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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Role of sphingolipids and polyubiquitin chains in intracellular trafficking of the yeast Gap1 permease

Lauwers, Elsa 24 October 2007 (has links)
In the past fifteen years, ubiquitin has emerged as a central regulator of membrane protein trafficking. In this context, covalent attachment of this small protein to lysine residues of cargo proteins, a reversible modification termed ubiquitylation, provides a signal for their targeting to the vacuolar/lysosomal lumen where they are degraded, both in yeast and higher eukaryotes. Ubiquitylation is also used as a means of controlling the function of specific proteins in several trafficking machineries. The role of lipids - and in particular of membrane domains named lipid rafts - in controlling the intracellular trafficking of membrane proteins has also been the subject of intense investigation in recent years. One of the membrane proteins of the yeast Saccharomyces cerevisiae whose intracellular trafficking has been extensively studied is the general amino acid permease Gap1. Yet some aspects of the function of ubiquitin in the nitrogen-dependent control of this protein remain controversial. Moreover, the potential role of lipid rafts in regulating the functional properties and traffic of the Gap1 permease had not been investigated before this thesis work. The first part of our work readdresses the role of Gap1 ubiquitylation, and more precisely of the modification of the permease with polyubiquitin chains linked through the lysine 63 of ubiquitin, in controlling the fate of this protein in the secretory pathway. Our observations indicate that nitrogen-induced ubiquitylation of newly synthesised Gap1 occurs in the trans-Golgi complex. However, contrary to the generally accepted view, this modification is not necessary for the permease to exit this compartment en route to the endosome but only for its subsequent targeting to the vacuolar lumen via the multivesicular body (MVB) pathway. Our results also provide evidence that K63-linked polyubiquitylation is important mostly at the late endosomal level, for proper sorting of Gap1 into the MVB pathway, whether the permease comes from the cell surface by endocytosis or directly from the secretory pathway. In the second part of this work, we present a set of data providing novel insights into the controversial question of the exact nature of lipid rafts in yeast. We first showed that the Gap1 permease is associated with detergent-resistant membranes (DRMs) - the proposed biochemical equivalent of lipid rafts - when it is located at the cell surface. Our data further suggest that this may be true for most if not all yeast plasma membrane proteins. Moreover, we found that Gap1 production must be coupled to de novo synthesis of sphingolipids (SLs), major constituents of rafts, in order for the newly synthesised permease to be correctly folded, active, associated with DRMs, and stable at the cell surface. We propose a model where Gap1 would associate with newly synthesised SLs during its biogenesis and/or secretion, this association shaping the permease into its native conformation and ensuring its incorporation and stabilisation in specific lipid domains at the plasma membrane. Failure of Gap1 to acquire this lipidic microenvironment in turns leads to its ubiquitin-dependent degradation by a quality-control mechanism. This model might be valid for many other plasma membrane proteins and might account for their lateral distribution between distinct membrane domains.
2

Development of dry powder formulations of proteins for inhalation / Développement de formulations sèches de protéines pour inhalation

Depreter, Flore 26 April 2012 (has links)
A number of therapeutic proteins are used for long in clinical practice. These include for example insulin, calcitonine, growth hormone, and parathyroid hormone for the treatment of various systemic disorders, as well as protein antigens in vaccine formulations. Due to the recent developments in biochemical engineering and in the comprehension of the physiopathology of many diseases, peptides and proteins are expected to become a drug class of increasing importance. Recently, novel biological drugs have for example been developed such as monoclonal antibodies, antibody fragments, soluble receptors, and receptor agonists or antagonists. These are mainly used for the treatment of auto-immune and inflammatory diseases (asthma, rheumatoid arthritis) and for the treatment of cancers. However, a major drawback of these biomolecules is the need to use parenteral administration. This is mainly due to the harsh pH conditions that proteins undergo by oral administration, leading to various physico-chemical degradations and loss of biological activity. <p><p>Pulmonary delivery of these proteins could constitute an alternative to parenteral delivery. Due to the very high surface area of the lungs, the low thickness of the alveolar epithelium and the high level of lung vascularisation, pulmonary administration can indeed provide fast systemic absorption of drugs, while avoiding hepatic first pass metabolism. On the