Capillary Electrophoresis for Separation of Biomolecules and Viruses

Gargaun, Ana

January 2016

This thesis examines the use of capillary electrophoresis for the study of several biomolecules and their interactions and viruses. The first two experimental chapters focus on its utility for thermodynamic and kinetic analysis of molecules. Chapter one focuses on the use of non-equilibrium capillary electrophoresis of equilibrium mixtures (NECEEM), to calculate the dissociation constant for the interaction between double stranded microRNA-122 and protein p19. NECEEM was used to calculate the rate constants (koff = 0.059 ± 0.013 s-1, kon = 0.0022 ± 0.0008 s-1M-1) and the dissociation constant between miR-122 and wild type p19 (Kd = 27 ± 9 nM). A new method was developed to calculate the rate constant koff, by using multiple electric fields; which resulted in a koff value of 0.072 ± 0.022 s-1. In chapter two, the dissociation constant, Kd, was determined between HIV trans-activation response element and nuclear protein TOE1. It was demonstrated that TOE1, more specifically peptides ER19 and ED35, were binding to TAR with Kd values of 4.08 ± 0.19 µM for ER19 and 7.43 ± 1.60 µM for ED35. The discovery of the peptides’ inhibitory action of viral replication at the transcription level is a significant step towards further elucidating mechanisms for host response to HIV-1 infection. The third chapter focuses on the use of capillary electrophoresis for studying vesicular stomatitis virus (VSV) and vaccinia virus (VV). A new method was developed for quantification of VSV, using dithiothreitol. Furthermore, CE was used to study the preservation of VSV by a previously selected aptamer construct (quadramer) during freeze-thaw cycles. It was found that the infectivity of quadramer and aptamer pool-protected virus was higher than pure virus after 60 freeze−thaw cycles. It was also found that adding quadramers to the virus without freezing (cycle 0) increased the virus infectivity by 30%. We also investigated the potency of a carbohydrate-based ice recrystallization inhibitor, N-octyl-D-gluconamide (NOGlc) for its ability to eliminate the cold chain and stabilize the potency of VV. Viral potency after storage at room temperature demonstrated that NOGlc conserved the infectivity of VV, during 40 days.

capillary electrophoresis

virus

biomolecular interactions

A microscopic quantum electrodynamical theory of novel nonlinear optical processes

Allcock, Philip

January 1996

No description available.

530.1

Dynamic Complexation-Capillary Electrophoresis: An Integrative Biophysical Tool For Thermodynamic Analysis Of Biomolecular Interactions

Seguí-Lines, Giselle

12 1900

<p>Capillary electrophoresis is a high resolution microseparation technique that is increasingly being recognized as a physical tool to characterize biomolecular interactions, where dynamic complexation of analytes with discrete additives is used to resolve complex mixtures of solutes, including enantiomers. Despite the wide interest in developing high-throughput screening platforms for drug discovery or disease prognosis, little emphasis has been placed on enhancing "pre-analysis steps" that are often the most crucial component determining the overall performance of a method. Off-line sample pretreatment protocols for complex biological samples are often time-consuming and not amenable for automation. The major goal of this thesis is the development of a single-step analytical platform by CE for targeted metabolites that integrate several different sample pretreatment processes during separation, which can also be used to characterize the thermodynamic parameters associated with covalent and non-covalent interactions. Two distinct projects in this thesis have been examined involving boronic acid-polyol and protein-cyclic nucleotide interactions that illustrate the concept of integrating sample pretreatment with chemical analysis based on dynamic complexation-capillary electrophoresis.</p> <p>The first project consists of a new strategy for enhancing target selectivity when using 3-nitrophenylboronic acid as an electrokinetic probe in dynamic complexation-capillary electrophoresis. The differential migration of ternary boronate ester complexes permits the selective analysis of micromolar levels of UV-transparent polyol stereoisomers in urine samples that is applicable to single-step screening of in-born errors of sugar metabolism, such as galactosemia. In the second project, the impact of ligand binding on protein stability is assessed by dynamic ligand exchangeaffinity capillary electrophoresis with laser-induced native fluorescence detection. This is a convenient yet rapid format for comparative thermodynamic studies of a regulatory subunit of protein kinase involving different cyclic nucleotide analogues without off-line sample pretreatment, since ligand exchange and protein unfolding processes are integrated incapillary during electromigration.</p> / Thesis / Master of Science (MSc)

