Biocompatible noble metal nanoparticle substrates for bioanalytical and biophysical analysis of protein and lipids

Bruzas, Ian R.

07 June 2019

No description available.

Chemistry

noble metal nanoparticles

biosensing

plasmonics

surface enhanced Raman spectroscopy

supported lipid bilayer

biophysics

Investigating Interfaces between Heterogeneous Catalysts and Metal-Organic Frameworks for Catalytic Selectivity Control:

Lo, Wei-Shang

January 2022

Thesis advisor: Matthias M. Waegele / Depositing metal-organic frameworks (MOFs) on the surfaces of metal nanoparticles (NPs) to enhance catalytic selectivity has recently attracted great attention; however, a solid understanding of how the NP-MOF interface promotes catalytic selectivity is lacking. In this thesis, we have conducted three fundamental studies and further applied the knowledge to other types of catalysts using enzymes. The first part of this thesis focuses on understanding the NP-MOF interfacial structures and their impact on catalytic performance. We have systematically probed the NP-MOF interface generated by three commonly used approaches by IR and Raman spectroscopy. We have revealed significant differences in interfacial chemical interactions between them, and have found that these differences in interfacial structure dramatically impact selectivity. For example, the interface generated by the coating approach contains trapped capping agents. This trapped capping agent reduces crotyl alcohol selectivity for the hydrogenation of crotonaldehyde. The second part of this thesis focuses on addressing the trapped capping agents at the NP-MOF interface. We developed an approach to creating a direct NP-MOF interface by utilizing weakly adsorbed capping agents during the MOF coating process. Their dynamic nature allows for their gradual dissociation from the NP surface with the assistance of the organic MOF linkers. Thus, direct chemical interactions can be built between NP and MOF, generating a clean and well-defined interface. Direct evidence on capping agent dissociation and formation of chemical interactions was obtained by Raman and IR spectroscopy. Combined with transmission electron microscopy and X-ray diffraction, we have revealed the relative orientation and facet alignment at the NP-MOF interface. The third part of this thesis investigates how various MOF components affect the selectivity of hydrogenation reactions catalyzed at the MOF-NP interface. We found that the replacement of Zr-oxo nodes with Ce-oxo nodes yields the highest selectivity for cinnamyl alcohol (~87%), whereas the functionalization of the terephthalic acid linker with -OH, CH3, -NO2 and NH2 groups only moderately modulates the selectivity relative to the Zr-UiO-66 (~58%). Reaction kinetics studies demonstrate that coating Pt NPs with Ce-UiO-66 increases the rate of C=O hydrogenation, which infrared spectroscopic observations suggest is due to the interaction of the C=O group with the Ce-oxo node. This work highlights the critical role of metal-oxo nodes in regulating the catalytic selectivity of metal NPs in specific reactions. The fourth part of this thesis extends the interface control to other catalysts involving enzymes. We compared the interfacial interactions of catalase in solid and hollow MOF microcrystals. The solid sample with confined catalase was prepared through a reported method. The hollow sample was generated by hollowing the MOFs crystal, sealing freestanding enzymes in the central cavities of the hollow MOF. By monitoring this hollowing process, we observed that the enzymes gradually changed from a confined form to a freestanding form. The freestanding enzymes in the hollow MOFs show higher activity in the decomposition of hydrogen peroxide, attributed to their lesser chemical interactions and confinement. This study highlights the importance of the freestanding state for the biological function of encapsulated enzymes. Taken together, the four sections in this thesis establish design rules for refining MOF-based catalyst design. / Thesis (PhD) — Boston College, 2022. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.

coating materials

composite materials

metal nanoparticles

metal-organic framework

selective hydrogenation

vibrational spectrascopy

Electrocatalysis at Metal Nanoparticles

Kumar, Sachin

12 August 2008

No description available.

