Assessment of the Fate and Transport of Silver Nanoparticles in Porous Media

El Badawy, Amro

23 September 2011

No description available.

Environmental Engineering

Silver Nanoparticles

Porous Media

Aggregation

Natural Organic Matter

Toxicity

Near Single-Molecule SERS-Based Detection Using Ultrafiltered, Unfunctionalized Silver Nanoparticles

Baker, Joshua Dale

05 September 2012

No description available.

Nanoscience

Nanotechnology

Physical Chemistry

Raman Spectroscopy

SERS

Physical Chemistry

Silver Nanoparticles

Nanoscience

Nanotechnology

SURFACE REACTIONS AND ULTRAFAST DYNAMICS IN NANO- AND MICRO-SIZED MATERIALS

Xu, Bolei

January 2016

In this dissertation, the laser spectroscopic methods, second harmonic generation (SHG) and ultrafast transient absorption, have been employed to study the reactions and dynamics in two different types of materials, namely, silver nanoparticles and micro-sized ultrathin crystalline oligoacenes. These two materials, although both are in small dimensions, represent two distinct types of systems with divergent characteristics: 1) systems in which interactions at the surface/interface are dominant, and 2) systems in which bulk interactions are dominant. Silver nanoparticles are an important member of the class of noble metal nanoparticles, and possess unique optical and chemical properties due to their ultrafine size and high surface-to-volume ratio. Strong SHG signal has been observed from silver nanoparticles dispersed in aqueous colloidal solution, in which the SHG signal is enhanced due to a resonance with the localized surface plasmon of silver nanoparticles. Further experiments proved that the SHG signal predominantly originates from the particle surface, in full agreement with the intrinsically interface-sensitive properties of SHG. With the surface origin of the signal now well established, SHG can be used to probe the adsorption and reactions of thiol molecules at the nanoparticle surface in situ and in real time. It is experimentally demonstrated that the free energy change, activation energy, as well as adsorption density of the reactions of a variety of neutral and anionic thiols at the particle surface can be measured by means of SHG. The reaction mechanisms at the molecular level have been deduced, and the neutral vs anionic thiols are found to exhibit qualitatively different reaction mechanisms that reflect the effect of their molecular interactions with the particle surface. Oligoacenes, such as pentacene and hexacene, constitute a family of organic semiconductors that exhibit remarkable optoelectronic properties. In contrast to the nanoparticles in which surface interactions are dominant, as the sizes of materials become larger, the bulk characteristics become more deterministic. Therefore, polarized linear absorption and transient absorption spectroscopies have been applied to study the excitonic properties of crystalline pentacene and the mechanism of singlet fission in crystalline hexacene, respectively. The polarized absorption spectra of crystalline pentacene have been obtained by measuring transmitted light normal to the ab herringbone plane of micro-sized ultrathin single crystals. The significant deviations between the spectral line shapes polarized along the b-axis and orthogonal to the b-axis provide detailed information on the anisotropic mixing nature of the Frenkel/charge-transfer excitons responsible for the pronounced Davydov splitting between the lowest-energy singlet states. Additionally, both singlet and triplet Davydov splittings were also observed from the linear and transient absorption experiments in micrometer-sized ultrathin hexacene single crystals. A two-step process of anisotropic singlet fission was uncovered from the kinetic data, in which singlet fission at different rates were deduced along the a- and b-axes. Both the spectral and kinetic features indicate that singlet fission in crystalline hexacene is an anisotropic and charge-transfer mediated many-molecule process. / Chemistry

Chemistry, Physical

Second Harmonic Generation

Silver Nanoparticles

Singlet Fission

Transient Absorption

Controlled Evaluation of Silver Nanoparticle Dissolution Using Atomic Force Microscopy

