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Surface modification of titanium substrates with polymer brushes to control cell adhesion for bioapplications

(Georgia Institute of Technology, 2008-11-17) Raynor, Jenny E.

Modification of the surface chemistry of materials used as implants in biomedical applications affords the ability to control cell adhesion, prevent inflammation and enhance integration with the host. Titanium and its alloys are strong and lightweight thereby making them desirable for applications such as hip and knee replacements, dental implants, and cardiac pacemaker implants. However, the lifetime of these implants is often limited by poor incorporation into the surrounding bone which results in loosening and wear. In order to overcome these limitations we have studied the modification of titanium substrates with a self-assembled monolayer that can be used to perform surface-initiated atom transfer radical polymerization (SI-ATRP) of a monomer to afford polymer brushes that effectively prevent the adhesion of cells. In addition, the polymer brushes afford the ability to tether a peptide sequence. Specific peptides containing adhesion sequences have been tethered to the polymer brushes. The resulting surfaces promote cell adhesion and osteoblast differentiation, thereby increasing bone tissue formation around the implant resulting in better incorporation of the implant.
Synthesis of functional lactide copolymers for use in biomedical applications

(Georgia Institute of Technology, 2008-07-08) Noga, David Edward

The biocompatibility and biodegradability of poly(lactic acid) (PLA) facilitate its use in a variety of biomedical applications, ranging from sutures to drug delivery. However, uncontrolled interactions with cells and insufficient mechanical properties have prevented PLA from reaching its full potential as a scaffold for use in tissue engineering. Methods to improve the mechanical, chemical and biological properties of PLA are limited by the lack of functional groups along the backbone of the polymer. One possible approach towards overcoming these limitations involves the incorporation of functional groups into the backbone of the polymer through the copolymerization of monomers bearing protected functional groups. Deprotection and modification of these functional groups could provide the opportunity to direct the attachment of cells, and enhance to the physical properties of the polymer. We have developed a general methodology for the synthesis of lactide monomers substituted with protected functional groups (alcohols protected as benzyl ethers, amines protected as benzyl carbamates and carboxylic acids protected as benzyl esters). The monomers were homopolymerized, and copolymerized with lactide, and deprotected to give functional PLA copolymers with pendant hydroxyl, amine, and carboxyl groups. A thorough investigation of the chemical modification of PLA copolymers bearing functional groups along the polymer backbone was performed on a copolymer prepared by copolymerizarion of a dibenzyloxy-substituted lactide monomer with lactide followed by reductive debenzylation. Reaction of the resulting hydroxyl-substited PLA with succinic anhydride resulted in an acid-substituted PLA that is amenable to standard EDC/NHS coupling. The utility of this copolymer was illustrated by coupling with an amine derivative of biotin, and an RGD-containing peptide sequence. The preparation of the biodegradable polyester substituted with RGD, a ubiquitous adhesion peptide, provided us with control over cellular attachment to the hybrid material. We also explored approaches to make use of the pendant functional groups on PLA to enhance the physical properties of polymer foams. Copolymers with pendant photocrosslinkable cinnamate groups were prepared by reaction of the hydroxyl-substited PLA copolymers with cinnamoyl chloride. The copolymer was foamed using thermally-induced phase separation (TIPS), and photocrosslinked upon irradiation at 300 nm. Irradiation resulted in an increase in the compressive modulus of the foams. Crosslinking also led to a decrease in the rate of hydrolytic degradation of the foams, thereby demonstrating the potential for use of these strategies in the development of porous scaffolds for bioengineering. Another potential approach towards the preparation of robust polymer foams is the incorporation of a rigid polymer block which can phase separate during foam formation to provide additional structural integrity. Several poly(norbornene)-PLA diblock copolymer compositions were prepared by the ring-opening of lactide by a hydroxyl-terminated poly(norbornene) macroinitiator. The ability of the diblock copolymer to phase separate at elevated temperature was verified using small-angle x-ray scattering and wide-angle x-ray scattering.
Synthesis and Characterization of Regioregular, Amphiphilic Semifluoroalkyl-Substituted Polythiophenes and Cofacial Bis(oligothienyl)naphthalenes

(Georgia Institute of Technology, 2007-11-14) Watt, Shannon L.

