Dünne, multi-sensitive Hydrogelschichten aus photovernetzbaren Blockcopolymeren

Kretschmer, Katja

29 October 2005

Ziel dieser Arbeit ist die Darstellung funktioneller Materialien, die ein multi-sensitives Ansprechverhalten aufweisen. Die Charakterisierung des Quellverhaltens der Gele stellt die Voraussetzung dar, die phasenseparierten Polymerfilme als multi-sensitive Sensorschichten mit verbessertem Ansprechverhalten einzusetzen. Die Aufgabe dieser Arbeit besteht in der Synthese von AB-Blockcopolymeren, die im wässrigen Medium auf die Temperatur oder auf die Temperatur und den pH-Wert ansprechen. Unter Verwendung der Makroinitiator-Technik werden Blockcopolymere synthetisiert. Zunächst werden temperatur-sensitive Polymere mit einem wasserlöslichen Polyethylenglykol-Block (PEG) und N-Isopropylacrylamid (NIPAAm) mittels "Atom Transfer Radical Polymerization" (ATRP) hergestellt. Die Umsetzung der durch "Nitroxide Mediated Radical Polymerization" (NMRP) hergestellten pH-sensitiven Poly(2-vinylpyridin)-Blöcke (P2VP) mit NIPAAm führt zu multi-sensitiven Blockcopolymeren. Da die Polymere auf ihre Quelleigenschaften in dünnen Filmen hin untersucht werden sollen, ist die Verwendung eines Chromophors, der in den NIPAAm-Block einpolymerisiert wird, nötig. Die Vernetzung der Polymerfilme erfolgt photochemisch. Das Quellverhalten der Polymerschichten wurde mit der Methode der "Surface Plasmon Resonance"-Spektroskopie (SPR) charakterisiert. Im Rahmen dieser Arbeit ist es gelungen, multi-sensitive Polymere darzustellen und deren Sensitivität in dünnen Polymerfilmen nachzuweisen. Bei den synthetisierten Polymeren handelt es sich um neuartige und funktionelle Materialien.

Blockcopolymere

Hydrogel

kontrolliert radikalische Polymerisation

stimuli-sensitiv

block copolymers

controlled radical polymerization

hydrogel

stimuli-sensitive

ddc:540

rvk:VK 8007

Blockcopolymere

Hydrogel

Polymerfilm

Radikalische Polymerisation

Dünne, multi-sensitive Hydrogelschichten aus photovernetzbaren Blockcopolymeren

Kretschmer, Katja

10 November 2005

Ziel dieser Arbeit ist die Darstellung funktioneller Materialien, die ein multi-sensitives Ansprechverhalten aufweisen. Die Charakterisierung des Quellverhaltens der Gele stellt die Voraussetzung dar, die phasenseparierten Polymerfilme als multi-sensitive Sensorschichten mit verbessertem Ansprechverhalten einzusetzen. Die Aufgabe dieser Arbeit besteht in der Synthese von AB-Blockcopolymeren, die im wässrigen Medium auf die Temperatur oder auf die Temperatur und den pH-Wert ansprechen. Unter Verwendung der Makroinitiator-Technik werden Blockcopolymere synthetisiert. Zunächst werden temperatur-sensitive Polymere mit einem wasserlöslichen Polyethylenglykol-Block (PEG) und N-Isopropylacrylamid (NIPAAm) mittels "Atom Transfer Radical Polymerization" (ATRP) hergestellt. Die Umsetzung der durch "Nitroxide Mediated Radical Polymerization" (NMRP) hergestellten pH-sensitiven Poly(2-vinylpyridin)-Blöcke (P2VP) mit NIPAAm führt zu multi-sensitiven Blockcopolymeren. Da die Polymere auf ihre Quelleigenschaften in dünnen Filmen hin untersucht werden sollen, ist die Verwendung eines Chromophors, der in den NIPAAm-Block einpolymerisiert wird, nötig. Die Vernetzung der Polymerfilme erfolgt photochemisch. Das Quellverhalten der Polymerschichten wurde mit der Methode der "Surface Plasmon Resonance"-Spektroskopie (SPR) charakterisiert. Im Rahmen dieser Arbeit ist es gelungen, multi-sensitive Polymere darzustellen und deren Sensitivität in dünnen Polymerfilmen nachzuweisen. Bei den synthetisierten Polymeren handelt es sich um neuartige und funktionelle Materialien.

info:eu-repo/classification/ddc/540

ddc:540

The Development and Characterization of Double Layer Hydrogel for Agricultural and Horticultural Applications

Kim, Sangjoon

10 September 2010

No description available.

