Xanthan gum and sodium alginate as sustained-release carriers in hydrophilic matrix tablets

Hodsdon, Alison Claire

January 1994

No description available.

615.1

Oral drug delivery

Water sorption and drug release behaviour of polymeric systems based on heterocyclic/cyclic methacrylates

Swai, Hulda Paulo Shaidi

January 2000

No description available.

615.1

Intra-oral drug delivery; Oral disease

Smart Microgel Studies. Interaction of Polyether-Modified Poly(Acrylic Acid) Microgels with Anticancer Drugs

Bromberg, Lev, Hatton, T. Alan

01 1900

Studies of submillimeter gels composed of covalently cross-linked poly(acrylic acid)-g-poly(ethylene oxide)-b-poly(propylene oxide)-b-poly(ethylene oxide) (Pluronic-PAA) networks are reviewed in light of potential applications of the microgels as drug carriers in oral delivery. The microgels are capable of volumetric transitions in response to environmental stimulae such as pH and temperature. It is shown that the type of Pluronic used in the microgel synthesis changes the structure of the resulting microgels, with the more hydrophobic Pluronic imparting porosity. Microgels based on Pluronic L92 (L92-PAA-EGDMA) possess higher ion-exchange capacity than microgels based on Pluronic F127 (F127-PAA-EGDMA), albeit the former are more hydrophobic. Analogously, more hydrophobic but heterogeneous L92-PAA-EGDMA exhibit superior capacity for equilibrium loading of hydrophobic drugs such as taxol, camptothecin and steroid hormones, as well as higher capacity for weakly basic drugs such as doxorubicin, mitomycin C, and mitoxantrone. / Singapore-MIT Alliance (SMA)

anticancer drugs

hydrophobic solutes

oral drug delivery

smart microgels

Progress toward a Colon Targeting Nanoparticle Based Drug Delivery System

Yu, Xiao

2012 May 1900

Hydrophobic drug paclitaxel nanoparticles (PAX NPs) and pH sensitive hydrogels were prepared in this study to build a colon targeting nanoparticle based drug delivery system for oral administration. Negative charged PAX NPs at the size of 110 +/- 10 nm were fabricated, characterized and then encapsulated in synthetic / biomacromolecule shell chitosan, dextran-sulfate using a layer by layer (LbL) self-assembly technique. Surface modifications were performed by covalently conjugating with poly (ethylene glycol) (H2N-PEG-carboxymethyl, Mw 3400) and fluorescence labeled wheat germ agglutinin (F-WGA), so as to build a biocompatible and targeted drug delivery system. Extended release of drug paclitaxel can be realized by adding more polyelectrolyte layers in the shell. High cell viability with PEG conjugated and high binding capacities of WGA modified nanoparticles with Caco-2 cells were observed. Preliminary study on stability of the nanoparticles in suspension at different pH was also performed. Two dextran based pH sensitive and enzyme degradable hydrogels: dextran maleic acid (Dex-MA), and glycidyl methacrylated dextran (Dex-GMA) were synthesized for oral delivery of nanoparticles. Hydrogels of both kinds were stable in simulated gastric fluid, but were prone to swelling and degradation in the presence or absence of enzyme dextranase in simulated intestinal fluid. The release profiles of nanoparticles could be tuned from 5 hr to 24 hr periods of time with more than 85% of the nanoparticle released in the simulated intestinal fluid. The release of PAX NPs was completed with longer time periods (45 hr-120 hr). Two possible release mechanisms were discussed for Dex-MA and Dex-GMA-co-AA hydrogels respectively: degradation controlled, and diffusion controlled. These biodegradable hydrogels, which can release nanoparticles depending on pH changes, together with the biocompatible and targeted nanoparticles, may be suitable as a potential colon targeting system for oral delivery of drug nanoparticles.

nanoparticles

hydrogel

colon targeting

oral drug delivery

controlled releases

MICRO/NANOENCAPSULATION OF PROTEINS WITHIN ALGINATE/CHITOSAN MATRIX BY SPRAY DRYING

Erdinc, Burak I.