Kent, Ronald Douglas

21 November 2011

Incorporation of silver nanoparticles (AgNPs) into an increasing number of consumer products has led to concern over the potential ecological impacts of their unintended release to the environment. Dissolution is an important environmental transformation that affects the form and concentration of AgNPs in natural waters; however, studies on AgNP dissolution kinetics are complicated by nanoparticle aggregation. Herein, nanosphere lithography (NSL) was used to fabricate uniform arrays of AgNPs immobilized on glass substrates. Nanoparticle immobilization enabled controlled evaluation of AgNP dissolution in an air-saturated phosphate buffer (pH 7, 25 °C) under variable NaCl concentrations in the absence of aggregation. Atomic force microscopy (AFM) was used to monitor changes in particle morphology and dissolution. Over the first day of exposure to ≥10 mM NaCl, the in-plane AgNP shape changed from triangular to circular, the sidewalls steepened, and the height increased by 6-12 nm. Subsequently, particle height and in-plane radius decreased at a constant rate over a 2-week period. Dissolution rates varied linearly from 0.4 to 2.2 nm/d over the 10-550 mM NaCl concentration range tested. NaCl-catalyzed dissolution of AgNPs may play an important role in AgNP fate in saline waters and biological media. This study demonstrates the utility of NSL and AFM for the direct investigation of un-aggregated AgNP dissolution. / Master of Science

chloride

atomic force microscopy

Nanomaterials

silver nanoparticles

Oxidation

dissolution

nanosphere lithography

convective self-assembly

Controlled Evaluation of Silver Nanoparticle Dissolution: Surface Coating, Size and Temperature Effects

Liu, Chang

30 March 2020

The environmental fate and transport of engineered nanomaterials have been broadly investigated and evaluated in many published studies. Silver nanoparticles (AgNPs) represent one of the most widely manufactured nanomaterials. They are currently being incorporated into a wide range of consumer products due to their purported antimicrobial properties. However, either the AgNPs themselves or dissolved Ag+ ions has a significant potential for the environmental release. The safety issues for nanoparticles are continuously being tested because of their potential danger to the environment and human health. Studies have explored the toxicity of AgNPs to a variety of organisms and have shown such toxicity is primarily driven by Ag+ ion release. Dissolution of nanoparticles is an important process that alters their properties and is a critical step in determining their safety. Therefore, studying nanoparticles' dissolution can help in the current move towards safer design and application of nanoparticles. This research endeavor sought to acquire comprehensive kinetic data of AgNP dissolution to aid in the development of quantitative risk assessments of AgNP fate. To evaluate the dissolution process in the absence of nanoparticle aggregation, AgNP arrays were produced on glass substrates using nanosphere lithography (NSL). Changes in the size and shape of the prepared AgNP arrays were monitored during the dissolution process by atomic force microscopy (AFM). The dissolution of AgNP is affected by both internal and external factors. First, surface coating effects were investigated by using three different coating agents (BSA, PEG1000, and PEG5000). Capping agent effects nanoparticle transformation rate by blocking reactants from the nanoparticle surface. Coatings prevented dissolution to different extents due to the various way they were attached to the AgNP surface. Evidence for the existence of bonds between the coating agents and the AgNPs was obtained by surface enhanced Raman spectroscopy. Moreover, to study the size effects on AgNP dissolution, small, medium, and large sized AgNPs were used. The surrounding medium and temperature were the two variables that were included in the size effects study. Relationships were established between medium concentration and dissolution rate for three different sized AgNP samples. By using the Arrhenius equation to plot the reaction constant vs. reaction temperature, the activation energy of AgNPs of different sizes were obtained and compared. / Doctor of Philosophy / Nanomaterials, defined as materials with at least one characteristic dimension less than 100 nm, often have useful attributes that are distinct from the bulk material. The novel physical, chemical, and biological properties enable the promising applications in various manufacturing industry. Silver nanoparticles (AgNPs) represent one of the most widely manufactured nanomaterials and has been used as the antimicrobial agent in a wide range of consumer products. However, either the AgNPs themselves or dissolved Ag+ ions has a significant potential for the environmental release. The environmental fate and transport of AgNPs drawn considerable attentions because of the potential danger to environment and human health. Dissolution of nanoparticles is an important process that alters their properties and is a critical step in determining their safety. Ag+ ions migrate from the nanoparticle surface to the bulk solution when an AgNP dissolves. Studying nanoparticles' dissolution can help in the current move towards safer design and application of nanoparticles. This research aimed to acquire comprehensive kinetic data of AgNP dissolution to aid in the development of quantitative risk assessments of AgNP fate. AgNP arrays were produced on glass substrates using nanosphere lithography (NSL) and changes in the size and shape during the dissolution process were monitored by atomic force microscopy (AFM). First, surface coating effects were investigated by using three different coating agents. Coatings prevented dissolution to different extents due to the various way they were attached to the AgNP surface. Moreover, small, medium, and large sized AgNPs were used to study the size effects on AgNP dissolution. The surrounding medium concentration and temperature were the two variables that were included in the size effects study.