Agricultural Chemicals

Agricultural Engineering

Chemical Engineering

Polyacrylamide hydrogel

Dehydration

Swelling

Mechanical property

Ionic hydrogel

Double layer hydroel

Polyurethane

Coating

Coated hydrogel

Dehydration simulation

Diffusion

Étude sur le comportement de l'adsorption du phosphate sur de l'hydrogel de chitosane microsphérique

Leduc, Jean-François

January 2015

La présence de phosphore dans les eaux comporte des risques pour la faune aquatique et la santé humaine. Ainsi, ce projet de recherche aborde cette problématique sur le traitement des eaux usées. En effet, il s’intègre dans La Stratégie pancanadienne sur la gestion des effluents d'eaux usées municipales du Conseil canadien des ministres de l’Environnement. Cette stratégie vise la diminution de la toxicité des rejets d’eaux usées, ce qui englobe les rejets de phosphore dans certains cas. Afin de remédier à ce problème, plusieurs techniques ont été développées, dont l’adsorption qui présente de nombreux avantages et peut être réalisée avec plusieurs types de matériaux, dont les biomatériaux. Cette étude est orientée vers la recherche de nouveaux matériaux adsorbant à base de biopolymère, à savoir le chitosane. Ce projet vise le traitement du phosphate par adsorption à l’aide d’hydrogel de chitosane microsphérique (HCM) pour déterminer l’efficacité de ce dernier. Les HCM ont été préparés par une méthode séquentielle consistant en la pulvérisation d’une solution de chitosane solubilisée suivi d’un processus de gélification. La caractérisation des HCM ont été fait par la distribution de taille et le potentiel zêta. Des essais en cuvée ont été effectués avec des microbilles de chitosane afin de déterminer la cinétique d’adsorption de ce processus. L’équilibre d’adsorption a été atteint en 30 minutes et le modèle représentant le mieux le phénomène cinétique d’adsorption est de pseudo-deuxième ordre. Dans ce processus d’élimination du phosphate, plusieurs facteurs influencent l’efficacité du traitement, dont la concentration initiale des anions phosphates, la concentration en adsorbant, le pH et la température de la solution. L’analyse du coefficient de distribution du phosphate sur les HCM démontre que l’adsorption est plus efficace dans des solutions peu concentrées (dont la concentration initiale est inférieure à 50 ppm de phosphate) et que le pH favorisant l’adsorption était de l’ordre de 6.5. Selon le modèle de Boyd, le taux d'adsorption est contrôlé par la diffusion dans la couche limite. Langmuir, Freundlich et Dubinin-Radushkhevic (D-R) ont été appliqués comme modèles d’adsorption pour décrire les isothermes et les résultats ont démontré une corrélation significative avec le modèle de Freundlich (R[indice supérieur 2] = 0,975). Les valeurs moyennes d'énergie libre obtenues avec le modèle D-R dévoilent que la sorption était de nature physique. Les variations d’énergie libre de Gibbs (ΔG) et d’enthalpie (ΔH) ont démontré le caractère spontané et exothermique de la réaction. Tandis que la valeur négative de ΔS indique une diminution de la variation l'entropie.

Hydrogel

Chitosane microsphérique

Phosphate

Adsorption

Modèle cinétique

Thermodynamique

Hybrid hydrogels based on RAFT mediated poly(N-vinyl pyrrolidone)

