Higher Order Electrokinetic Effects for Applied Biological Analytics

January 2018

abstract: Microfluidic systems have gained popularity in the last two decades for their potential applications in manipulating micro- and nano- particulates of interest. Several different microfluidics devices have been built capable of rapidly probing, sorting, and trapping analytes of interest. Microfluidics can be combined with separation science to address challenges of obtaining a concentrated and pure distinct analyte from mixtures of increasingly similar entities. Many of these techniques have been developed to assess biological analytes of interest; one of which is dielectrophoresis (DEP), a force which acts on polarizable analytes in the presence of a non-uniform electric fields. This method can achieve high resolution separations with the unique attribute of concentrating, rather than diluting, analytes upon separation. Studies utilizing DEP have manipulated a wide range of analytes including various cell types, proteins, DNA, and viruses. These analytes range from approximately 50 nm to 1 µm in size. Many of the currently-utilized techniques for assessing these analytes are time intensive, cost prohibitive, and require specialized equipment and technical skills. The work presented in this dissertation focuses on developing and utilizing insulator-based dielectrophoresis (iDEP) to probe a wide range of analytes; where the intrinsic properties of an analyte will determine its behavior in a microchannel. This is based on the analyte’s interactions with the electrokinetic and dielectrophoretic forces present. Novel applications of this technique to probe the biophysical difference(s) between serovars of the foodborne pathogen, Listeria monocytogenes, and surface modified Escherichia coli, are investigated. Both of these applications demonstrate the capabilities of iDEP to achieve high resolution separations and probe slight changes in the biophysical properties of an analyte of interest. To improve upon existing iDEP strategies a novel insulator design which streamlines analytes in an iDEP device while still achieving the desirable forces for separation is developed, fabricated, and tested. Finally, pioneering work to develop an iDEP device capable of manipulating larger analytes, which range in size 10-250 µm, is presented. / Dissertation/Thesis / Doctoral Dissertation Chemistry 2018

Chemistry

Bioanalytics

Dielectrophoresis

Electrokinetics

Microfluidics

Manufacturing of human mesenchymal stem cells : the analytical challenges

Neale-Edwards, Emma C.

January 2018

It has been repeatedly proven that cell therapies can address many current unmet clinical treatment needs and also improve on current treatment options for various diseases, from neurological disorders to bone repair (Rosset et al. 2014; Corey et al. 2017). Though the potential of cell therapies has been demonstrated at a relatively small scale, the realisation of bringing cell based treatments to a larger market is hindered by the complexity of the product along with safety concerned and high production cost. Safety concerns can be informed with more in-depth analytical analysis of the product, however this in turn increase the costs involved in producing a cell therapy (Davie et al. 2012). Consequently the cost of analytical techniques also needs to be reduced, to address this need the area of microfluidic based bioanalytics holds much promise (Titmarsh et al. 2014). The culturing of human mesenchymal stem cells (hMSC) was used as a proof of concept model to demonstrate where improved bioanalytical and bioassay methods could be utilised in the production of cell therapies. Cells from four donors were cultured under three different oxygen environments and the conditioned medium assessed for pro-angiogenic capabilities using a tube formation bioassay and a proportion of the cytokine secretome profile measured using Luminex technology. Thorough secretome analysis it was shown that predicting cytokine levels based solely on the donor was not possible as the handling of the cells also had an influence on the secretome profile. The donor expression profiles did not behave in the same manner across all oxygen environments, for example in some donors IL-8 levels increased per cell at lower oxygen where as other donors showed a decrease per cell. While the tube formation assay showed some differences between donors in pro-angiogenic capabilities it also highlights the challenges with interpreting large data sets. The feasibility of using a microcapillary film (MCF) based enzyme-linked immunosorbent assay (ELISA) to detected two relevant cytokines, IL-8 and hepatocyte growth factor (HGF) was investigated. Following on from this work the development of a combined MCF ELISA assay with hMSC cell culture to produce a fully closed cell screening system was initiated. It was shown that it was feasible to measure IL-8 and HGF using the MCF ELISA platform but further work would need to be done to make the system more compatible with the manufacturing environment. In order to adapt the MCF to also be an hMSC culture platform the first challenge was to functionalise the Fluorinated Ethylene Propylene (FEP) surface of the MCF. It was concluded that a poly (vinyl- alcohol) (PVA) and gelatin mixture produced a homogenous coating to which a consistent level of hMSC would attach. This work was carried out on a flat surface; therefore steps were taken to adapt this knowledge into the MCF, while there was evidence of hMSCs present inside the MCF more work will need to be done to bring this concept to an established platform.