other hand, drugs for local treatment can also be administered directly into the lung, which allows delivering high doses while limiting systemic side effects. Nevertheless, administration of drugs to the lungs requires some challenges to be taken up. It is indeed necessary to provide the drug as very small solid or liquid microparticles (1-5 µm) in order to reach the lungs. For solid microparticles, it is also needed to overcome the very high inter-particle interactions by using appropriate formulation strategies and by including deaggregation mechanisms in the inhalation device. Other issues are more specifically related to the pulmonary administration of proteins. These can indeed undergo physico-chemical degradations during processing, administration, and/or storage. Moreover, if systemic action is required, proteins will often need addition of an absorption enhancer to cross the alveolar epithelium because of their large molecular weight and hydrophilicity. <p><p>In this work, we developed formulations for pulmonary delivery of proteins using two model proteins. Insulin (5.8 kDa) was chosen as a model of small protein. It is also an application of systemic pulmonary delivery. On the other hand, an anti-IL13 monoclonal antibody fragment (54 kDa) was used as a model of larger protein. This molecule is currently in development for the treatment of asthma and provided an application for local pulmonary delivery. The formulation strategy was to produce dry powders using a combination of micronisation techniques (high speed and high pressure homogenisations), drying techniques (spray-drying, freeze-drying), and addition of lipid excipients. These lipid excipients were added as a coating around the protein particles and were expected to prevent protein degradations during processing and/or storage, essentially by avoiding contact with water. It could also improve the aerodynamic properties of the powders by modification of the surface properties of the particles and/or limitation of the capillary forces.<p><p>First, we evaluated insulin lipid-coated formulations and formulations without excipients, produced using high pressure homogenisation and spray-drying. In the case of lipid-coated formulations, a physiological lipid composition based on a mixture of cholesterol and phospholipids was used. We were able to obtain good aerodynamic features for the different formulations tested, with fine particle fractions between 46% and 63% versus 11% for raw insulin powder. These are high FPF values in comparison with those obtained for other protein formulations for inhalation currently under development, which often have an in vitro deposition of around 30%. Insulin presented a good stability in the dry state, even when no lipid coating was added.<p>The presence of a lipid coating of up to 30% (w/w) did not significantly improve the aerodynamic behaviour of the powders, but the coated formulations exhibited decreased residual moisture content after 3-month storage, which should be of interest for the long-term stability of the formulations. <p><p>In a second step, two of the developed insulin formulations were evaluated in a clinical study to determine whether the formulations give high deep lung deposition in vivo, and how insulin is absorbed into the systemic blood stream. This pharmaco-scintigraphic trial was performed on twelve type 1 diabetic patients using an uncoated formulation and a formulation coated with 20% (w/w) of lipids. The two formulations showed interesting features, with pharmacokinetic profiles that mimic the natural insulin secretion pattern. Bioavailability was within the ranges of two of the three dry powder insulins that have reached phase III clinical development. However, the formulation with a lipid coating exhibited a lower lung deposition in comparison with the uncoated formulation, which was not expected from the previous in vitro results. Additional in vitro experiments indicated that this lower performance was related to a decrease in the disaggregation efficiency of the powder at a sub-optimal inhalation flow-rate. An extensive training of the patients to the inhalation procedure could therefore improve the lung deposition of the coated formulation.<p><p>Finally, we developed and evaluated dry powder formulations of the anti-IL13 antibody fragment. These were produced using, successively, freeze-drying, high pressure homogenisation (HPH), and spray-drying. The influence of different types and concentrations of stabilising excipients was evaluated for each production step. Due to its more elaborated structure, the antibody fragment was found to be more sensitive than insulin to physico-chemical degradation, particularly during the HPH process, which led to different types of degradation products. These could partly be avoided by adding 50% sucrose during freeze-drying and 10% Na glycocholate or palmitic acid in the liquid phase during HPH (dispersing agents). However, the presence of a small fraction of insoluble aggregates could not be fully avoided. Further spray-drying of the suspensions in the presence of 10% Na glycocholate or palmitic acid led to the formation of a hydrophilic or hydrophobic coating