Conjugated polymers and oligomers have been widely studied based on their wide range of useful properties and applications. Given the importance of self-assembly and charge transfer in the development of conjugated materials for use in electronic applications, it is crucial to: (i) prepare functional materials by molecular design, (ii) evaluate the structure-property relationships of new materials, and (iii) develop fundamental understanding of electronic structure and charge transport behavior. The use of conjugated polymeric materials in electronic applications relies on control of the assembly and orientation of the polymer chains in the solid state. Conjugated polymers with liquid crystalline behavior could be used to implement an additional level of control over orientation and resultant properties. Substitution of the conjugated polythiophene backbone with semifluoroalkyl side chains (i.e., the diblock -(CH2)m(CF2)nF) has afforded materials with unusual properties. The mutual immiscibility of the aromatic backbone, the alkyl side-chain segments, and the fluoroalkyl side-chain termini provides control over supramolecular packing. A series of eight polymers has been synthesized, in which the lengths of the alkyl (m) and fluoroalkyl (n) segments are varied. One regiorandom analogue and two poly(3-alkylthiophene)s were also synthesized for comparative purposes. The structure, molecular weight, and regioregularity of the polymers were evaluated using a variety of techniques. The semifluoroalkyl-substituted polymers have been systematically studied to determine the effect of side chain length and m:n block ratios on their solution state, liquid crystalline, and solid state properties. The effect of side chains on conjugation was determined, where solubility allowed, by solution-state UV-visible and fluorescence spectroscopy. The thermal and liquid crystalline properties of the homopolymers were evaluated by DSC, variable-temperature X-ray diffraction, and polarized optical microscopy. Several semifluoroalkyl-substituted polythiophene homologues show liquid crystalline behavior. Molecular packing and charge transport are key factors governing the use of conjugated materials in electronic applications. A wide variety of oligomers have been studied as models for charge migration in conjugated polymers. One-dimensional models do not adequately represent two-dimensional charge transport; thus, a variety of two-dimensional, covalently-linked models have been developed. Previous work by our group, and others, led to the proposal of bis(oligothienyl) compounds as models to study the interaction of the ð-conjugated chains. Previous reports by other researchers described the synthesis and characterization of hydrogen-terminated analogues of 1,8-bis(oligothienyl)naphthalenes. However, these materials proved to be unsuitable for use as charge transport models, as they were subject to irreversible polymerization upon oxidation. Installation of methyl groups at the terminal a-positions of 1,8-bis(oligothienyl)naphthalenes allowed us to create a series of models in which conjugated chains are held in close proximity. This provides access to multiple redox states, and future systems based on these molecules may be used as models for charge transport or as functional materials for incorporation into devices.
Stacked Conjugated Oligomers as Molecular Models to Examine Interchain Interactions in Conjugated Materials

(Georgia Institute of Technology, 2006-11-20) Knoblock, Kurt M.

Previous studies of the redox states of linear conjugated oligomers as models for polarons and bipolarons in conjugated polymers do not fully address the influence of intermolecular interactions on the electronic structure of conjugated systems in the solid state. Fusion of oligothiophenes onto a bicyclo[4.4.1]undecane core holds the conjugated oligomers in a permanent cofacial stack. One- and two-electron oxidation of the stacked oligomers affords mono(radical cation)s and dications that serve as models for polarons and bipolarons in p-doped conjugated polymers and demonstrates the effect of pi-stacking on the electronic structure of these species. Installation of phenyl-capped and ferrocenyl-capped oligothiophenes allows us to systematically vary pi-stacked oligomers and study intramolecular charge migration in other linear conjugated molecules.
Surface-directed assembly of fibrillar extracellular matrices

(Georgia Institute of Technology, 2005-04-21) Capadona, Jeffrey R.

Biologically-inspired materials have emerged as promising substrates for enhanced repair in various therapeutic and regenerative medicine applications, including nervous and vascular tissues, bone, and cartilage. These strategies focus on the development of materials that integrate well-characterized domains from biomacromolecules to mimic individual functions of the extracellular matrix (ECM), including cell adhesive motifs, growth factor binding sites, and protease sensitivity. A vital property of the ECM is the fibrillar architecture arising from supramolecular assembly. For example, the fibrillar structure of fibronectin (FN) matrices modulates cell cycle progression, migration, gene expression, cell differentiation, and the assembly of other matrix proteins. Current biomaterials do not actively promote deposition and assembly of ECM. In this research, we describe the rational design and investigation of non-fouling biomimetic surfaces in which an oligopeptide sequence (FN13) from the self-assembly domain of FN is tethered to non-fouling substrates. This surface modification directs cell-mediated co-assembly of robust fibrillar FN and type I collagen (COL) matrices reminiscent of ECM, and increases in cell proliferation rates. Furthermore, the effect of this peptide is surface-directed, as addition of the soluble peptide has no effect on matrix assembly. We have also identified a critical surface density of the immobilized peptide to elicit the full activity. These results contribute to the development and design of biomimetic surface modifications that direct cell function for biomedical and biotechnology applications.
Novel conducting polymeric materials: 1. Fluoroalkylated polythiophenes 2. Stacked oligothiophenes as models for the interchain charge transfer in conducting polymers