Nanotechnology

silver nanoparticles

nanosphere lithography

dissolution

atomic force microscopy

surface functionalization

size effects

temperature effects

Development of Epidermal Growth Factor Receptor (EGFR) Specific Nanoprobes for Surface Enhanced Raman Spectroscopy (SERS)

Lucas, Leanne Jennifer

29 July 2013

Novel biocompatible nanoprobes for optical imaging of Epidermal Growth Factor receptor (EGFR) were created. 5 and 18 nm gold nanoparticles (AuNPs) and 5 and 45 nm diameter silver nanoparticles (AgNPs) were conjugated to EGF protein via ?-lipoic acid. AgNPs were not previously attached to EGF. TOF-MS confirms EGF-linker formation. ELISA verifies the linked-EGF activity alone and with EGF-NPs. Core-shell silver-gold nanoparticles (AgAuNPs) gave similar results. TEM staining with uranyl acetate exhibits a bright ring, smaller than EGF, around nanoparticles. Dark field microscopy shows localized, intense cytoplasmic scattering, possibly lipid droplets, in cancer cells incubated with or without nanoprobes. Following injection, mice organs were harvested for EGF-NP immune response determination. Sterilization likely inactivated EGF before ICP-MS. Intense surface enhanced Raman scattering (SERS, 632.8 nm) follows MgSO4 induced EGF-AgNPs aggregation. Pelleted EGF-AgNP tagged cancer cells lack SERS indicative intensity contrast. AgAuNPs could provide increased stability, brighter SERS, and reduced silver biocompatibility concerns.

La bioaccumulation d’une nanoparticule d’argent (nAg) par l’algue verte Chlamydomonas reinhardtii : distinguer la contribution de la particule de celle de l’ion Ag+