Interaction Characteristics of Viral Protease Targets and Inhibitors : Perspectives for drug discovery and development of model systems

Shuman, Cynthia F

January 2003

Viral proteases are important targets for anti-viral drugs. Discovery of protease inhibitors as anti-viral drugs is aided by an understanding of the interactions between viral protease and inhibitors. This thesis addresses the characterization of protease-inhibitor interactions for application to drug discovery and model system development. The choice of a relevant target is essential to molecular interaction studies. Therefore, full-length NS3 protein of hepatitis C virus (HCV) was obtained, providing a more relevant target and a better model for the development of HCV protease inhibitors. In addition, resistance to anti-viral drugs, a serious problem in the treatment of AIDS, prompted the investigation of resistant variants of human immunodeficiency virus (HIV) protease. Drug resistance was initially explored by characterization of the interactions between a series of closely related inhibitors and resistant variants of HIV protease, using an inhibition assay to determine the inhibition dissociation constants (Ki). The relationship between structure, activity and resistance profiles was not clarified, indicating that the effect of structural changes in the inhibitors and the protease are not predictable and must be analyzed case wise. It was proposed that additional kinetic characterization of the interactions was required and a biosensor-based method allowing for determination of affinity, KD, and interaction rate constants, kon and koff, was adopted. The increased physiological relevance of this method was confirmed, and the affinity data have better correlation with cell culture data. In addition, interactions between clinical inhibitors of HIV protease and enzyme variants indicate that increased dissociation rates (koff) are associated with the development of resistance. Thermodynamic characterization of the interactions between HIV-1 protease and clinically relevant inhibitors revealed distinct energetic characteristics for inhibitors. The resolution of the energetics of association and dissociation identified an inhibitor with unique interaction characteristics and confirmed the validity of using this method for further characterization of molecular interactions. This work resulted in the development of model systems for the analysis of kinetics, resistance and thermodynamic characteristics of protein-inhibitor interactions. The results give increased understanding of the biomolecular interactions and can be applied to drug discovery.

Biochemistry

viral proteases

biomolecular interactions

kinetics

thermodynamics

biosensors

drug discovery

Biokemi

Biochemistry and Molecular Biology

Biokemi och molekylärbiologi

Aplicação de Monte Carlo para a geração de ensembles e análise termodinâmica da interação biomolecular / Monte Carlo applications for creation of new ensembles and thermodynamic analysis of the biomolecular interaction