02 November 2007

Currently, therapeutic proteins and peptides are delivered subcutaneously, as they are readily denatured in the acidic, protease rich environment of the stomach or gastrointestinal track and low bioavailability results from poor intestinal absorption through the paracellular route. Encapsulation of therapeutic peptides and proteins into polymeric micro- and nano- particle systems has been proposed as a possible strategy to overcome limitations to oral protein administration. Furthermore, it was shown that nanoparticles having diameters less than 5µm are able to be taken up by the M cells of Peyer’s patches found in intestinal mucosa . However, the current methodologies to produce particles within desired range involves organic solvents and several steps. In this study, spray drying was investigated as a microencapsulation alternative, as it offers the potential for single step operation, producing dry particles, with the potential for extending the microparticle size into the nano-range. The particles were produced by spray drying of alginate/protein solutions. The effect of spray drying operational parameters on particle properties such as recovery, residual activity and particle size was studied. Particle recovery depended on the inlet temperature of the drying air, whereas the particle size was affected by the feed rate and the alginate concentration of the feed solution. Increase in alginate:protein ratio increased protein stability during the process and shelf live experiments. Presence of 0.2 g trehalose/g particle increased the residual activity up to 90%. The resulting spherical micro and nanoparticles had smooth surfaces. Stable glycol-chitosan-ca-alginate particles were produced with single step operation. The resulting particles had mean diameter around 3.5μm and released 35% of the initial protein content to the simulated stomach environment within 2 hours. The protein distribution within the particle was studied by confocal laser scanning microscope with florescent labeled protein. The image showed protein deposition toward the surface of the particles. Total drying time and Peclet number was calculated for the particles and found to be 8.5 ms and 240, which indicates that particle formation was governed mainly by convection, which resulted in a hollow central region and protein distribution toward the particle surface. This study shows that stable alginate particles containing proteins can be produced in a single step by spray drying, where the particles had a mean size lower than the critical diameter necessary to be orally absorbed by M cell’s of the Peyer’s patches in the gastrointestinal tract and thus can be considered as a promising technology for oral peptide and protein delivery. / Thesis (Master, Chemical Engineering) -- Queen's University, 2007-10-30 12:20:47.728

spray drying

protein microencapsulation

alginate

nanoencapsulation

particles

oral drug delivery

Evaluation of mucosal damage and recovery in the gastrointestinal tract of rats by penetration enhancers

Narkar, Yogeeta.

January 2006

Thesis (Ph.D.)--University of Wisconsin--Madison, 2006 / eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (p. 186-199).

Evaluation of mucosal damage and recovery in the gastrointestinal tract of rats by penetration enhancers /

Narkar, Yogeeta.

January 2006

Thesis (Ph.D.)--University of Wisconsin--Madison, 2006 / Includes bibliographical references (p. 186-199). Also available on the Internet.

Regenerated cellulose for controlled oral drug delivery

Bhatt, Bhavik Janankkumar

01 May 2012

The performance of regenerated cellulose (RC) films and capsules was investigated for their applications in oral controlled drug delivery. Regenerated cellulose films were prepared by non-solvent-mediated, phase inversion of native and depolymerized cotton linter solutions (methylolcellulose; cellulose dissolved in dimethyl sulfoxide/ paraformaldehyde solvent system) in water as well as by phase inversion of native cotton linter solutions in organic non-solvents followed by thermal annealing. These films were monolithic in dry state and formed porous structures when hydrated. Irrespective of the degree of polymerization of the starting cellulose source or the use of organic non-solvents, the cellulose chain length was not significantly altered and cellulose was in an amorphous state. Flux analysis in diffusion cells, using ethanol-water mixtures as the solvent medium, indicated that the films take up solvent to form porous routes for transport of solute. The amount of solvent uptake required to form these routes was greater for films prepared from depolymerized cotton linter. Ionic and hydrophobic solutes traverse the films using the porous pathways following hydration of the film. Blended RC films were prepared by combining native and depolymerized cotton linter solutions in varying ratios and phase-inverting in water, followed by thermal annealing. Porosity, pore size and water uptake of the hydrated films decreased, while the length of the transport pathway (tortuosity) increased, as the fraction of depolymerized cellulose increased in the blended films. Differences in methylene blue dye adsorption on phase-inverted vs. phase-inverted and thermally annealed RC films indicated that the type of non-solvent utilized for phase-inversion does not affect the internal RC film structure during the phase-inversion process. However, as the boiling point of the non-solvent increased, the amount of irreversible polymer consolidation and formation non-swelling domains (hornification) increased during the thermal annealing process. This, in turn, led to reduced porosity and solute flux through these RC films. Two-piece cellulose capsules were fabricated by phase-inversion of methylolcellulose solutions in water using a dip-coating approach. Zero-order release rates for a number of drugs increased as their water solubility increased. The release of water soluble drugs occurred by osmotically-driven convection and diffusion through the pores in the capsule wall, while the release of moderate to poorly soluble drugs predominantly occurred by diffusion. Moreover, as the drug solubility increased, the apparent permeability of the drugs through the capsule wall decreased, which indicated that the inward osmotic flux of water reduced the diffusivity of the drug through the pores. The hydraulic permeability of the cellulose capsules was determined to be higher than for conventional ethylcellulose and cellulose acetate coated osmotic drug delivery systems, indicating that the cellulose-based capsules may be better suited for osmotic drug delivery.

