Interspecies Pharmacokinetic Scaling and Metabolism of Alcohols and Glycols

Gupta, Pankaj

01 January 2006

Background: Despite the numerous pharmaceutical applications of alcohols andglycols, the interspecies differences with respect to their pharmacokinetics (PK) arepoorly understood. The aim of this research was to use in-vivo and in-vitro approaches to compare and model the PK characteristics across various species.Methods: Appropriate published in-vivo studies (in different species) foralcohols and glycols were carefully selected. PK analysis was performed using (a) noncompartmental analysis and (b) compartmental modeling to estimate relevant dose-independent PK parameters. Next, six alcohols (methanol, ethanol, 1 -propanol, 1 -butanol, 1-hexanol, and 1-octanol), two glycols (ethylene glycol and propylene glycol)and one secondary alcohol (2-propanol) were examined as in-vitro substrates for equine ADH using a UV spectrophotometric assay to evaluate the effect of molecular structure. Furthermore, in-vitro metabolism of ethanol and propylene glycol was also characterized in hepatic cytosolic fractions from rat, rabbit, dog and human and in-vitro in-vivo correlation for the hepatic disposition parameters was assessed. Finally, allometric scaling relationships for ethanol and propylene glycol PK parameters (in-vivo and in-vitro) were developed and validated.Results: Alcohols and glycols exhibited nonlinear PK due to saturable hepaticmetabolism in all species. The reported in-vivo data were well described by oneltwo compartment PK models with parallel saturable metabolism and first-order renalexcretion. In-vitro equine ADH experiments revealed differences in affinity andturnover between the substrates: Enzyme affinity (1/Km) and in-vitro intrinsic clearance (CLintin-vitro) correlated positively with logP values; glycols showed lower CLintin-vitro values than straight-chain alcohols. In-vitro hepatic cytosol studies yielded acceptable in-vivo predictions for the metabolic clearance (CLmet) of ethanol and propylene glycol in the rat, dog and human, but not the rabbit. Vdss, Vmax, CLintin-vitro, CLmet scaled allometrically across species with similar powers for both ethanol and propylene glycol, and good agreement between in-vivo and in-vitro scaling was noted. The allometric scaling models gave excellent predictions when externally validated against in-vivo concentration-time data. Conclusions: The present research demonstrates .the successful application of amodeling-based approach to elucidate interspecies relationships for alcohols andglycols, compounds which exhibit nonlinear PK and mainly low hepatic extractionbehavior. The in-vitro experimental systems have been used successfully forcharacterizing alcohol/glycol metabolism and predicting in-vivo disposition.

ethanol

propylene

hydrophobic drugs

Medicine and Health Sciences

Pharmacy and Pharmaceutical Sciences

Design of macromolecular drug delivery systems using molecular dynamics simulation

Patel, Sarthakkumar

06 1900

In recent years, the use of self-associating block copolymer based drug delivery systems have attracted increasing attention as nanoscopic carriers for the encapsulation and the controlled delivery of water insoluble drugs. Currently, most of the drug formulations proceed by trial and error method with no distinct method to predict the right combination of block copolymers and drugs to give all the desired functional properties. This is simply because such drug delivery systems involve complex intermolecular interactions and geometric fitting of molecules of different shapes. So, in the context of block copolymer design process, quantification and prediction of the interactions between potential block copolymers and the target drug are of great importance. Computer simulations that can predict the level and type of interactions encountered in drug/block copolymer pairs will enable researchers to make educated decisions on choosing a particular polymeric carrier for a given drug, avoiding time consuming and expensive trial and error based formulation experiments. In the present thesis, we reported the use of molecular dynamics (MD) simulation to predict the solubility of sets of hydrophobic drug molecules having different spatial distribution of hydrogen bond forming moieties in a series of micelle-forming PEO-b-PCL block copolymers with and without functionalized PCL blocks. The solubility predictions based on the MD results were then compared with those obtained from the solubility experiments and those obtained by the commonly used group contribution method (GCM). MD analysis techniques like radial distribution functions provided useful atomistic details to understand the molecular origin of miscibility and/or immiscibility observed between drugs and di-block copolymers. Based on the evidence of reported work, intermolecular specific interactions, intra-molecular interactions, local molecular packing, and stereochemistry of the hydrophobic block all play important roles in inducing miscibility between drugs and block copolymers. Additionally, not only the architecture of block copolymers but also the molecular characteristics of drug molecules, e.g., spatial distributions of hydrogen bond donors and acceptors on their molecules can affect the miscibility characteristics of binary mixtures. Depending on the groups present on drugs and block copolymers, any of the above factors can play vital role in the process of favouring encapsulation. The understanding of relative contributions of these interactions can help us to customize the performance of drug carriers by engineering the structure of block copolymers. / Chemical Engineering

