Restoration of Lung Sphingosine Levels Improves the Immune Response to Infection in a Murine Two-hit Sepsis/Pneumonia Model

Whitacre, Brynne E.

January 2017

No description available.

Immunology

sepsis

sphingosine

microparticles

alveolar macrophage

pulmonary infection

CLP

CONTROLLED PRESENTATION OF GENETIC MATERIAL WITHIN STEM CELL CONDENSATIONS FOR REGULATION OF CELL BEHAVIOR FOR BONE TISSUE ENGINEERING

McMillan, Alexandra

01 June 2018

No description available.

Biomedical Engineering

Biology

Polymeric Nanoparticles and Microcapsules for Biomedical Applications

Singh, Andrew

January 2024

Nanoparticle-based delivery vehicles have received substantial interest in the field of drug delivery particularly pertaining to chemotherapeutics. By virtue of their size, nanoscale drug delivery vehicles overcome many obstacles encountered by traditional systems. Moreover, nanocarriers can be fabricated to be ‘smart’, meaning they can be responsive to internal stimuli relating to the microenvironment of the tumor and/or external stimuli that can be delivered non-invasively from outside of the body. One such external trigger is ultrasound, well-known for its role in biomedical imaging based on its wide availability, non-invasiveness, and safety but increasingly being applied for drug delivery. This thesis proposes solutions to two key challenges associated with locally-targeted polymer-based drug delivery: enhanced tumor accumulation and externally-triggered control over release kinetics. In the former case, brush polymer PLA-PEG analogues are synthesized and explored to correlate how the architecture of these brush blocks affects the resulting self-assembled nanoparticle size, zeta potential, cytotoxicity in vitro, circulation time, and accumulation profiles in vivo. Indeed, brush copolymer analogues allow for copolymerization with additional monomers while conserving ‘stealth properties of linear copolymers, as well as exhibit superior circulation times and longer-term tumor accumulation. In the latter case, a new ultrasound-triggered drug delivery platform is designed consisting of a hollow polymeric shell in which silica “corks” are entrapped; the application of ultrasound can exploit the high difference in the compressibility between the polymeric shell and the silica corks to pop out or otherwise perturb the cork particles, allowing for both on-demand drug release as well as a pulsatile release profiles to be achieved. Overall, by manipulating the surface properties and/or morphologies of polymer-based micro/nanoparticles, the results of this thesis show that key challenges in local drug delivery can be addressed and applied specifically to applications in cancer therapy. / Dissertation / Doctor of Philosophy (PhD) / Drug delivery vehicles attempt to address many of the shortcomings of traditional therapeutics, in particular their low solubility and a lack of tissue targeting, which result in poor efficacy and unwanted side-effects. Polymers specifically have been commonly employed in biomedical applications as there are a wide range of biodegradable polymers that do not cause adverse effects during intended application and can be removed from the body through normal biological function. More recently, more advanced, ‘smart’ materials have been developed that can respond to internal or external stimuli to better address treatment needs. This thesis presents novel polymer-based drug delivery vehicles with new structures useful to passively target particular sites in the body and/or alter drug release profiles, enabling improved drug efficacy and reduced side-effects.

Drug Delivery

Nanoparticles

Microparticles

Microcapsules

Ultrasound

Stimuli-responsive

Impact of process variables on the micromeritic and physicochemical properties of spray-dried porous microparticles, part I: introduction of a new morphology classification system

Paluch, Krzysztof J., Tajber, L., Corrigan, O.I., Healy, A.M.

04 June 2012

Yes / Objectives This work investigated the impact of spray drying variables such as feedconcentration, solvent composition and the drying mode, on the micromeriticproperties of chlorothiazide sodium (CTZNa) and chlorothiazide potassium(CTZK).Methods Microparticles were prepared by spray drying and characterised usingthermal analysis, helium pycnometry, laser diffraction, specific surface area analysisand scanning electron microscopy.Key findings Microparticles produced under different process conditions pre-sented several types of morphology.To systematise the description of morphology ofmicroparticles, a novel morphology classification system was introduced. The shapeof the microparticles was described as spherical (1) or irregular (2) and the surfacewas classified as smooth (A) or crumpled (B). Three classes of morphology of micro-particles were discerned visually: class I, non-porous; classes II and III, comprisingdiffering types of porosity characteristics. The interior was categorised as solid/continuous (a), hollow (b), unknown (g) and hollow with microparticulate content(d). Nanoporous microparticles of CTZNa and CTZK, produced without recircula-tion of the drying gas, had the largest specific surface area of 72.3 and 90.2 m2/g,respectively, and presented morphology of class 1BIIIa.Conclusions Alteration of spray drying process variables, particularly solvent com-position and feed concentration can have a significant effect on the morphology ofspray dried microparticulate products. Morphology of spray dried particles may beusefully described using the morphology classification system. / The Irish Research Council for Science and Engineering Technology (IRCSET), the Solid State Pharmaceutical Cluster (SSPC), supported by Science Foundation Ireland under grant number [07/SRC/B1158] and the Irish Drug Delivery Research Network, a Strategic Research Cluster grant (07/SRC/B1154) under the National Development Plan co-funded by EU Structural Funds and Science Foundation Ireland.

