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11	Interactions of Engineered Silica Nanoparticles with Cell Membrane Models Asghari Adib, Ali 14 September 2017 (has links) No description available. Biomedical Engineering Chemical Engineering Silica nanoparticles Lipid monolayer Vesicle
12	Neurotransmitters recognition based on gold nanoparticles and mesoporous silica nanoparticles for sensing and controlled release applications Godoy Reyes, Tania Mariel 10 December 2020 (has links) [ES] La presente tesis doctoral titulada "Reconocimiento de neurotransmisores basado en nanopartículas de oro y de sílice mesoporosa para aplicaciones de detección y liberación controlada" es una tesis realizada por compendio de artículos la cual se centra en el diseño, preparación, caracterización y evaluación de distintos nanodispositivos para la detección colorimétrica de neurotransmisores y sistemas de liberación controlada que responden a neurotransmisores basados en nanopartículas de oro y nanopartículas de sílice mesoporosa, equipadas con ligandos orgánicos, efectores enzimáticos, puertas moleculares y especies cromofluorogénicas o medicamentos. En el primer capítulo se introduce una visión general de lo que son los neurotransmisores, sus principales características y el importante papel que éstos desempeñan en el funcionamiento de nuestro organismo. Además, se presenta una descripción general de las propiedades y potenciales aplicaciones de las nanopartículas de oro funcionalizadas con ligandos orgánicos como sistemas de detección y las nanopartículas mesoporosas de sílice funcionalizadas con puertas moleculares como sistemas de liberación controlada. A continuación, en el segundo capítulo se presentan los objetivos generales que son abordados en los siguientes capítulos experimentales. En el tercer capítulo, se presentan tres sistemas de detección colorimétrica de neurotransmisores basados en la agregación de nanopartículas de oro doblemente funcionalizadas con ligandos orgánicos. El primer sistema es un sensor capaz de detectar de forma selectiva el neurotransmisor serotonina, utilizando nanopartículas de oro funcionalizadas con ditio-bis(propionato de succinimidilo) y N-Acetil-L-Cisteína. El segundo sistema consiste en un sensor para la detección selectiva del neurotransmisor norepinefrina diseñado a partir de nanopartículas de oro funcionalizadas con 4-(liponiloxi)benzaldehído y ácido 4-mercato fenilborónico. El tercer sistema está compuesto por nanopartículas de oro funcionalizadas con 4-(liponiloxi)benzaldehído y N-Acetil-L-Cisteína, para la detección de normetanefrina, un importante biomarcador del tumor feocromocitoma. Todos estos sistemas se evalúan en medios competitivos como suero sanguíneo u orina. En el cuarto capítulo se muestran dos sistemas de liberación controlados enzimáticamente basados en la apertura de puertas moleculares. El primer sistema de liberación controlada responde a la presencia del neurotransmisor acetilcolina. En concreto, se utilizan nanopartículas de sílice mesoporosa funcionalizadas en su superficie con grupos de ácido fenilborónico y tapadas con la enzima acetilcolinesterasa mediante la formación de ésteres cíclicos de ácido fenilborónico entre las cadenas de oligosacáridos de la enzima y los grupos fenilborónicos de la superficie de las nanopartículas. En este caso la reacción enzimática produce ácido acético que da lugar a la hidrolisis de los ésteres borónicos, destapando los poros y liberando la carga contenida en el interior. Además, se evalúa la capacidad del dispositivo diseñado para liberar el citotóxico doxorubicina en células cancerosas en presencia de acetiltiocolina. El segundo sistema consiste en un nanodispositivo para la liberación controlada en respuesta al neurotransmisor L-glutamato. Para esto se utilizan nanopartículas tipo Janus de oro-sílice mesoporosa funcionalizadas con la enzima L-glutamato oxidasa en la parte del oro y con una puerta molecular autoinmolante de arilboronato en la superficie de la sílice. La liberación controlada se basa en el reconocimiento del L-glutamato por la enzima L-glutamato oxidasa y la posterior formación de peróxido de hidrogeno, que es la especie que induce la escisión de la puerta autoinmolante y la subsecuente apertura de los poros. Finalment es mostra que el sistema dissenyat és capaç d'alliberar un fàrmac citotòxic en cèl·lules de càncer de cervell després de detectar la presència de L-glutamat. / [CA] La present tesi doctoral titulada "Reconeixement de neurotransmissors basat en nanopartícules d'or i de sílice mesoporosa per a aplicacions de detecció i alliberació controlada" és una tesi realitzada per compendi d'articles la qual se centra en el disseny, preparació, caracterització i avaluació de