Síntese e modificação de nanomateriais visando o desenvolvimento de sensores / Synthesis and modification of nanomaterials for sensors development

Miranda, Barbara Santos de, 1984-

06 October 2013

Orientador: Lauro Tatsuo Kubota / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Química / Made available in DSpace on 2018-08-23T23:55:15Z (GMT). No. of bitstreams: 1 Miranda_BarbaraSantosde_D.pdf: 3761472 bytes, checksum: d04db9862f7022a5bea49d756efbfdbc (MD5) Previous issue date: 2013 / Resumo: Este trabalho apresenta o desenvolvimento de dois sensores distintos que através da aplicação de nanomateriais em seus sistemas apresentam uma melhora no desempenho. Com o objetivo de estabilizar a fase alfa do hidróxido de níquel, foi proposta uma nova síntese que resultou em um novo material de hidróxido de níquel e nanopartículas de ouro. O do hidróxido de níquel se apresentou com a estrutura alfa desejada, a estrutura e morfologia das nanopartículas de ouro foram preservadas. O material híbrido se apresenta nanoestruturado e sem separação de fases. Sugere-se que este novo material seja formado como um nanocompósito onde as nanopartículas de ouro formam a matriz e o hidróxido de níquel recobre a superfície. A estabilidade do novo material é bem superior que a do hidróxido de níquel puro, quedas de corrente após 50 ciclos consecutivos de 6% contra 50% respectivamente. A atividade eletrocatalítica deste novo nanomaterial foi investigada frente à glicose e a constante eletrocatalítica obtida para o nanocompósito foi cerca de 7 vezes maior que para o hidróxido de níquel puro. A sensibilidade do eletrodo modificado com a-Ni(OH)2/AuNP se manteve similar aos da literatura. O segundo sensor estudado foi a aplicação de nanopartículas fluorescentes como marcadores do imunosensor para a detecção precoce do esporo do fungo da ferrugem asiática da soja. As nanopartículas fluorescentes permitiram alcancar um baixo limite de detecção, 2.2 ng/mL, o menor encontrado na literatura. Além disso, foi investigado outros parâmetros para o desenvolvimento de um dispositivo point-of-care, como o melhor substrato para reter o analito, a membrana de nitrocelulose, se apresentou com as melhores propriedades frente as alternativas. Ainda mais, o dispositivo foi construido para que possa ser utilizado por pessoas não treinadas no campo, em um tempo de análise menor que ELISA e PCR, sem o uso de equipamento caros e complicados, usando somente uma lâmpada de UV simples como fonte de excitação e a visualização do sinal a olho nu com um limite de detecção de apenas 300 esporos, o que e ainda dez vezes mais baixo que o atual teste comercial. / Abstract: This work presents the development of two distinct sensors that have shown great improvements in their performance trough nanoparticle application in their systems. The first study aims to stabilize the nickel hydroxide alpha structure for future carbohydrate detection. We proposed a new synthesis, which resulted in a nickel hydroxide and gold nanoparticle hybrid material. The new material has the expected nickel hydroxide alpha structure, maintains gold nanoparticle¿s structure and morphology and allows a simple electrode modification. We suggest that the new material is a nanocomposite where gold nanoparticles are the matrix while the nickel hydroxide cover the surface. The new material has higher stability properties than the pure nickel hydroxide, after 50 cycles the current decreased 6 and 50% respectively. In addition, an improvement was observed in the catalytic constant, approximately 7 times bigger than plain nickel hydroxide. Although the new material showed these good improvements, the electrode sensitivity did not differ from other studies in the literature. The second study presented comprehends the application of fluorescent nanoparticles as markers of an immunosensor for early diagnosis of Asian soybean rust spore. The use of these nanoparticles resulted in a very low limit detection sensor, 2.2 ng/mL, the lowest ever found in the literature. Moreover, others parameters were investigated in order to develop a point-of-care device, as the substrate to retain the analyte for the assay. Furthermore, the device was built in order to be used by the farmer himself, in loco, fast, without expensive equipment, a UV lamp as an excitation source and the signal is visible to naked eye. The visual detection limit is around 300 spores, which is tenfold lower than the available commercial kit. / Doutorado / Físico-Química / Doutora em Ciências