Molecular dynamics simulation

Hydrophobic drugs

Block copolymer

Solubility

Interaction parameter

Design of macromolecular drug delivery systems using molecular dynamics simulation

Patel, Sarthakkumar

Unknown Date

No description available.

Molecular dynamics simulation

Hydrophobic drugs

Block copolymer

Solubility

Interaction parameter

Synthèse et caractérisation de capsules multicouches fonctionnelles à base de polysaccharides modifiés / Synthesis and characterization of functional multilayer capsules based on chemically modified polysaccharides

Cui, Di

26 May 2011

This work focused on the design of functional capsules made of chemically modified polysaccharides. The layer-by-layer capsules have attracted great interest due to their Indeed, as an advanced multifunctionality which can be advantageously used for pharmaceutical and biomedical applications. Polysaccharides, which are generally biocompatible and biodegradable, are very attractive materials for the construction of bio-related multilayer systems. Considering the intrinsic antibacterial properties of chitosan (CHI), this polysaccharide was selected and quaternized to prepare in physiological conditions contact-killing capsules by combination with hyaluronic acid (HA). The relationship between the antibacterial activity of the quaternized chitosan derivatives (QCHI) and that of QCHI-based capsules was investigated. Then, in order to encapsulate small hydrophobic drugs within the wall of capsules, alkylated derivatives of HA were used as the negatively charged partner of QCHI for the capsules formation. The encapsulation of the hydrophobic dye, nile red (NR), in the hydrophobic shell of capsules was determined. At last, to release the payload under mild conditions was studied by synthesizing rapidly degradable capsules composed of hydrolysable cationic dextran derivatives and HA. The degradation of the layer-by-layer assemblies, both multilayer films and microcapsules is discussed. / Ce travail de thèse porte sur la conception de capsules fonctionnelles à base de polysaccharides chimiquement modifiés. Les capsules couche par couche connaissent actuellement un essor important lié à leur multifonctionnalité pouvant être avantageusement mise à profit dans les domaines pharmaceutique et biomédical. Les polysaccharides, généralement biocompatibles et biodégradables, constituent des matériaux de choix pour la construction de systèmes multicouches. Compte tenu des propriétés antibactériennes intrinsèques du chitosane (CHI), ce polysaccharide a été choisi puis quaternisé afin de préparer dans des conditions physiologiques des capsules par complexation avec l'acide hyaluronique (HA), capables de tuer les bactéries par simple contact. La relation entre l'activité antibactérienne des dérivés quaternisés du chitosane (QCHI) et celle des capsules préparées à partir de QCHI a été étudiée. En outre, afin d'encapsuler des médicaments hydrophobes dans la paroi des capsules, des dérivés alkylés du HA ont été utilisés en tant que partenaire chargé négativement du QCHI pour la formation des capsules. L'encapsulation d'une sonde fluorescente hydrophobe, le nile rouge (NR), dans le réservoir hydrophobe des capsules a été réalisée avec succès. Enfin, pour libérer des médicaments encapsulés dans des capsules dans des conditions douces, des capsules rapidement dégradables comprenant des dérivés cationiques hydrolysables du dextrane et de HA ont été préparées. La dégradation des assemblages couches par multicouches a été analysée par différentes approches à la fois à partir de capsules et de films plans.