around the particles, respectively. Na glycocholate was found to be particularly effective in protecting the antibody during spray-drying, which was found to be at least partly related to its ability to inhibit sucrose recrystallisation. However, the best formulation still presented a small fraction of insoluble aggregates (6%). The aerodynamic evaluation of the formulations showed FPFs that were compatible with lung deposition, with the formulation containing Na glycocholate presenting the highest FPF (42%). The formulation coated with palmitic acid presented a slightly lower FPF (35%). The aerodynamic properties of this formulation remained unchanged at a sub-optimal inspiratory flow rate, to the contrary of what was observed for the insulin formulation coated with 20% (w/w) cholesterol and phospholipids. Palmitic acid could therefore be of interest as a hydrophobic coating material, and provide long-term stability of protein drugs. <p>The work performed with the insulin and anti-IL13 molecules provided the proof-of-concept that it was possible to obtain dry powder protein formulations with appropriate aerodynamic properties and good overall physico-chemical stability, using simple production techniques and few selected excipients. The formulation strategy presented in this work could therefore be of interest for the future development of inhaled proteins for local or systemic applications. <p> / Doctorat en sciences pharmaceutiques / info:eu-repo/semantics/nonPublished
3

Role of sphingolipids and polyubiquitin chains in intracellular trafficking of the yeast GAP1 permease

Lauwers, Elsa 24 October 2007 (has links)
In the past fifteen years, ubiquitin has emerged as a central regulator of membrane protein trafficking. In this context, covalent attachment of this small protein to lysine residues of cargo proteins, a reversible modification termed ubiquitylation, provides a signal for their targeting to the vacuolar/lysosomal lumen where they are degraded, both in yeast and higher eukaryotes. Ubiquitylation is also used as a means of controlling the function of specific proteins in several trafficking machineries. The role of lipids - and in particular of membrane domains named lipid rafts - in controlling the intracellular trafficking of membrane proteins has also been the subject of intense investigation in recent years.<p>One of the membrane proteins of the yeast Saccharomyces cerevisiae whose intracellular trafficking has been extensively studied is the general amino acid permease Gap1. Yet some aspects of the function of ubiquitin in the nitrogen-dependent control of this protein remain controversial. Moreover, the potential role of lipid rafts in regulating the functional properties and traffic of the Gap1 permease had not been investigated before this thesis work. <p>The first part of our work readdresses the role of Gap1 ubiquitylation, and more precisely of the modification of the permease with polyubiquitin chains linked through the lysine 63 of ubiquitin, in controlling the fate of this protein in the secretory pathway. Our observations indicate that nitrogen-induced ubiquitylation of newly synthesised Gap1 occurs in the trans-Golgi complex. However, contrary to the generally accepted view, this modification is not necessary for the permease to exit this compartment en route to the endosome but only for its subsequent targeting to the vacuolar lumen via the multivesicular body (MVB) pathway. Our results also provide evidence that K63-linked polyubiquitylation is important mostly at the late endosomal level, for proper sorting of Gap1 into the MVB pathway, whether the permease comes from the cell surface by endocytosis or directly from the secretory pathway. <p>In the second part of this work, we present a set of data providing novel insights into the controversial question of the exact nature of lipid rafts in yeast. We first showed that the Gap1 permease is associated with detergent-resistant membranes (DRMs) - the proposed biochemical equivalent of lipid rafts - when it is located at the cell surface. Our data further suggest that this may be true for most if not all yeast plasma membrane proteins. Moreover, we found that Gap1 production must be coupled to de novo synthesis of sphingolipids (SLs), major constituents of rafts, in order for the newly synthesised permease to be correctly folded, active, associated with DRMs, and stable at the cell surface. We propose a model where Gap1 would associate with newly synthesised SLs during its biogenesis and/or secretion, this association shaping the permease into its native conformation and ensuring its incorporation and stabilisation in specific lipid domains at the plasma membrane. Failure of Gap1 to acquire this lipidic microenvironment in turns leads to its ubiquitin-dependent degradation by a quality-control mechanism. This model might be valid for many other plasma membrane proteins and might account for their lateral distribution between distinct membrane domains. <p> / Doctorat en Sciences / info:eu-repo/semantics/nonPublished
4

The milk fat globule membrane: physico-chemical studies and its techno-functional valorisation in buttermilk

Vanderghem, Caroline 04 June 2009 (has links)
