Hwa

01 1900

This paper presents the fabrication of controlled release devices for anticancer drug paclitaxel using supercritical antisolvent method. The thermodynamic and hydrodynamic effects during supercritical antisolvent process on the particle properties obtained were investigated. Scanning electron microscopy was employed to study particle sizes and morphologies achieved. It was observed that increasing supercritical pressure improves the surface morphology of particles obtained, and increasing the flow rate of the organic solution jet reduces the particle sizes obtained. A modified Supercritical Antisolvent with Enhanced Mass transfer setup was developed to produce monodispersed nanoparticles with high recovery yield. High performance liquid chromatography was used to determine the encapsulation efficiency and in vitro release profiles of paclitaxel loaded particles obtained. The encapsulation efficiencies of particles obtained using the modified SASEM process were high and up to 83.5%, and sustained release of paclitaxel from the polymer matrix was observed over 36 days release. The thermogram properties of the particles were also analyzed using differential scanning calorimetry to determine the crystalline state of polymer and drug. / Singapore-MIT Alliance (SMA)

Supercritical antisolvent

controlled release devices

paclitaxel

Poly L lactide

ultrasonication

Structure and blood compatibility of highly oriented poly(l-lactic acid) chain extended by ethylene glycol diglycidyl ether

Li, Z., Zhao, X., Ye, L., Coates, Philip D., Caton-Rose, Philip D., Martyn, Michael T.

14 November 2014

Yes / Highly-oriented poly(l-lactic acid) (PLLA) with fibrillar structure and micro-grooves was fabricated through solid hot drawing technology for further improving the mechanical properties and blood biocompatibility of PLLA as blood-contacting medical devices. In order to enhance the melt strength and thus obtain high orientation degree, PLLA was first chain extended with ethylene glycol diglycidyl ether (EGDE). The extending degree as high as 25.79 mol% can be obtained at 0.7 wt% EGDE content. The complex viscosity, storage and viscous modulus for chain extended PLLA were improved resulting from the enhancement of molecular entanglement, and consequently higher draw ratio can be achieved during the subsequent hot stretching. The tensile strength and modulus of PLLA were improved dramatically by stretching. The stress-induced crystallization of PLLA occurred during drawing. The interfacial tension (γs·blood) between PLLA surface and blood decreased by chain extension and molecular orientation, indicating the weakened interaction between bioactive substance in the blood and the surface of PLLA. Modification and orientation could significantly enhance the blood compatibility of PLLA by prolonging clotting time and decreasing hemolysis ratio, protein adsorption and platelet activation. The bionic character of oriented PLLA and its anti-coagulation mechanism were tried to be explored. / This research was supported by National Natural Science Foundation of China (Grant No. 51303109)

Poly (l-lactic acid) (PLLA)

Orientation

Blood compatibility

Factors Contributing to Degradation of Holmium-166 Poly-L- Lactic Acid Microspheres

Tigwell, Mackenzie

January 2023

This research studied Ho166/PLLA microspheres, a promising treatment for tumours in the liver. The Ho166 is generated through a neutron capture reaction during irradiation in a nuclear reactor. Previous work has found that neutron-irradiation in-core causes damage to microspheres and causes additional degradation to progress once suspended in media. The cause of this damage was not well understood and is the focus of this research. This research studied factors present in-core such as heat, gamma radiation, and impacts of lead shielding, for their impact on microsphere quality. Additionally, this research looked at the potential of reactive oxygen species causing damage once microspheres are suspended in liquid. Thresholds for damage were identified to correlate with the glass transition temperature of poly- l-lactic acid. Exposure to gamma radiation induces heating, as well as structural changes to the polymer which shifts the temperature where the glass transition occurs. Damage formed from gamma radiation, independent of other variables, was seen at extreme accumulated doses. Notably, exposure to gamma radiation and heat did not cause a progression of damage over time. Samples exposed only to these factors remained stable in solution for extended periods. A theory was proposed that reactive oxygen species formed by the interaction of ionizing radiation with the suspending media may be causing the progression of damage over time. This factor would only be present for microspheres having undergone neutron capture reactions, forming radioactive holmium. Testing confirmed a potential impact of radiation interactions with the suspending media contributing to damage progression. Several thicknesses of lead shielding surrounding the sample chamber were tested in-core. There were significant impacts on temperature, neutron flux, and microsphere quality. / Thesis / Master of Science (MSc) / This research studied Ho166/PLLA microspheres, a promising treatment for tumours in the liver. The preparation of this treatment includes microspheres being neutron irradiated in the core of a nuclear reactor. Irradiation in-core leads to damage of microspheres. This research studied factors present in-core such as heat, gamma radiation, and thickness of lead shielding, for their impact on microsphere quality. Additionally, this research looked at the potential of reactive oxygen species causing damage once microspheres are suspended in liquid. Thresholds for damage were identified for temperature and gamma radiation exposure. Radiation interactions in liquid suggest possible damaging effects over time. Finally changing the thickness of lead shielding in core had significant impact on temperature, neutron flux, and microsphere quality.