Multicouches

Polysaccharide

Microcapsules

Activité antimicribienne

Biodegradabilité

Multilayers

Polysaccharide

Microcapsules

Antimicrobial activity

Encapsulation of hydrophobic drugs

Hyaluronic acid hydrogel materials

Zawko, Scott Andrew

02 February 2011

Hyaluronic acid (HA) is one of the primary chemical building blocks of the extracellular matrix and thus is an attractive material for biomedical applications. FDA approved HA-based materials are available as dermal fillers, joint viscosupplements, vitreous substitutes, and abdominal adhesion barriers. The engineering of new HA-based materials and applications is an active area of research. Here we develop several new types of HA-based hydrogels with unique and useful properties. To address the challenge of delivering hydrophobic drugs from hydrophilic hydrogel matrices we have grafted HA hydrogels with [Beta]-cyclodextrin to create hydrogels capable of binding poorly water soluble drugs. To create HA hydrogels with unique anisotropic swelling behavior we have developed a dual-crosslinking technique in which a super-swelling chemically crosslinked hydrogel is patterned with low-swelling photocrosslinked domains. When this dual-crosslinked hydrogel is swelled it contorts into a new shape because of differential swelling among photopatterned regions. To address the challenge of creating hydrogel scaffolds with biomimetic branched porosity we have invented a "crystal templating" technique. This technique grows dendritic crystals throughout a biopolymer solution, crosslinks the biopolymer around the crystals, and washes the crystals away to yield a hydrogel with a dendritic macroporous network. Lastly, we invented a method for patterning a substrate with a microarray of hydrogel compartments. A microarray of living cells is obtained when cells are seeded on the hydrogel patterned substrate. This method addresses the need for an inexpensive, simple method for obtaining living cell microarrays that does not require clean room labs and lithographic expertise. Each of these new materials were based on hyaluronic acid hydrogels but the methods are generalizable to hydrogels of other polymers too. In conclusion, the novel methods in this dissertation are a significant contribution to the engineering of HA-based materials. / text

Hyaluronic acid-based hydrogels

Hydrophobic drugs

Anisotropic swelling behavior

Hydrogel scaffolds

Biomimetic branched porosity

Dendritic crystals

Biopolymer solution

Hydrogel patterned substrate

Living cell microarrays

Dendritiska nanogeler som platform för läkemedelsleverans / Dendritic nanogel for drug delivery platform

UYSAL, GÜNES

January 2019

Utveckling av polymer baserade läkemedelsbärare i nanostorlek har blivit allt viktigare för att effektivisera behandling och diagnosering av olika sjukdomar, speciellt cancer. Flera läkemedel som används i kemoterapi har bristfälliga egenskaper som låg löslighet i vatten, oönskad nedbrytbara till dess inaktiva form, och distribution i stora volymer till oönskade organ p.g.a. dess icke-selektiva förmåga. Nanopartiklar är små partiklar med diameter 1-500 nm som genom passiv/aktiv transport kan passera olika biologiska barriärer och transportera läkemedel i optimala mängder till specifika celler. Denna selektiva transport bidrar till ökad terapeutiskt index och minskning av toxiska effekter i övriga delar av kroppen. Hyperförgrenade linjär-dendritiska hybrider är en subgrupp av dendritiska polymer som har stor potential att användas som byggstenar i utvecklingen av läkemedelsbärare. I detta projekt producerades ett bibliotek av hyperförgrenade linjär-dendritiska material via Fischer esterifikation reaktionen som är en snabb, billig och uppskalningsbar produktionsmetod. Vidare post funktionaliserades materialen med allyl grupper för produktion av nano geler genom UV-inducerad korslänkning och vidare funktionalisering. Samtliga producerade hyperförgrenade linjär-dendritiska material hade förmågan att bilda miceller i vatten. Materialen med bäst micelle bildningsförmåga användes för att kemiskt korslänka dem och producera nano geler. Nano gelernas inre del funktionaliserades framgångsrikt med tre olika funktionella grupper; katjoniska, anjoniska och hydrofoba via resterande fria allyler. Detta påvisar att dessa dendritiska nano geler har potential att bära olika material som hydrofobiska läkemedel eller genetiskt material. Dom producerade nano gelerna hade en hydrodynamisk volym inom intervallet 124-200 nm. Detta är fördelaktigt då dem kan transporteras till tumörområdet via ökad permeabilitet och retention, också kallad EPR effekten, utan att initiera ett immunologiskt svar eller filtreras från blodomloppet via njuren. / The development of nano- based drug carriers is of high importance in anti-cancer treatment as anticancer drugs suffers from limitations as low aqueous solubility, non-selective targeting, off-target degradation and low therapeutic concentrations at target site. Hyperbranched polymers are potential candidates as drug carrier due to its unique properties as globular shape, high number of functional groups and high degree of branching. In addition, hyperbranched polymers are synthesized via one-step polymerization reaction with high yields, low costs and good scale-up possibilities. In this project a library of hyperbranched linear-dendritic hybrid materials based of 2,2-bis(hydroxymethyl)propionic acid (bis-MPA) and monofunctional poly (ethylene glycol) (mPEG) was synthesized via the Fischer esterification reaction. The materials were then post functionalised with hydrophobic allyl groups. The materials self-assembled into micelles in water and candidates with best self-assembly ability were used to fabricate dendritic nanogels by UV-induced cross-linking. The formed dendritic nanogels obtained a hydrodynamic volume between 124-200 nm, which indicates that these dendritic nanogels can be used as drug carrier and accumulate at target-site via the enhanced permeability and retention (EPR) effect. The dendritic nanogels inner core was also successfully attached with cationic, hydrophobic and anionic groups respectively. This confirmed that the dendritic nanogels have the potential to encapsulate different types of cargo such as DNA or hydrophobic drugs in the inner core.