Eksteen, Zaskia-Hillet

12 1900

Thesis (MSc (Chemistry and Polymer Science))--University of Stellenbosch, 2009. / Thesis submitted in partial fulfilment for the degree of Master of Science (polymer science) at Stellenbosch University / ENGLISH ABSTRACT: The goal of this study was to synthesize hybrid hydrogels via a chemical crosslinking mechanism through use of chain end functional poly(N-vinyl pyrrolidone)(PVP) with various topologies. The crosslinking chemistries should be benign in nature i.e. at physiological pH ranges and at 37 °C. The degradation products should be biologically tolerable and renal clearance should be possible (< 30 000 g/mol PVP0. PVP of various topologies, controlled molar mass and quantitative chain end functionality was obtained via Reversible Addition Fragmentation chain Transfer (RAFT) mediated polymerization (PDI = 1.1- 1.4). The synthesized polymers were chain end functionalized to introduce thiol or aldehyde moieties. Thiol chain ends were obtained through post polymerization modification of xanthate functional PVP with either aminolysis or reduction. The aldehyde moiety was obtained by post polymerization modification of xanthate end functional PVP with sequential hydrolysis and thermolysis. Thiol functional four arm star PVP was reacted with acrylate difunctional poly(ethylene glycol) (DIAC PEG) crosslinker under standard Michael addition conditions. In order to obtain thioether crosslinked hydrogels from tetra functional star PVP molecules it was found that a minimum thiol functionalization of 30% and a molar ratio of acrylate:thiol of 1:1.1 is required. The Schiff base reaction was used to synthesize imine or secondary amine (after reduction) crosslinks with the lysine residues on either lysozyme or bovine serum albumin (BSA) or the primary amines of bis-(2-amino ethyl)amine). Hydrogels were obtained from aldehyde functionalized PVP molecules with a fraction of functional aldehyde chain ends of 0.88 for difunctional molecules and 0.50 for tetra functional star PVP molecules with lysozyme or BSA crosslinkers. The reaction rate was favoured by lowered pH (<6.0) and an optimum molar ratio of amine : aldehyde of 1:0.8. Hydrogels were analyzed by equilibrium swelling calculations to determine the molar mass between crosslinks and the estimated pore size. In both crosslinking systems the properties of the formed hydrogels were seen to be affected by molar ratio used and by the topology of the crosslinking agent. PVP BSA and PVP PEG hydrogels were tested for 24 h and 48 h cell viability by using H9C2 myoblast cells. A concentration range of 0.25 x 10(2) to 0.01 g/mL was studied. Cell mortality was tested by Trypan blue staining and results were verified with MTT assay. A very low cell death precentage (<37%)was observed. Cells even appeared to experience a stimulatory effect after 48 h of exposure at low concentrations of PVP PEG hydrogel treatments. The properties of the formed hydrogel could be tuned by the molar mass ratios of PVP and crosslinker. The functionality of the crosslinker directly affects the molar mass between crosslinks and thus indirectly the degradation profile. It was concluded that PVP molecules with various topologies, well-defined molar masses and chain end functionality could be obtained via RAFT mediated polymerization. Obtained polymers were successfully modified and crosslinked to obtain hydrogels with stoichiometrically tuneable properties i.e. initial swelling ratio, degradation time, molar mass between crosslinks. The hydrogels had very positive cell viability results that would definitely justify further research into these materials as “tissue-mimetic” materials. / AFRIKAANSE OPSOMMING: Die doel van die studie is om poli(N-viniel pirollidoon) (PVP) gebaseerde hibried hidrogelle te sintetiseer deur middel van kovalente kruisbindings met toepaslike kruisverbinder molekules. Die chemiese reaksies betrokke in die vorming van hierdie kovalente kruisbindings moet gematig van aard wees, by fisiologiese pH en by 37 °C plaasvind. Die degradasieprodukte van die hibried-hidrogel moet biologies verdraagsaam en ook uitskeibaar deur die endokrinologiese sisteem wees. PVP van verskillende topologieë, beheerde molêre massa en kwantitatiewe kettingendfunksionaliteit is berei deur ‘n omkeerbare addisie-fragmentasiekettingoordrag (OAFO)-beheerde polimerisasieproses (PDI = 1.1-1.4). Xantaat-kettingend-PVP is aangepas na thiol of aldehied kettingendfunksies. Thiolendfunksies is verkry deur middel van ‘n aminolisasie-reaksie. Xantaat kettingend-PVP is stapsgewys gemodifiseer deur hidroliese en verhittingstappe om die aldehied ketting-endfunksionaliteit te bekom. Thiol ketting-endfunksionele vier-armige ster-PVP is kovalent gebind aan difunksionele poly(etileen glikol) deur middel van die Michael-addisiereaksie. PVP PEG hidrogelle het slegs gevorm met vier-armige ster-PVP molekules wat oor ‘n minimum van 30 % thiol-funksionaliteit beskik het en ‘n optimale molêre massa verhouding van 1:1.1 vir ankrilaat to thiol. Die Schiff-basisreaksie is gebruik om hidrogel te sintetiseer wat met imiene of amiene (na redusering) kovalente bindings gekruisbind is. In hierdie sisteme het hidrogel slegs gevorm as die aldehied-PVP molekules oor ‘n fraksie funksionele kettingend-waarde van 0.88 vir dialdehied-PVP molekules en 0.5 vir vier armige ster-PVP molekules beskik het. Die reaksie snelheid van die Schiff-basis kovalente bindings is bevoordeel deur die pH te verlaag (≤ 6.0) en ‘n gunstige molêre massa verhouding van 1:0.8 vir die nukleofiel teen oor die akseptor molekule is waargeneem. Ewewigswel berekeninge is gebruik om die molêre massa tussen kruisbindings en die gemiddelde benaderde porieë binne die drie-dimensionele interne struktuur van die hydrogel te bepaal. Die seltoksisiteit van PVP-BSA en PVP-PEG hidrogelle is oor 24 h en 48 h in die teenwoordigheid van H9c2 mioblast-selle getoets. Die hydrogel behandelings is uitgevoer in ‘n konsentrasie reeks van 0.25 x 10(2) tot 0.01 g/mL. Selmortaliteit is getoets deur ‘n Trypan-blou verkleuringstudie. Hierdie resultate is ondersteun deur MTT sel-lewensvatbaarheidstoetse. ‘n Lae selmortaliteit (≤ 37 %) is waargeneem en, opspraakwekkend, het van die selle na 48 h verhoogde vitaliteit getoon in die teenwoordigheid van lae konsentrasies PVP-PEG hidrogelle. Dit is bevind dat hidrogel eienskappe deur stoichiometriese molêre massa verhoudings asook die keuse in die topologie van kruisverbinder beïnvloed word. Hierdie eienskappe het ‘n direkte effek op die degradasieprofiel van die gevormde hidrogel. Samevattend dus is PVP molekules met ‘n variasie van topologieë, spesifieke molêre massas en kettingfunksionalitete deur middel van OAFO-gemedieerde polimerisasies gesintetiseer. Xantaatkettingendfunksionele PVP-molekules kon suksesvol omgeskakel word na die kettingendfunksionaliteit van ons keuse om ‘n hibriedhidrogel met stoichiometries-manupileerbare eienskappe te sintetiseer. Die positiewe sel-lewensvatbaarbheidstudie resultate staaf verdere ondersoeke in hierdie PVPgebaseerde hibried hidrogelmateriaal as ‘n weefsel nabootsingsmateriaal.