Nanomateriais

Biosensores

Hidróxido de níquel

Bioanalítica

Nanomaterials

Biosensor

Nickel hydroxide

Point-of-care

Bioanalytics

REMOTE AMBIENT AEROSOLS FOUND IN THE SOUTHERN GREAT PLAINS AND EASTERN NORTH ATLANTIC: A COMPREHENSIVE ANALYSIS OF OPTICAL BEHAVIOR AND AEROSOL-CLOUD INTERACTION

Bonanno, Daniel J.

01 January 2023

The data presented in this thesis showcases the investigation of various aerosol types and the role they play in the hydrological system and global climate models. Long-range transport aerosols, including atmospheric soot, mineral dust, and ammonium sulfate, in addition to near-site sources such as secondary organic aerosols (SOAs), sea spray, aliphatic hydrocarbons, and other organics, are prioritized in the analysis of two separate remote field studies. Each of these campaigns revealed the juxtaposition between dry summer months and wet winter months, and the connection between seasonal variability and sample collection. Two spectromicroscopic techniques were used to elucidate chemical composition, morphology and size of particles. Quantification of C, N, and O was performed using scanning transmission X-ray microscopy coupled with near edge X-ray fine structure (STXM/NEXAFS) and used to generate organic volume fractions and to provide mixing state parameters and diversity measurements. This was followed by utilizing scanning electron microscopy in the energy dispersive X-ray (SEM/EDX) mode on the same particle sets to characterize 11 heavier elements: Na, Mg, P, S, Cl, K, Ca, Mn, Fe, Ni, and Zn.

Nanoscience

Physical chemistry

Environmental science

Aerosols

Bioanalytics

Climate

Nanoparticle

Optical

Speciation

Chemistry

Environmental Sciences

Physical Sciences and Mathematics

Untersuchungen zur effizienten Herstellung von Substraten für die oberflächenverstärkte Infrarotspektroskopie