diferents nanodispositius per a la detecció colorimètrica de neurotransmissors i sistemes d'alliberació controlada que responen a neurotransmissors basats en nanopartícules d'or i nanopartícules de sílice mesoporosa equipades amb lligands orgànics, efectors enzimàtics, portes moleculars i espècies cromofluorogénicos o medicaments. En el primer capítol s'introdueix una visió general del que són els neurotransmissors, les seves principals característiques i l'important paper que aquests tenen en el funcionament del nostre organisme. A més es presenta una descripció general de les propietats i potencials aplicacions de les nanopartícules d'or funcionalitzades amb lligands orgànics com a sistemes de detecció, i de les nanopartícules mesoporoses de sílice funcionalitzades amb portes moleculars com a sistemes d'alliberament controlat. A continuació, en el segon capítol es presenten els objectius generals que són abordats en els següents capítols experimentals. En el tercer capítol, es presenten tres sistemes de detecció colorimètrica de neurotransmissors basats en l'agregació de nanopartícules d'or doblement funcionalitzades amb lligands orgànics. El primer sistema és un sensor capaç de detectar de forma selectiva el neurotransmissor serotonina, utilitzant nanopartícules d'or funcionalitzades amb ditiobis (propionat de succinimidilo) i N acetil-L-cisteïna. El segon sistema consisteix en un sensor per a la detecció selectiva de neurotransmissor norepinefrina dissenyat a partir de nanopartícules d'or funcionalitzades amb 4- (liponiloxi) benzaldehid i Àcid 4-mercatofenilborònic. El tercer sistema està compost per nanopartícules d'or funcionalitzades amb 4- (liponiloxi) benzaldehid i N acetil-L-cisteïna, per a la detecció de normatanefrina un important biomarcador del tumor feocromocitoma. Tots aquests sistemes s'avaluen en mitjans competitius com sèrum sanguini u orina. En el quart capítol es mostren dos sistemes d'alliberament controlats enzimàticament basats en l'obertura de portes moleculars. El primer sistema d'alliberament controlat respon a la presència del neurotransmissor acetilcolina. En concret, s'utilitzen nanopartícules de sílice mesoporosa funcionalitzades en la seva superfície amb grups d'àcid fenilborònic i tapades amb l'enzim acetilcolina esterasa mitjançant la formació d'èsters cíclics d'àcid fenilborònic entre les cadenes d'oligosacàrids de l'enzim i els grups fenilborónicos de la superfície de les nanopartícules. En aquest cas, la reacció enzimàtica produeix àcid acètic que dóna lloc a la hidròlisi dels èsters borònics, destapant els porus i alliberant la càrrega continguda a l'interior. A més, s'avalua la capacitat del dispositiu dissenyat per alliberar el citotòxic doxorubicina en cèl·lules canceroses en presència d'acetiltiocolina. El segon sistema consisteix en un nanodispositiu per alliberació controlada en resposta al neurotransmissor L-glutamat, per al que s'utilitzen nanopartícules tipus Janus d'or-sílice mesoporosa funcionalitzades amb l'enzim L-glutamat oxidasa en la part de l'or i amb una porta molecular autoimmolant d'arilboronat a la superfície de la sílice. La alliberació controlada es basa en el reconeixement de L-glutamat per l'enzim L-glutamat oxidasa i la posterior formació de peròxid d'hidrogen, que és l'espècie que indueix l'escissió de la porta autoimmolant i la subseqüent obertura dels porus. Finalment es mostra que el sistema dissenyat és capaç d'alliberar un fàrmac citotòxic en cèl·lules de càncer de cervell després de detectar la presència de L-glutamat. / [EN] This doctoral thesis entitled "Neurotransmitters recognition based on gold and mesoporous silica nanoparticles for sensing and controlled release applications" it is a thesis carried out by compendium of articles, which is focused on the design, preparation, characterization and evaluation of nanodevices for the colorimetric sensing of neurotransmitters and controlled delivery systems responsive to neurotransmitters, based on gold nanoparticles and mesoporous silica nanoparticles equipped with organic ligands, enzymatic effectors, molecular gates and chromo-fluorogenic species or drugs. The first chapter introduces an overview about what neurotransmitters are, their main characteristics and the important role they play in the functioning of our body. In addition, a general description of the properties and potential applications of gold nanoparticles functionalized with organic ligands as detection systems and mesoporous silica nanoparticles functionalized with molecular gates as controlled delivery systems is presented. In the second chapter, the general objectives that are addressed in the following experimental chapters are presented. In the third chapter, three colorimetric detection