Browsing by Subject "nanoparticles"
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Item A continuous impingement mixing process for effective dispersion of nanoparticles in polymers(Texas A&M University, 2006-10-30) Ganapathy Subramanian, Santhana GopinathMixing refers to any process that increases the uniformity of composition and is an integral part of polymer processing. The effective mixing of nanoparticles into polymers continues to be one of the leading problems that limit large scale production of polymer nanocomposites. Impingement mixing is a novel, relatively simple, continuous flow mixing process wherein mixing is accomplished by immersing a high velocity jet in a slower co-flowing stream. The resulting recirculating flow produces an energy cascade that provides a wide range of length scales for efficient mixing. An impingement mixing process was developed and studied through experiments and simulations. Numerical simulations were conducted using FLUENT to understand better the mechanism of operation of the mixer. The formation of a recirculation zone was found to affect the dispersion of nanoparticles. Results of the simulations were compared with experimental data obtained under similar conditions. While this process may be used for any polymernanoparticle combination, the primary focus of this study was the dispersion of Single Walled Carbon Nanotubes (SWNTs) in an epoxy matrix. The dispersion of SWNTs was evaluated by analyzing SEM images of the composites. The image analysis technique used the concept of Shannon Entropy to obtain an index of dispersion that was representative of the degree of mixing. This method of obtaining a dispersion index can be applied to any image analysis technique in which the two components that make up the mixture can be clearly distinguished. The mixing process was also used to disperse SWNTs into a limited number of other polymers. The mixing process is an "enabling" process that may be employed for virtually any polymer-nanoparticle combination. This mixing process was shown to be an effective and efficient means of quickly dispersing nanoparticles in polymers.Item A Small Scale Magnetic Particle Relaxometer(2013-12-09) El Ghamrawy, AhmedMagnetic Particle Imaging (MPI) is a newly found imaging modality. It utilizes superparamagnetic materials as tracers in the blood stream to obtain very high resolutions. MPI promises to have high sensitivity, high spatial resolution and no radiation compared to other imaging modalities. Most commercially available MRI tracers (used for MPI for now) are all non-harmful when compared to Iodine (used for CT scan) and Gadolinium (used for MRI). MPI research is divided into three categories: MPI scanner development, superparamagnetic materials development, and image reconstruction techniques. In this project a small scale LabView-based system will be developed for use on small lab created phantoms, using 25 nm superparamagnetic iron oxide (SPIO) particles. At first a relaxometer will be developed, the imager will come as the next step. Transmitting and receiving signals will be implemented using LabView and a National Instruments PXI-1033 Chassis. Lab-built coils will be used to send the excitation signal and receive the signal induced by those SPIO?s. The objective of this project is to be introduced to a new imaging modality that can have various applications and at the same time considered safe. The system being built is considered inexpensive and shows most of the aspects of how magnetic particle imaging works, starting with the physical phenomena, superparamagnetic nanoparticle properties and relaxation, signal generation and acquisition, and an introduction to the hardware of MPI. The system can be used to introduce engineers and engineering students to the MPI physical phenomena.Item Characterization and Reaction Studies of Silica Supported Platinum and Rhodium Model Catalysts(2012-02-14) Lundwall, Matthew JamesThe physical and catalytic properties of silica supported platinum or rhodium model catalysts are studied under both ultra high vacuum (UHV) and elevated pressure reaction conditions (>1torr). Platinum or rhodium nanoparticles are vapor deposited onto a SiO2/Mo(112) surface and characterized using various surface analytical methods. CO chemisorption is utilized as a surface probe to estimate the concentration of various sites on the nanoparticles through thermal desorption spectroscopy (TDS) and infrared reflection absorption spectroscopy (IRAS) along with microscopy techniques to estimate particle size. The results are compared with hard sphere models of face centered cubic metals described as truncated cubo-octahedron. Results demonstrate the excellent agreement between chemisorption and hard sphere models in estimating the concentration of undercoordinated atoms on the