Chemistry

Materials Science

Fuel cells

metal nanoparticles

CO electrooxidation

oxygen electroreduction

nanoparticle arrays

cyclic voltammetry

Ultrafast Charge Carrier Dynamics in Au/Semiconductor Nanoheterostructures

Lambright, Scott

17 July 2014

No description available.

Physics

Nanoscience

Nanotechnology

Chemistry

nanoscience

nanotechnology

quantum dot

metal nanoparticles

transient absorption spectroscopy

FRET

Application of Mass Spectrometry to the Characterization of Core and Ligand Shell Modifications of Silver Molecular Nanoparticles

Atnagulov, Aydar

January 2017

No description available.

Chemistry

Analytical Chemistry

Materials Science

Physical Chemistry

noble metal nanoparticles

molecular nanoparticles

mass spectrometry

silver

Photochemical energy conversion in metal-semiconductor hybrid nanocrystals

Razgoniaeva, Natalia, Razgoniaeva

18 July 2016

No description available.

Chemistry

Quantum dots

solar cells

catalysis

interfaces

colloidal synthesis

metal nanoparticles

Connecting Thermodynamics and Kinetics of Ligand Controlled Colloidal Pd Nanoparticle Synthesis

Li, Wenhui

24 April 2019

Colloidal nanoparticles are widely used for industrial and scientific purposes in many fields, including catalysis, biosensing, drug delivery, and electrochemistry. It has been reported that most of the functional properties and performance of the nanoparticles are highly dependent on the particle size and morphology. Therefore, controlled synthesis of nanomaterials with desired size and structure is greatly beneficial to the application. This dissertation presents a systematic study on the effect of ligands on the colloidal Pd nanoparticle synthesis mechanism, kinetics, and final particle size. Specifically, the research is focused on investigating how the ligand bindings to different metal species, i.e., metal precursor and nanoparticle surface, affect the nucleation and growth pathways and rates and connecting the binding thermodynamics to the kinetics quantitatively. The first part of the work (Chapters 4 and 5) is establishing isothermal titration calorimetry (ITC) methodology for obtaining the thermodynamic values (Gibbs free energy, equilibrium constant, enthalpy and entropy) of the ligand-metal precursor binding reactions, and the simultaneous metal precursor trimer dissociation. In brief, the binding products and reactions were characterized by nuclear magnetic resonance (NMR), and an ITC model was developed to fit the unique ITC heat curve and extract the thermodynamic properties of the reactions above. Furthermore, in Chapter 6, the thermodynamic properties, especially the entropy trend changing with the ligand chain length was investigated on different metal precursors based on the established ITC methodology, showing that the entropic penalty plays a significant role in the binding equilibrium. The second part of the dissertation (Chapter 7 and 8) presents the kinetic and mechanistic study on size-tuning of the colloidal Pd nanoparticles only by changing different coordinating solvents as ligands together with the trioctylphosphine ligand. In-situ small angle X-ray scattering was applied to characterize the time evolutions of size, size distribution, and particle concentration using synthesis reactor connected to a capillary flow cell. From the real-time kinetic measurements, the nucleation and growth rates were calculated and correlated with the thermodynamics, i.e., Gibbs free energies of solvent-ligand-metal precursor reactivity and ligand-nanoparticle surface binding which were modified by the coordination of different solvents. Higher reactivity leads to faster nucleation and high nanoparticle concentration, and stronger solvent/ligand-particle coordination energy results in higher ligand capping density and slower growth. The interplay of both effects reduces the final particle size. Furthermore, because of the significance of the ligand-metal interactions, the synthesis temperature and ligand to metal precursor ratio were systematically to modify the relative binding between the ligand and precursor, and the ligand and nanoparticle, and determine the effect on the nucleation and growth rates. The results show that the relative rates of nucleation and growth is critical to the final size. A methodology for using the in-situ measurements to predict the final size by developing a kinetic model based is discussed. / Doctor of Philosophy / Metal nanoparticles dispersed in solution phase, i.e., colloidal nanoparticles, are of great scientific interests due to their unique properties different from bulk metal materials. The size, shape and other morphology features can largely affect the nanomaterial properties and functional performances. Therefore, a successful synthesis of nanoparticles with desired structures is highly beneficial to the development of their application. Ligands, which are long-chain molecules that can cap on the surface of the nanoparticles, have been known as stabilizers of the nanoparticles in the solution phase. Whereas in recent studies, it has been found that changing the ligand type and concentration in the synthesis can result in different sizes and shapes of nanomaterials, which indicates that the ligands are playing critical roles in the synthesis mechanisms to control the kinetics. To have a better understanding on the control effects of the ligands, systematic studies were conducted on the ligand interactions (bindings) between the ligand-metal compound (as the metal source and initial agent in the nanomaterial synthesis) and ligand-nanoparticle surface, of which both can be quantified by thermodynamics. Using isothermal titration calorimetry, the ligand-metal precursor binding strength was measured and found to be dependent on ligand chain length and the metal precursors, which further affects the reactivity of the metal precursor based on the results of density functional theory calculations. On the other hand, the ligand-nanoparticle surface binding strength was found to affect the capping density of the ligands on the nanoparticle surface. In order to connect the thermodynamics to the kinetics, namely the nucleation (formation of new particles) and growth (particle size increase) rates, small angle X-ray scattering (SAXS) characterization was performed in real time during the synthesis on the nanoparticles. This technique allows the capture of the size, size distribution and concentration of nanoparticles changing with time, and the nucleation and growth rates were further calculated from the SAXS data. By changing solvents with the same functions of ligands but of different coordinating abilities, a correlation between the kinetics and thermodynamics was observed. The nucleation rate increases with the metal precursor reactivity, which corresponds to stronger solvent binding to the precursor. On the other hand, the stronger ligand-nanoparticle binding slows down the growth by lowering the surface capping density. To go deeper into the ligand-metal binding and kinetics correlation, the binding properties were tuned by changing other synthesis conditions, i.e., different temperatures and ligand to metal ratios (ligand concentration), and a qualitative discussion was given on the effects of these conditions on the synthesis kinetics and final particle size.