systems of neurotransmitters based on the aggregation of gold nanoparticles doubly functionalized with organic ligands are presented. The first system is a sensor capable of selectively detecting the neurotransmitter serotonin, using gold nanoparticles functionalized with dithio-bis(succinimidyl propionate) and N acetyl-L-cysteine. The second system consists of a sensor for the selective detection of the neurotransmitter norepinephrine designed from gold nanoparticles functionalized with 4- (liponyloxy)benzaldehyde and 4-mercaptophenylboronic acid. The third system is composed of gold nanoparticles functionalized with 4-(liponyloxy)benzaldehyde and N-Acetyl-L-Cysteine, for the detection of normetanephrine, an important biomarker of the pheochromocytoma tumor. All these systems are evaluated in competitive media such as blood serum or urine. In the fourth chapter, two enzymatic controlled delivery systems based on the opening of molecular gates are developed. The first controlled delivery system responds to the presence of the neurotransmitter acetylcholine. Specifically, it consists of mesoporous silica nanoparticles functionalized on their surface with phenylboronic acid groups and capped with the enzyme acetylcholinesterase, via the formation of cyclic phenylboronic acid esters between the oligosaccharide chains of the enzyme and the phenylboronic groups on the nanoparticles surface. In this case, the enzymatic reaction produces acetic acid that induces the hydrolysis of the boronic esters, uncapping the pores and releasing the entrapped payload. In addition, the ability of the nanodevice to release the cytotoxic doxorubicin in cancer cells in the presence of acetylthiocholine is evaluated. The second delivery system consists of a nanodevice responsive to the neurotransmitter L-glutamate. It is based on Janus gold-silica mesoporous nanoparticles functionalized with the enzyme L-glutamate oxidase in the gold part and with a self-immolative arylboronate molecular gate on the surface of the silica. Controlled delivery is based on the recognition of L-glutamate by the enzyme L-glutamate oxidase and the subsequent formation of hydrogen peroxide, which results in the cleavage of the self-immolative gate and the uncapping of the pores. Finally, it is shown that the designed system is capable of releasing a cytotoxic drug in brain cancer cells after detecting the presence of L-glutamate. / The authors acknowledge financial support from the Spanish Government (Projects MAT2015-64139-C4-1-R, MAT2015-64139-C4-4-R (MINECO/FEDER) and Project AGL2015-70235-C2-2-R) and the Generalitat Valenciana (Projects PROMETEOII/2014/047 and PROMETEO/2018/024). T. Godoy-Reyes is grateful to Generalitat Valenciana for her Santiago Grisolía fellowship. A. García-Fernández is grateful to the Spanish Government for her FPU fellowship. A. Llopis-Lorente thanks “La Caixa” Foundation for his PhD grant. SCSIE (Universitat de València) is gratefully acknowledged for all the equipment employed. / Godoy Reyes, TM. (2020). Neurotransmitters recognition based on gold nanoparticles and mesoporous silica nanoparticles for sensing and controlled release applications [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/158420 / TESIS Detección colorimétrica Liberacion controlada Nanoparticulas de silice mesoporosa Nanoparticulas de oro Neurotrasmisores Neurotransmitters Gold nanoparticles Sensing Colorimetric detection Mesoporous silica nanoparticles Controlled delivery Silica nanoparticles QUIMICA INORGANICA
13	Behaviour of nanocolloidal particles on mica : investigations using atomic force microscopy Walker, Richard John January 2010 (has links) In this thesis we used atomic force microscopy (AFM) to investigate systematically the behaviour of both electrostatically stabilised silica and sterically stabilised polystyrene (PS) colloidal systems on freshly cleaved mica substrates. For the silica colloidal nanoparticles we explored the effect of colloidal suspension concentration, particle size, and different application techniques on both the adsorption behaviour and subsequent structuring of the particles. For the PS colloidal nanoparticles we explored concentration effects and experimented with both dip-coating and droplet application techniques. We showed that silica nanoparticles adsorbed onto mica via irreversible adsorption that possessed lateral mobility due to the weak attraction between the nanoparticles and the substrate, facilitating subsequent capillary structuring of the nanoparticles during drying. We associated the effects of volume fraction with Debye screening, and kinetics effects with particle size and volume fraction. We also successfully imaged a partially dried film and showed the role of convective/capillary