Leclerc, Simon

08 1900

L’explosion de la nanotechnologie a permis l’intégration d’une multitude de nanoparticules dans des produits de consommation. Les nanoparticules d’argent (nAg) sont les plus utilisées à ces fins, selon les derniers recensements disponibles. La plupart des études toxicologiques, à ce jour, ont fait état de l’implication très évidente de l’ion Ag+ dans la toxicité aigüe des nAg; cependant, quelques études ont mis en évidence des effets toxicologiques dus aux nAg. Il y a un certain consensus à propos d’un risque de contamination des eaux douces via leur rejet par les effluents des réseaux d’aqueducs. Puisque les concentrations en Ag+ sont généralement très faibles dans les eaux douces (de l’ordre du pg L-1), de par la formation de complexes non-labiles avec des thiols (organiques et inorganiques) et des sulfures, la toxicité inhérente aux nAg pourrait ne pas être négligeable- comparativement aux tests en laboratoires. Cette étude s’intéressait donc aux mécanismes de bioaccumulation d’argent par l’algue verte C. reinhardtii suite à l’exposition à des nAg de 5 nm (enrobage d’acide polyacrylique). La bioaccumulation d’argent pour l’exposition à Ag+ servait de point de comparaison; également, les abondances de l’ARNm de l’isocitrate lyase 1 (ICL1) et de l’ARNm de Copper Transporter 2 (CTR2) étaient mesurées comme témoins biologiques de la bioaccumulation de Ag+. Les expériences ont été menées en présence d’un tampon organique (NaHEPES, 2 x 10-2 M; Ca2+, 5x 10-5 M) à pH de 7,00. Pour des expositions à temps fixe de 2 heures, la bioaccumulation d’argent pour nAg était supérieure à ce qui était prédit par sa concentration initiale en Ag+; cependant, il n’y avait pas de différence d’abondance des ARNm de ICL1 et de CTR2 entre nAg et Ag+. D’un autre côté, pour une exposition à temps variables, la bioaccumulation d’argent pour nAg était supérieure à ce qui était prédit par sa concentration initiale en Ag+ et une augmentation de l’abondance de l’ARNm de ICL1 était notée pour nAg. Cependant, il n’y avait aucune différence significative au niveau de l’abondance de l’ARNm de CTR2 entre nAg et une solution équivalente en Ag+. L’ajout d’un fort ligand organique (L-Cystéine; log K= 11,5) à une solution de nAg en diminuait radicalement la bioaccumulation d’argent par rapport à nAg-sans ajout de ligand. Par contre, l’abondance des ARNm de ICL1 et de CTR2 étaient stimulées significativement par rapport à une solution contrôle non-exposée à nAg, ni à Ag+. Les résultats suggéraient fortement que les nAg généraient des ions Ag+ au contact de C. reinhardtii. / The recent developments in nanotechnology have given rise to a new and increasing economical market where nanoparticles are at the forefront. Recent inventories of the nanoparticles-containing products have shown that silver nanoparticle- containing products are the most frequently used consumer nanomaterial. Due to the fear of a large scale contamination-and even pollution- of the aquatic environment from silver nanoparticles (nAg), studies have been conducted to assess their toxicities, which, in many cases, have been found to be mediated by the concomitant presence of Ag+. Notably, few studies have found evidence of toxicity due to the nAg, per se. Since numerous non-labile complexes are formed with Ag+ in freshwaters- especially with thiols and sulfides-, nAg toxicity might be more relevant in comparison to laboratory tests where the Ag+ tends to dominate toxicity studies. Therefore, this study investigated the mechanisms underlying silver bioaccumulation by the green alga, C. reinhardtii upon exposure to solutions of nAg (nominal size of 5 nm; poly-acrylate coating). Silver bioaccumulation upon exposures to the free ion alone served for comparison. In parallel, the abundance of two mRNAs- ICL1 and CTR2- were used to better understand the mechanisms underlying the bioaccumulation of Ag+ (and potentially nAg). The experiments were conducted in pH buffered solutions (NaHEPES, 2 x 10-2 M; Ca2+, 5x 10-5 M) at pH 7.00. For 2-hour exposures, the silver bioaccumulation for solutions of nAg exceeded what was expected from their Ag+ content only; however, no differences were noticed in the abundance of the expression of ICL1 and CTR2. For variable time exposures, the silver bioaccumulation for solutions of nAg exceeded what was expected from their Ag+ content only. Moreover, the expression of ICL1 was significantly higher for nAg than what was expected based upon an exposure to Ag+ only. When exposed to nAg, expression levels of CTR2 could be predicted from levels based solely on the Ag+ concentrations. The addition of a large excess of L-Cysteine, which is a very strong silver ligand (log K =11.5), to a nAg solution largely decreased silver bioaccumulation, however, bioaccumulation remained significant and the expression of both ICL1 and CTR2 were significantly higher than that of the control solutions (without Ag+). The results strongly suggest that nAg generated Ag+ ions when in contact with C. reinhardtii and that the nAg released to freshwaters might exert its toxicity through organism-contact-dependant release of Ag+.

Nanoparticules d’argent

Chlamydomonas reinhardtii

Bioaccumulation

ARNm

Copper Transporter 2

Cuivre

Silver nanoparticles

Copper

mRNA

Síntese foto-assistida de nanopartículas de prata metálica em filmes híbridos de Ormosil-fosfotungstato / Photo-assisted synthesis of metallic silver nanoparticles in Ormosil-phosphotungstate hybrid films