Spray drying

Morphology

Solvent

Specific surface area

Amorphous

Nanoporous microparticles

A novel approach to crystallisation of nanodispersible microparticles by spray drying for improved tabletability

Paluch, Krzysztof J., Tajber, L., Adamczyk, B., Corrigan, O.I., Healy, A.M.

15 June 2012

Yes / High-dose API powders which are to be tableted by direct compression should have high compactibility and compressibility. This note reports on a novel approach to the manufacture of crystalline powders intended for direct compaction with improved compactibility and compressibility properties. The poorly compactable API, chlorothiazide, was spray dried from a water/acetone solvent mix producing additive-free nanocrystalline microparticles (NCMPs) of median particle size 3.5 μm. Tablets compacted from NCMPs had tensile strengths ranging from 0.5 to 4.6 MPa (compared to 0.6–0.9 MPa for tablets of micronised CTZ) at compression forces ranging from 6 kN to 13 kN. NCMP tablets also had high porosities (34–20%) and large specific surface areas (4.4–4.8 m2/g). The time taken for tablets made of NCMPs to erode was not statistically longer (p > 0.05) than for tablets made of micronised CTZ. Fragmentation of NCMPs on compression was observed. The volume fraction of particles below 1 μm present in the suspension recovered after erosion of NCMP tablets was 34.8 ± 3.43%, while no nanosized particles were detected in the slurry after erosion of compacted micronised CTZ. / Solid State Pharmaceutical Cluster (SSPC), supported by Science Foundation Ireland under grant number 07/SRC/B1158.

Spray drying

Tabletability

Specific surface area

Nanocrystalline microparticles

Erosion

Nanosuspension

Test de génotypage plaquettaire in vitro à base de sandwichs de microparticules biofonctionnalisées : détection par capteur de fluorescence à ondes évanescentes, imagerie de fluorescence et cytométrie en flux