Katzmann, Julia

12 January 2016

Metallische Nanostäbe mit einer Länge im Mikrometer-Bereich wirken als Antennen für infrarotes Licht: Indem unter Lichteinfall eine kollektive Schwingung der Leitungselektronen angeregt wird (ein sogenanntes Plasmon), wird das elektrische Feld an den Stabenden stark konzentriert. Besonders starke Feldkonzentrationen treten auf, wenn zwei Antennenarme durch eine schmale Lücke getrennt sind (Dimerantenne). Somit können die Antennen Licht-Materie-Wechselwirkungen -- wie beispielsweise die Absorption infraroten Lichtes von Molekülen -- verstärken. Dieses als oberflächenverstärkte Infrarotabsorption (SEIRA) bezeichnete Phänomen ist sehr nützlich, um Signale in der Infrarotspektroskopie zu verstärken. Diese Arbeit widmet sich der effizienten Herstellung von metallischen Nanostäben für SEIRA. Im ersten Schwerpunktthema werden Dimerantennen, die per Elektronenstrahllithographie (EBL) hergestellt wurden und eine auflösungsbegrenzte Lücke aufweisen, durch eine photochemische Reduktion von Metallsalzkomplexen nachträglich vergrößert. Dadurch verringert sich die Lückengröße und erreicht Werte deutlich unter der Auflösungsgrenze der EBL. Es wird gezeigt, dass diese photochemische Abscheidung die IR-optischen Eigenschaften der Dimerantennen durch plasmonische Kopplung entscheidend verändert. Zudem steigt die Infrarotabsorption von in der Lücke befindlichen Molekülen mit sinkender Lückengröße. Im zweiten Schwerpunktthema liegt der Fokus auf der günstigen Fabrikation einer Vielzahl von IR-Antennen in einem parallelen Prozess. Dabei werden poröse Template aus anodisiertem Aluminiumoxid (AAO) als Negativ für die herzustellenden Metallstäbe benutzt. Es wird zuerst gezeigt, dass die Poren des Templates durch die photochemische Reduktion von Goldsalzkomplexen befüllt werden können. Für eine gezielte Einstellung der Stäbchenlänge und die Generierung einer nanoskaligen Lücke wird weiterhin die elektrochemische Befüllung der Template untersucht. Die hiermit hergestellten IR-Antennen werden vereinzelt, auf ein Substrat aufgetragen und hinsichtlich ihrer Struktur und ihrer IR-optischen Eigenschaften charakterisiert. Die Vor- und Nachteile der untersuchten Herstellungsmethoden und ihre Eignung für die Fabrikation von IR-Antennen für SEIRA werden diskutiert. / Metallic nanorods with lengths in the micrometer regime act as antennas for infrared light: As incident light excites a collective oscillation of the conduction electrons (a so-called plasmon), the electric field is concentrated at the rod ends. In case two antenna arms are separated by a small gap (dimer antenna), a particularly high field concentration occurs. Thereby the antennas are capable of enhancing light-matter-interaction -- for example the absorption of infrared light by molecules. This phenomenon, termed as surface enhanced infrared absorption (SEIRA), is very useful to enhance absorption signals in infrared spectroscopy. This thesis attends to the efficient fabrication of metallic nanorods for SEIRA. The first topic in focus is the manipulation of dimer antennas fabricated by electron beam lithography (EBL), featuring a gap of resolution-limited size. By applying a photochemical reduction of metal salt complexes in solution, the dimer arms are subsequently enlarged. Thereby the gap size is reduced and reaches values clearly below the resolution limit of EBL. It is shown that the IR optical properties of dimer antennas dramatically change during photochemical metal deposition. This is due to plasmonic coupling. Additionally, the absorption of infrared light by molecules located in the gap increases with decreasing gap size. The second topic in focus is the cheap fabrication of a large number of IR antennas in a parallel process. Here, porous templates of anodized aluminum oxide (AAO) are used as a negative for the metal rods to be fabricated. Firstly, it is shown that the pores of the template can be filled by photochemical reduction of gold salt complexes. For a targeted adjustment of the rod lengths and the generation of a nanoscale gap, secondly, the electrochemical filling of acsu AAO is investigated. The IR antennas prepared by this method are extracted from the template, transferred to a substrate, and individually characterized in terms of their structure and IR optical properties. Advantages and drawbacks of the fabrication methods investigated in this work as well as their applicability to the fabrication of IR antennas for SEIRA are being discussed.

Spektroskopie

Plasmonik

Plasmon

Antenne

Nanoantenne

Nanofabrikation

Lithographie

Nanotechnologie

Infrarot

Bioanalytik

spectroscopy

plasmonics

plasmon

antenna

nanoantenna

nanofabrication

lithography

nanotechnology

infrared

bioanalytics

ddc:530

rvk:UH 6000

Untersuchungen zur effizienten Herstellung von Substraten für die oberflächenverstärkte Infrarotspektroskopie