nanoparticle surface. Surfaces are then subjected to high pressure reaction conditions to test the efficacy of utilizing the rate of a chemical reaction to obtain structural information about the surface. The surfaces are translated in-situ to a high pressure reaction cell where both structure insensitive and sensitive reactions are performed. Structure insensitive reactions (e.g. CO oxidation) allow a method to calculate the total active area on a per atom basis for silica supported platinum and rhodium model catalysts under reaction conditions. While structure sensitive reactions allow an estimate of the types of reaction sites, such as step sites (?C7) under reaction conditions (e.g. n-heptane dehydrocyclization). High pressure structure sensitive reactions (e.g. ethylene hydroformylation) are also shown to drastically alter the morphology of the surface by dispersing nanoparticles leading to inhibition of catalytic pathways. Moreover, the relationships between high index single crystals, oxide supported nanoparticles, and high surface area technical catalysts are established. Overall, the results demonstrate the utility of model catalysts in understanding the structure-activity relationships in heterogeneous catalytic reactions and the usefulness of high pressure reactions as an analytical probe of surface morphology.Item Consolidation of copper and aluminum micro and nanoparticles via equal channel angular extrusion(2009-05-15) Hutchins, Cathleen RuthUltrafine grained (UFG), and nanocrystalline (nc) materials are of interest because of the high strength, compared with coarse grained counterparts. Several current methods to fabricate UFG and nc materials result in samples too small for practical use. In addition, the fabrication of nc materials, in particular, is difficult, and defects in the material causes significant reduction in strength and ductility of these materials. The present study uses Equal Channel Angular Extrusion (ECAE) to produce relatively large consolidates of UFG and nc materials. ECAE has been used to consolidate micro and nanocrystalline powders. The behavior of consolidated pure Cu and aluminum alloys in the nano and micron size were explored. The effects of different routes, extrusion temperature, and post-ECAE processing on microstructure and mechanical behavior were studied. Processing parameters were explored to determine the influence of each parameter on the consolidation performance. The goals of experimenting with different processing parameters were to increase the ductility of the material, while maintaining relatively strong specimens. Comparisons were made with a recently developed powder compaction constitutive model and corresponding simulations. ECAE of microcrystalline powders produced relatively ductile materials, with high strength. Swaging of these consolidated powders produced samples which were softer and less ductile in tension, than the non-swaged samples. ECAE produced effective consolidation of Cu nanoparticles with average sizes of 100 nm, with an ultimate tensile strength of 680 MPa, with a fracture strain as much as 10%, which is higher than previously reported 7% [Haouaoui, 2005].Item Cytotoxicological Response to Engineered Nanomaterials: A Pathway-Driven Process(2012-07-16) Romoser, Amelia AntoniaNanoparticles, while included in a growing number of consumer products, may pose risks to human health due to heavy metal leaching and/or the production of reactive oxygen species following exposures. Subcellular mechanisms of action triggered as a result of exposure to various nanoparticles are still largely unexplored. In this work, an effort to elucidate such toxicological parameters was accomplished by evaluating oxidative stress generation, changes in gene and protein expression, and cell cycle status after low-dose exposures to a variety of metal and carbon-based nanomaterials in primary human dermal cells. Additionally, mitigation of nanoparticle toxicity via microencapsulation was investigated to assess the feasibility of utilizing nanomaterials in dermally implantable biosensor applications. Cellular immune and inflammatory processes were measured via qPCR and immunoblotting, which revealed gene and protein expression modulation along the NF-kappaB pathway after a variety of nanoparticle exposures. The role of immunoregulatory transcription factor NF-kappaB was examined in an oxidative stress context in cells exposed to a panel of nanoparticles, whereby glutathione conversion and modulation of oxidative stress proteins in normal and NF-kappaB knockdown human dermal fibroblasts were monitored. Results revealed decreased antioxidant response and corresponding increased levels of oxidative stress and cell death in exposed normal cells, compared to NF-kappaB incompetent cells. However, reactive oxygen species production