Cornillon, Amandine

January 2014

Résumé : Cette thèse porte sur l’élaboration d’un outil de capture d’ADN permettant d’identifier une mutation génétique (SNP) grâce à la formation de sandwichs avec des particules de carboxylatex biofonctionnalisées avec des oligonucléotides couplée à une détection de la fluorescence. Le modèle biologique choisi pour ce projet est le génotypage plaquettaire et plus particulièrement la recherche du gène biallélique HPA-1. Le principal objectif de ce travail a été d’optimiser un outil de capture préalablement développé dans l’équipe (Trévisan, 2011) afin de réduire le nombre d’étapes et de simplifier la mise en œuvre globale du test en modifiant les interactions moléculaires utilisée pour capturer l’ADN cible et en utilisant des particules fluorescentes comme élément de détection. En présence d’ADN cible, des sandwichs sont formés entre les particules fluorescentes et les particules magnétiques biofonctionnalisées. Ces sandwichs sont purifiés par séparation magnétique et la fluorescence est détectée par trois méthodes : la cytométrie en flux, l’imagerie de fluorescence et l’Evareader (détection par ondes évanescentes). Dans un premier temps, les paramètres de fonctionnalisation chimique et biologique des différentes particules (magnétiques et fluorescentes) ont été déterminés et optimisés ainsi que les conditions d’hybridation pour la capture de l’ADN cible. Ensuite, la formation des sandwichs et leur détection ont été suivies par des mesures de fluorescence en utilisant trois méthodes différentes : la cytométrie en flux, l’imagerie de fluorescence et l’Evareader (capteur à ondes évanescentes). Les résultats obtenus avec les différentes méthodes de détection sont concordants et montrent que l’outil de capture d’ADN développé permet de capturer la cible synthétique (oligonucléotide) HPA-1 en réduisant le temps d’analyse de 45 min. Dans nos conditions, le test permet de discriminer l’allèle a de l’allèle b du gène HPA-1 qui ne diffère que d’un nucléotide. Le rapport des signaux de fluorescence issus du sandwich spécifique et du sandwich non spécifique est d’environ 2,5 à 3. Ce rapport devra être amélioré par la suite, en optimisant les conditions de formation des sandwichs. La prochaine étape consistera à optimiser le système de capture d’ADN développé pour gagner en spécificité et déterminer la limite de détection du test. Ce test devra également être validé avec des échantillons biologiques. A plus long terme, la fluorescence pourra être détectée par un photodétecteur miniaturisé actuellement développé à l’Université de Sherbrooke. Des études préliminaires présentées dans ce manuscrit montrent les potentialités de ce nouveau transducteur. // Abstract : This thesis is about the development of a new assay to capture DNA. This assay is based on the formation of sandwiches between biofunctionnalized with oligonucleotides carboxylatex microparticles combined with fluorescence detection. It should be able to discriminate single nucleotide polymorphism (SNP). This assay is designed to be applied to platelet genotyping for the research of the gene HPA-1. The main goal of this work was to improve an assay previously developed (Trévisan, 2011) by INL and EFS Rhône-Alpes. The objectives are to reduce the number of steps and to simplify the test. To do so, the molecular interactions used in order to capture target DNA are modified and fluorescent microparticles are used for the detection. In the presence of target DNA, sandwiches are formed between both biofunctionnalized fluorescent and magnetic particles. Those sandwiches are purified through magnetic separation. Then, fluorescence is detected by three methods: flow cytometry, fluorescence imaging and Evareader (detection with an evanescent wave). First, chemical and biological parameters for the functionalization of the different particles (magnetic and fluorescent) are determined. The conditions for the capture of target DNA were optimized. Then, the formation and the detection of the sandwiches were estimated by measuring the fluorescence using three different methods: flow cytometry, fluorescence imaging and Evareader. The results obtained with the three methods are consistent. They show that the new system enables to capture synthetic target (oligonucleotide) HPA-1 with a reduction of total time analysis of 45 min. In our conditions, SNP can be discriminated for HPA-1 gene. For this discrimination, the fluorescence signal ratio about 2.5 to 3. This ratio should be improved by optimizing the conditions of sandwiches formation. Next step will consist in the optimization of the system developed to capture DNA in order to gain specificity and to determine the limit of detection. This test should also be validated with biological samples. In the long term, fluorescence could be detected by a miniaturized photodetector developed in the University of Sherbrook. Preliminary studies presented in this manuscript show the potentialities of this new transducer.

Microparticules magnétiques

Microparticules fluorescentes

Sandwichs

Génotypage plaquettaire

Capteur à ondes évanescentes

Cytométrie en flux

Oligonucléotide

Magnetic microparticles

Fluorescent microparticles

Sandwiches

Patelet genotyping

Envanescent wave sensor

Flow cytométry

Oligonucleotide

Chitosan derived formulations and EmzaloidTM technology for mucosal vaccination against diphtheria : nasal efficacy in mice / Erika M. Truter

Truter, Erika Mare

January 2005

Previous studies have demonstrated that chitosan and its derivative, N-trimethyl chitosan chloride (TMC) are effective and safe absorption enhancers to improve mucosal delivery of macromolecular drugs including vaccines. Furthermore, chitosan and TMC can easily form microparticles and nanoparticles, which have the ability to encapsulate large amounts of antigens. Emzaloid™ technology has proven in the past to be an effective delivery system for numerous drugs. Emzaloids can entrap, transport and deliver large amounts of drugs including vaccines. In this study, the ability of chitosan microparticles and nanoparticles, TMC microparticles as well as micrometer and nanometer range Emzaloids to enhance both the systemic and mucosal (local) immune response against diphtheria toxoid (DT) after nasal administration in mice was investigated. The above mentioned formulations were prepared and characterised according to size and morphology. DT was then associated to the chitosan microparticles and nanoparticles as well as TMC microparticles to determine the antigen loading and release. It was found that the loading efficacy of the formulations was 88.9 %, 27.74 % and 63.1 % respectively, and the loading capacity of the formulations was 25.7 %, 8.03 % and 18.3 %. DT loaded and unloaded (empty) chitosan microparticles and nanoparticles, TMC microparticles, micrometer and nanometer range Emzaloids as well as DT in phosphate buffered saline (PBS) were administered nasally to mice. Mice were also vaccinated subcutaneous with DT associated to alum as a positive control. All mice were vaccinated on three consecutive days in week 1 and boosted in week 3. Sera was analysed for anti- DT IgG and nasal lavages were analysed for anti-DT IgA using an enzyme linked imrnunosorbent assay (ELISA). In the study conducted to determine the systemic (IgG) and local (IgA) immune responses it was seen that DT associated to all the experimental formulations produced a systemic immune response. The said formulations produced a significantly higher systemic immune response when compared to the formulation of DT in PBS. Furthermore, the mice vaccinated with DT associated to the TMC formulations showed a much higher systemic immune response than the mice that were vaccinated subcutaneously with DT associated to alum, whereas the other formulations produced systemic immune responses that were comparable to that of DT associated to alum. It was also found that DT associated to the experimental formulations produced a local immune response, however only DT associated to TMC microparticles produced a consistent local immune response. It can be concluded from the in vivo experiments that the TMC formulations, moreover, the TMC microparticles is the most effective and promising formulation for the nasal delivery of vaccines. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2005.