Cunha, João Victor de Souza

19 August 2016

As interações moleculares, em especial as de caráter não-covalente, são processos-chave em vários aspectos da biologia celular e molecular, desde a comunicação entre as células ou da velocidade e especificidade das reações enzimáticas. Portanto, há a necessidade de estudar e criar métodos preditivos para calcular a afinidade entre moléculas nos processos de interação, os quais encontram uma gama de aplicações, incluindo a descoberta de novos fármacos. No geral, entre esses valores de afinidade, o mais importante é a energia livre de ligação, que normalmente é determinada por modos computacionalmente rápidos, porém sem uma forte base teórica, ou por cálculos muito complexos, utilizando dinâmica molecular, onde mesmo com um grande poder de determinação da afinidade, é muito custoso computacionalmente. O objetivo deste trabalho é avaliar um modelo menos custoso computacionalmente e que promova um aprofundamento na avaliação de resultados obtidos a partir de simulações de docking molecular. Para esta finalidade, o método de Monte Carlo é empregado para a amostragem de orientações e conformações do ligante do sítio ativo macromolecular. A avaliação desta metodologia demonstrou que é possível calcular grandezas entrópicas e entálpicas e analisar a capacidade interativa entre complexos proteína-ligante de forma satisfatória para o complexo lisozima do bacteriófago T4. / The molecular interactions, especially the ones with a non-covalent nature, are key processes in general aspects of cellular and molecular biology, including cellular communication and velocity and specificity of enzymatic reactions. So, there is a strong need for studies and development of methods for the calculation of the affinity on interaction processes, since these have a wide range of applications like rational drug design. The free energy of binding is the most important measure among the affinity measurements. It can be calculated by quick computational means, but lacking on strong theoretical basis or by complex calculations using molecular dynamics, where one can compute accurate results but at the price of an increased computer power. The aim of this project is to evaluate a computationally inexpensive model which can improve the results from molecular docking simulations. For this end, the Monte Carlo method is implemented to sample different ligand configurations inside the macromolecular binding site. The evaluation of this methodology showed that is possible to calculate entropy and enthalpy, along analyzing the interactive capacity between receptor-ligands complexes in a satisfactory way for the bacteriophage T4.

Biomolecular interactions

Energia livre

Free energy

Interações biomoleculares

Monte Carlo metropolis

Monte Carlo metropolis

Aplicação de Monte Carlo para a geração de ensembles e análise termodinâmica da interação biomolecular / Monte Carlo applications for creation of new ensembles and thermodynamic analysis of the biomolecular interaction

João Victor de Souza Cunha

19 August 2016

As interações moleculares, em especial as de caráter não-covalente, são processos-chave em vários aspectos da biologia celular e molecular, desde a comunicação entre as células ou da velocidade e especificidade das reações enzimáticas. Portanto, há a necessidade de estudar e criar métodos preditivos para calcular a afinidade entre moléculas nos processos de interação, os quais encontram uma gama de aplicações, incluindo a descoberta de novos fármacos. No geral, entre esses valores de afinidade, o mais importante é a energia livre de ligação, que normalmente é determinada por modos computacionalmente rápidos, porém sem uma forte base teórica, ou por cálculos muito complexos, utilizando dinâmica molecular, onde mesmo com um grande poder de determinação da afinidade, é muito custoso computacionalmente. O objetivo deste trabalho é avaliar um modelo menos custoso computacionalmente e que promova um aprofundamento na avaliação de resultados obtidos a partir de simulações de docking molecular. Para esta finalidade, o método de Monte Carlo é empregado para a amostragem de orientações e conformações do ligante do sítio ativo macromolecular. A avaliação desta metodologia demonstrou que é possível calcular grandezas entrópicas e entálpicas e analisar a capacidade interativa entre complexos proteína-ligante de forma satisfatória para o complexo lisozima do bacteriófago T4. / The molecular interactions, especially the ones with a non-covalent nature, are key processes in general aspects of cellular and molecular biology, including cellular communication and velocity and specificity of enzymatic reactions. So, there is a strong need for studies and development of methods for the calculation of the affinity on interaction processes, since these have a wide range of applications like rational drug design. The free energy of binding is the most important measure among the affinity measurements. It can be calculated by quick computational means, but lacking on strong theoretical basis or by complex calculations using molecular dynamics, where one can compute accurate results but at the price of an increased computer power. The aim of this project is to evaluate a computationally inexpensive model which can improve the results from molecular docking simulations. For this end, the Monte Carlo method is implemented to sample different ligand configurations inside the macromolecular binding site. The evaluation of this methodology showed that is possible to calculate entropy and enthalpy, along analyzing the interactive capacity between receptor-ligands complexes in a satisfactory way for the bacteriophage T4.