Microsphere

Holmium

Selective Internal Radiation Therapy

Poly-L-lactic acid

POROUS POLYMER MEMBRANES AS SUPPORTING SCAFFOLDS FOR BILAYER UPID MEMBRANES (BLM)

DHOKE, MANJIRI ARVIND

27 September 2005

No description available.

Bilayer Lipid Membranes

Polymers Membranes

Poly (l-lactic Acid)

Doppelthydrophile Blockcopolymere als Mineralisationstemplate

Kasparova, Pavla

January 2002

Die vorliegende Arbeit beschäftigt sich mit der Synthese und den Eigenschaften von doppelthydrophilen Blockcopolymeren und ihrer Anwendung in einem biomimetischen Mineralisationsprozeß von Calciumcarbonat und Bariumsulfat. Doppelthydrophile Blockcopolymere bestehen aus einem hydrophilen Block, der nicht mit Mineralien wechselwirkt und einem zweiten Polyelektrolyt-Block, der stark mit Mineraloberflächen wechselwirkt. Diese Blockcopolymere wurden durch ringöffnende Polymerisation von N-carboxyanhydriden (NCA′s) und a-methoxy-ω-amino[poly(ethylene glycol)] PEG-NH2 als Initiator hergestellt.<br /> Die hergestellten Blockcopolymere wurden als effektive Wachstumsmodifikatoren für die Kristallisation von Calciumcarbonat und Bariumsulfat Mineralien eingesetzt. Die so erhaltenen Mineralpartikel (Kugeln, Hantel, eiförmige Partikel) wurden durch Lichtmikroskopie in Lösung, SEM und TEM charakterisiert. Röntgenweitwinkelstreuung (WAXS) wurde verwendet, um die Modifikation von Calciumcarbonat zu ermitteln und die Größe der Calciumcarbonat- und Bariumsulfat-Nanopartikel zu ermitteln. / This work describes the synthesis and characterization of double hydrophilic block copolymers and their use in a biomimetic mineralization process of Calcium Carbonate and Barium Sulfate.<br /> Double hydrophilic block copolymers consist of a hydrophilic block that does not interact with minerals and another hydrophilic polyelectrolyte block that strongly interacts with mineral surfaces. These polymers were synthesised via ring opening polymerisation of N-carboxyanhydride (NCA), and the first hydrophilic block a-methoxy-ω-amino[poly(ethylene glycol)] PEG-NH2 was used as an initiator.<br /> The prepared block copolymers were used as effective crystal growth modifiers to control the crystallization of Calcium Carbonate and Barium Sulfate minerals. The resulting mineral particles (spheres, dumbbells, egg-like particles) were characterised by light microscopy in solution, by SEM, and by TEM. X-Ray scattering measurements (WAXS) were used to prove the modification of Calcium Carbonate particles and to calculate the size of Calcium Carbonate and Barium Sulfate nanoparticles.