hyperbranched polymers

anticancer treatment

dendritic nanogels

EPR-effect

hydrophobic drugs

nano partiklar

anti-cancer behandling

dendritiska nano geler

funktionalisering

hydrodynamisk volym

Engineering and Technology

Teknik och teknologier

Investigation of Graphene Oxide Based Multilayered Capsules/Films for Drugs Delivery And Antimicrobial Applications

Kurapati, Rajendra

January 2013

Polyelectrolyte multilayer capsules fabricated by layer-by-layer (LbL) self-assembly technique consistsing of core-shell structure have emerged as potential drug delivery systems along with their applications in micro-reactors, cosmetics, vaccines and antimicrobial coatings. Various ligands and stimuli responsive entities can be incorporated into the core and shell of the capsules for targeted delivery and/or controlled release applications. Though multilayer capsules have been studied extensively as delivery systems, their utility for encapsulation of hydrophobic drugs and multiple drugs have not been explored in detail so far. Application of traditional polyelectrolyte capsules has several limitations, which renders them inapplicable for encapsulation of multiple drugs, hydrophobic drugs and also for releasing drugs on demand without addition of the external photothermal agents such as metal nanoparticles into the shells of the capsules. Thus, in this thesis, an attempt has been made to develop novel multifunctional multilayered capsules to overcome the above mentioned limitations. We have formulated two novel methods to functionalize the core with cyclodextrin molecules and the shell of the capsules with two-dimensional material, graphene oxide (GO). The properties such as high surface area along with π bonds, broad NIR-absorption, superior photothermal conversion and antimicrobial activity of graphene oxide has been explored and it has been demonstrated that 2-D graphene oxide is unique compared to the regular polyelectrolytes. By functionalizing the shell of capsules with GO as one of the layer material, a simple and efficient way for encapsulating multiple drugs into core and shell of the capsules is achieved by utilizing the large surface area and amphiphilic nature of GO. Based on the unique optical absorption and photothermal conversion properties of GO, we have demonstrated a facile route for near-infrared (NIR)-laser triggered release with low laser power. In the second part, functionalization of the hollow core of the capsules has been functionalized using cylodextrin (CD)-incorporated CaCO3 porous sacrificial templates, where both CD-CaCO3 and CD-modified capsules are used as high efficient carriers for hydrophobic drugs. In the third part, synergistic antimicrobial therapy was achieved using composite graphene oxide/polymer LbL films by combining the intrinsic antimicrobial activity and photothermal conversion ability of graphene oxide and the results depicted superior antimicrobial activity towards E. coli. These composite films also can be used as efficient antimicrobial coatings on biomedical devices or implants. The thesis has been divided into five chapters based on the individual works. In Chapter 1, a brief review on the history of LbL self-assembly, mechanism of self-assembly along with factors affecting the process have been discussed. Followed by a brief discussion about the fabrication of multilayered hollow capsules (core-shell structure), their applications in drug delivery and fabrication of multifunctional multilayered capsules through core and shell have been discussed. Finally, recent developments in LbL self-assembly and multilayered hollow capsules using carbon based materials (fullerenes, carbon nanotubes and graphene oxide) and their biomedical applications have been presented. Chapter 2 deals with the study on fabricating multifunctional multilayered capsules for facile encapsulation of multiple drugs into the capsules, which is achieved by functionalizing the capsules with graphene oxide (GO) as one of the layer materials. The GO composite capsules exhibited unique permeability properties compared to traditional multilayered capsules made of two polyelectrolytes. Multiple drugs could be simultaneously encapsulated in the capsules in a simple and effective manner. These capsules were found to exhibit a “core-shell” loading property for encapsulation