Colloidal metal nanoparticles

Pd nanoparticles

nanoparticle synthesis

ligand

thermodynamics

nucleation and growth kinetics

Calixarenes and Nanoparticles : Synthesis, Properties and Applications / Calixarènes et nanoparticules : synthèse, propriétés et applications

Ray, Priyanka

16 July 2013

Le travail présenté dans ce manuscrit inclut la synthèse organique des différents types de calixarènes, l'étude de leurs propriétés optiques, des simulations théoriques pour déterminer leurs conformations favorables et leurs utilisations pour stabiliser des nanoparticules. Des nanoparticules d’argent, d’or, de platine et des nanoparticules bimétalliques (Ag-Au) ont été synthétisées en utilisant par réduction radiolytique ainsi que la synthèse la photochimique. Ces nanoparticules sont stabilisées en utilisant des calixarènes et divers polymères. Les nanomatériaux ont été caractérisés par spectroscopie d’absorption UV-Visible et spectroscopie de fluorescence et par des observations en microscopie électronique en transmission. Comme les nanoparticules métalliques sont connues pour leurs applications dans divers domaines, des propriétés antibactériennes de nanoparticules d'argent et des propriétés électrocatalytiques des nanoparticules d'or ont été testées. / The work presented in this manuscript includes the organic synthesis of different types of calixarenes, the study of their optical properties, computational studies for determination of their favourable conformations and their use in the stabilisation of nanoparticles. Silver, gold, platinum and bimetallic (Ag-Au) nanoparticles were synthesised using radiolytic reduction as well as photochemical method. These nanoparticles were stabilised by calixarenes and also other ligands which included several polymers. The nanomaterials were characterised using UV-Visible absorption and fluorescence spectroscopy and transmission electron microscopy (TEM) measurements. As metal nanoparticles are known for their applications in various fields, the antibacterial properties of silver nanoparticles and the electrocatalytic properties of gold nanoparticles were tested.