Capsules

Film technology

Oral drug delivery

Osmotic drug delivery

Regenerated Cellulose

Pharmacy and Pharmaceutical Sciences

Identification of a Peptide Sequence That Improves Transport of Macromolecules Across the Intestinal Mucosal Barrier Targeting Goblet Cells

Kang, Sang, Woo, Jung Hee, Kim, Min Kook, Woo, Sang Soo, Choi, Jin Hyuk, Lee, Hong Gu, Lee, Nam Kyung, Choi, Yun Jaie

01 June 2008

In this study, we demonstrated that the CSKSSDYQC-peptide ligand which was identified from a random phage-peptide library through an in vivo phage display technique with rats could prominently improve the transport efficiency of macromolecules, such as large filamentous phage particles (M13 bacteriophage), across the intestinal mucosal barrier. Synthetic CSKSSDYQC-peptide ligands significantly inhibited the binding of phage P1 encoding CSKSSDYQC-peptide ligands to the intestinal mucosal tissue and immunohistochemical analysis showed that the CSKSSDYQC-peptide ligands could be transported across the intestinal mucosal barrier via goblet cells as their specific gateway. Thus, we inferred that CSKSSDYQC-peptide ligand might have a specific receptor on the goblet cells and transported from intestinal lumen to systemic circulation by transcytosis mechanism. These results suggest that CSKSSDYQC-ligand could be a promising tool for development of an efficient oral delivery system for macromolecular therapeutics in the carrier-drug conjugate strategy.

goblet cell

intestinal mucosa

oral drug delivery system

phage display

receptor-mediated endocytosis

transcytosis

Mixed Polysaccharide Esters for Amorphous Solid Dispersion Oral Drug Delivery Vehicles