was not an absolute precursor to DNA damage, which was measured by the comet assay, gamma-H2AX expression, and flow cytometry. Protein analysis revealed that map kinase p38, rather than p53, was involved in the halting of the cell cycle in S-phase after ZnO exposures, which caused DNA double strand breaks. Microencapsulation of fluorescent quantum dot nanoparticles, specifically, was utilized as a method to improve system functionality and surrounding cellular viability for the purpose of a dermal analyte detection assay. In vitro results indicated a functional localization of nanoparticles, as well as cessation of cellular uptake. Subsequently, cellular metabolism was unaffected over the range of time and concentrations tested in comparison to unencapsulated quantum dot treatments, indicating the usefulness of this technique in developing nanoparticle-driven biomedical applications.Item Femtosecond time-resolved spectroscopy of coherent oscillations in nanomaterials(2009-05-15) Jerebtsov, Serguei NikolaevichThe interaction of laser radiation with a material can excite coherent lattice vibration. The observation of such periodic motion of the atoms in the lattice provides information on the properties of the material. In the present work a femtosecond pump-probe technique was applied for studies of acoustic vibrations in nanoparticles and nanowires, and coherent optical phonons in thin films. The elastic properties of spherical Ag nanoparticles and Ag and Bi nanowires were studied in a dual-color femtosecond pump-probe experiment. The results of the period determinations of the acoustic vibrations, obtained from the time-domain measurements with low intensity pump pulses, together with the information about the size of the particles, were used to determine the elastic constants of the materials. Also changes in the measured acoustical response of the Ag nanowires under high intensity laser excitation were studied. In addition the coherent optical phonon excitation in a Bi film was studied in a femtosecond pump-probe experiment. A red-shift of the phonon frequency at the high photoexcitation density was observed. To separate the effect of the lattice softening and the lattice anharmonicity the excitation with two pump pulses was employed. Numerical simulations, which took into account the evolution of the spatial inhomogeneity of the excitation density, were carried out and compared to the experimental results.Item Heteroepitaxial Self Assembling Noble Metal Nanoparticles in Monocrystalline Silicon(2013-08-13) Martin, Michael S.Embedding metal nanoparticles in crystalline silicon possesses numerous possible applications to fabricate optoelectronic switches, increase efficiency of radiation detectors, decrease the thickness of monocrystalline silicon solar panels and investigate fundamental properties. Noble metal nanoparticles made of gold or silver are grown in cavities in monocrystalline silicon formed by helium ion implantation and high temperature annealing at depth greater than 500 nm from the surface. Metals are introduced into the system by low energy ion implantation or physical vapor deposited thin film on the surface, and diffused into cavities by heat treatment. Nanoparticles nucleate on the inner surface of cavities heteroepitaxially and form face centered cubic crystal structure in the case of silver. Excessive heat treatment causes metal to be emitted from nanoparticles into bulk after trapping and nanoparticle formation. Helium ion implantation, annealing and diffusion heat treatment conditions have been optimized so that residual crystalline damage, point defects and dislocations, is reduced in monocrystalline silicon substrate.Item Iron oxide nanoparticles as a contrast agent for thermoacoustic tomography(2009-06-02) Keho, Aaron LopezAn exogenous contrast agent has been developed to enhance the contrast achievable in Thermoacoustic Tomography (TAT). TAT utilizes the penetration depth of microwave energy while producing high resolution images through acoustic waves. A sample irradiated by a microwave source expands due to thermoelastic expansion. The acoustic wave created by this expansion is recorded by an ultrasonic transducer. The water content in biological samples poses an obstacle, as it is the primary absorber of microwave radiation. The addition of an exogenous contrast agent improves image quality by more effectively converting microwave energy to heat. The use of iron oxide nanoparticles in MRI applications has been explored but super paramagnetic iron oxide nanoparticles (SPION) have benefits in microwave applications, as well. Through ferromagnetic resonance, SPION samples more effectively convert microwave energy into heat. This transduction to heat creates significantly larger thermoacoustic waves than water, alone. Characterization of the SPION