Katzmann, Julia

12 January 2016

Metallische Nanostäbe mit einer Länge im Mikrometer-Bereich wirken als Antennen für infrarotes Licht: Indem unter Lichteinfall eine kollektive Schwingung der Leitungselektronen angeregt wird (ein sogenanntes Plasmon), wird das elektrische Feld an den Stabenden stark konzentriert. Besonders starke Feldkonzentrationen treten auf, wenn zwei Antennenarme durch eine schmale Lücke getrennt sind (Dimerantenne). Somit können die Antennen Licht-Materie-Wechselwirkungen -- wie beispielsweise die Absorption infraroten Lichtes von Molekülen -- verstärken. Dieses als oberflächenverstärkte Infrarotabsorption (SEIRA) bezeichnete Phänomen ist sehr nützlich, um Signale in der Infrarotspektroskopie zu verstärken. Diese Arbeit widmet sich der effizienten Herstellung von metallischen Nanostäben für SEIRA. Im ersten Schwerpunktthema werden Dimerantennen, die per Elektronenstrahllithographie (EBL) hergestellt wurden und eine auflösungsbegrenzte Lücke aufweisen, durch eine photochemische Reduktion von Metallsalzkomplexen nachträglich vergrößert. Dadurch verringert sich die Lückengröße und erreicht Werte deutlich unter der Auflösungsgrenze der EBL. Es wird gezeigt, dass diese photochemische Abscheidung die IR-optischen Eigenschaften der Dimerantennen durch plasmonische Kopplung entscheidend verändert. Zudem steigt die Infrarotabsorption von in der Lücke befindlichen Molekülen mit sinkender Lückengröße. Im zweiten Schwerpunktthema liegt der Fokus auf der günstigen Fabrikation einer Vielzahl von IR-Antennen in einem parallelen Prozess. Dabei werden poröse Template aus anodisiertem Aluminiumoxid (AAO) als Negativ für die herzustellenden Metallstäbe benutzt. Es wird zuerst gezeigt, dass die Poren des Templates durch die photochemische Reduktion von Goldsalzkomplexen befüllt werden können. Für eine gezielte Einstellung der Stäbchenlänge und die Generierung einer nanoskaligen Lücke wird weiterhin die elektrochemische Befüllung der Template untersucht. Die hiermit hergestellten IR-Antennen werden vereinzelt, auf ein Substrat aufgetragen und hinsichtlich ihrer Struktur und ihrer IR-optischen Eigenschaften charakterisiert. Die Vor- und Nachteile der untersuchten Herstellungsmethoden und ihre Eignung für die Fabrikation von IR-Antennen für SEIRA werden diskutiert. / Metallic nanorods with lengths in the micrometer regime act as antennas for infrared light: As incident light excites a collective oscillation of the conduction electrons (a so-called plasmon), the electric field is concentrated at the rod ends. In case two antenna arms are separated by a small gap (dimer antenna), a particularly high field concentration occurs. Thereby the antennas are capable of enhancing light-matter-interaction -- for example the absorption of infrared light by molecules. This phenomenon, termed as surface enhanced infrared absorption (SEIRA), is very useful to enhance absorption signals in infrared spectroscopy. This thesis attends to the efficient fabrication of metallic nanorods for SEIRA. The first topic in focus is the manipulation of dimer antennas fabricated by electron beam lithography (EBL), featuring a gap of resolution-limited size. By applying a photochemical reduction of metal salt complexes in solution, the dimer arms are subsequently enlarged. Thereby the gap size is reduced and reaches values clearly below the resolution limit of EBL. It is shown that the IR optical properties of dimer antennas dramatically change during photochemical metal deposition. This is due to plasmonic coupling. Additionally, the absorption of infrared light by molecules located in the gap increases with decreasing gap size. The second topic in focus is the cheap fabrication of a large number of IR antennas in a parallel process. Here, porous templates of anodized aluminum oxide (AAO) are used as a negative for the metal rods to be fabricated. Firstly, it is shown that the pores of the template can be filled by photochemical reduction of gold salt complexes. For a targeted adjustment of the rod lengths and the generation of a nanoscale gap, secondly, the electrochemical filling of acsu AAO is investigated. The IR antennas prepared by this method are extracted from the template, transferred to a substrate, and individually characterized in terms of their structure and IR optical properties. Advantages and drawbacks of the fabrication methods investigated in this work as well as their applicability to the fabrication of IR antennas for SEIRA are being discussed.

info:eu-repo/classification/ddc/530

ddc:530