Energia livre

Interações biomoleculares

Monte Carlo metropolis

Biomolecular interactions

Free energy

Monte Carlo metropolis

Multifunkční biomolekulární soubory pro paralelizovanou analýzu biomolekulárních interakcí / Multifunctional biomolecular assemblies for parallelized analysis of biomolecular interactions

Bocková, Markéta

January 2019

Title: Multifunctional biomolecular assemblies for parallelized analysis of biomolecular interactions Author: Markéta Bocková Department / Institute: Institute of Physics, Charles University Supervisor of the doctoral thesis: Prof. Jiří Homola, Ph.D., DSc., Institute of Photonics and Electronics, The Czech Academy of Sciences Abstract: Surface plasmon resonance (SPR) biosensors represent the most advanced optical method for the direct, real-time monitoring of biomolecular interactions without the need for labelling. This doctoral thesis aims to advance the SPR biosensor method and to expand its utility in the investigation of biomolecular interactions. This encompasses activities on two major fronts of SPR biosensor research - immobilization methods and biosensing methodologies. Methods for the immobilization of biomolecules were researched with the aim of enabling the immobilization of a broad range of biomolecules on the SPR biosensor surface in a spatially controlled manner. The development of novel biosensing methodologies was pursued in order to address the current limitations of SPR biosensors associated with non-specific adsorption and limited analyte transport, and thus to improve the accuracy and robustness of SPR biosensor measurements. Finally, advances in the development of immobilization...

Detecção condutométrica sem contato: uma nova ferramenta para monitoramento de interações biomoleculares em microssistemas analíticos / Contactless conductivity detection: a new tool for monitoring biomolecular interactions on analytical microsystems