(Georgia Institute of Technology, 2004-07-12) Li, Ling

Polythiophenes have great potential as semiconductors for use in organic field effect transistors and light emitting diodes. Recent research has been focused on the design, synthesis and characterization of fluorinated polythiophenes and oligothiophenes. Various fluoroalkyl side chains have been introduced to induce polymer self-assembly, to control the electronic properties of the conjugated backbone, and to modify the solubility of the polymer in supercritical CO2. This work led to the preparation of poly(3-(perfluorooctyl)thiophene), which is one of only a few examples of n-dopable polythiophenes, and is the first supercritical CO2-soluble conducting polymer. An alternating copolymer consisting of 3-perfluoroakyl and 3-alkylthiophene units has been synthesized. This polymer, with alternating electron-donating and withdrawing substituents, has a high quantum yield for fluorescence in solution relative to the two homopolymers, and strong fluorescence in solid state. Based on the study on its nanocrystals, the unusual photophyiscs may be due to the formation of the supramolecular structure with hexagonal packing. A novel thiophene monomer, 3-(1,1-difluorooctyl)thiophene, was prepared to further tune the electronic structure of polythiophenes by changing the fluorination pattern of side chains, while retaining solubility in organic solvents by virtue of the hydrocarbon side chain. a-Hexyl-w-perfluorohexylsexithiophene was synthesized to make a novel amphiphilic material for use in TFTs. Models for interchain charge transfer in doped conducting polymers were also developed. Stacked and unstacked conjugated oligomers have been synthesized as models for conducting polymers. The bis(radical cation) form and the dication-neutral form of compounds in which conjugated oligomers are held in a stacked arrangement are shown to coexist and in equilibrium with each other. The coexistence of these two forms further suggests that both may serve as charge carriers. Interconversion between these forms by disproportionation mimics a possible mechanism for charge migration in doped conjugated polymers.
Synthesis and Pharmacology of Potential Site-Specific Therapeutic Agents for Cocaine Abuse

(Georgia Institute of Technology, 2004-06-28) Moore, Susanna

Synthesis and Pharmacology of Potential Site-Directed Therapeutic Agents for Cocaine Abuse Susanna Moore 235 Pages Directed by Dr. David M. Collard and Dr. Howard M. Deutsch Stimulants such as cocaine continue to dominate the nations illicit drug problem. An effective medication for any aspect of cocaine addiction has not been developed. Cocaine binds, although not selectively, to the dopamine transporter (DAT) and disrupts normal dopamine (DA) neurotransmission between neurons. While the dopamine hypothesis for the mechanism of action of cocaine has been widely accepted, cocaine also possesses the ability to block the uptake of serotonin at the serotonin transporter (5-HTT) and norepinephrine at the norepinephrine transporter (NET). The purpose of the work described herein is directed towards synthesizing and testing compounds selective for the DAT, leading to the identification of candidates as potential pharmacotherapies for cocaine dependence. A series of disubstituted and trisubstituted [2.2.2] and [2.2.1]bicycles were synthesized and tested for inhibitor potency in [3H]WIN 35,428 (WIN) binding at the DAT and for inhibition of [3H]DA uptake. Based on results from some of the pharmacology data new regio- and stereochemical isomers of bicyclic [2.2.1]heptanes and [2.2.2]octanes were synthesized. This will lead to further structure-activity-relationships, which will provide a better understanding of the structural requirements needed to bind at the DAT.
Design of New Polyester Architectures through Copolymerization, Crosslinking, and Diels-Alder Grafting

(Georgia Institute of Technology, 2004-04-12) Vargas, Marian

The compound 2,6-anthracenedicarboxylic acid is used as a comonomer for the synthesis of poly(ethylene terephthalate). The resulting copolymers are characterized and further functionalized by Diels-Alder grafting or crosslinking through the anthracenate unit. Diels-Alder reaction is used to graft small molecules and oligomers endcapped with maleimide as dienophiles on to poly(ethylene terephthalate-co-2,6-anthracenedicarboxylate),PET-co-A. Maleimide-capped poly(ethylene glycol) is grafted onto PET-co-A to improved its hydrophilicity. 2,6-Anthracenedicarboxylic acid is also incorporated into the known liquid crystalline polymer, LCP, poly(4-oxybenzoate-co-1,4-phenylene isophthalate), HIQ40. The resulting copolymer, poly(4-oxybenzoate-co-1,4-phenylene isophthalate-co-2,6-phenylene anthracenate), HIQ40-co-A, shows LCP behavior. These HIQ40-co-A copolymers are grafted with maleimide end-capped monomers and polymers andcrosslinked with bismaleimides through a Diels-Alder mechanism.
Structure-property relationships in copolyester fibers and composite fibers

(Georgia Institute of Technology, 2004-04-12) Ma, Hongming

Polyethylene terephthalate is one of the most important engineering thermal plastics used for fibers, films and bottles. Despite its wide applications and vast global market, PET has shortcomings, which limits it usage in many areas. PET has a glass transition temperature (Tg) of 80 DEGREE Celsius, this temperature is too low for certain applications. Increase in glass transition temperature, high temperature mechanical properties, and dimensional stability is of great importance to further expand the applications of PET. Significant research efforts have been made toward this goal, using a variety of approaches. In this work, we attempt to improve the properties of PET melt spun filament. Three strategies has been investigated (i) copolymerization of more rigid comonomer, 4, 4' bibenzoate unit into the PET structure, (ii) UV crosslinking of functionalized PET fiber, and (iii) Reinforcing PET matrix with carbon nanofibers.
New comonomers and pet-based copolymers for functional high-barrier applications

(Georgia Institute of Technology, 2003-05) Andrade, Genara Selene