of dual drugs into the core and shell of the capsules respectively. In addition, the graphene oxide composite capsules showed excellent biocompatibility towards MCF-7 cells. This study is the first one that demonstrates the potential of hybrid polyelectrolyte capsules without the use of micelles or polymer-drug conjugates for multi-drug encapsulation. Chapter 3 deals with the development of a facile route for near-infrared (NIR)-light triggered release of encapsulated drugs from the multilayered capsules via incorporation of graphene oxide (GO) into layer-by-layer (LbL) assembled capsules without addition of any external additives such as metal nanoparticles (NPs) or carbon nanotubes (CNTs) into the shells of the capsules. Till now, there is no report on light-responsive drug delivery system by utilizing the NIR-optical absorption properties of GO. Here, graphene oxide (GO) plays a dual role, serving as a structural component of LbL capsules as well as strong NIR-light absorbing agent, which efficiently converts absorbed light into heat. Upon NIR-laser irradiation, the microcapsules were opened in “point-wise fashion” due to local heating caused by laser irradiation. The rupturing mechanism of the capsules has been clearly demonstrated using confocal fluorescence microscopy and high resolution transmission electron microscopy. The light-triggering ability of these capsules has been applied successfully to release the encapsulated anticancer drug, doxorubicin. Chapter 4 deals with simple and versatile simple routes for encapsulation of model hydrophobic drug. Encapsulation of hydrophobic drugs in pharmaceutical industries is always a big challenge due to limited number of available drug carrier systems and poor aqueous solubility of hydrophobic drugs. Here, by combining the special properties of cyclodextrins (CDs) with biodegradable inorganic calcium carbonate microparticles, the hybrid CD-CaCO3 mesoporous microparticles have been prepared for the first time. These CD-CaCO3 microparticles were utilized as sacrificial templates to prepare CDs-modified LbL capsules. We have demonstrated that both the hybrid CD-CaCO3 microparticles and CDs-modified capsules are potential carriers for encapsulation of model hydrophobic drugs (self-fluorescent coumarine and nile red dyes) with high loading efficiency using supramolecular host-guest interaction between entrapped CDs and hydrophobic dye molecules. Compared with other inorganic drug carrier systems (mesoporous silica), CaCO3 porous particles have better biocompatibility, biodegradability and cost-effective and without use of any organic solvents. Both these hybrid CD-CaCO3 microparticles and CDs-modified capsules can be good candidates for encapsulation of hydrophobic drugs without involving extreme chemical conditions for fabrication. Chapter 5 deals with development of facile synergistic method for killing pathogenic bacteria by combining the intrinsic antimicrobial activity of graphene oxide (GO) and unique photothermal conversion property of GO into a single material. We fabricated composite LbL films of graphene oxide (GO) and poly(allylamine hydrochloride) (PAH) films. Antimicrobial activity of these GO composite films has been studied using Escherichia coli (E. coli) cells by varying number of deposited layers on glass slides (20 to 80 layers) and results suggest that by increasing the number of deposited layers, antimicrobial activity is also increased gradually. Based on the unique optical properties of GO, photothermal therapy have been carried out for killing of E. coli using GO composite films by varying number of deposited layers (20 to 80 layers) by irradiation of NIR-pulse laser at 1064 nm wavelength (Nd:YAG, 10 ns pulse, 10 Hz). The photothermal results revealed the enhanced antimicrobial activity compared to GO composite films alone without NIR-laser irradiation. The synergistic photothermal killing ability along with intrinsic antimicrobial activity of GO films results in much faster killing compared to films alone.

Graphene Oxide Multilayered Capsules

Polyelectrolyte Multilayer Capsules

Drug Delivery

Hydrophobic Drugs

Antimicrobial Therapy

Hydrophobic Drug Encapsulation

Graphene Oxide Multilayered Films

Graphene Oxide Multilayered Capsules

Graphene oxide Based Multilayer Capsules

Materials Engineering