Coltro, Wendell Karlos Tomazelli

07 November 2008

O trabalho descrito nesta tese mostra a aplicação de um sistema de detecção condutométrica sem contato acoplado capacitivamente (C4D) para monitorar interações biomoleculares em microssistemas analíticos. Inicialmente, o desempenho analítico de microssistemas fabricados em vidro, poli(dimetilsiloxano) (PDMS) e poliéster-toner (PT) foi avaliado de modo a escolher o melhor material (em termos de facilidades de fabricação, custo e repetibilidade) para os ensaios biomoleculares. Dentre os materiais estudados, os dispositivos fabricados em PT mostraram-se mais adequados para testes rápidos, onde a repetibilidade analítica não é o parâmetro mais importante. Os dispositivos fabricados em PDMS e selados contra uma placa de vidro apresentaram os melhores resultados em termos de repetibilidade e o desempenho analítico foi similar aos dispositivos de vidro. Dessa maneira, os dispositivos fabricados em PDMS/vidro foram escolhidos para a demonstração dos objetivos da tese. Por outro lado, os dispositivos fabricados em PT foram explorados para estudar a configuração geométrica do sistema de C4D. A instrumentação para monitoramento dos ensaios de ligação foi composta basicamente de dois sistemas de C4D, um software escrito em LabVIEW e um sistema de bombeamento das soluções. De modo a encontrar a configuração ideal da cela de detecção, geometrias contendo três, quatro e cinco eletrodos foram avaliadas em dispositivos de PT. A configuração ótima foi composta de três eletrodos, espaçados simetricamente. Nesta geometria, um eletrodo é utilizado para aplicar o sinal senoidal de excitação e os outros dois são utilizados para capturar o sinal resultante. As dimensões dos eletrodos (largura e espaçamento entre eles) foram otimizados usando ferramentas quimométricas. O complexo avidina-biotina foi utilizado como modelo de ligação para mostrar a aplicabilidade do sistema proposto. Para os microssistemas biomoleculares, os eletrodos (com geometria otimizada) foram fabricados sobre a superfície de uma placa de vidro por fotolitografia, sputtering e lift-off. Os eletrodos de detecção foram isolados com uma camada de óxido de silício com espessura de 50 nm, depositada pelo processo de deposição química em fase de vapor assistida por plasma. A camada de SiO2 foi modificada quimicamente com solução de 3-amino-propil-trietóxi-silano em etanol. Para imobilização covalente de biotina, uma alíquota de 10 ?L de fotobiotina dissolvida em água (0,1 mg/mL) foi adicionada à superfície e exposta a radiação ultravioleta (365 nm, 10 mW/cm2) durante 15 min. A detecção foi realizada aplicando um sinal senoidal, a partir de um gerador de funções, ao eletrodo de excitação registrando o sinal resultante nos dois eletrodos receptores. Para minimizar a captura de ruído elétrico, os experimentos foram realizados em uma gaiola de Faraday. O controle e a aquisição de dados foi feito mediante um software escrito em LabVIEW monitorando os sensorgramas de condutividade em tempo real. Os canais microfluídicos foram fabricados em PDMS por litografia suave e selados irrevesivelmente contra a placa de vidro contendo os eletrodos isolados e modificados quimicamente. As soluções (tampão e amostra) foram manuseadas com auxílio de uma bomba peristáltica ou duas bombas seringas. Soluções contendo tampão e avidina foram introduzidas nos microcanais e as mudanças de conductividade foram monitoradas em função do tempo. As soluções contendo avidina permaneceram em contato com a superfície modificada até o sinal de condutividade atingir um patamar de equilíbrio. Depois disso, solução tampão foi introduzida no microcanal para remover os analitos adsorvidos à superfície. Duas válvulas solenóides foram utilizadas para permitir um controle automático da distribuição das soluções nos microcanais. O limite de detecção obtido para a interação entre avidina e biotina foi de 75 nmol L-1. / The study reported in this thesis shows the application of a capacitively coupled contactless conductivity detection (C4D) for monitoring biomolecular interactions on analytical microsystems. Initially, the analytical performance of the microsystems fabricated in glass, poly(dimethylsiloxane) (PDMS) and polyester-toner (PT) was investigated in order to choose the best material (in terms of fabrication facilities, costs and repeatability) for the biomolecular assays. Among all substrate materials studied, devices fabricated in PT showed suitability for quick experiments, in which the analytical repeatability is not the most important parameter. The devices fabricated in PDMS and sealed against a glass plate presented the best results in terms of repeatability and the analytical performance was similar to that one of glass devices. For this reason, PDMS/glass devices were chosen for showing the goals of this thesis. On the other hand, PT devices were employed to study the geometrical design of the C4D system. The instrumentation for monitoring binding assays was basically composed of two C4D systems, a software written in LabVIEW and a solution pumping system. In order to find the suitable detection cell configuration for this dual-C4D system, designs containing three, four and five electrodes were evaluated on PT devices. The optimal design was composed of three electrodes symmetrically spaced. In this configuration, one electrode is used for applying an excitation sinusoidal wave and the other two for picking up the resulting signal. The dimensions of the electrodes (width and gap) were optimized by chemometric tools. The avidin-biotin complex was used as a binding model for showing the feasibility of the proposed system. For the biomolecular microsystems, electrodes were fabricated on glass surface using photolithographic, sputtering and lift-off processes. Detection electrodes were insulated with a 50-nm silicon oxide layer deposited by plasmaenhanced chemical vapor deposition. The SiO2 layer was functionalized by immersing the cleaned surface in a 3-aminopropyltriethoxy-silane solution in ethanol for 3 h. For biotinylation of the amino-silane layer, 10 ?L of photobiotin dissolved in deionized water (0.1 mg/mL) was dropped on the modified glass surface and exposed to a 365 nm UV radiation at intensity of 10 mW/cm2 for 15 min. Detection was carried out by passing a sinusoidal excitation signal from the function signal generator to the first electrode and picking up the resulting signal at the two receiver electrodes. To reduce electrical noise pickup, all measurements were carried out in a Faraday cage. The data acquisition was obtained in a software written in LabVIEW and the conductivity sensorgrams were recorded in real-time. The microfluidic network was fabricated in PDMS by soft lithography and irreversibly sealed against the electrodes plate. Solutions were handled into microfluidic channels using a peristaltic pump or two syringe pumps. Buffer and avidin-containing solution was injected into the microchannels and conductivity changes were monitored over time. Avidin solutions were allowed to remain in contact with the surface until a stable conductivity had reached equilibrium. Avidin-free buffer solutions were then injected to rinse off non-specifically bound analytes. Two solenoid valves were used to allow an automatic dispensing of the sample/buffer solution into microchannels. The limit of detection found for avidin-biotin system was 75 nmol L-1.