Vanderghem Caroline. (2009). La membrane du globule gras du lait : études physico-chimiques et sa valorisation technofonctionnelle dans les babeurres (Thèse de doctorat en Anglais). Gembloux, Belgique, Faculté Universitaire des Sciences Agronomiques de Gembloux. 198p., 14 tabl., 59 fig. Résumé La membrane du globule gras du lait (MGGL) est une structure complexe qui enveloppe, protège et délivre des composants bioactifs et des nutriments dune façon efficace au nouveau-né. Sa structure est unique par rapport à dautres systèmes biologiques de transport de lipides. Lobjectif général de ce travail a été de contribuer à augmenter les connaissances et la compréhension de cet émulsifiant naturel. La première partie de cette thèse concerne létude de la structure de la MGGL. Limportance des protéines membranaires concernant la stabilité et leur disposition dans la MGGL ont été étudiés. Les protéines de la MGGL sont présentes en petite quantité dans le lait et une technique de pré-fractionnement simpose afin de les isoler par rapport aux autres protéines du lait (caséines et protéines du lactosérum). Une technique dextraction qui a été développée dans notre laboratoire a été testée afin disoler la MGGL de la crème laitière. Une analyse détaillée a révélé que cette procédure est très bien adaptée pour lélimination dun maximum de protéines du lait écrémé. Une approche protéomique a été établie et a permis lidentification de protéines majeures de la MFGM ainsi que dautres protéines mineures (GTP-binding proteins, annexins, actin) afin de compléter le protéome. Par la suite, différentes protéases ont été testées en vue dobtenir différents degrés et/ou sélectivité dhydrolyse des protéines de la MGGL. La distribution asymétrique des protéines de la MGGL a été étudiée par une approche basée sur lattaque protéolytique du globule gras natif. Sur base de nos résultats et des données bibliographiques récentes, un nouveau modèle de la structure de la MGGL est proposé. La deuxième partie de cette thèse est consacrée à évaluer les propriétés technofonctionnelles de la MGGL dans les babeurres. Les propriétés interfaciales, moussantes et émulsifiantes du babeurre sont comparées à dautres ingrédients laitiers comme le lait écrémé et le concentré protéique de lactosérum. Nos résultats montrent le bon pouvoir émulsifiant du babeurre en comparaison des autres ingrédients laitiers. Dans les émulsions recombinées, la stabilité envers le crémage a été améliorée et les membranes ont présenté une meilleure résistance face à la coalescence. Les résultats sur la tension interfaciale et les propriétés rhéologiques interfaciales ont été mis en relation avec certaines propriétés des mousses et des émulsions. Vanderghem Caroline. (2009). The milk fat globule membrane: physico-chemical studies and its techno-functional valorisation in buttermilk (Thèse de doctorat). Gembloux, Belgium, Gembloux Agricultural University, 198p., 14 tabl., 59 fig. Summary The milk fat globule membrane (MFGM) is a complex structure that surrounds, protects and delivers bioactive compounds and nutrients in an efficient manner to the neonate. Its structure is unique in relation with any other biological lipid transport system. The overall aim of this work was to contribute to increase the knowledge and comprehension of this natural emulsifier. The first part of this thesis concerned the study of the structure of the MFGM. Membrane proteins were targeted and their importance regarding stability and disposition in the MFGM was studied. MFGM proteins are present at low concentrations in milk and a pre-fractionation of the sample is required in order of MFGM proteins to be visible among other milk proteins (caseins and whey proteins). A mild procedure developed in our laboratory was tested in order to isolate MFGM from cream. Detailed analysis revealed that this procedure is very well suited for the elimination of a maximum of skim milk proteins. A proteomic approach was established and allowed the identification of the most important MFGM proteins and additional minor MFGM proteins for additional completion of the proteome (GTP-binding proteins, annexins, actin). Subsequently, different proteases were screened in an attempt to obtain different degrees and/or selective proteolysis of MFGM proteins. Asymmetric arrangement of MFGM proteins was studied with an approach based on the proteolytic attack on the native fat globule. Based on our results and recent bibliographic data, an updated model of the MFGM structure was proposed. The second part of this thesis was devoted to assess the techno-functional properties of the MFGM in buttermilks. Interfacial, foaming and emulsifying properties of buttermilk were assessed and compared to classic milk ingredients such as skim milk and whey protein concentrate. Our results highlighted that buttermilk possesses good emulsifying power compared to other milk ingredients. In buttermilk recombined emulsions stability towards creaming was improved and the recombined membrane presented a great resistance to coalescence. Results of the interfacial pressure and the interfacial rheological properties were related to some foams and emulsions properties.