samples is executed through TAT, TEM, XPS, EDS, and a vector network analyzer with a dielectric probe kit. Onedimensional and phantom model imaging with an iron oxide nanoparticle contrast agent provide a two-fold improvement in contrast at current system configurations. Further enhancement is possible through adjustments to the nanoparticles and TAT system.Item Mercury Removal from Aqueous Systems Using Commercial and Laboratory Prepared Metal Oxide Nanoparticles(2010-10-12) Desai, IshanFive commercial metal oxide nanoparticles (CuO, SiO2, Fe2O3, TiO2 and Al2O3) have been individually screened for mercury removal in a batch reactor under bicarbonate buffered and non-buffered aqueous solutions (DI water). Copper oxide was then selected for surface modification to enhance mercury removal. The surfaces of both laboratory prepared and commercially available copper oxide nanoparticles were treated with 1-octanethiol to produce copper sulfide and/or copper alkanethiol nanoparticles. The resulting particles were characterized using X-Ray Fluorescence(XRF), X-Ray Diffraction (XRD) and Scanning Electron Microscopy (SEM). The novel nanoparticles demonstrated very high mercury removal (> 99%) from both the buffered and non-buffered aqueous solutions.Item Multi-functional Bio-synthetic Hybrid Nanostructures for Enhanced Cellular Uptake, Endosomal Escape and Targeted Delivery Toward Diagnostics and Therapeutics(2012-09-26) Shrestha, Ritu 1984-Applications of nanotechnology in medicine, also known as nanomedicine, is a rapidly growing field as it holds great potential in the development of novel therapeutics toward treatment of various diseases. Shell crosslinked knedel-like nanoparticles (SCKs) that are self assembled from amphiphilic block copolymers into polymeric micelles followed by crosslinking selectively throughout the shell domain have been investigated as theranostic agents for the delivery of nucleic acids and incorporation of imaging probes. The main focus of this dissertation is to design and develop unique multifunctional bio-synthetic hybrid nanoparticles that can carry agents for radiolabeling, moieties for inducing stealth properties to minimize protein adsorption in vivo, ligands for site-specific targeting, therapeutic payloads, and are optimized for efficient delivery of cargoes intracellularly and to the target sites toward constructing novel nanoscopic objects for therapy and diagnosis. Alteration of polymeric building blocks of the nanoparticles provides opportunities for precise control over the sizes, shapes, compositions, structures and properties of the nanoparticles. To ensure ideal performance of nanoparticles as theranostic agents, it is critical to ensure high intracellular bioavailability of the therapeutic payload conjugated to nanoparticles. Special efforts were made by employing well-defined multi-step polymerization and polymer modification reactions that involved conjugation of peptide nucleic acids (PNAs) to chain terminus of poly(ethylene glycol) (PEG) chain grafts such that they were presented at the outermost surface of SCKs. Additionally, chemical modification reactions were performed on the polymer backbone to integrate positive charges onto the shell of the nanoparticles to afford cationic SCKs (cSCKs) for facilitating cellular entry and electrostatic interactions with negatively charged nucleic acids. Covalent conjugation of F3, a tumor homing peptide, post-assembly of the nanoparticles enhanced cellular uptake and knockdown of nucleolin (a shuttling protein overexpressed at the sites of angiogenesis) and thus inhibiting tumor cell growth. Furthermore, these polymer precursors of the cSCKs were modified with partial to full incorporation of histamines to facilitate their endosomal escape for efficient delivery into the cytosol. The cSCKs were further templated onto high aspect ratio anionic cylinders to form hierarchically-assembled nanostructures that bring together individual components with unique functions, such as one carrying a therapeutic payload and the other with sites for radiolabeling. These higher order nanoobjects enhance circulation in vivo, have capabilities to package nucleic acids electrostatically and contain sites for radiolabeling, providing an overall advantage over the individual components, which could each facilitate only one or the other of the combined functions. Hierarchically-assembled nanostructures were investigated for their cellular uptake, transfection behavior and radiolabeling efficiency, as the next generation of theranostic agents.Item Poly(lactide)-containing Multifunctional Nanoparticles: Synthesis, Domain-selective Degradation and Therapeutic Applicability(2013-02-14) Samarajeewa, SandaniConstruction of nanoassemblies from degradable components is desired for packaging and controlled release of active