Nasal vaccination

Chitosan microparticles

Chitosan nanoparticles

Emzaloids

Diphtheria toxoid

Systematic immune response (IgG)

Local immune response (IgA)

ELISA assay

Chitosan derived formulations and EmzaloidTM technology for mucosal vaccination against diphtheria : nasal efficacy in mice / Erika M. Truter

Truter, Erika Mare

January 2005

Previous studies have demonstrated that chitosan and its derivative, N-trimethyl chitosan chloride (TMC) are effective and safe absorption enhancers to improve mucosal delivery of macromolecular drugs including vaccines. Furthermore, chitosan and TMC can easily form microparticles and nanoparticles, which have the ability to encapsulate large amounts of antigens. Emzaloid™ technology has proven in the past to be an effective delivery system for numerous drugs. Emzaloids can entrap, transport and deliver large amounts of drugs including vaccines. In this study, the ability of chitosan microparticles and nanoparticles, TMC microparticles as well as micrometer and nanometer range Emzaloids to enhance both the systemic and mucosal (local) immune response against diphtheria toxoid (DT) after nasal administration in mice was investigated. The above mentioned formulations were prepared and characterised according to size and morphology. DT was then associated to the chitosan microparticles and nanoparticles as well as TMC microparticles to determine the antigen loading and release. It was found that the loading efficacy of the formulations was 88.9 %, 27.74 % and 63.1 % respectively, and the loading capacity of the formulations was 25.7 %, 8.03 % and 18.3 %. DT loaded and unloaded (empty) chitosan microparticles and nanoparticles, TMC microparticles, micrometer and nanometer range Emzaloids as well as DT in phosphate buffered saline (PBS) were administered nasally to mice. Mice were also vaccinated subcutaneous with DT associated to alum as a positive control. All mice were vaccinated on three consecutive days in week 1 and boosted in week 3. Sera was analysed for anti- DT IgG and nasal lavages were analysed for anti-DT IgA using an enzyme linked imrnunosorbent assay (ELISA). In the study conducted to determine the systemic (IgG) and local (IgA) immune responses it was seen that DT associated to all the experimental formulations produced a systemic immune response. The said formulations produced a significantly higher systemic immune response when compared to the formulation of DT in PBS. Furthermore, the mice vaccinated with DT associated to the TMC formulations showed a much higher systemic immune response than the mice that were vaccinated subcutaneously with DT associated to alum, whereas the other formulations produced systemic immune responses that were comparable to that of DT associated to alum. It was also found that DT associated to the experimental formulations produced a local immune response, however only DT associated to TMC microparticles produced a consistent local immune response. It can be concluded from the in vivo experiments that the TMC formulations, moreover, the TMC microparticles is the most effective and promising formulation for the nasal delivery of vaccines. / Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2005.

Nasal vaccination

Chitosan microparticles

Chitosan nanoparticles

Emzaloids

Diphtheria toxoid

Systematic immune response (IgG)

Local immune response (IgA)

ELISA assay

Test de génotypage plaquettaire in vitro à base de sandwich de microparticules biofonctionnalisées : Détection par capteur de fluorescence à ondes évanescentes, imagerie de fluorescence et cytométrie en flux / Biofunctionnalized microparticles based sandwiches for in vitro platelet genotyping test : detection by evanescent waves biosensor, fluorescence scanner and flow cytometry