analytical microsystems

biomolecular interactions

biosensors

biossensores

contactless conductivity detection

detecção condutométrica sem contato

interações biomoleculares

microssistemas analíticos

Detecção condutométrica sem contato: uma nova ferramenta para monitoramento de interações biomoleculares em microssistemas analíticos / Contactless conductivity detection: a new tool for monitoring biomolecular interactions on analytical microsystems

Wendell Karlos Tomazelli Coltro

07 November 2008

O trabalho descrito nesta tese mostra a aplicação de um sistema de detecção condutométrica sem contato acoplado capacitivamente (C4D) para monitorar interações biomoleculares em microssistemas analíticos. Inicialmente, o desempenho analítico de microssistemas fabricados em vidro, poli(dimetilsiloxano) (PDMS) e poliéster-toner (PT) foi avaliado de modo a escolher o melhor material (em termos de facilidades de fabricação, custo e repetibilidade) para os ensaios biomoleculares. Dentre os materiais estudados, os dispositivos fabricados em PT mostraram-se mais adequados para testes rápidos, onde a repetibilidade analítica não é o parâmetro mais importante. Os dispositivos fabricados em PDMS e selados contra uma placa de vidro apresentaram os melhores resultados em termos de repetibilidade e o desempenho analítico foi similar aos dispositivos de vidro. Dessa maneira, os dispositivos fabricados em PDMS/vidro foram escolhidos para a demonstração dos objetivos da tese. Por outro lado, os dispositivos fabricados em PT foram explorados para estudar a configuração geométrica do sistema de C4D. A instrumentação para monitoramento dos ensaios de ligação foi composta basicamente de dois sistemas de C4D, um software escrito em LabVIEW e um sistema de bombeamento das soluções. De modo a encontrar a configuração ideal da cela de detecção, geometrias contendo três, quatro e cinco eletrodos foram avaliadas em dispositivos de PT. A configuração ótima foi composta de três eletrodos, espaçados simetricamente. Nesta geometria, um eletrodo é utilizado para aplicar o sinal senoidal de excitação e os outros dois são utilizados para capturar o sinal resultante. As dimensões dos eletrodos (largura e espaçamento entre eles) foram otimizados usando ferramentas quimométricas. O complexo avidina-biotina foi utilizado como modelo de ligação para mostrar a aplicabilidade do sistema proposto. Para os microssistemas biomoleculares, os eletrodos (com geometria otimizada) foram fabricados sobre a superfície de uma placa de vidro por fotolitografia, sputtering e lift-off. Os eletrodos de detecção foram isolados com uma camada de óxido de silício com espessura de 50 nm, depositada pelo processo de deposição química em fase de vapor assistida por plasma. A camada de SiO2 foi modificada quimicamente com solução de 3-amino-propil-trietóxi-silano em etanol. Para imobilização covalente de biotina, uma alíquota de 10 ?L de fotobiotina dissolvida em água (0,1 mg/mL) foi adicionada à superfície e exposta a radiação ultravioleta (365 nm, 10 mW/cm2) durante 15 min. A detecção foi realizada aplicando um sinal senoidal, a partir de um gerador de funções, ao eletrodo de excitação registrando o sinal resultante nos dois eletrodos receptores. Para minimizar a captura de ruído elétrico, os experimentos foram realizados em uma gaiola de Faraday. O controle e a aquisição de dados foi feito mediante um software escrito em LabVIEW monitorando os sensorgramas de condutividade em tempo real. Os canais microfluídicos foram fabricados em PDMS por litografia suave e selados irrevesivelmente contra a placa de vidro contendo os eletrodos isolados e modificados quimicamente. As soluções (tampão e amostra) foram manuseadas com auxílio de uma bomba peristáltica ou duas bombas seringas. Soluções contendo tampão e avidina foram introduzidas nos microcanais e as mudanças de conductividade foram monitoradas em função do tempo. As soluções contendo avidina permaneceram em contato com a superfície modificada até o sinal de condutividade atingir um patamar de equilíbrio. Depois disso, solução tampão foi introduzida no microcanal para remover os analitos adsorvidos à superfície. Duas válvulas