Noveletto, Julia Cristina

19 May 2017

Filmes híbridos fotoativos de Ormosil (silicatos organicamente modificados) contendo o polioxometalato de Keggin ácido fosfotungstico (H3PW12O40) e cátions Ag+ foram preparados por meio da rota sol-gel e deposição de filme por dip-coating. A caracterização por FTIR, Raman, XRF e DRX evidenciou a formação da matriz de organossilicato e o aprisionamento dos poliânions PW12O403- e cátions Ag+. O comportamento fotocrômico dos filmes de Ormosil-fosfotungstato baseiam-se na redução fotoinduzida do fosfotungstato por exposição à radiação UV, o que leva à formação de compostos coloridos de valência mista conhecidos como heteropolyblues. No entanto, a presença de cátions Ag+ altera completamente o comportamento fotocrômico destes filmes híbridos. Os poliânions de fosfotungstato fotorreduzidos são agentes redutores eficientes na redução dos cátions Ag+, resultando na formação in situ de nanopartículas de prata metálica na matriz híbrida como evidenciado pela intensa banda plasmônica centrada em 390 nm no espectro eletrônico da amostra. A caracterização por Uv-vis e Espectroscopia de Absorção de Raios X próxima a Borda de Absorção (XANES) mostrou que a foto-redução pode ser revertida por tratamento térmico o que caracteriza um comportamento fotocrômico reversível. O comportamento cinético da amostra foi analisado propondo mecanismos para as reações de redução e oxidação da prata, responsáveis pela alteração de coloração do material. O aprisionamento de compostos fotoativos em matrizes híbridas orgânico-inorgânico via sol-gel é uma estratégia interessante para a preparação de materiais fotocrômicos com potenciais aplicações tecnológicas. A reversibilidade fotocrômica destes materiais os torna bons candidatos para aplicação em sistemas de memória óptica, filtros óticos de passa-banda estreita, dispositivos de ótica não linear, sensores de radiação UV e revestimentos bactericidas. / Sol gel entrapment of photoactive compounds in organic-inorganic hybrid matrices is an interesting strategy for the preparation of photochromic materials with potential technological applications. In this study, we report the preparation of photoactive Ormosil (organically modified silicates) hybrid films containing the Keggin polyoxometalate phosphotungstate (H3PW12O40) and Ag+ cations by sol-gel synthesis and dip coating deposition. The materials have been characterized by infrared absorption spectroscopy (FTIR), Raman spectroscopy and X-ray Fluorescence (XRF), thus evidencing the formation of hybrid organosilicate matrix and the entrapment of the PW12O40-3 polyanions and Ag+ cations. The photochromic behavior of the Ormosil-phosphotungstate films is based on photoinduced reduction of phosphotungstate upon exposure to UV radiation, which leads to the formation of colored mixed valence compounds known as heteropolyblues. However, the presence of Ag+ cations completely changes the photochromic behavior of these hybrid films. The photoreduced phosphotungstate polyanions rapidly promote the reduction of Ag+ cations, resulting in the in situ formation of silver metal nanoparticles (Ag0) inside the hybrid matrix as evidenced by the intense plasmonic band centered at 390nm as shown by electronic, UV-vis, spectroscopy and its yellowish color. The Uv-vis and X-ray Near Edge Absorption Spectroscopy (XANES) characterization shown that this process is reversible and the yellowish color characteristic of the metallic silver nanoparticles disappears once the hybrid films are heated at 353 K. Thus, the coloration is achieved upon UV exposure and discoloration occurs upon simple heating. Therefore, the described photoactive properties, the prepared hybrid films have potential application in optical memory systems, single bandpass optical filters, non-linear optical devices, UV radiation sensors and bactericidal coatings.

Filmes finos

Fotocromismo

Hybrid materials

Materiais híbridos

Nanopartículas de prata

Photochromism

Polioxometalatos

Polyoxometalates

Silver nanoparticles

Sol-gel

Sol-gel

Thin films

Mecanismos de ação de nanopartículas de prata no comportamento de propriedades mecânicas celulares / Mechanisms of action of silver nanoparticles in the behavior of cell mechanical properties