forces in the structuring of the nanoparticles. Studies with variations in particle size generated a number of different topography structures; with dewetting phenomena observed for 10 nm nanoparticles and the formation of crystalline structures for 100 nm nanoparticles. Spin coating techniques were used to produce even larger crystalline structures of nanoparticles. Size dependent ordering occurred for low concentration samples due to the polydispersity of the colloidal suspension. We showed that acceleration can affect interparticle spacing. We also studied the role of rotational speed on the crystallinity of the particle configurations and showed how fine tuning of rotational speed can generate large scale monolayer crystalline formations of nanoparticles. 541.33
14	A Study Of The Physicochemical Properties Of Dense And Mesoporous Silica Nanoparticles That Impact Protein Adsorption From Biological Fluids Clemments, Alden Michael 01 January 2016 (has links) At the intersection of materials chemistry and biology, biomaterials have been successfully employed in an array of medical applications. From diagnostic tools to targeted drug delivery, the modular physical and chemical properties of these materials provide numerous applications. For example, porous nanoparticles have been widely integrated as vehicles to carry chemotherapeutics to localized tumor sites. By encapsulating these cytotoxic compounds within a porous framework, the commonly associated adverse side effects of conventional chemotherapeutics, such as Doxorubicin, have been greatly reduced. One such material, mesoporous silica, has received widespread attention due to its excellent biocompatibility, high surface area to mass ratio, tunable pore diameters and volumes, and robust surface chemistry. However, recent studies have demonstrated that exposing silica nanoparticles, and other synthetic materials, to biological milieu envelops the particles in layers of proteins and biomolecules. The resulting protein coat, known as the "protein corona", has been shown to have profound effects on bioavailability, cellular targeting, and cytotoxicity. Thus, in order to develop safe and effective particle-based therapies, it is of utmost importance to establish a more thorough understanding of this process. To examine how changes in surface chemistry influence protein adsorption, monodisperse, spherical mesoporous silica nanoparticles, ca. 50 nm, were modified with a variety of surface functionalizations, -NH2, -COOH, and -PEG. Exposing these materials to biological fluid revealed drastically different protein fingerprints, suggesting a strong correlation between the surface chemistry and the identity and composition of the protein corona. Quantification of the protein corona, i.e. mg protein/mg particles, was then achieved by performing thermogravimetric analysis. These values, in concert with spectral counts obtained by shotgun proteomics, illustrates a method for quantifying individual proteins present in the corona. Spherical, silica particles of varying diameters, 70-900 nm, were then synthesized to investigate how particle diameter may affect the biomolecular identity of the protein corona. Applying the previously described methods, it was found that mesoporous particles exhibit a higher affinity for low-molecular weight proteins compared to dense silica particles of similar diameters. Finally, stochastic optical reconstruction microscopy (STORM) was used to map protein adsorption/diffusion throughout as-prepared (pore diameter ~ 30 Å) .and large pore (pore diameter > 60 Å) mesoporous silica particles. By collecting three-dimensional data on the protein-adsorbed materials, a sphere-fitting algorithm could be applied to determine the center and radius of the host particle. This calculation demonstrated that the depth by which specific proteins diffused into the porous framework was a function of both the protein's molecular weight as well as the pore diameter. corona mesoporous protein adsorption silica nanoparticles STORM Biology Chemistry Mechanics of Materials