solenóides foram utilizadas para permitir um controle automático da distribuição das soluções nos microcanais. O limite de detecção obtido para a interação entre avidina e biotina foi de 75 nmol L-1. / The study reported in this thesis shows the application of a capacitively coupled contactless conductivity detection (C4D) for monitoring biomolecular interactions on analytical microsystems. Initially, the analytical performance of the microsystems fabricated in glass, poly(dimethylsiloxane) (PDMS) and polyester-toner (PT) was investigated in order to choose the best material (in terms of fabrication facilities, costs and repeatability) for the biomolecular assays. Among all substrate materials studied, devices fabricated in PT showed suitability for quick experiments, in which the analytical repeatability is not the most important parameter. The devices fabricated in PDMS and sealed against a glass plate presented the best results in terms of repeatability and the analytical performance was similar to that one of glass devices. For this reason, PDMS/glass devices were chosen for showing the goals of this thesis. On the other hand, PT devices were employed to study the geometrical design of the C4D system. The instrumentation for monitoring binding assays was basically composed of two C4D systems, a software written in LabVIEW and a solution pumping system. In order to find the suitable detection cell configuration for this dual-C4D system, designs containing three, four and five electrodes were evaluated on PT devices. The optimal design was composed of three electrodes symmetrically spaced. In this configuration, one electrode is used for applying an excitation sinusoidal wave and the other two for picking up the resulting signal. The dimensions of the electrodes (width and gap) were optimized by chemometric tools. The avidin-biotin complex was used as a binding model for showing the feasibility of the proposed system. For the biomolecular microsystems, electrodes were fabricated on glass surface using photolithographic, sputtering and lift-off processes. Detection electrodes were insulated with a 50-nm silicon oxide layer deposited by plasmaenhanced chemical vapor deposition. The SiO2 layer was functionalized by immersing the cleaned surface in a 3-aminopropyltriethoxy-silane solution in ethanol for 3 h. For biotinylation of the amino-silane layer, 10 ?L of photobiotin dissolved in deionized water (0.1 mg/mL) was dropped on the modified glass surface and exposed to a 365 nm UV radiation at intensity of 10 mW/cm2 for 15 min. Detection was carried out by passing a sinusoidal excitation signal from the function signal generator to the first electrode and picking up the resulting signal at the two receiver electrodes. To reduce electrical noise pickup, all measurements were carried out in a Faraday cage. The data acquisition was obtained in a software written in LabVIEW and the conductivity sensorgrams were recorded in real-time. The microfluidic network was fabricated in PDMS by soft lithography and irreversibly sealed against the electrodes plate. Solutions were handled into microfluidic channels using a peristaltic pump or two syringe pumps. Buffer and avidin-containing solution was injected into the microchannels and conductivity changes were monitored over time. Avidin solutions were allowed to remain in contact with the surface until a stable conductivity had reached equilibrium. Avidin-free buffer solutions were then injected to rinse off non-specifically bound analytes. Two solenoid valves were used to allow an automatic dispensing of the sample/buffer solution into microchannels. The limit of detection found for avidin-biotin system was 75 nmol L-1.

biossensores

detecção condutométrica sem contato

interações biomoleculares

microssistemas analíticos

analytical microsystems

biomolecular interactions

biosensors

contactless conductivity detection

Développement d'un instrument plasmonique bimodal couplant SPRI et SERS pour la détection et l'identification de molécules biologiques / Development of a bimodal plasmonic instrument coupling SPRI and SERS for the detection and identification of biological molecules