Sousa, Edi Carlos Pereira de

23 May 2018

Neste trabalho estudamos a interação de dois tipos de nanopartículas de prata metálica, obtidas pelo processo de poliol (IQUSP) e pelo método eletrolítico (Khemia®), em células de músculo liso. Um extenso trabalho de caracterização foi realizado, descrevendo a natureza físico-química dessas nanopartículas. Medidas de absorção óptica mostraram que as nanopartículas exibem bandas suaves em torno de 400 nm, região do azul do espectro eletromagnético, devido à ressonância dos plasmons de superfície, evidenciando a tendência à agregação com o tempo. Microscopia eletrônica de transmissão foi realizada para obter as imagens das nanopartículas em micrografias. Histogramas foram construídos para determinar o tamanho das NPs e o índice de polidispersividade. Espectros de EDS foram obtidos para a caracterização química das amostras. Difratogramas de raios X foram obtidos para as AgNPs. Os picos de difração foram indexados e revelaram uma única fase cristalina da prata, com estrutura cúbica e estado de oxidação, Ag0. Com o auxílio desses difratogramas, foram calculados o parâmetro de rede e a distância interplanar dos planos de difração. Utilizando a equação de Scherrer e um ajuste gaussiano dos picos de Ag mostrados nos difratogramas de raios X, foi possível obter o tamanho do cristalito para nanopartículas IQUSP. Experimentos de DLS mostraram distribuição de número monomodal para AgNPs Khemia® e, para AgNPs IQUSP lavadas, distribuição bimodal, estimando-se a distribuição de número e tamanho. Os resultados mostraram que a distribuição dominante é sempre para raios menores, sugerindo partículas menores que se agregam com o tempo e formam maiores dimensões. Resultados de SAXS mostraram que as amostras fornecem boa intensidade de espalhamento. Utilizando modelos teóricos foram calculados o raio médio da distribuição, polidispersividade e raio de giro. Os dados revelaram que as nanopartículas IQUSP possuem um raio maior que as AgNPs Khemia® e não apresentaram agregação. Em contrapartida, AgNPs Khemia® apresentaram maior agregação, com polidispersividade relativa de 72%. Para AgNPs IQ--USP, análises de SAXS forneceram tamanho de partícula comparável a TEM e bastante diferente de DLS. As medidas de SAXS para AgNPs Khemia® mostram diferenças com as medidas de TEM e DLS. Ficou evidente o efeito da agregação, que tem influências desde o preparo das amostras até o tempo de realização das medidas. Testes de citotocixidade e estudos de análise morfológica por microscopia de fluorescência evidenciaram as características citotóxicas de cada nanopartícula. Os resultados apresentados pela análise morfológica realizada com microscopia de fluorescência concordam com os testes de citotoxicidade. AgNPs IQUSP mostraram alta toxicidade até a concentração 9.37 mg/mL, onde as células são apresentadas com fragmentação nuclear. Em concentrações mais baixas, as AgNPs IQUSP exibiram características morfológicas comparáveis ao grupo controle. Por sua vez, AgNPs Khemia® mostram alta toxicidade até a concentração 1.37 mg/mL, com índice IC50 variando na faixa de 1.3 a 6.7 mg/mL. Foi possível observar que concentrações mais altas induzem à fragmentação nuclear, desencadeando processos como apoptose e necrose. Experimentos utilizando a técnica de OMTC demonstraram que as diferentes concentrações de nanopartículas de prata podem modificar a rigidez celular. Isto é evidenciado quando comparamos o grupo controle com os demais grupos, com as diferentes concentrações de NPs. Para concentrações mais altas de nanopartículas, verificou-se um aumento da viscoelasticidade. Os dois tipos de nanopartículas estudadas apresentaram mudanças nas propriedades mecânicas, mas as AgNPs Khemia® apresentaram um maior aumento na viscoelasticidade nas diferentes concentrações de NPs. Essa mudança na viscoelasticidade foi explicada como sendo devido à maior disponibilidade do cálcio, liberado por células apoptóticas, o qual é utilizado no complexo miosina-actina para gerar contração muscular. / In this work we study the interaction of two types of metallic silver nanoparticles, obtained by the polyol process (IQUSP) and the electrolytic method (Khemia®), in smooth muscle cells. An extensive characterization work was carried out, describing the physico-chemical nature of these nanoparticles. Optical absorption measurements showed that nanoparticles exhibit smooth bands around 400 nm, the blue region of the electromagnetic spectrum, due to the resonance of the surface plasmons, evidencing the tendency to aggregate with time. Transmission electron microscopy was performed to obtain images of the nanoparticles in micrographs. Histograms were constructed to determine the size of NPs and the index of polydispersity. EDS spectra were obtained for the chemical characterization of the samples. X-ray diffraction patterns were obtained for the AgNPs. The diffraction peaks have been indexed and showed a single crystal layer of silver, with cubic structure and oxidation state, Ag0. By means of these diffractograms, the network parameter and the interplanar distance of the diffraction planes were calculated. Using the Scherrer equation and a Gaussian fit of the Ag peaks shown in the X-ray diffractograms, it was possible to obtain the crystallite size for IQ-USP nanoparticles. DLS experiments showed monomodal number distribution for Khemia® AgNPs and, for washed IQUSP AgNPs, bimodal distribution, estimating the number and size distribution. The results showed that the dominant distribution is always for smaller rays, suggesting smaller particles that aggregate with time and form larger dimensions. SAXS results showed that the samples provide good scattering intensity. Using the theoretical models, the average radius of the distribution, polydispersity and radius of gyration were calculated. The data revealed that the IQUSP nanoparticles have a larger radius than the Khemia® and did not show aggregation. In contrast, Khemia® AgNPs showed higher aggregation, with 72% relative polydispersity. For IQ-USP AgNPs, SAXS analyzes provided particle size comparable to TEM and quite different from DLS. SAXS measurements for Khemia® AgNPs show differences with TEM and DLS measurements. It was evident the effect of the aggregation that has influences from the sample preparation until the time of performing the measurements. Cytotoxicity tests and morphological analysis studies by fluorescence microscopy evidenced the cytotoxic characteristics of each nanoparticle. The results presented by the morphological analysis performed with fluorescence microscopy agree with the cytotoxicity tests. IQ-USP nanoparticles showed high toxicity up to the concentration of 9.37 mg/mL, where the cells are presented with nuclear fragmentation. At lower concentrations, the IQUSP AgNPs exhibited morphological characteristics comparable to the control group. In addition, Khemia® AgNPs show high toxicity up to the concentration of 1.37 mg/mL, with IC50 in the range of 1.3 to 6.7 mg/mL. It was possible to observe that higher concentrations induce nuclear fragmentation, triggering processes such as apoptosis and necrosis. Experiments using the OMTC technique demonstrated that different concentrations of silver nanoparticles can modify cell stiffness. This is evidenced when we compare the control group with the other groups, with the different concentrations of NPs. For higher concentrations of nanoparticles, there was an increase in viscoelasticity. The two types of nanoparticles studied showed changes in mechanical properties, but Khemia® AgNPs showed a greater increase in viscoelasticity at different concentrations. This change in viscoelasticity was explained to be due to the increased availability of calcium, released by apoptotic cells, which is used in the myosin-actin complex to generate muscle contraction.

