Global ETD Search

21	EXPANDING APPLICATIONS OF IRON OXIDE NANOPARTICLES BY SURFACE FUCNTIONALIZATION: FROM MAGNETIC RESONANCE IMAGING TO NANO-CATALYSIS Duanmu, Chuansong 01 December 2009 (has links) In this dissertation, research efforts mainly focused on exploring the applications of superparamagnetic iron oxide nanoparticles (SPIONs) in MR imaging and nanocatalysis via surface functionalization. A dopamine-based surface-functionalization strategy was established. The Simanek dendrons (G1 to G3), oligonucleotides and amino acids were loaded onto SPION surfaces via this approach to develop pH-sensitive MRI contrast agents, specific-DNA MR probes and a biomimetic hydrolysis catalyst. Dendron-SPION conjugates (G1 to G3) have good aqueous solubilities and high transverse relaxivities (>300 s-1mM-1). They also showed interesting strong pH-sensitive R2 and R2 relaxivities, which were governed by the clustering states of dendron-SPIONs in different pH environments. Values of R2m and R2* m/R2m varied by over an order of magnitude around pH 5. The efficient cell-uptake (~3 million/cell) and low cytotoxicity of G1 to G3-SPIONs were demonstrated on HeLa cell cultures. The strong R2* effects were observed indicating the SPION clustering in HeLa cells. Two SPION-oligonuleotide conjugates were synthesized by coupling two half-match oligonucleotides onto domapine-capped SPIONs via SPDP linkers. They served as MR probes to detect a single-strand DNA with the same sequence to miRNA-21 based on the change of R2 values due to the DNA-bridged SPION clustering. The detection limit of the DNA could reach to 16.5 nM. A biomimetic hydrolysis nanocatalyst (i.e., Fe2O3-Asp-His complex) was developed by loading Asp and His-dopamine derivatives onto SPIONs. Paraoxon and nitrophenyl acetate were hydrolyzed under a mild condition (neutral pH, 37 °C) catalyzed by the Fe2O3-Asp-His complex. The two amino acids Asp and His cooperated with each other on the SPION surfaces to catalyze hydrolysis reactions. This catalyst could be recycled by a magnet and reused for four times without a significant loss of catalytic activity. Dendron Iron Oxide Nanoparticles MRI Contrast Agent Nanocatalysis Surface Functionalization
22	Nanopartículas antiferromagnéticas de MnO para aplicações em biomedicina como agentes de contraste / Antiffeomagnetic MNo nanoparticles for applications in biomedicine as a contrast agent Herbert Rodrigo Neves 24 February 2012 (has links) Nanomateriais têm sido amplamente estudados, como resultado de suas propriedades físicas e químicas diferenciadas, que oferecem um grande número de possibilidades para aplicações em biomedicina, principalmente na terapia de câncer e no desenvolvimento de estratégias de diagnóstico não invasivo. O óxido de ferro superparamagnético (SPION) é o principal material estudado como agente de contraste para imagem por ressonância magnética, devido à sua capacidade de reduzir o tempo de relaxação transversal (T2) em diferentes tecidos e sua menor toxicidade que os complexos de Gd3+ e Mn2+ usados atualmente. Entretanto, o acumulo de SPIONs pode ser facilmente confundido com sinais referentes à calcificação, depósito de metais pesados e sangramentos, e a alta susceptibilidade magnética do material promove distorções na imagem. Assim, alguns aspectos são desejáveis em material para que este tenha potencial para substituir o SPION, tais como forma nanoparticulada, para fácil modificação de superfície e possibilidade de funcionalização com agentes biosseletivos, e contraste positivo em T1. As nanopartículas (NPs) antiferromagnéticas de MnO atendem a todos os requisitos necessários para substituir o óxido de ferro. As NPs de MnO foram sintetizadas a partir da decomposição térmica do acetilacetonato de manganês(II) em uma variação do método poliol modificado, resultando na formação de NPs com tamanho médio de 21 ± 3,9 nm. Foi realizada a substituição de ligantes de superfície para que se substituísse o ácido oleico adsorvido sobre o material por 3-aminopropiltrimetoxisilano (APTMS) e foi determinada a concentração de grupamentos amino sobre a superfície das NPs. Posteriormente, obteve-se uma estrutura do tipo \"core/shell\" dispersível em meio aquoso e biocompatível pela reação dos grupos amino livres com o carboxilato da carboximetil dextrana (CMDex). O potencial de superfície e a estabilidade coloidal das NPs funcionalizadas foram caracterizados por mobilidade eletroforética e por espalhamento de luz dinâmico em água deionizada e em