Petrova, Stella

04 December 2023

Using various synthetic strategies, we designed several libraries of novel polysaccharide mixed ester derivatives for oral drug delivery applications. Cellulose and cellulose esters have been extensively studied and utilized for different applications such as separation membranes, sustainable plastics, and enteric coatings in oral drug delivery carriers. We sought to exploit the ring-opening of cyclic anhydrides, succinic and glutaric anhydride, to append ω-carboxyl groups to commercially available cellulose and cellulose ester substrates. We used scalable synthetic strategies and widely available and cheap reagents to show a proof-of-concept for the manufacturability of these different polymer derivatives. We incorporated different degrees of substitution of ω-carboxyl groups to impart a range of water solubility in these polymers. The derivatives displayed excellent <i>T</i>g values for ASD applications, adequate water solubility, and good amphiphilic properties. We designed very effective amorphous solid dispersion (ASD) oral drug delivery polymers that prevented recrystallization of felodipine for hours and had excellent congruent polymer-drug release from the formulation at 20% drug loading. During the ring-opening reactions of the cellulose derivatives with glutaric anhydride we discovered that crosslinking and gelation can occur, especially with cellulose and cellulose ester substrates with a high degree of substitution (DS) of hydroxy groups. We isolated and characterized these gelled products using rheology, and solid-state 1D and 2D NMR spectroscopy, to evaluate whether the gels are physical or chemical in nature and proposed a mechanism for gelation. We determined that the gels are mostly physical but can proceed to chemical crosslinking over time. We designed a library of cellulose ester derivatives, and we investigated their performance as amorphous solid dispersion (ASD) drug delivery vehicles for the lipophilic drug felodipine, through <i>in vitro</i> experiments. Aside from felodipine, many other active pharmaceutical ingredients (APIs) are also highly crystalline and poorly water-soluble. ASDs are used to disrupt the crystalline packing of these drugs through dispersing them in amorphous polymeric carriers, facilitating their water-solubility, and preventing their recrystallization. We showed that our polymers performed remarkably well in the <i>in vitro</i> studies and inhibited crystallization of model compound felodipine for several hours while providing optimal drug release, affording highly promising ASD polymers. If company formulators are unable to develop an effective oral-delivery carrier to prevent a drug from recrystallizing, then the drug cannot be tested in <i>in vivo</i> toxicology studies, and therefore cannot be brought to market because of its poor aqueous solubility and subsequent low bioavailability. To test the robustness of our polymers, we also performed <i>in vitro</i> ASD experiments at the pharmaceutical company AbbVie with their most rapidly crystallizing pipeline compounds, and several commercially available drugs (Compound A, axitinib, and ziprasidone). We demonstrated that our polymers could also prevent drug recrystallization with these rapid crystallizers, outperforming commercial polymers like FDA-approved hydroxypropyl methyl cellulose acetate succinate (HPMCAS (MF)), even at exceptionally high drug loading ratios of 40 times the concentration of polymer. α-1,3-Glucans are an emerging class of polysaccharides and are structurally different than cellulose due to their α (1→3) linkage versus the cellulose β (1→4) glycosidic linkage. We demonstrated that we could modify these derivatives using a variety of esterification strategies and TEMPO-mediated C6 selective oxidation, affording a myriad of different novel polymer products, some of which are structural analogs of the cellulose ester derivatives we previously created. The polymers had higher <i>T</i>g values than the cellulose ester polymers, which may be useful for applications where heat resistance is desired. In the future, we will screen some of these α-1,3-glucan derivatives with poorly water-soluble enzalutamide, posaconazole and celecoxib model drugs, to evaluate their crystallization inhibition properties and the influence of polymer morphology upon structure-property relationships. We expect that these synthetic polymer strategies will offer scalable routes to novel ASD polymers, which we demonstrated to be highly effective drug crystallization inhibitors against a variety of different hydrophobic pharmaceutical compounds. / Doctor of Philosophy / Polysaccharides are polymers comprised of many linked sugar molecules and are an incredibly abundant and renewable resource. They are found everywhere in nature such as the wood from trees, the shells of crabs, the exoskeletons of bugs, and the mushrooms that sprout in damp forests. The research in this dissertation focuses on the use and chemical modification of polysaccharides for designing new, polysaccharide-based oral drug delivery systems called amorphous solid dispersions (ASDs), which significantly aid in the solubility and bioavailability of important medications. We started with the chemical modification of cellulose, the most abundant plant polysaccharide on planet Earth, and previously modified commercial cellulose substrates (known as cellulose esters) to create novel polymers for ASDs. We successfully modified these polymers, characterized them, and evaluated their potential as oral drug delivery vehicles by formulating them with several different classes of potent drugs used to treat a variety of diseases such as hypertension and schizophrenia. We showed that our designed cellulose ester polymers kept these hydrophobic drugs water-soluble for long-enough so that they can be adequately absorbed in the human body through the gastrointestinal tract, significantly outperforming commercial polymers in many cases. During the chemical modification of the cellulose esters, we also observed that they were prone to form gels, and we investigated this gelation phenomena in more detail through rheometry, 1D and 2D solid-state nuclear magnetic resonance spectroscopy (similar in principle to the medical diagnostic method, magnetic resonance imaging or MRI). We discovered that these gels can be physically and/or chemically linked together, and that different gelation mechanisms can dominate depending on the polysaccharide substrate and the esterification reagent used. We extended our research to other polysaccharide derivatives called α-1,3-glucans, which can be sourced from fungi, and/or enzymatically synthesized in the lab. Using various synthetic esterification and oxidation chemical methods to functionalize this polysaccharide, we designed a library of entirely novel polymers with different physical structures relative to the cellulose ester polymers. The polymers displayed thermal properties that show promise in drug delivery vehicle applications and in applications where high heat resistance is required. Overall, we developed next-generation polymers for amorphous solid dispersion oral drug delivery applications. We displayed the versatility of using a select few chemistry strategies to create a variety of different polymers with very different physicochemical properties. We hope that this work will help researchers design sustainable, plant-based polymers for ASD applications and we hope to nurture future structure-function studies to improve ASD performance for the benefit of patients in need.

cellulose esters

α-1

3-glucan esters

gelation

amorphous solid dispersions

bioavailability

polysaccharides

oral drug delivery