15	A Multi-Method Approach for the Quantification of Surface Amine Groups on Silica Nanoparticles Sun, Ying 29 July 2019 (has links) As nanomaterials continue to garner interest in a wide range of industries and scientific fields, commercial suppliers have met growing consumer demand by readily offering custom particles with size, shape and surface functionality made-to-order. By circumventing the challenging and complex synthesis of functionalized nanoparticles, these businesses seek to provide greater access for the experimentation and application of these nanoscale platforms. In many cases, amine functional groups are covalently attached as a surface coating on a nanoparticle to provide a starting point for chemical derivatization and commonly, conjugation of biomolecules in medical science applications. Successful conjugation can improve the compatibility, interfacing and activity of therapeutic and diagnostic nanomedicines. Amines are amongst the most popular reactive groups used in bioconjugation pathways owing to the many high-yield alkylation and acylation reaction are involved in. For the design of functionalized nanomaterials with precisely tuned surface chemical properties, it is important to develop techniques and methods which can accurately and reproducibly characterize these materials. Quantification of surface functional groups is crucial, as these groups not only allow for conjugation of chemical species, but they also influence the surface charge and therefore aggregation behavior of nanomaterials. The loss of colloidal stability of functionalized nanomaterials can often correspond to a significant if not complete loss of functionality. Thus, we sought to develop multiple characterization approaches for the quantification of surface amine groups. Silica nanoparticles were selected as a model nanomaterial as they are widely used, commercially available, and their surface chemistry has been investigated and studied for decades. Various commercial batches of silica nanoparticles were procured with sizes ranging from 20 – 120 nm. Two colorimetric assays were developed and adapted for their ease-of-use, sensitivity, and convenience. In addition, a fluorine labelling technique was developed which enabled analysis by quantitative solid-state 19F NMR and X-ray photoelectron spectroscopy (XPS). XPS provided data on surface chemical composition at a depth of ≈ 10 nm, which allowed us to determine coupling efficiencies of the fluorine labelling technique and evaluate the reactivity of the two assays. The ensemble of surface-specific quantification techniques was used to evaluate multiple commercial batches of aminated silica and investigate batch-to-batch variability and the influence of particle size with degree of functionalization. In addition, resulting measurements of surface amine content were compared and validated by an independent method based on quantitative solution 1H NMR, which was developed for total functional group content determination. This allowed for us to assess the role of accessibility and reactivity of the amine groups present in our silica particles. Overall, the objective of this study was to develop a multi-method approach for the quantification of amine functional groups on silica nanoparticles. At the same time, we hoped to set a precedent for the development and application of multiple characterization techniques with an emphasis of comparing them on the basis of reproducibility, sensitivity, and mutual validation. Nanotechnology Analytical Chemistry Silica Nanoparticles Amine Functional Groups Quantification Surface Chemistry Functionalized Materials Nanomaterial Characterization
16	Fluorescência molecular em nanopartículas de sílica marcadas com quercetina e rodamina B / Molecular fluorescence in silica nanoparticles doped with quercetin and rhodamine B Frederice, Rafael 16 April 2009 (has links) Nanoesferas de sílica contendo fluoróforos encapsulados (o complexo quercetina- Al+3 e o corante rodamina B) foram preparadas com alto controle de tamanho e morfologia, utilizando catálise ácida e básica do tetraetilortossilicato (TEOS). As nanopartículas obtidas apresentaram diâmetro da ordem de 200-300 nm, possuindo maior regularidade quando preparadas em meio alcalino. Nas preparações foram utilizados o método de Stöber e o método caroço-casca. Devido à hidrólise da quercetina em meio básico, as partículas funcionalizadas com o flavonóide ou com o complexo quercetina-Al+3, apresentaram maior intensidade de emissão sob catálise ácida. No caso da catálise básica, as partículas apresentaram emissão significativa quando preparadas utilizando um sol de alumina, porém foram obtidos paralelepípedos nanométricos. Os decaimentos de fluorescência para o sistema quercetina-alumina são biexponenciais, em concordância com os dois complexos quercetina-Al+3 formados no interior da nanopartícula de sílica. No caso da rodamina B, foram realizadas medidas de espectroscopia de correlação de fluorescência, que mostraram uma relação entre relaxação difusional com tamanho e autoagregação das partículas. / Silica nanospheres doped with quercetin-Al+3 and rhodamine B were synthesized with high size control and morphology, using acid and basic catalysis of tetraethylorthosilicate (TEOS). The nanoparticle diameter obtained was about 200- 300 nm, with higher regularity when synthesized in alkaline media. The Stöber\'s and core-shell