condições que mimetizavam o sangue. As NPs apresentaram toxicidade em células cancerosas de carcinoma cervical humano (HeLa). Entretanto, não foi observada toxicidade significativa na linhagem de células não cancerosas NCTC clone L929. Tanto as NPs como sintetizadas quanto as recobertas com CMDex apresentaram controle de tamanho e forma, apresentando distribuição de tamanho compatível com o esperado para as aplicações em biomedicina. / Nanomaterials have been widely studied as a result of their interesting physical and chemical properties, which offer a large number of possibilities for applications in biomedicine mainly in cancer therapy and the development of strategies for non-invasive diagnosis. The superparamagnetic iron oxide nanoparticles (SPION) is the main studied material as contrast agent for magnetic resonance imaging (MRI) due to its ability to reduce the transverse relaxation time (T2) in different tissues and lower toxicity than Gd3+ and Mn2+ complexes currently used. However, this SPIONs accumulation can be confused with signals from calcification, bleeding or metal deposits, and the high magnetic susceptibility distorts the background image because its ferromagnetic behavior. Some aspects are desirable to replace SPIONs, such as nanoparticulate form for simple surface modification and labeling with targeting agents, and positive longitudinal T1 relaxation time contrast ability. The antiferromagnetic MnO NPs attend all these requirements and overcome the drawback of using SPION. In our study, MnO NPs were synthesized by the thermal decomposition of Mn(II) acetylacetonate by a variation of the modified polyol process resulting in spherical nanoparticles with average size of 21 ± 3,9 nm. The ligand-exchange step was used to replace the oleic acid adsorbed on the as-synthesized NPs surface by 3-aminopropyltriethoxysilane (APTMS) and the total free amine groups on the NPs surface was determined. After that, a biocompatible and water-dispersible core/shell structure was obtained by coating with carboxymethyl dextran (CMDex) using the free amine-terminal group from APTMS and the carboxylate groups present in the CMDex molecules conjungation. Surface potential and colloidal stability of these functionalized NPs were evaluated by electrophoretic mobility and dynamic light scattering techniques in both water and artificial blood by using the Simulated Body Fluid (SBF) medium. While the water-dispersible NPs have shown toxicity in the human cell line derived from cervical cancer (HeLa), they have not shown significantly cytotoxicity in the healthy fibroblast cells (cell line L929). Both the as-synthesized and coated NPs present controlled size and shape and the final NPs size distribution and magnetic properties are compatible with the expected for biomedical applications. agente de contraste antiferromagnetismo MnO antiferromagnetism contrast agent MnO
23	Detection of Enzyme Activity in a Pancreatic Tumor Model Using CatalyCEST Contrast MRI Goldsher, Anetta Victoria, Goldsher, Anetta Victoria January 2017 (has links) Detection of enzyme activity has gained popularity in molecular imaging because increased activity of enzymes such as urokinase plasminogen activator (uPA) can serve as biomarkers and assist in cancer diagnosis. Chemical exchange saturation transfer (CEST) Magnetic Resonance Imaging (MRI) is a non-invasive technique that can be utilized to detect enzyme activity; however, CEST MRI is not the only technique that can assess enzyme activity. Chapter 1 provides an overview of various imaging modalities that have been used to detect enzyme activity in vivo. Advances made in probe-design are discussed, in addition to advantages and disadvantages of each technique. Chapter 2 focuses on detection of uPA activity in a pancreatic cancer tumor model using a catalyCEST MRI contrast agent. Chapter 2 also discusses the importance of uPA in tumor biology, addresses the synthesis of the contrast agent, and evaluates the results of in vivo detection and ex vivo validation of uPA activity in response to therapy of pancreatic tumor models of Capan-2. The in vivo and ex vivo results showed no significant difference in uPA activity between chemotherapy-treated and non-treated mice. Additionally, no significant difference was observed between before and after chemotherapy-treated groups. Chapter 3 addresses some of the limitations of the study detailed in Chapter 2 and proposes improvements. CEST contrast agent molecular imaging MRI pancretic cancer uPA