5

Development and evaluation in vitro and in vivo of injectable hydrolipidic gels with sustained-release properties for the management of articular pathologies / Développement et évaluation in vitro et in vivo de gels hydrolipidiques injectables à libération prolongée pour le traitement de pathologies articulaires

Reeff, Jonathan 25 June 2014 (has links)
Future changes in the incidence and prevalence of OA are difficult to predict. As incidence and prevalence rise with increasing age, extending life expectancy will result in greater numbers with OA. Actually, usual therapeutic approaches are really restricted because of important side effects with long-term use. Therefore, there is a need to develop improved formulations which are well tolerated, biocompatible and biodegradable. Ideally, these new treatments should be able to deliver locally sufficient amount of anti-inflammatory or analgesic drugs into the site of arthritic inflammation while stabilizing or better restoring the mechanical integrity of the joint. In this way, the objective of this project is to develop slow-release gels that are sterile, injectable, characterized by viscoelastic properties and capable to sustain the in situ release of both hydrophilic and lipophilic drugs. The intraarticular delivery combined to sustained-release property should be interesting to reduce the number of injection required while prolonging the local drug activity over weeks. For that purpose, glycerol monooleate (GMO), also called “monolein” was selected for its capacity to form highly viscous crystalline phase structures upon contact with an aqueous fluid (e.g. synovial fluid). <p>In the first step of this work, it was decided to develop and characterize hydro-lipidic gels based on the use of monolein and hyaluronic acid in order to provide in vitro sustained release of hydrophilic drugs such as clonidine and lipophilic drugs such as betamethasone. Initially, a compatibility study was performed on the main ingredients selected in order to check that there were not physico-chemical incompatibilities, which could be deleterious regarding to their stability in formulation. Then, the development of hydro-lipidic gels was initiated by considering on the first hand the solubility of each ingredient and on the other hand the syringeability, the rheological properties and the in vitro dissolution profiles obtained for the developed formulations. The objective of this preformulation program was to identify potential candidates that presented suitable syringeability while being able to sustain the release of drugs over weeks and being characterized by interesting viscoelastic properties for the long-term management of osteoarthritis. Moreover, several methods of quantification and characterization were developed in order to allow the physico-chemical properties (rheology, syringeability, water uptake, stability and dissolution profiles) of the developed formulations to be studied.<p>Results of the compatibility study showed that the concomitant use of monolein, hyaluronic acid and clonidine/betamethasone is not contraindicated. Next, the preformulation program allowed many injectable drug delivery systems to be prepared. However, the carrier that best meets our needs was composed of 10,0 % (wt/wt) absolute ethanol ;15,0 % propylene glycol (wt/wt) ;15,0 % (wt/wt) water ;55,0 % (wt/wt) de monolein ;5,0 % (wt/wt) purified soybean oil ;0,03 % (wt/wt) α-tocophérol and 7,5 mg/g sodium hyaluronate (1.9 MDa). This carrier assured suitable syringeability and rheological properties. Indeed, it presented marked pseudoplastic flow behavior that allowed relatively fast injection through a narrow needle, followed by an increase in viscosity upon contact with aqueous fluids to obtain an in vitro sustained release of hydrophilic and lipophilic drugs over a few weeks. As a consequence, it was assumed that this carrier should be able to jellify in situ upon contact with physiological fluid such as synovial fluid. Then, according to EMA recommendations, a fast and easy manufacturing process that could be applied in a cleanroom at industrial scale was validated in our Laboratory. Finally, according to these promising results obtained in vitro, a stability study was performed on the carrier alone and containing clonidine or betamethasone according to ICH recommendations described for products intended for storage in a refrigerator. In that purpose, several parameters such as the quantification of drugs, the pH, the molecular weight of hyaluronic acid, the dissolution profiles of drugs and the rheological properties of the formulations were recorded depending on time and conditions of storage. This stability study showed clearly the importance to adjust the pH value of the formulation. Indeed, it was demonstrated that a pH value of 6.5, adjusted with diluted NaOH, allowed the stability of the formulation to be significantly improved. During this first step of this project, our Laboratory initiated two new collaborations. On the first hand, collaboration with the Laboratory of Professor Siepmann (University of Lille 2 – Faculty of Pharmacy) was started for their expertise on mathematical modeling. On the other hand, collaboration with the Laboratory of Professor Jerôme (ULg – Faculty of sciences) was started for their expertise on macromolecular chemistry and more particularly on rheological properties.