Nanoparticules métalliques

Calixarènes

Fluorescence

Études computationnelles

Propriétés anti-bactériennes

Metal nanoparticles

Calixarenes

Fluorescence

Computational studies

Anti-bacterial properties

Estudo da ação in vitro de nanopartícula de prata / Study of in vitro action of silver nanoparticle

Cavassin, Emerson Danguy

12 September 2013

O presente estudo avaliou a ação in vitro de diferentes nanopartículas de prata (nanoAg) sintetizadas pelo Instituto de Pesquisas Tecnológicas (IPT) e Universidade Federal de São Carlos (IFSC) e controles de sulfadiazina de prata, nitrato de prata e nanoAg comercial Sigma, frente a bactérias e leveduras. Os objetivos do estudo foram avaliar a ação in vitro de NanoAg sintetizadas no Brasil frente a bactérias sensíveis aos antimicrobianos e multirresistentes (MR), incluindo Gram positivos e negativos, além de candidas isoladas de amostras clínicas. Definir as condições de síntese que resultem em nanoAg com melhor efeito antimicrobiano in vitro frente a isolados sensíveis e MR. Foram utilizadas diferentes metodologias tais como agar well diffusion, determinação de concentração inibitória mínima CIM, concentração bactericida mínima (CBM), curva do tempo de morte e inibição da formação de biofilme. Ao todo, foram avaliados 110 isolados, sendo 37 sensíveis aos antimicrobianos, 54 MR, e 19 candidas frente a 29 nanoAg com diferentes características de síntese. Os testes de difusão em meio sólido apresentaram heterogeneidade de resultados frente aos micro-organismos avaliados. Enquanto as informações de CIM50 e CIM90 evidenciaram não existir variações no efeito inibitório frente isolados sensíveis ou resistentes aos antimicrobianos. As curvas do tempo de morte ilustraram a dinâmica de inibição dos compostos de prata e a interferência do sangue nos testes in vitro. A partir dos testes com biofilme foi possível observar efeito inibitório e de descolamento de biofilme previamente formado. Os resultados permitiram concluir a maior eficácia para nanoAg com Citrato e Quitosana, seguido por nitrato de prata, sulfadiazina de prata e PVA. A NanoAg comercial (Sigma, 60 nm) apresentou resultados inferiores ao de nanoAg Citrato, nanoAg Quitosana e nitrato de prata. Estes resultados abrem caminho para novas análises de nanoAg sintetizadas no Brasil em busca de produtos com maior eficácia com ação contra bactérias MR e candidas / The present study evaluated the in vitro action of different silver nanoparticles (nanoAg) synthesized by \"Instituto de Pesquisas Tecnológicas\" (IPT) and \"Universidade Federal de São Carlos\" (IFSC) and silver sulfadiazine, silver nitrate and commercial nanoAg Sigma against bacteria and yeasts. The objectives of the study were to evaluate the in vitro action of NanoAg synthesized in Brazil against antimicrobial susceptible bacteria and multidrug-resistant (MDR), including Gram positive and negative, as well as some candida isolates from clinical source. Define the conditions that result in nanoAg synthesis with best in vitro antimicrobial effect against sensitive isolates and MDR. Different methodologies were used such as agar well diffusion, determination of minimum inhibitory concentration (MIC), minimum bactericidal concentration (CBM), the time-kill curve and inhibition of biofilm formation. Altogether 110 isolates were evaluated, being 37 antimicrobial sensitive, 54 MDR, and 19 candidas, against 29 nanoAg with different synthesis. The solid medium diffusion tests showed heterogeneity of results against the evaluated microorganisms. While the information of MIC50 and MIC90 showed no changes in inhibitory effect against sensitive isolates or MDR. The time-kill curve illustrated the dynamics of inhibition of silver compounds and the interference of blood on the in vitro tests. From the tests with biofilm was possible to observe biofilm inhibitory effect and detachment of biofilm previously formed. The conclusion defined to greater effectiveness for nanoAg with Chitosan and Citrate, followed by silver nitrate, silver sulfadiazine and PVA. The commercial NanoAg (Sigma, 60 nm) presented lower performance than nanoAg citrate, nanoAg Chitosan and silver nitrate. These results open the way for new analyses of Brazil synthetized nanoAg with better efficiency against MDR bacterial and candida