therapeutics, and eventual biodegradability in vivo. In this study, shell crosslinked micelles composed of biodegradable poly(lactide) (PLA) core were prepared by the self-assembly of an amphiphilic diblock copolymer synthesized by a combination of ring opening polymerization (ROP) and reversible addition-fragmentation chain transfer (RAFT) polymerization. Enzymatic degradation of the PLA cores of the nanoparticles was achieved upon the addition of proteinase K (PK). Kinetic analyses and comparison of the properties of the nanomaterials as a function of degradation extent will be discussed. Building upon our findings from selective-excavation of the PLA core, enzyme- and redox-responsive nanoparticles were constructed for the encapsulation and stimuli-responsive release of an antitumor drug. This potent chemotherapeutic, otherwise poorly soluble in water was dispersed into aqueous solution by the supramolecular co-assembly with an amphiphilic block copolymer, and the release from within the core of these nanoparticles were gated by crosslinking the hydrophilic shell region with a reduction-responsive crosslinker. Enzyme- and reduction-triggered release behavior of the antitumor drug was demonstrated along with their remarkably high in vitro efficacy. As cationic nanoparticles are a promising class of transfection agents for nucleic acid delivery, in the next part of the study, synthetic methodologies were developed for the conversion of the negatively-charged shell of the enzymatically-degradable shell crosslinked micelles to positively-charged cationic nanoparticles for the complexation of nucleic acids. These degradable cationic nanoparticles were found to efficiently deliver and transfect plasmid DNA in vitro. The hydrolysis of the PLA core and crosslinkers of the nanocarriers may provide a mechanism for their programmed disassembly within endosomes, which would in-turn promote endosomal disruption by osmotic swelling, and release of active therapeutics from the polymeric assemblies. In the last part, a comparative degradation study was performed between the anionic and cationic micellar assemblies in the presence of two model enzymes, and electrostatic interaction-mediated preferential hydrolysis was demonstrated between the oppositely-charged enzyme-micelle pairs. These findings may be of potential significance toward the design of charge-mediated enzyme-responsive nanomaterials that are capable of undergoing environmentally-triggered therapeutic release, disassembly or morphological alterations under selective enzyme conditions.Item Progress toward a Colon Targeting Nanoparticle Based Drug Delivery System(2012-07-16) Yu, XiaoHydrophobic 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.Item Structure-function relationships in dendrimer-encapsulated metal nanoparticles(Texas A&M University, 2006-04-12) Wilson, Orla MaryThe synthesis, characterization and structure-function relationships of mono- and bimetallic dendrimerencapsulated nanoparticles (DENs) are described. Control over the factors influencing the structure of bimetallic DENs has been attained for PdAu and AuAg systems. The bimetallic DENs are characterized by UV-vis, HRTEM, and single-particle energy dispersive x-ray spectroscopy (EDS). In addition, we use catalysis and selective extraction to chemically probe the surface structure. The fabrication of TiO2-supported Pd, Au and PdAu nanocomposites from DEN precursors is shown to be a viable route for the synthesis of catalytically active, reasonably monodisperse heterogeneous catalysts. Using the dendrimer-templating synthesis, tight control over the size of 1- 2 nm Pd DEN catalysts has led to the observation of a particle-size effect for the hydrogenation of allyl alcohol. We have proposed that for particles with diameters between 1.5? 1.9 nm the reaction occurs preferentially on the exposed face atoms.Item Synthesis of Through-bond Energy Transfer Cassettes and Their Encapsulation in Silica and Calcium Phosphate Nanoparticles(2011-02-22) Jose, JineyWater-soluble fluorescent probes with emission in the 600-800 nm region have significant potential in biological applications such as cell imaging. Most fluorescent probes however suffer from limited fluorescence brightness in aqueous media due to aggregation and self-quenching. Their photostability in animal models for an extended period of time is also a concern. One way of improving their photophysical properties is to encapsulate them in a protective matrix to form fluorescent nanoparticles. We have synthesized a set of six through-bond energy transfer cassettes which emit in the 600-800 nm region with Fluorescein or BODIPY as donor and benzophenoxazine dye Nile Red or cyanine dye Cy5 as acceptor. Their photophysical properties in organic and aqueous media were evaluated. Some of these cassettes were