Hydrogel

RAFT

Tissue mimetic

Cell viability

Chemistry and polymer science

Development of hyaluronic acid – poly(ethylene glycol) hydrogels towards hematopoietic differentiation of mouse embryonic stem cells

Erickson, Kathryn Marie

2009 August 1900

The fields of tissue engineering, regenerative medicine, and stem cell engineering are rapidly growing. However, these fields must overcome several obstacles before they can make a significant impact on treating cellular disorders. Two major hurdles that must be addressed are: determining how to control the pluripotency of stem cells and developing systems for high-throughput culture of stem cells. The prospect of using a cell source capable of differentiating into cells of any tissue in the body (embryonic stem cells) has received enormous interest in recent years. The pluripotent attribute of embryonic stem cells seems ideal but developing methods to drive embryonic stem cells to specific lineages, including the hematopoietic lineage, is a complex process dependent on multiple intrinsic and extrinsic factors including chemical, cellular, and environmental signaling. With regards to environmental signaling, the use of three-dimensional culture systems such as scaffolds and hydrogels, have been utilized in an attempt to drive lineage-specific differentiation in a synthetic, biomimetic microenvironment. To determine specific environmental factors responsible for hematopoietic differentiation a systematic biological and engineering process must be implemented. A biodegradable hydrogel composed of the hyaluronic acid, a polysaccharide abundant in the bone marrow microenvironment, and the synthetic polymer, poly(ethylene glycol) was formulated to culture mouse embryonic stem cells (mESCs). Photoencapsulation of mESCs did not significantly decrease cellular viability or proliferation. The FACS data was inconclusive however, from gene expression studies, it was determined that the hydrogel culture system promoted differentiation of mESCs as evidenced by a down-regulation of the gene encoding for stem cell maintenance transcription factor, Oct-3/4. Furthermore, embryoid bodies, necessary for in vitro differentiation were observed in the hydrogel systems. Although an increase in the gene encoding for the cell surface marker, c-kit was up-regulated, the surface marker, sca-1 was not up-regulated. Up-regulation of both c-kit and sca-1 is necessary for the development of hematopoietic progenitor cells. Results indicate that the differentiation of mESCs into the hematopoietic lineage was unsuccessful but differentiation in these hydrogel systems did occur. Future cell marker and gene expression studies are necessary to determine which cell lineage the encapsulated mESCs are differentiating into before the effects of incorporating other environmental, cellular, and chemical factors can be investigated. / text