<p>In the second step of this work, it was decided to evaluate in vitro the safety and the efficiency of the developed carrier and formulations containing clonidine or betamethasone. In this way, it was suggested to test selected drugs and potential candidates formulations on equine polymorphonuclear leukocytes (PMN) by measuring the production of reactive oxygen species (ROS) by PMNs stimulated or not with phorbol 12-myristate 13-acetate (PMA). For that purpose, our Laboratory initiated a new collaboration with the Laboratory of Professor Serteyn (ULg – Faculty of veterinary) for their expertise on equine PMNs and quantification of (ROS) produced in particular in inflammatory diseases.<p>This in vitro study has shown that no pro-inflammatory effect appeared by incubating carrier with unstimulated PMNs in comparison with the control assay. However, the production of ROS was quickly and considerably decreased when stimulated cells were placed in contact with carrier regardless on the incorporation of clonidine or betamethasone. This observation demonstrated that developed carrier provided a strong antioxidant effect, certainly by trapping the ROS produced. These results were very promising because that antioxidant effect of carrier could inhibit oxidative damages and might consequently potentiate the prevention of inflammatory conditions. Concerning the clonidine and betamethasone, only the last one provided significant inhibition of the ROS activity.<p>Finally, by considering the very promising results obtained with the in vitro study on PMNs, an in vivo study on rabbits, which seemed to be the most appropriate small animal model for this kind of intraarticular formulations, was performed to evaluate the toxicity and the efficiency of the developed carrier and formulation containing betamethasone. Therefore, our Laboratory started collaboration with the unit of research in osteo-articular pathologies (UROC) of Pr. Henrotin (ULg) for their expertise in animal models, in particular rabbits with osteoarticular pathologies such as osteoarthritis. For this purpose, this in vivo study was outsourced by TNO (Delft, Holland) and was designed as follow: (i) 0.9 % saline buffered (n=8); (ii) carrier (n=8); (iii) formulation containing betamethasone (n=8); (iv) Durolane® (n=8) a marketed product of HA. Surprisingly, it seemed that the control group (saline buffered) presented macroscopical and histological scores that were globally low according to literature. As a consequence, it was difficult to conclude about the efficiency of the developed treatments by considering only this pilot study. However, it is important to note that it seemed that the expected viscoelastic protection of the carrier to prevent the degradation of articular cartilage was not optimal regardless on the incorporation of betamethasone. Nevertheless, the histological analyses of synovial membranes from each treated groups demonstrated that there was no pro-inflammatory reaction. This meant that all formulations tested were well tolerated despite of the apparition of lumps (in 37.5 % of treated rabbits) that are probably due to both the high volume injected (900 µL) and an excessive and unexpected in situ water uptake of developed formulations based on GMO. However, this lack of rejection of the developed carrier could be very important since it allowed new perspectives to be considered. For example, other articular disorders could be targeted by incorporating drugs, for which in situ sustained release or mechanical protection could be beneficial. <p>Our laboratory is member of a collaborative project "JOINT-AIC" from BioWin and is supported by a grant from the Walloon Region. The development of analytical methods, the evaluation of physico-chemical properties and finally the preparation of sterile batches of formulations based on GMO intended for in vitro and in vivo studies were performed in the Laboratory of Galenic and Biopharmacy of the Faculty of Pharmacy of ULB./L’arthrose est une pathologie dont la prévalence et le coût ne font qu’augmenter dans notre société vieillissante. Les moyens thérapeutiques actuels étant fort limités suite à de sérieux effets secondaires à long terme, il existe réellement un besoin médical important de développer de nouveaux traitements locaux qui soient bien tolérés, biocompatibles et biodégradables. Idéalement, ceux-ci devraient être actifs au niveau du processus inflammatoire ou de la douleur tout en étant capable de stabiliser, voire de restaurer, l’intégrité mécanique de l’articulation. <p>Dans cette optique, l’objectif de ce projet a été de développer des systèmes hydrolipidiques stériles, injectables et