1 |
Novel approaches to both delay and enhance the onset of paracetamol induced analgesiaSoutar, Sonia Anne January 2001 (has links)
No description available.
|
2 |
Implications of plasticization on the properties of hot-melt extruded oral dosage formsSchilling, Sandra Ursula 27 May 2010 (has links)
The influence of plasticization and other formulation factors on the properties of hot-melt extruded dosage forms for the controlled release of water-soluble active compounds was investigated. Citric acid monohydrate was demonstrated to function as a solid-state plasticizer in hot-melt extruded Eudragit® RS PO tablets and in cast films when concentrations below the compatibility limit were employed. Melting of the organic acid and solubilization in the polymer during extrusion were necessary to observe the plasticizing effect. The release rate of diltiazem hydrochloride, used as a high-melting, water-soluble model drug, from melt extruded Eudragit® RS PO matrix tablets increased and became independent of the original drug particle size in the presence of citric acid monohydrate. Thermal analysis of physical mixtures demonstrated that citric acid promoted drug melting during extrusion by interaction and melting point depression. Diltiazem hydrochloride remained amorphous in the final dosage form, and leaching of citric acid monohydrate enhanced drug diffusion by increasing the matrix porosity. Delayed-release matrix pellets with particle sizes below one mm were prepared by hot-melt extrusion, and the influence of the matrix forming polymer and the type and level of plasticizer on the processibility and release properties was investigated. Pellets complied with the USP requirement for delayed release articles to release less than 10% drug at pH 1.2 after 2 hours when plasticized Eudragit® S100 was used as the release-controlling material. High levels of efficient plasticizers had to be employed to decrease the polymeric melt viscosity, increase the process yield and enable extrusion at moderate temperatures to avoid instabilities during processing and storage. The aqueous solubility of the plasticizer further impacted the drug release rate in acid. A novel application of hot-melt extrusion for the preparation of monolithic matrices comprising enteric coated particles was studied. The influence of the mechanical strength of the multiparticulates, pellet loading and nature of the hydrophilic carrier material on the preservation of the delayed-release properties after extrusion was investigated. Soft particles coated with brittle films remained intact when low-melting carriers that did not solubilize the enteric film during extrusion were used, and the dissolution profile was stable over one year. / text
|
3 |
DEVELOPMENT OF INNOVATIVE MODIFIED-RELEASE LIQUID ORAL DOSAGE FORMSRonchi, Federica 08 September 2020 (has links) (PDF)
Modified-release oral drug delivery dosage forms are widely used in the pharmaceutical field to overcome all the potential issues imposed by the physiological variabilities of the gastrointestinal tract as well as to maintain drug concentrations within the therapeutic window. In the market, they are available only as solid dosage forms such as capsules or tablets. The development of a liquid oral dosage form with modified-release properties has been keenly awaited. This form could increase the compliance of patients with a swallowing impairment (i.e. paediatric, older or critically ill patients) and, consequently, the efficacy of the therapeutic treatment. In this study, a new technology has been developed that consists of multi-layered particles suspended extemporaneously in a syrup. Omeprazole and budesonide have been employed as model drugs. The coating procedure was optimized to obtain a yield of minimum 90% w/w and a median diameter below 500 µm. Once the final suspension is prepared extemporaneously, it presents sufficient stability to guarantee the administration of multiple doses filled into a syrup bottle and kept for a limited storage time at room temperature (e.g. up to 10 doses to be administered within 10 days). / Doctorat en Sciences biomédicales et pharmaceutiques (Pharmacie) / info:eu-repo/semantics/nonPublished
|
4 |
Optimisation de la pH-sensibilité de protéines végétales en vue d'améliorer leurs capacités d'encapsulation de principes actifs destinés à la voie orale / Optimization of pH-sensitivity of vegetable proteins in order to improve their capacity to encapsulate Active Pharmaceutical Ingredients for oral administrationAnaya Castro, Maria Antonieta 21 February 2018 (has links)
Dans le domaine pharmaceutique, la voie orale demeure la voie d’administration de prédilection, car plus simple et mieux acceptée par les patients. Cependant, ce mode d’administration pose problème pour de nombreux principes actifs (PA) présentant une faible solubilité, une faible perméabilité et/ou une instabilité dans l’environnement gastro-intestinal. Leur micro-encapsulation dans des matrices polymériques peut permettre d’y répondre, notamment si les microparticules générées résistent aux environnements rencontrés lors du tractus gastro-intestinal et jouent alors un rôle protecteur, tant pour le principe actif que pour les muqueuses rencontrées. La recherche de nouveaux excipients, issus des agro-ressources tels que les polymères naturels, est en plein essor. Les protéines végétales, grâce à leurs propriétés fonctionnelles