hydrogel

stem cell

hyaluronic acid

poly(ethylene glycol)

differentiation

Lysozyme Deposition Studies on Silicone Hydrogel Contact Lens Materials

Nagapatnam Subbaraman, Lakshman

January 2005

Over 60 proteins have been detected in the tear film and among these lysozyme has attracted the greatest attention. Several techniques for elucidating the identity, quantity and conformation of lysozyme deposited on soft contact lenses have been developed. Lysozyme also deposits on the newly introduced silicone hydrogel (SH) lens materials, but in extremely low levels compared to conventional hydrogel lenses. Hence, a major analytical complication with the study of the SH contact lens materials relates to the minute quantity of deposited lysozyme. The first project of this thesis involved the development of a method whereby lysozyme mass extracted from SH lens materials would be preserved over time and would be compatible with an optimized Western blotting procedure. This methodological development was incorporated into a clinical study (CLENS-100?? and Silicone Hydrogels ? CLASH study) wherein the difference in the degree of total protein, the difference in lysozyme deposition and activity recovered from lotrafilcon A SH lens material when subjects used surfactant containing rewetting drops (CLENS-100??) versus control saline was investigated. The remaining experiments were in vitro experiments wherein the lenses were doped in artificial lysozyme solution containing ¹²⁵I-labeled lysozyme. These experiments were performed to gain insight into the kinetics of lysozyme deposition on SH lens materials and also the efficacy of a reagent in extracting lysozyme from SH lens materials. A protocol was developed whereby the percentage loss of lysozyme mass found on lotrafilcon A SH lenses was reduced from approximately 33% to <1% (p<0. 001), following extraction and resuspension. The results from the CLASH study demonstrated that when subjects used a surfactant containing rewetting drop instead of a control saline drop total protein deposition (1. 2??0. 7 ??g/lens versus 1. 9??0. 8 ??g/lens, p<0. 001), lysozyme deposition (0. 7??0. 5 ??g/lens versus 1. 1??0. 7 ??g/lens, p<0. 001) and percentage lysozyme denaturation (76??10% versus 85??7%, p=0. 002) were all reduced. The results from the kinetics study demonstrated that lysozyme accumulated rapidly on etafilcon A lenses (1 hr, 98??8 ??g/lens), reached a maximum on the 7th day (1386??21 ??g/lens) and then reached a plateau (p=NS). Lysozyme accumulation on FDA Group II and SH lenses continued to increase across all time periods, with no plateau being observed (p<0. 001). The results from the extraction efficiency study showed that 0. 2% trifluoroacetic acid/ acetonitrile was 98. 3??1. 1% and 91. 4??1. 4% efficient in extracting lysozyme deposited on etafilcon A and galyfilcon lenses, while the lysozyme extraction efficiency was 66. 3??5. 3 % and 56. 7??3. 8% for lotrafilcon A and balafilcon lens materials (p<0. 001). The results from these studies re-emphasize that novel SH lens materials are highly resistant to protein deposition and demonstrate high levels of biocompatibility.

Optometry & Ophthalmology

lysozyme

silicone hydrogel

contact lens

proteins

deposition

The preparation and characterization of thermo-sensitive colored hydrogel film and surfactant-free porous polystyrene three-dimensional network.