viscoélastiques qui soient capables de prolonger in situ la libération de principes actifs hydrophiles et lipophiles. Cette caractéristique devait permettre de réduire le nombre d’injections nécessaires dans le cadre du traitement symptomatique de l’arthrose et de maintenir l’effet des composés sur un minimum de quatre à six semaines. Cette étude entre dans le cadre du projet JOINT-AIC entièrement financé par le programme BioWin de la Région Wallonne. Le développement, la validation des méthodes analytiques, l’évaluation des propriétés physico-chimiques ainsi que la préparation stérile des lots de formulation destinés aux tests in vitro et in vivo ont été réalisés au sein du Laboratoire de Galénique et Biopharmacie de la Faculté de Pharmacie de l’ULB. <p>Au cours de ce projet, il a donc fallu dans un premier temps développer et caractériser des formulations hydrolipidiques à base de monoléine et d’acide hyaluronique permettant une libération in vitro prolongée de principes actifs tels que la clonidine (hydrophile) et le dipropionate de bétaméthasone (lipophile). Une étude de compatibilité a ainsi été préalablement réalisée afin de s’assurer qu’aucun des constituants principaux de la formulation ne présentaient d’incompatibilité physico-chimique qui pourrait être délétère vis-à-vis de leur stabilité en formulation. Ensuite, le développement de préparations hydro-lipidiques a été initié en tenant compte, d’une part de la solubilité des différents composants et, d’autre part de l’injectabilité, des propriétés rhéologiques et des profils de libération de la clonidine obtenus à partir des gels développés. Cette étude visait à obtenir une composition de référence qui soit à la fois injectable et capable de libérer un principe actif hydrophile sur plusieurs jours, voire plusieurs semaines, tout en possédant des propriétés rhéologiques intéressantes dans le cadre d’une viscosupplémentation articulaire. Enfin, un protocole de fabrication en milieu aseptique a été développé et plusieurs méthodes pour étudier les propriétés physico-chimiques des gels développés telles que la rhéologie, l’injectabilité, l’indice de gonflement, la stabilité et les profils de libérations ont été mises en place. <p>Les résultats ont montré qu’aucune incompatibilité ne semblait exister entre les trois composés majeurs de notre préparation, la monoléine, l’acide hyaluronique et la clonidine. Le développement des formulations nous a ensuite permis d’obtenir de nouveaux systèmes hydrolipidiques stériles et injectables à délivrance prolongée. Le véhicule qui remplissait au mieux nos objectifs était composé de 10,0% (m/m) d’éthanol ;de 15,0% de propylène glycol (m/m) ;de 15,0% (m/m) d’eau ;de 55,0% (m/m) de monoléine ;5,0% (m/m) d’huile de soja purifiée ;0,03% (m/m) d’α-tocophérol, de 7,5 mg/g d’HA et son pH était ajusté à 6,5 avec du NaOH 1N. Ce véhicule a montré un intérêt réel dans le cadre du développement de préparations biodégradables et biocompatibles pour le traitement de pathologies articulaires.En effet, cette composition présentait un écoulement de type pseudoplastique et des propriétés rhéologiques qui lui procuraient une bonne injectabilité. De plus, cette formulation a démontré in vitro une excellente capacité à gélifier au contact de fluides aqueux et à ralentir efficacement sur plusieurs semaines la libération des différents principes actifs incorporés (clonidine et dipropionate de bétaméthasone). Nous pouvions, dès lors, envisager que celle-ci serait capable de gélifier in situ au contact d’un fluide physiologique tel que le liquide synovial. Ensuite, suivant les recommandations de l’EMA, nous avons décidé d’utiliser l’association d’une filtration stérilisante et d’une préparation en milieu aseptique pour obtenir des formulations qui répondaient aux exigences en matière de préparation parentérale. C’est ainsi qu’un protocole de fabrication stérile de nos gels a été développé par nos soins en vue d’une éventuelle mise à l’échelle industrielle. Enfin, une étude de stabilité sur une année, suivant les normes ICH décrites pour des formulations destinées à être conservées au frigo, a été réalisée sur différents véhicules développés et contenant soit la clonidine, soit le dipropionate de bétaméthasone. Dans cette optique, plusieurs paramètres, tels que le dosage en principe actif, l’évolution du pH et du poids moléculaire de HA, le profil de libération ainsi que la rhéologie des formulations ont été évalués au cours du temps aux différentes conditions de conservation testées. Cette étude a permis de démontrer toute l’importance d’ajuster le pH de la préparation pour prévenir l’hydrolyse de l’HA, et cela indépendamment de l’incorporation de principe actif. Ainsi, il a pu être montré que l’ajustement du pH du véhicule à 6,5 à partir de NaOH dilué permettait d’améliorer considérablement la stabilité de la formulation puisqu’aucune modification significative de ses différents paramètres physico-chimiques et teneurs n’a été observée après un an de conservation à 5 et à 25 °C (60% HR) mais également après six mois à 30 °C (65% HR). Au cours de cette première partie, deux collaborations ont été initiées, l’une avec le Laboratoire du Prof. Siepmann de l’Université de Lille 2 et l’autre avec le Prof. Jerôme de l’Université de Liège. Avec l’aide du Prof. Siepmann, il a été possible de mettre au point un modèle mathématique pour caractériser les profils de libération des principes actifs à partir des différents véhicules développés. Le Prof. Jerôme a, quant à elle, mis à notre disposition un rhéomètre qui a permis d’approfondir nos connaissances sur les propriétés rhéologiques et viscoélastiques des formulations.