telles qu’une bonne solubilité, une viscosité relativement basse, et des propriétés émulsifiantes et filmogènes, représentent des candidats privilégiés. De plus, la grande diversité de leurs groupements fonctionnels permet d’envisager des modifications chimiques ou enzymatiques variées. L’objectif de ce travail était d’étudier l’intérêt de la protéine de soja en tant que matériau enrobant de principes actifs pharmaceutiques destinés à la voie orale, et plus particulièrement en tant que candidat pour l’élaboration de formes gastro-résistantes. Un isolat protéique de soja (SPI) été utilisé comme matière enrobante et l’atomisation comme procédé. L’ibuprofène, anti-inflammatoire non stéroïdien, a été choisi comme molécule modèle du fait de sa faible solubilité nécessitant une amélioration de sa biodisponibilité, et de ses effets indésirables gastriques nécessitant une mise en forme entérique. Deux modifications chimiques des protéines (l’acylation et la succinylation) ont été étudiées dans le but de modifier la solubilité de la protéine de soja. Ces modifications ont été effectuées dans le respect des principes de la Chimie Verte, notamment en absence de solvant organique. Les microcapsules obtenues par atomisation ont été caractérisées en termes de taux et efficacité d'encapsulation, morphologie et distribution de tailles des particules, état physique du PA encapsulé et capacité de libération en milieu gastrique et intestinal simulé. Les résultats obtenus ont permis de valider l’intérêt des modifications chimiques de la protéine de soja pour moduler les cinétiques de libération d’actif. Les modifications chimiques sont apparues particulièrement adaptées pour l’encapsulation de principes actifs hydrophobes, et ont permis de l’obtention de cinétiques de libération d’ibuprofène ralenties à pH acide (gastrique). La dernière partie de ce travail a permis de valider cette dernière hypothèse par la réalisation de formes gastro-résistantes sur le modèle des comprimés MUPS (multiple unit pellet system). Les résultats de ce travail exploratoire démontrent que les protéines de soja, associées à un procédé de mise en forme multi-particulaire couplé à de la compression directe, peuvent constituer une alternative biosourcée, respectueuse de l’environnement (manipulation en solvant aqueux, temps de séchage et étapes de compression réduits) et sûre à l’enrobage utilisé dans les formes gastro-résistantes traditionnelles. / In the pharmaceutical field, the oral route remains the preferred route of administration because it is simpler and better accepted by patients. However, this mode of administration is problematic for many active pharmaceutical ingredients (API) with low solubility, low permeability and/or instability in the gastrointestinal environment. Their microencapsulation in polymeric matrices can make them able to respond to these factors, especially if the microparticles generated resist the environments encountered during the gastrointestinal tract and then play a protective role, both for the API and for the mucous membranes encountered. The search for new excipients, from agroresources such as natural polymers, is booming. Vegetable proteins, thanks to their functional properties such as good solubility, relatively low viscosity, and emulsifying and film-forming properties, are preferred candidates. In addition, the great diversity of their functional groups makes it possible to envisage various chemical or enzymatic modifications. The aim of this work was to study the interest of soy protein as a coating material for API intended for the oral route, and more particularly as a candidate for the development of gastro-resistant forms. A soy protein isolate (SPI) was used as a coating material and the atomization as a process. Ibuprofen, a nonsteroidal anti-inflammatory drug, was chosen as a model molecule because of its low solubility requiring an improvement in its bioavailability, and its gastric side effects requiring an enteric shaping. Two chemical modifications of proteins (acylation and succinylation) have been studied in order to modify the solubility of the soy protein. These modifications were carried out in accordance with the principles of Green Chemistry, especially in the absence of organic solvent. The microcapsules obtained by spray-drying were characterized in terms of rate and encapsulation efficiency, morphology and size distribution of the particles, physical state of the encapsulated API and capacity of release in simulated gastric and intestinal medium. The results obtained validated the interest of the chemical modifications of the soy protein to modulate the release kinetics of API. The chemical modifications appeared particularly suitable for the encapsulation of hydrophobic active ingredients, and allowed to obtain ibuprofen release kinetics decreased to acidic pH (gastric). The last part of this work allowed to validate this last hypothesis by the realization of gastro-resistant forms on the model of MUPS tablets (multiple unit pellet system). The results of this exploratory work demonstrate that soy protein, combined with a multiparticle shaping process coupled with direct compression, can be a biosourced, environmentally friendly alternative (aqueous solvent handling, drying and compression steps reduced) and confident to the coating used in traditional gastroresistant forms.
|
Page generated in 0.0397 seconds