Cornillon, Amandine

18 December 2014

Cette thèse porte sur l’élaboration d’un outil de capture d’ADN permettant d’identifier une mutation génétique (SNP) grâce à la formation de sandwichs avec des particules de carboxylatex biofonctionnalisées avec des oligonucléotides couplée à une détection de la fluorescence. Le modèle biologique choisi pour ce projet est le génotypage plaquettaire et plus particulièrement la recherche du gène biallélique HPA-1. Le principal objectif de ce travail a été d’optimiser un outil de capture préalablement développé dans l’équipe (Trévisan, 2011) afin de réduire le nombre d’étapes et de simplifier la mise en oeuvre globale du test en modifiant les interactions moléculaires utilisée pour capturer l’ADN cible et en utilisant des particules fluorescentes comme élément de détection. En présence d’ADN cible, des sandwichs sont formés entre les particules fluorescentes et les particules magnétiques biofonctionnalisées. Ces sandwichs sont purifiés par séparation magnétique et la fluorescence est détectée par trois méthodes : la cytométrie en flux, l’imagerie de fluorescence et l’Evareader (détection par ondes évanescentes). Dans un premier temps, les paramètres de fonctionnalisation chimique et biologique des différentes particules (magnétiques et fluorescentes) ont été déterminés et optimisés ainsi que les conditions d’hybridation pour la capture de l’ADN cible. Ensuite, la formation des sandwichs et leur détection ont été suivies par des mesures de fluorescence en utilisant trois méthodes différentes : la cytométrie en flux, l’imagerie de fluorescence et l’Evareader (capteur à ondes évanescentes). Les résultats obtenus avec les différentes méthodes de détection sont concordants et montrent que l’outil de capture d’ADN développé permet de capturer la cible synthétique (oligonucléotide) HPA-1 en réduisant le temps d’analyse de 45 min. Dans nos conditions, le test permet de discriminer l’allèle a de l’allèle b du gène HPA-1 qui ne diffère que d’un nucléotide. Le rapport des signaux de fluorescence issus du sandwich spécifique et du sandwich non spécifique est d’environ 2,5 à 3. Ce rapport devra être amélioré par la suite, en optimisant les conditions de formation des sandwichs. La prochaine étape consistera à optimiser le système de capture d’ADN développé pour gagner en spécificité et déterminer la limite de détection du test. Ce test devra également être validé avec des échantillons biologiques. A plus long terme, la fluorescence pourra être détectée par un photodétecteur miniaturisé actuellement développé à l’Université de Sherbrooke. Des études préliminaires présentées dans ce manuscrit montrent les potentialités de ce nouveau transducteur. / This thesis is about the development of a new assay to capture DNA. This assay is based on the formation of sandwiches between biofunctionnalized with oligonucleotides carboxylatex microparticles combined with fluorescence detection. It should be able to discriminate single nucleotide polymorphism (SNP). This assay is designed to be applied to platelet genotyping for the research of the gene HPA-1. The main goal of this work was to improve an assay previously developed (Trévisan, 2011) by INL and EFS Rhône-Alpes. The objectives are to reduce the number of steps and to simplify the test. To do so, the molecular interactions used in order to capture target DNA are modified and fluorescent microparticles are used for the detection. In the presence of target DNA, sandwiches are formed between both biofunctionnalized fluorescent and magnetic particles. Those sandwiches are purified through magnetic separation. Then, fluorescence is detected by three methods: flow cytometry, fluorescence imaging and Evareader (detection with an evanescent wave). First, chemical and biological parameters for the functionalization of the different particles (magnetic and fluorescent) are determined. The conditions for the capture of target DNA were optimized. Then, the formation and the detection of the sandwiches were estimated by measuring the fluorescence using three different methods: flow cytometry, fluorescence imaging and Evareader. The results obtained with the three methods are consistent. They show that the new system enables to capture synthetic target (oligonucleotide) HPA-1 with a reduction of total time analysis of 45 min. In our conditions, SNP can be discriminated for HPA-1 gene. For this discrimination, the fluorescence signal ratio about 2.5 to 3. This ratio should be improved by optimizing the conditions of sandwiches formation. Next step will consist in the optimization of the system developed to capture DNA in order to gain specificity and to determine the limit of detection. This test should also be validated with biological samples. In the long term, fluorescence could be detected by a miniaturized photodetector developed in the University of Sherbrook. Preliminary studies presented in this manuscript show the potentialities of this new transducer.

Microparticules magnétiques

Microparticules fluorescentes

Sandwichs

Génotypage plaquettaire

Capteur à ondes évanescentes

Cytométrie en flux

Oligonucléotide

Magnetic microparticles

Fluorescent microparticles

Sandwiches

Platelet genotyping

Evanescent wave sensor

Flow cytometry

Oligonucleotide

Mechanisms of Anti-Angiogenic Signaling by CD36

Ramakrishnan, Devi Prasadh

13 February 2015

No description available.

Molecular Biology

Biology

Angiogenesis

CD36

Microparticles

Microvesicles

Microvascular Endothelial Cells

VEGF

VEGFR2

Thrombospondin

TSR

TSP-1

SHP-1

Oxidative stress

NADPH oxidase

Plasma microparticles

Vasculitis

new blood vessel