24	Nouveaux complexes de lanthanides pour le développement d'agents de contraste bimodaux IRM/luminescence / New lanthanides complexes for the development of bimodal MRI/NIR luminescence contrast agents Tallec, Gaylord 06 October 2011 (has links) L'imagerie par résonance magnétique est une des méthodes de diagnostic les plus utilisées, aussi bien dans le domaine médical que dans les études précliniques. Cependant, la relaxivité des agents de contraste commerciaux ne représente qu'une fraction de la relaxivité prédite par la théorie et il est nécessaire d'optimiser les différents paramètres dont elle dépend pour atteindre des valeurs de relaxivité plus élevées : nombre de molécules d'eau en première sphère de coordination, vitesse d'échange de l'eau, dynamique de rotation du complexe, relaxation électronique, distance Gd(III)-proton. Dans ce travail, nous présentons la synthèse, la stabilité et la relaxivité des complexes de Gd(III) de deux séries de ligands tripodes dérivés de la 8-hydroxyquinoléine, basés l'une sur une plateforme 1,4,7 triazacyclononane, l'autre sur un pivot azote central. Ces complexes ont montré des stabilités comparables à celles des agents commerciaux, des valeurs de relaxivités élevées dans l'eau ainsi qu'en milieu biologique. L'utilisation de la 8-hydroxyquinoléine comme base des ligands a permis de sensibiliser le Nd(III) et l'Yb(III) pour la luminescence proche infrarouge, ouvrant la possibilité pour le développement de nouveaux systèmes bimodaux. / Magnetic resonance imaging is a commonly used diagnostic method in medicinal practice as well as in biological and preclinical research. However, the relaxivity of commercial contrast agents is only a few percent of the theoretically predicted relaxivity. An optimisation of the different parameters who have an impact on the relaxivity (number of gadolinium bound water molecules, water exchange rate, rotation dynamic of the complex, electronic relaxation, Gd(III)-proton distance) is needed to obtain higher relaxivities. In this work, we present the synthesis, the stability and the relaxivity of the Gd(III) complexes of two series of 8-hydroxyquinolinate-based ligands, one using a 1,4,7 triazacyclononane platform, the other one using a central nitrogen architecture. Theses complexes show stabilities comparable to commercial agents, and high relaxivities in both water and serum. The 8-hydroxyquinolinate moiety allows these ligands to sensitize Nd(III) and Yb(III) for Near Infra Red (NIR) luminescence, leading to a new class of potential bimodal systems. Gadolinium Agent de contrast IRM Luminescence Gadolinium Contrast agent MRI Luminescence
25	Tailoring Crystalline Phase and Surface of Lanthanide-Based Nanoparticles for MRI Applications Liu, Nan 22 November 2019 (has links) Lanthanide-based nanoparticles (Ln3+-based NPs) are promising candidates as magnetic resonance imaging (MRI) contrast agents. The present thesis aims to investigate the effect of the crystalline phase of Ln3+-based NPs on their MRI contrast performance. Understanding the phase-dependent MRI contrast behaviour of Ln3+-based NPs will provide insights into the development of brighter MRI contrast agents for future in vivo biomedical applications. A set of NaGdF4 NPs (6-8 nm) in cubic and hexagonal phases in the same size range was synthesized by employing a microwave-assisted approach, allowing the influence of host crystallinity on MRI T1 relaxivity to be investigated (chapter 4). The results showed that cubic NaGdF4 NPs exhibited superior performance as MRI T1 contrast agents than their hexagonal analogues, irrespective of the chosen surface modification, e.g. small citrate groups or longer chain poly(acrylic acid). NaDyF4 NPs (3 nm) were synthesized in both phases to assess whether phase-dependent MRI contrast behaviour consistently exists in other Ln3+-base NPs of the NaLnF4 family (chapter 5). Again, it was demonstrated that cubic NaDyF4 NPs had a better contrast performance as T2 contrast agents than the hexagonal NPs. Alternatively, cubic NaEuF4 NPs, exhibiting additional optical properties (e.g. red emission under UV excitation), were prepared as potential candidates for the preparation of chemical exchange saturation transfer (CEST) contrast agents (chapter 5). Chapter 6 introduces preliminary dispersion stability studies of cubic NaGdF4 NPs dispersed in different buffer solutions, the obtained hydrodynamic diameters indicated that NaGdF4 NPs possessed better dispersity in saline than that in PBS solution. Lanthanide-based nanoparticles Magnetic resonance imaging Contrast agent Host crystallinity
