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Synthesis and Structure-Property Relationships of Polysaccharide-Based Block Copolymers and HydrogelsChen, Junyi 04 February 2020 (has links)
Polysaccharides are known as among the most abundant natural polymers on the Earth. As this class of material is usually renewable, biodegradable, biocompatible in many contexts and environmentally friendly, it is of great interest to use these benign polymers to design and prepare materials, especially for applications with green and biomedical purposes. In this dissertation we will discuss novel pathways to two different types of polysaccharide-based materials: block copolymers and hydrogels.
Block copolymers are composed of two or even more covalent bonded polymer blocks that have quite distinct properties. Synthesis of polysaccharide-based block copolymers is an attractive and challenging research topic, opening up promising application potential and requiring advances in polysaccharide regio- and chemoselectivity. Herein, we report two independent approaches to prepare these interesting and potential useful materials. In one approach, trimethyl cellulose was modified regiospecifically at the reducing end anomeric carbon to create an ω-unsaturated alkyl acetal by solvolysis with an ω-unsaturated alcohol. Then, olefin cross-metathesis, a known versatile and mild tool for polysaccharide chemical modification, was used to couple the trimethyl cellulose block with various polymer blocks containing acrylates. To demonstrate the method, trimethyl cellulose-b-poly(tetrahydrofuran), cellulose-b-poly(ethylene glycol), and cellulose-b-poly(lactic acid) were synthesized by this coupling strategy. In another approach, we introduced a simple and novel method to prepare dextran-based block copolymers. In this strategy, N-bromosuccinimide (NBS)/triphenyl phosphine (PPh3) was chosen to regioselectively brominate the only primary alcohol of linear unbranched dextran. The resulting dextran, bearing a terminal C-6 bromide, was coupled with several amine terminated polymers via SN2 substitution to obtain block copolymers, including dextran-b-polystyrene, dextran-b-poly(N-isopropylacrylamide) and dextran-b-poly(ethylene glycol). Dextran-b-poly(N-isopropylacrylamide) exhibits thermally-induced micellization as revealed by dynamic light scattering, forming micelles with 155 nm diameter at 40 °C. Dextran-b-polystyrene film was analyzed by small angle X-ray scattering, suggesting the existence of microphase separation.
This dissertation also introduces a novel, simple and effective strategy to prepare polysaccharide-based hydrogels. Hydrogels are typically crosslinked hydrophilic polymers that have high water affinity and no longer dissolve in water. Polysaccharide-based hydrogels are of great interest to for biomedical applications due to their benefits including biocompatibility, polyfunctionality, and biodegradability. Recently the Edgar group has discovered that chemoselective oxidation of oligo(hydroxypropyl)-substituted polysaccharides impairs ketone groups at the termini of the oligo(hydroxypropyl) side chains. These ketones can condense with amines to form imines, leading hydrogel formation., Based on this concept, we prepared oxidized hydroxypropyl polysaccharide/chitosan hydrogels. This class of all-polysaccharide hydrogels exhibits a series of interesting properties such as tunable moduli (300 Pa to 13 kPa), self-healing, injectability, and high swelling ratios. To further explore imine-crosslinked hydrogels, we designed thermally responsive hydrogels by using a Jeffamine, a polyethylene oxide-b-polypropylene oxide-b-polyethylene oxide triblock copolymer with two terminal amines. As the Jeffamine has a lower critical solution temperature, oxidized hydroxypropyl cellulose/Jeffamine hydrogels display moduli that are tunable by controlling the temperature. / Doctor of Philosophy / Polysaccharide are natural polymers that are among the most abundant polymers on Earth. It is greatly in society's interest to extend the scope of their applications, due to the benign nature of polysaccharides. This dissertation mainly focuses on two polysaccharides: cellulose and dextran. Cellulose is a long linear polymer of linked glucose molecules. As cellulose is sustainable, biodegradable, non-toxic, affordable and accessable for chemical modification, it is a suitable polymer for biomedical and environmentally friendly application. Dextran is also a polymer chain made up only of glucose but connected with each other differently from cellulose by, bacterial fermentation, and it may be lightly branched. It is biocompatible in many situations and is biodegradable both in vivo and in the environment, thus it has been investigated for drug delivery and many other medical applications. Using these two polysaccharides, we designed and prepared two quite different classes of materials: block copolymers and hydrogels.
Block copolymers consist of two or more different types of polymer blocks connected by strong covalent bonds. As block copolymerization enables construction of a single polymer comprising segments with distinct properties, it is appealing to synthesize a block copolymer which preserves the properties of natural polymers coupled to very different polymers, such as polyolefins (e.g. the polyethylene that is used for milk bottles). In order to prepare polysaccharide-based block copolymers, we developed two different synthetic routes to end-functionalize methyl cellulose and dextran , and these resulting products were used to prepare two independent series of polysaccharide-based block copolymers via combination (in other words, sticking the polysaccharide and, e.g., the polyethylene together end to end). This study confirms the feasibility of this method to make methyl cellulose-based and dextran-based block copolymers. We expect these classes of materials will have significant potential in applications including drug delivery, as compatibilizers for polymer blends of materials that otherwise cannot be mixed (polyolefin/polysaccharide), membrane and adhesive.
Hydrogels are crosslinked polymer networks with high water affinity, and they have been heavily investigated in the field of tissue engineering, drug delivery, agriculture and 3D printing. Polysaccharide-based hydrogels are attractive materials for these applications because they are biocompatible, biodegradable and have polyfunctionality. However, any use of toxic small molecules to crosslink the hydrogels diminishes their usefulness in biomedical applications. In this work, we demonstrate a simple, green and efficient method for preparation of all-polysaccharide-based hydrogels. The starting materials, oxidized hydroxypropylpolysaccharide, were simply prepared by using household bleach (NaOCl) as the oxidation reagent. We discovered that oxidized hydroxypropyl polysaccharides readily form hydrogels with hydrophilic amine-containing polymers like chitosan (a natural polysaccharide that comes from shells of crustaceans like crabs or shrimp) and Jeffamines, affording interesting properties including tunable stiffness, self-healing, injectability, and responsiveness to acidity and temperature. We expect that this new class of hydrogel will be very promising for biomedical-related applications.
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