Chemistry and allied sciences

Nouveaux dendrigrafts de poly-L-lysine (DGL) fonctionnalisés : vers des architectures de type "Janus" / Novel functional poly-L-lysine dendrigrafts (DGL) : toward "Janus" architectures

Liu, Tao

18 December 2012

Les dendrimères de type Janus (à deux faces) prennent une importance croissante du fait de leurs applications thérapeutiques ou diagnostiques potentielles, mais demandent des synthèses multi-étapes laborieuses. Les dendrigrafts de poly-L-Lysine (DGL) récemment découverts proposent une alternative "à faible coût" aux dendrimères. Ces DGL sont préparés par cycles successifs de polycondensation d'un N-carboxyanhydride (Lys(Tfa)NCA) dans l'eau suivie de la déprotection des chaînes latérales. Le spectre d'applications des DGL déjà identifiées s'élargira nettement si l'on parvient à construire des architectures DGL de type "Janus", ce qui requiert de fonctionnaliser le DGL (avec des groupes "clickables") de façon contrôlée, tant au cœur qu'en périphérie.Le chapitre I est une synthèse bibliographique qui montre les principales différences entre dendrimères et dendrigrafts, et qui résume l'état de l'art du domaine en ce qui concerne les matériaux à base de lysine.Le chapitre II étudie la fonctionnalisation périphérique du DGL par la chimie Click-Huisgen (CuAAC), et met en avant l'électrophorèse capillaire (EC) et l'analyse de la dispersion de Taylor (TDA), qui sont des outils efficaces pour caractériser le degré de fonctionnalisation du DGL, en montrant que celle-ci est homogène et régulière.Le Chapitre III est consacré à la synthèse et caractérisation de DGL fonctionnalisés à cœur (par un bras PEG portant un azoture terminal "clickable"), obtenus en modifiant la synthèse des DGL natifs, en particulier via l'amorçage de la condensation de NCA par une amine fonctionnelle. L'accessibilité de la fonction à cœur a été étudiée par réaction Click avec un chromophore, et par des tests de reconnaissance immunochimique en compétition.Enfin le chapitre IV résume notre stratégie de synthèse vers des DGL de type Janus (à deux face) et présente des résultats préliminaires qui valident le concept, avec comme perspective plus lointaine un accès éventuel à des DGL "Janus" à trois faces. / "Janus"-like (double-faced) dendrimers gain increasing attention for their high potential of therapeutic or diagnostic applications, however involving tedious, multistep synthesis. Recently discovered poly-L-lysine dendrigrafts (DGL), prepared through the alternation of N-carboxyanhydride (Lys(Tfa)-NCA) polycondensation in aqueous medium with deprotection of side chain amines, constitute promising "low-cost" equivalents of dendrimers. The already identified spectrum of DGL applications will benefit from an easy access to "Janus"-like DGL architectures, what requires controlled functionalisation (suitable for further click chemistry) of both core and periphery of DGLs.The chapter I is a bibliographic survey of the topic, highlighting the main differences between dendrigrafts and dendrimers, and summarising the state-of the-art about lysine-based materials in both domains.The chapter II investigates the surface functionalisation of DGL by Huisgen Click chemistry (CuAAC), and promotes capillary electrophoresis (CE) and Taylor Dispersion Analysis (TDA) as efficient analytic tools for characterising the functionalisation extent of DGL, thus proving the regularity and homogeneity of surface functionalisation.The chapter III is devoted to the synthesis and characterisation of core-functionalised DGL (bearing a PEG2–4 spacer with a clickable azido endgroup), through a modification of the "native" DGL synthetic route, involving initiation of NCA polycondensation in water by a functional amine. The DGL core group accessibility was assessed by click coupling with a chromophore group, and by immunochemical competition assays, concluding that a sufficiently long PEG linker ensures good core group accessibility.The chapter IV outlines the synthetic route toward double faced Janus DGL and presents preliminary results as a proof of the concept. Further, this synthetic strategy might potentially be extended to three-faced Janus DGL.

Dendrimères greffés

Poly-L-lysine

Chimie Click

Architecture Janus

Fonctionnalisation chimique

Dendrigrafts

Poly-L-lysine

Click chemistry

Janus architecture

Chemical functionalization