encapsulated in silica or calcium phosphate nanoparticles (20 nm in diameter) to improve their solubility and photophysical properties in aqueous media. We also synthesized some water-soluble benzophenoxazine based fluorophores and the impact of different water-soluble groups on their emission characteristics in aqueous media was studied. Selected fluorophores were used for in vitro cellular imaging studies.Item TAILORING THE PLATEAU BURNING RATES OF COMPOSITE PROPELLANTS BY THE USE OF NANOSCALE ADDITIVES(2010-07-14) Stephens, MatthewComposite propellants are composed of a solid oxidizer that is mixed into a hydrocarbon binder that when polymerized results in a solid mass capable of selfsustained combustion after ignition. Plateau propellants exhibit burning rate curves that do not follow the typical linear relationship between burning rate and pressure when plotted on a log-log scale, and because of this deviation their burning behavior is classified as anomalous burning. It is not unusual for solid-particle additives to be added to propellants in order to enhance burning rate or other properties. However, the effect of nano-size solid additives in these propellants is not fully understood or agreed upon within the research community. The current project set out to explore what possible variables were creating this result and to explore new additives. This thesis contains a literature review chronicling the last half-century of research to better understand the mechanisms that govern anomalous burning and to shed light on current research into plateau and related propellants. In addition to the review, a series of experiments investigating the use of nanoscale TiO2-based additives in AP-HTPB composite propellants was performed. The baseline propellant consisted of either 70% or 80% monomodal AP (223 ?m) and 30% or 20% binder composed of IPDI-cured HTPB with Tepanol. Propellants? burning rates were tested using a strand bomb between 500 and 2500 psi (34.0-170.1 atm). Analysis of the burning rate data shows that the crystal phase and synthesis method of the TiO2 additive are influential to plateau tailoring and to the apparent effectiveness of the additive in altering the burning rate of the composite propellant. Some of the discrepancy in the literature regarding the effectiveness of TiO2 as a tailoring additive may be due to differences in how the additive was produced. Doping the TiO2 with small amounts of metallic elements (Al, Fe, or Gd) showed additional effects on the burning rate that depend on the doping material and the amount of the dopant.Item The use of Surface Enhanced Raman Spectroscopy (SERS) for biomedical applications(Texas A&M University, 2007-04-25) Chowdhury, Mustafa HabibRecent advances in nanotechnology and the biotechnology revolution have created an immense opportunity for the use of noble metal nanoparticles as Surface Enhanced Raman Spectroscopy (SERS) substrates for biological sensing and diagnostics. This is because SERS enhances the intensity of the Raman scattered signal from an analyte by orders of 106 or more. This dissertation deals with the different aspects involved in the application of SERS for biosensing. It discusses initial studies performed using traditional chemically reduced silver colloidal nanoparticles for the SERS detection of a myriad of proteins and nucleic acids. It examines ways to circumvent the inherent aggregation problems associated with colloidal nanoparticles that frequently lead to poor data reproducibility. The different methods examined to create robust SERS substrates include the creation of thermally evaporated silver island films on microscope glass slides, using the technique of Nanosphere Lithography (NSL) to create hexagonally close packed periodic particle arrays of silver nanoparticles on glass substrates as well as the use of optically tunable gold nanoshell films on glass substrates. The three different types of SERS surfaces are characterized using UV-Vis absorption spectroscopy, Electron Microscopy (EM), Atomic Force Microscopy (AFM) as well as SERS using the model Raman active molecule trans-1,2-bis(4-pyridyl)ethylene (BPE). Also discussed is ongoing work in the initial stages of the development of a SERS based biosensor using gold nanoshell films for the direct detection of b-amyloid, the causative agent for Alzheimer's disease. Lastly, the use of gold nanoshells as SERS substrates for the intracellular detection of various biomolecules within mouse fibroblast cells in cell culture is discussed. The dissertation puts into perspective how this study can represent the first steps in the development of a robust gold nanoshell based SERS biosensor that can improve the ability to monitor biological processes in real time, thus providing new avenues for designing systems for the early diagnosis of diseases.