<p>Ensuite, la seconde partie de notre travail a consisté à évaluer la tolérance, ainsi que l’efficacité des principes actifs sélectionnés et des formulations développées, à travers un modèle in vitro de cellules de l’inflammation (neutrophiles équins). Cette étude avait pour objectif d’évaluer deux aspects importants de la formulation :d’une part vérifier l’absence de réaction pro-inflammatoire qui pourrait être in vivo destructrice vis-à-vis du véhicule ainsi que des tissus environnants, et d’autre part vérifier l’effet anti-inflammatoire propre à la clonidine et au dipropionate de bétaméthasone seuls et en formulation. Cette étude a été réalisée avec la collaboration du Laboratoire du Prof. Serteyn de l’Université de Liège.Cette étude in vitro a démontré que les cellules restaient viables au moins pendant quatre heures lorsqu’elles étaient exposées à la matrice épurée de ses solvants. Ensuite, de manière surprenante, il a même pu être démontré que le véhicule permettait à la fois de prévenir et de réduire significativement la production des espèces réactives de l’oxygène (ROS) par les neutrophiles équins lorsque ceux-ci étaient stimulés au phorbol 12-myristate 13-acetate (PMA). Cette propriété peut être d’un grand intérêt dans le cadre de la prise en charge de l’arthrose car cette activité antioxydante pourrait permettre d’inhiber les dommages oxydatifs générés par les ROS et ainsi prévenir les dommages liés au développement du processus inflammatoire et qui peut, à long terme, s’avérer délétère pour les tissus environnants tels que le cartilage. Cette propriété du véhicule semble trouver son origine dans la monoléine qui, de par sa composition en alpha-tocophérol (200 ppm), présente également une activité antioxydante vis-à-vis des ROS. Toutefois, une action synergique liée à l’HA, à l’huile de soja ou à l’alpha-tocophérol incorporés aux formulations, n’est pas à exclure. Enfin, parmi les deux principes actifs sélectionnés, seul le dipropionate de bétaméthasone a montré une inhibition significative de la production des ROS.<p>Enfin, en tenant compte des résultats obtenus sur cellules, une étude in vivo pilote a été réalisée sur base d’un modèle de lapins. Cette étude visait à vérifier la tolérance ainsi que l’efficacité en prophylaxie de l’arthrose du véhicule développé ainsi que de la formulation contenant le dipropionate de bétaméthasone. Dans ce but, quatre groupes d’animaux (n=8) ont été constitués pour chacun des traitements testés :(i) groupe témoin :0,9 % tampon salin pH 7,4 ;(ii) véhicule à base de GMO développé; (iii) véhicule contenant du dipropionate de bétaméthasone ;(iv) groupe référence :Durolane®. Cette étude a été réalisée avec l’aide du Laboratoire du Prof. Henrotin de l’Université de Liège. L’hébergement des animaux ainsi que les actes chirurgicaux ont, quant à eux, été sous-traités par TNO (Delft, Pays-Bas).<p>De manière étonnante, il s’est avéré que le groupe contrôle présentait des scores macroscopique et histologique globalement peu élevés par rapport à ce qui est rapporté dans la littérature. Compte tenu de cette observation, il est difficile de se prononcer, sur base uniquement de cette étude, sur l’efficacité des différents traitements testés. Toutefois, il faut reconnaître que l’effet protecteur attendu pour le véhicule vis-à-vis de la dégradation du cartilage ne semble pas optimal et cela indépendamment de l’incorporation de dipropionate de bétaméthasone. Par ailleurs, l’étude des membranes synoviales a permis de démontrer qu’il n’y avait aucune différence significative en termes d’inflammation et de structure entre le groupe contrôle et les différents groupes traités. Ce qui signifie qu’aucun rejet n’a été observé vis-à-vis des formulations et que celles-ci ont, par conséquent, été bien tolérées malgré la formation de masses liées probablement au volume important injecté (900 µL) et au gonflement in situ du produit chez 37,5 % des lapins. Cette observation est importante puisqu’elle permet d’envisager de nouvelles perspectives telles que l’incorporation d’autres principes actifs pouvant éventuellement viser d’autres pathologies articulaires et pour lesquels une libération prolongée ou une protection mécanique du principe actif in situ serait bénéfique. <p><p><p><p><p><p> / Doctorat en Sciences biomédicales et pharmaceutiques / info:eu-repo/semantics/nonPublished

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