methods were used as preparation methods. Because the alkaline hydrolysis of quercetin, the flavonoid or the quercetin-Al+3 complex doped nanoparticles showed higher emission intensity when acid catalysis was used. When basic catalysis was performed, the particles prepared with an alumina-sol showed expressive emission intensity, but nanometric parallelepipeds were obtained. The quercetin-alumina fluorescence decays are biexponential, agreeing with the two types of quercetin-Al+3 complexes formed in the nanoparticles domain. In the case of rhodamine B, fluorescence correlation spectroscopy (FCS) measurements were performed, showing a relation between diffusion relaxation with size and aggregation behavior. alkaline hydrolysis espectroscopia de fluorescência fluorescence spectroscopy fluoróforos fluorophores hidrólise alcalina nanopartículas de sílica silica nanoparticles
17	[en] HYBRID SILICA NANOPARTICLES FOR STABILIZATION OF BIPHASIC DISPERSIONS / [pt] NANOPARTÍCULAS DE SÍLICA HÍBRIDAS PARA ESTABILIZAÇÃO DE DISPERSÕES BIFÁSICAS LUIS MIGUEL GUTIERREZ BELENO 20 February 2019 (has links) [pt] As dispersões bifásicas (ex. espumas e emulsões), de grande relevância prática na química e na engenharia, são termodinamicamente instáveis devido à diminuição de energia livre no processo de coalescência. Esta limitação é comumente minimizada através de mecanismos de estabilização eletrostática e estérica. Recentemente, há um interesse crescente na estabilização de emulsões e espumas usando partículas sólidas (tipo Pickering), devido à forte adsorção das mesmas nas interfaces para formar uma película sólida. Dependendo do tamanho e do ângulo de contato, a adsorção das partículas pode tornar-se irreversível, melhorando a estabilidade em comparação com sistemas estabilizados por surfactante. Como nanopartículas de molhabilidade intermédia são relativamente raras, o ajuste deste parâmetro é o principal desafio para obter dispersões estáveis. No presente estudo, nanopartículas de sílica (SiNPs) foram modificadas superficialmente com 3-aminopropil trimetoxisilano e hexadeciltrimetoxisilano como agentes sililantes, para se obter três tipos diferentes de nanopartículas híbridas de maior hidrofobicidade, visando a formulação de dispersões bifásicas altamente estáveis usando um método de baixa energia (agitação manual). As SiNPs modificadas foram caracterizadas através de testes qualitativos, infravermelho, analise termogravimétrica, analise elementar e ressonância magnética nuclear de carbono treze e de silício vinte nove no estado sólido para confirmar o enxerto dos grupos funcionais. As propriedades das NPs em relação à sua dispersabilidade e comportamento em interfaces foram avaliadas por espalhamento de luz dinâmica e a tensão superficial crítica de molhabilidade. Finalmente, foram preparadas espumas líquidas e emulsões água-em-óleo (A/O) utilizando as partículas híbridas obtidas e pequenas quantidades de surfactantes, para facilitar o processo de dispersão. Os resultados mostraram que as NPs mais hidrofílicas estabilizam melhor a interface ar/água (espumas), enquanto a estabilização máxima em emulsões é obtida com as NPs mais hidrofóbicas, uma vez que a interação com a fase contínua é otimizada. Além disso, a presença de grupos funcionais na superfície das SiNPs oferece a possibilidade de obter efeitos de sinergia com os surfactantes, controlando a adsorção mista na interface. As aplicações potenciais destes resultados podem abranger diversas áreas, tais como biomedicina, ciência dos materiais, recuperação de petróleo, cosméticos e alimentos. / [en] Biphasic dispersions (e.g. foams and emulsions) are of practical relevance to many chemical and engineering fields. These dispersions are thermodynamically unstable, since their decay results in a decrease of the free energy. Different mechanisms can prevent the coalescence of the dispersion, such as electrostatic and steric stabilization. Recently, there has been an increased interest in the study of stabilization of emulsions and foams using solid particles (Pickering type), since particles can strongly adsorb at interfaces to form a solid film, replacing the incompatible water-oil(ar) interface by the more favorable oil(ar)-particle and particlewater interfaces. Depending on their size and contact angle of selective wetting, particle adsorption can become irreversible, with increased stability of particle-stabilized dispersions compared to surfactant-stabilized systems. Since particles of intermediate wettability by nature are relatively rare, tailoring particle wettability is the major challenge to obtain stable dispersions. In the present study, hybrid silica nanoparticles (SiNPs) were prepared by modification of their surface using 3 