Compostos de prata

Metal nanoparticles

Microbial sensitivity tests

Nanoparticles/microbiology

Nanopartículas metálicas

Nanopartículas/microbiologia

Silver compounds

Testes de sensibilidade microbiana

Detecção dos interferentes endócrinos estradiol e estriol em amostras ambientais e clínicas empregando eletrodos modificados com grafeno, nanopartículas metálicas e quantum dots / Detection of endocrine disruptors stradiol and estriol in environmental and clinical samples using modified electrodes with graphene, metal nanoparticles and quantum dots

Cincotto, Fernando Henrique

10 November 2016

Para o desenvolvimento dos sensores aqui descritos foram utilizados materiais inovadores considerando relatos atuais da literatura, materiais estes: óxido de grafeno, óxido de grafeno reduzido, nanocompósitos de grafeno e nanopartículas (ródio, antimônio e sílica mesoporosa desordenada), materiais híbridos a base de grafeno e quantum dots de CdTe, além de biossensores incorporando a enzima lacase. Estes materiais foram sintetizados utilizando metodologias específicas e caracterizados por diversas técnicas analíticas como microscopia eletrônica de transmissão de alta resolução, microscopia de força atômica, espectroscopia Raman, difração de raios-X, espectroscopias de UV-Vis e fotoluminescência, e técnicas eletroquímicas. Posteriormente, os materiais foram utilizados para modificação em eletrodos de carbono vítreo e utilizados na determinação de interferentes endócrinos (os hormônios estriol e 17β-estradiol) como sensores eletroquímicos em amostras ambientais e clínicas. Em essência, os eletrodos desenvolvidos apresentaram importantes vantagens, tais como alta sensibilidade, boa reprodutibilidade, simples instrumentação, fácil preparação e procedimentos analíticos rápidos, apresentando baixos limites de detecção, na ordem de picomolar e nanomolar, com baixa taxa de interferência de outras espécies na mesma matriz da amostra. Concluindo assim que as técnicas eletroquímicas podem ser facilmente aplicadas na determinação de interferentes endócrinos em amostras reais. / For the development of the sensors described here innovators materials were used considering current literature reports, these materials: Graphene oxide, reduced graphene oxide, nanocomposites graphene and nanoparticles (rhodium and antimony), hybrid materials of graphene and CdTe quantum dots, and biosensors incorporating the laccase enzyme. These materials were synthesized using specific methodologies and characterized by several analytical techniques such as transmission electron microscopy, high resolution transmission electron microscopy, atomic force microscopy, Raman spectroscopy, X-ray diffraction, UV-Vis and photoluminescence spectroscopy and electrochemical techniques. Subsequently, the materials were used for modification of glassy carbon electrodes to the determination of endocrine disruptors (estriol and 17β-estradiol hormone) as electrochemical sensors for environmental and clinical samples. In essence, developed electrodes showed important advantages such as high sensitivity, good reproducibility, simple instrumentation, easy preparation and quick analytical procedures, with low detection limits in the range of picomolar and nanomolar, low interference rate of other species in same matrix sample. Finally, electrochemical techniques can be easily applied in the determination of endocrine disruptors in real samples.

electrochemical sensor

endocrine disruptors

grafeno

graphene

interferentes endócrinos

metal nanoparticles

nanopartículas metálicas

quantum dots

quantum dots

sensor eletroquímico