caracterização

cell mechanics

characterization

citotoxicidade

cytotoxicity

fluorescence microscopy

mecânica celular

microscopia de fluorescência

nanopartículas de prata

silver nanoparticles

viscoelasticidade.

viscoelasticity.

Modulação de fluorescência de amino coumarinas e acridinas por nanopartículas de prata / Fluorescence modulation of acridine and coumarin dyes by silver nanoparticles

Sabatini, Carolina Aparecida

17 August 2007

Nanopartículas de prata foram preparadas pela redução química de íons prata (AgNO3) por borohidreto de sódio (NaBH4) na presença de poli-(N)-vinil-2-pirrolidona em solução de álcoois de cadeia curta. As nanopartículas de prata apresentaram maior estabilidade em 2- propanol, e o diâmetro aproximado das nanopartículas Ag0 obtidas neste solvente é de aproximadamente 6 nm. As propriedades fotofísicas dos corantes coumarinas e derivados de acridina, em 2-propanol, são afetados pela presença das nanopartículas de prata. A interação das nanopartículas de prata com os derivados de acridina leva a uma mudança espectral da banda de absorção de transferência de carga intramolecular ´ICT - intramolecular charge transfer´. Para dois dos derivados de acridina, há um aumento significativo de emissão com a adição inicial de nanopartículas de Ag0. Mas em altas concentrações de nanopartículas de prata, ocorre supressão estática de fluorescência, com uma progressiva diminuição da eficiência de fluorescência. A intensidade de fluorescência das amino coumarinas é somente suprimida pela presença de nanopartículas de prata em solução. / Silver nanoparticles were synthesized by chemical reduction of silver ions by sodium borohydride in the presence of poly-(N)-vinyl-2-pyrrolidone in solution of short chain alcohols. The nanoparticles are stable in 2-propanol, and the average diameter of the Ag colloid obtained in this solvent is about 6 nm. The photophysical properties of acridinium and coumarin dyes in 2-propanol are affected by the presence of silver nanoparticles. The interaction of silver nanoparticles with acridinium derivative leads to a spectral change of its intramolecular charge transfer (ICT) absorption band. The dye emission increases suddenly with the initial addition of the Ag metal nanoparticles, but at a high concentration of the colloid, static fluorescence quenching occurs with a progressive decrease of the fluorescence efficiency. Amino coumarin fluorescence is only quenched by the silver nanoparticles in solution in the concentration range used.

corantes

dyes

fluorescence

fluorescência

ICT

nanopartículas de prata

plasmon resonance

ressonância de plasmon

silver nanoparticles