Olivéro, Aurore

16 December 2016

L’imagerie par Résonance des Plasmons de Surface (SPRI) est une technique d’analyse d’interactions moléculaires présentant de nombreux avantages. Elle peut être appliquée en temps réel et sans marquage, pour étudier un grand nombre d’interactions simultanément sur un même échantillon. La transduction d’un événement d‘interaction entre deux molécules complémentaires en un signal optique, repose sur la perturbation de l’onde plasmonique évanescente créée à la surface d’un film métallique mince.Toutefois, bien que la mesure SPR soit directe et sans marquage, sa spécificité repose entièrement sur celle des molécules sondes déposées à la surface de la puce et donc sur la chimie ayant servi à les immobiliser. Cette limitation devient problématique pour adresser les grands enjeux de santé actuels, liés à la détection de molécules à l’état de traces. En particulier, de nouveaux systèmes d’analyse plus sensibles sont requis pour pouvoir diagnostiquer le cancer au plus tôt, ou encore détecter la présence de contaminants agro-alimentaires en faible concentration.Dans cette perspective d’amélioration de la spécificité de détection, ce travail porte sur la mise au point d’un instrument bimodal couplant la SPRI, capable de quantifier la capture de molécules cibles, à la Spectrométrie Raman Exaltée de Surface (SERS), qui permet d’identifier la nature des molécules capturées en déterminant leur « empreinte » moléculaire. Cette thèse s’inscrit dans un projet ANR regroupant un consortium de partenaires académiques et un industriel.Ce document se concentre sur le développement de l’instrument optique combinant les deux systèmes de détection en un seul prototype. La mesure SPRI est réalisée en configuration Kretschmann, tandis que l’analyse SERS s’effectue par le dessus, en milieu liquide, à travers un hublot. Ces deux mesures simultanées sont rendues possibles grâce à la mise au point d’un substrat métallique nanostructuré. Une caractérisation détaillée du système optique est tout d’abord présentée, puis de premiers résultats de validation de la mesure bimodale sur un cas modèle d’interaction biomoléculaire ADN sont démontrés. Ces expériences prometteuses confirment le fonctionnement de l’instrument bimodal dans la perspective d’applications d’intérêt biologique. / Surface Plasmon Resonance Imaging (SPRI) is a powerful technique to study molecular interactions providing a real time, label free and high throughput analysis. The transduction of an interaction between complementary molecules into an optical signal is based on the perturbation of a plasmonic evanescent wave supported by a thin metallic film.However, despite its direct and label free assets, the specificity of SPR measurements is only guaranteed by the probe molecules grafted on the metallic surface and therefore by the quality of the surface chemistry. This limitation becomes an issue when addressing major health concerns relying on the detection of trace molecules. In particular, new systems are required to help early diagnosis and the control of food contaminants.In view of improving measurement’s specificity, this work reports the development of a bimodal instrument coupling SPRI, allowing the quantification of captured molecules, with Surface Enhanced Raman Spectroscopy (SERS), adding the precise identification of the molecules by measuring their spectroscopic fingerprint. This PhD is part of an ANR project bringing together academic and industrial partners.This manuscript focuses on the development of the optical instrument combining the two detection systems in a unique prototype. SPRI measurements are performed in the Kretschmann configuration while SERS analysis is implemented from the top, in solution, through a glass window. Nanostructured substrates have been designed and realized to allow the simultaneous experiment.The optical system is described, characterized and validated on the model case of a DNA hybridization. These first results prove the capabilities of the bimodal instrument in the perspective of more complex biological applications.

Instrumentation optique

Plasmonique

SPRI

SERS

Biopuce nanostructurée

Interactions biomoléculaires

Optical instrumentation

Plasmonics

SPRI

SERS

Nanostructured biochip

Biomolecular interactions

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