aminopropyltrimethoxysilane and hexadecyltrimethoxysilane as silanizing agents, to obtain three different nanoparticles with increased hydrophobicity, aiming to achieve highly stable biphasic dispersions using a low-energy method. The modified SiNPs were characterized using qualitative tests, FTIR, TGA, CHN and NMR (Si) to confirm grafting of functional groups. In addition, nanoparticle properties regarding aqueous dispersions and behavior at interfaces were evaluated by DLS and critical wetting surface tension. Liquid foams and water-in-oil (W/O) emulsions were prepared using the obtained hybrid particles and small amounts of different surfactants, to facilitate the dispersion process. The results showed that while more hydrophilic NPs stabilize better the air/water interface (foams), maximum stabilization in W/O emulsions is achieved with the most hydrophobic NPs, since interaction with continuous phase is optimized. In addition, the presence of different functional groups at the surface of the SiNPs offers the possibility for increased synergy with surfactants, controlling the mixed adsorption at the interface. The potential applications of these results can cover diverse fields such as biomedicine, materials science, oil recovery, cosmetics and food. [pt] EMULSOES [en] EMULSIONS [pt] ESPUMA [en] FOAM [pt] NANOPARTICULAS DE SILICA [en] SILICA NANOPARTICLES [pt] DISPERSOES BIFASICAS [en] BIPHASIC DISPERSIONS
18	Multimodal nanoparticles for image-guided delivery of mesenchymal stem cells in the treatment of myocardial infarction Sweeney, Sean 01 May 2015 (has links) One of the leading causes of death and hospital stays in the United States, myocardial infarction (MI) occurs when coronary blockages lead to downstream ischemia in the myocardium. Following the MI, the heart activates a number of pathways to repair or remodel the infarcted zone. Endothelial cells respond to ischemia by de-differentiating to form neovasculature and myofibroblasts. The resident cardiac differentiable stem cells (CDCs) are recruited via local cytokines and chemokines to the infarct zone where they too differentiate into myofibroblasts. Mesenchymal stem cells (MSCs) of the bone marrow respond to circulating factors by immobilizing to the heart and differentiating down cardiac lineages. In regenerative medicine approaches, these processes are exploited to augment the resident supply of reparative cells. Clinical trials to transplant cardiac stem cells into MI zones have been met with mixed results. When CDCs are harvested from autologous or type-matched donors, the cells are prepared with a minimum of manipulations, but the yield is quite small. Conversely, MSCs from bone marrow are highly proliferative, but the manipulations in culture required to trigger cardiac differentiation have been found to transform the cell into a more immunogenic phenotype. In addition, there is a dearth of in vivo evidence for the fate of transplanted cells. Currently, intracardiac echocardiographs are used to assess the infarcted area and to guide delivery of stem cell transplants. However, this modality is invasive, short-term, and does not image the transplanted cells directly. In this project, I addressed these shortcomings with a regenerative medicine and bioimaging approach. Our lab has developed multimodal nanoparticles based on a core of mesoporous silica, functionalized with fluorescein or tetramethylrhodamine isothiocyanate for visibility in fluorescent microscopy, Gd2O3 for magnetic resonance imaging (MRI), and trifluoropropyl moieties for ultrasound applications. After establishing in vitro models of cardiac stem cells using CDCs and MSCs, the particles were implemented and characterized in vitro. At a concentration of 125 μg/mL in culture, the particles are highly biocompatible, and labeled cells were found to be fluorescent, echogenic, and detectable with MRI in prepared agar phantoms. Ex vivo mouse hearts, first mounted in agar phantoms, then left in situ, were implemented as a model for guided delivery using ultrasound and follow-up cell tracking with MRI. These results in this project demonstrate the feasibility of this highly novel and practical approach. Additional studies will be carried out to evaluate the biocompatibility and retention versus clearance in live animal models, prior to the carrying out of true pre-clinical models for myocardial infarction. publicabstract Magnetic Resonance Imaging Mesenchymal Stem Cells Mesoporous Silica Nanoparticles Myocardial Infarction Ultrasound