26	Material Characterization Using Nuclear Magnetic Resonance Pope, Giovanna Marcella 23 February 2022 (has links) Nuclear magnetic resonance techniques can provide highly accurate information about the local environment of both liquid and solid samples. In the first half of this dissertation research, solid state NMR has provided experimental evidence for turbostratic disorder in layered covalent organic solids. Additionally, comparison with candidate structures allowed a proposed correction to the accepted structure of Covalent Organic Framework-5. The second half of the dissertation work emphasized liquid NMR spectroscopy applied to doped iron oxides (IOs). In particular, the effect of IOs on water proton T2 relaxation times were determined as a measure of contrast agent efficacy. Both types of data lend towards structure elucidation for material efficiency. COF space group contrast agent relaxation Physical Sciences and Mathematics
27	Synthesis and Functional Evaluation of Novel Chiral Dendrimer-triamine-coordinated Gd-MRI Contrast Agents That Can Act as Molecular Probes / 分子プローブ型新規キラルデンドリマートリアミン配位Gd-MRI造影剤の合成と機能評価 Miyake, Yuka 23 March 2016 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第19738号 / 工博第4193号 / 新制\|\|工\|\|1647(附属図書館) / 32774 / 京都大学大学院工学研究科物質エネルギー化学専攻 / (主査)教授近藤輝幸, 教授辻康之, 教授大江浩一 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DGAM MRI contrast agent Gadolinium Dendrimer Molecular imaging Drug design 500
28	Non-destructive Evaluation of Ultrasound Contrast Agent / Icke-destruktiv utvärdering av ultraljudskontrastmedel Löffler, Wendi January 2019 (has links) Clinical ultrasound imaging techniques can be greatly improved by the use of ultrasound contrast agents (UCAs). While microbubbles (MBs) without shell are unstable and cannot be used for practical applications,a shell produced from biocompatible polyvinylalcohol (PVA) significantly improves chemical versatility and stability. The oscillation characteristics of a UCA are strongly dependent on concentration, applied pressure and viscoelastic parameters of the shell. Modifications in the shell as incorporation of antibodies or targeted molecules affect the bubble oscillation and resonance frequency of the MB suspension. In this presented work a tool for systematic characterization of UCAs is developed. Linear acoustic behaviour of PVA shelled MBs is examined. The acoustic driving pressure is kept below 100 kPa. The MB concentration is 1·10^{6} ml^{-1}. Attenuation and phase velocity profiles of ultrasound waves propagating through the UCA are measured using six narrow-band single crystal transducers that cover a frequency range between 1 and 15 MHz. The oscillation of a single bubble is modeled as a linear oscillator adapting HOFF’s model suitable for allshell thicknesses. The suspension is modeled through superposition of single bubbles. Knowing all parameters the resonance frequency of a MB suspension can be predicted. The model is fitted to experimental data to determine the viscoelastic shell parameters. The shell thickness is challenging to determine exactly and assumed to be either proportional to the outer shell radius or constant. Assuming a proportional shell thickness the calculated resulting shell parameters were shear modulus G_s = 14.5 MPa, shear viscosity η_s = 0.322 Pa·s and shell thickness d_s = 16 % of the outer radius. When instead assuming a constant shell thickness the determined parameters were in similar order of magnitude. Resonance frequency of the suspension was determined to 11.6 MHz. The developed tool can be used to characterize MBs with a modified shell independently of shell thickness and to predict resonance frequency of gas or air filled UCAs with known shell parameters. ultrasound microbubbles contrast agent attenuation phase velocity Medical Engineering Medicinteknik
29	DEVELOPMENT OF PARACEST MRI TO DETECT CANCER BIOMARKERS Liu, Guanshu 10 January 2008 (has links) No description available. Engineering, Biomedical MRI molecular imaging contrast agent PARACEST cancer biomarker
30	Ultraharmonic and Broadband Cavitation Thresholds for Ultrasound Contrast Agents in an In-Vitro Flow Model Gruber, Matthew J. 22 June 2015 (has links) No description available. Biomedical Research Ultrasound Therapeutic Cavitation Ultraharmonic Thrombolysis Contrast Agent

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