Zhou, Bo

12 1900

Polymer hydrogel films change their properties in response to environmental change. This remarkable phenomenon results in many potential applications of polymer hydrogel films. In this thesis colored thermo-sensitive poly(N-isopropylacrylamide) (PNIPAAm) hydrogel film was prepared by firstly synthesizing polymer latex and secondarily crosslinking the nanoparticles and casting the polymers onto glass. The shape-memory effect has been observed when changing the environmental temperature. The temperature-dependent of turbidity of polymer hydrogel film was measured by HP UVVisible spectrophotometer. This intelligent hydrogel might be used in chemomechanical systems and separation devices as well as sensors. Polymer adsorption plays an important role in many products and processes. In this thesis, surfactant-free three-dimensional polystyrene (PS) nanoparticle network has been prepared. The infrared spectroscopy and solubility experiment are performed to prove the crosslinking mechanism, also the BET method was used to measure the adsorption and desorption of polystyrene network. The BET constant (C) is calculated (C=6.32). The chemically bonded polymer nanoparticle network might have potential applications as catalyst or used for chromatographic columns.

Polymer colloids.

Polymer

hydrogel

films

colored

thermo-sensitive

nanoparticle

Polymer hydrogel nanoparticles and their networks

Lu, Xihua

08 1900

The thermally responsive hydroxypropyl cellulose (HPC) hydrogel nanoparticles have been synthesized and characterized. The HPC particles were obtained by chemically crosslinking collapsed HPC polymer chains in water-surfactant (dodecyltrimethylammonium bromide) dispersion above the lower critical solution temperature (LCST) of the HPC. The size distributions of microgel particles, measured by dynamic light scattering, have been correlated with synthesis conditions including surfactant concentration, polymer concentration, and reaction temperature. The swelling and phase transition properties of resultant HPC microgels have been analyzed using both static and dynamic light scattering techniques. By first making gel nanoparticles and then covalently bonding them together, we have engineered a new class of gels with two levels of structural hierarchy: the primary network is crosslinked polymer chains in each individual particle, while the secondary network is a system of crosslinked nanoparticles. The covalent bonding contributes to the structural stability of the nanostructured gels, while self-assembly provides them with crystal structures that diffract light, resulting in colors. By using N-isopropylacrylamide copolymer hydrogel nanoparticles, we have synthesized nanoparticle networks that display a striking iridescence like precious opal but are soft and flexible like gelatin. This is in contrast to previous colored hydrogels, which were created either by adding dyes or fluorescent, or by organic solvent or by embedding a colloidal crystal array of polymer solid spheres . Creating such periodic 3D structures in materials allows us to obtain useful functionality not only from the constituent building blocks but also from the long-range ordering that characterizes these structures. Hydroxypropyl cellulose (HPC) and poly (acrylic acid ) (PAA) complexes were studied using turbidity measurement and laser light scattering. The phase transition temperature of the complexes is found to depend on pH and molecular weights of PAA and HPC. The driving force for this phenomenon is due to the hydrogen bonding and hydrophobic interaction of the macromolecules. Based on the principle of the PAA/HPC complexes, the PAA nanoparticles were synthesized in 0.1wt % HPC aqueous solution at room temperature.

Polymer colloids.

Nanoparticles.

hydrogel

nanoparticle

network

laser light scattering

crystal

Synthesis and Characterization of Clickable Dendrimer Hydrogels for Ocular Drug Delivery

Tian, Jingfei

28 April 2014

Topical medication is a standard treatment for glaucoma. However, frequent dosing makes the therapy inconvenient and patient unfriendly. There is a great need to develop new topical formulations that provide long lasting noninvasive drug release. In this thesis, novel clickable dendrimer hydrogels for anti-glaucoma drug delivery were synthesized and characterized. Polyamidoamine (PAMAM) dendrimers have been widely applied for drug delivery. The physical characteristics they possess include monodispersity, water solubility, encapsulation ability, and a large number of surface groups. Polycationic PAMAM dendrimer G3 was surface modified with alkyne-PEG5-acid and then reacted with polyethylene glycol bisazide (PEG-BA, 1100 gmol-1) through click chemistry to form a cross-linked hydrogel. The resulting hydrogels were characterized in terms of mechanical properties, swelling, structural morphology, pH-dependent degradation, anti-glaucoma drugs (brimonidine tartrate and timolol maleate) release and cytotoxicity. To fully explore PAMAM dendrimers to make clickable hydrogels, polyanionic PAMAM dendrimer G4.5 was also surface modified with propargylamine to possess alkyne groups and successfully formed a hydrogel with PEG-BA. The work conducted in the thesis shows that clickable dendrimer hydrogels were successfully developed and shown to possess desired properties for delivery of anti-glaucoma drugs.

dendrimer

hydrogel

drug delivery

glaucoma

Engineering