19	Passive mass transport for direct and quantitative SERS detection using purified silica encapsulated metal nanoparticles Shrestha, Binaya Kumar 01 July 2015 (has links) This thesis focuses on understanding implications of nanomaterial quality control and mass transport through internally etched silica coated nanoparticles for direct and quantitative molecular detection using surface enhanced Raman scattering (SERS). Prior to use, bare nanoparticles (partially or uncoated with silica) are removal using column chromatography to improve the quality of these nanomaterials and their SERS reproducibility. Separation of silica coated nanoparticles with two different diameters is achieved using Surfactant-free size exclusion chromatography with modest fractionation. Next, selective molecular transport is modeled and monitored using SERS and evaluated as a function of solution ionic strength, pH, and polarity. Molecular detection is achieved when the analytes first partition through the silica membrane then interact with the metal surface at short distances (i.e., less than 2 nm). The SERS intensities of unique molecular vibrational modes for a given molecule increases as the number of molecules that bind to the metal surface increases and are enhanced via both chemical and electromagnetic enhancement mechanisms as long as the vibrational mode has a component of polarizability tensor along the surface normal. SERS signals increase linearly with molecular concentration until the three-dimensional SERS-active volume is saturated with molecules. Implications of molecular orientation as well as surface selection rules on SERS intensities of molecular vibrational modes are studied to improve quantitative and reproducible SERS detection using internally etched Ag@Au@SiO2 nanoparticles. Using the unique vibrational modes, SERS intensities for p-aminothiophenol as a function of metal core compositions and plasmonics are studied. By understanding molecular transport mechanisms through internally etched silica matrices coated on metal nanoparticles, important experimental and materials design parameters are learned, which can be subsequently applied to the direct and quantifiable detection of small molecules in real samples without the need for lengthy separations and assays. publicabstract quantitative SERS SERS silica nanoparticles silver core gold shell nanoparticles Chemistry
20	From Responsive Interfaces to Honeycomb Membranes by Controlled Radical Polymerisation Nyström, Daniel January 2008 (has links) In this study, surface modification of both organic and inorganic substrates (in terms of cellulose and silica nanoparticles, respectively) has been explored using surface-initiated atom transfer radical polymerisation (ATRP). The desire to modify bio-based materials to fit into new application areas and the need for bio-based materials with improved material properties is steadily increasing due to environmental concern. Superhydrophobic and self-cleaning cellulose surfaces were fabricated by combining ATRP with post-functionalisation. Glycidyl methacrylate was grafted from filter paper, and the epoxide groups were used as reactive handles to create a branched “graft-on-graft” architecture. Post-functionalisation of this architecture with perfluorinated chains or alkyl chains resulted in the formation of superhydrophobic surfaces. Grafting of N-isopropylacrylamide (NIPAAm) from filter paper yielded cellulose surfaces capable of switching the wettability, from hydrophilic to hydrophobic, in response to changes in temperature. The wettability of cellulose surfaces grafted with poly(4-vinylpyridine) (P4VP) could be adjusted from hydrophilic to hydrophobic by changing pH. Furthermore, cellulose surfaces responding to changes in both pH and temperature were obtained via grafting of block copolymers of PNIPAAm and P4VP. The use of inorganic nano-particles in composites has attracted considerable academic and industrial interest due to their excellent mechanical and thermal properties. Styrene was grafted from the surface of silica nanoparticles using ATRP. The resulting organic-inorganic hybrid materials did not aggregate to the same extent as the un-modified silica particles. The polystyrene-modified silica particles were used for the fabrication of honeycomb membranes. It was evident that the pore sizes and the number of porous layers could be tuned by varying the conditions used for film casting. To broaden the range of polymers available for film casting into honeycomb membranes, a block copolymer of polystyrene and poly(methyl methacrylate) was grafted from silica nanoparticles. Polymer-blends of polystyrene-modified particles and poly(9,9´-dihexylfluorene) (PDHF) were also used as an alternative to incorporate functionality into honeycomb membranes. / QC 20100901 Isoporous membranes Silica nanoparticles ATRP Functional surfaces cellulose Polymer chemistry Polymerkemi

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